Affiliations
System Department Chair of Hospital Medicine, Vice President of Medical Affairs, Ochsner Health System, New Orleans, Louisiana
Given name(s)
Steven B.
Family name
Deitelzweig
Degrees
MD

In reply: VTE prevention in major orthopedic surgery

Article Type
Changed
Thu, 05/17/2018 - 15:07
Display Headline
In reply: VTE prevention in major orthopedic surgery

Editor's Note: This letter concerns an article in a Cleveland Clinic Journal of Medicine supplement (Preventing Venous Thromboembolism Throughout the Continuum of Care) distributed to only a portion of the Journal's regular readership, owing to the terms of the grant supporting the supplement.

In Reply: We appreciate the comments by Drs. Fishmann and Boyd, but we strongly disagree with their suggestion that aspirin monotherapy is an appropriate option for the prevention of venous thromboembolism (VTE) following major orthopedic surgery.

As discussed in our original article,1 multiple large-scale clinical trials in patients undergoing elective hip arthroplasty, knee arthroplasty, or hip fracture surgery have demonstrated the thromboprophylactic efficacy of warfarin, unfractionated heparin, low-molecular-weight heparin (LMWH), fondaparinux, and oral direct thrombin inhibitors. The relative risk reduction with these agents has been greater than 50% in most studies. In contrast, in a large meta-analysis of VTE prophylaxis following total hip replacement, which included data from 56 randomized trials published between 1966 and 1993, aspirin was not beneficial in preventing DVT.14

The largest prospective randomized trial comparing aspirin with placebo for VTE prevention was conducted between 1992 and 1998 among 17,444 patients in five countries.5 It involved 13,356 patients requiring hip fracture surgery and 4,088 patients requiring elective hip arthroplasty. Patients were randomized to receive aspirin 160 mg/day or placebo for 35 days. However, additional forms of VTE prophylaxis were allowed if deemed necessary by the clinician. In fact, 26% of patients received LMWH in addition to aspirin, and dual therapy was probably more common in those patients at highest thromboembolic risk. As such, the 36% relative risk reduction in VTE ascribed to aspirin should be viewed with caution. Further, this is a smaller risk reduction than that observed in trials of other anticoagulant agents.

A large, well-designed, randomized clinical trial comparing aspirin to LMWH or fondaparinux remains to be conducted.

Dr. Fishmann cites a small study of patients undergoing knee arthroplasty who received spinal anesthesia and intermittent calf compression devices.7 In this underpowered study, 275 patients were randomized to receive aspirin 325 mg twice daily or enoxaparin 30 mg twice daily for 3 weeks. The overall DVT rates were 14.1% in the enoxaparin group vs 17.8% in the aspirin group (P = .27).7 Patients who received aspirin had significantly more postoperative drainage than those randomized to enoxaparin. In addition, the protocol for scheduling enoxaparin 48 hours postoperatively is not consistent with recommendations of the American College of Chest Physicians (ACCP) and may have reduced the efficacy of enoxaparin.

The other evidence in support of aspirin cited by Dr. Fishmann includes an editorial,9 an uncontrolled retrospective analysis,8 a single-center retrospective review,10 and a review article.6 Although there is evidence that the use of aspirin is probably associated with a modest reduction in postoperative VTE risk, it has been unequivocally surpassed in efficacy by other anticoagulants.

Both the latest (2004) ACCP guidelines on VTE2 and the 2006 International Consensus Statement on VTE prevention and treatment15 advise against aspirin monotherapy as VTE prophylaxis in any patient groups. It is likely that the upcoming 2008 ACCP guidelines will also advocate against using aspirin as well.

Lastly, the most recent guideline from the American Academy of Orthopaedic Surgeons advocating aspirin as monotherapy11 is based on the assumption that the major important clinical end point in the orthopedic surgery patient is clinical pulmonary embolism, an end point that was not included as a lone primary end point in any of the modern randomized controlled studies in major orthopedic surgery. This represents a flawed logic for the development of evidence-based guideline recommendations, and this recommendation has not been advocated by well-respected bodies such as the ACCP and the international groups that developed the International Consensus Statement. Furthermore, if this practice is going to be advocated by the American Academy of Orthopaedic Surgeons, then large rigorously designed randomized trials must be conducted to compare aspirin to currently available anticoagulants, and the type of joint surgery should be clearly defined.

References
  1. Deitelzweig SB, McKean SC, Amin AN, Brotman DJ, Jaffer AK, Spyropoulos AC. Prevention of venous thromboembolism in the orthopedic surgery patient. Cleve Clin J Med 2008; 75(suppl 3):S27–S36.
  2. Geerts WH, Pineo GF, Heit JA, et al. Prevention of venous thromboembolism: the Seventh ACCP Conference on Antithrombotic and Thrombolytic Therapy. Chest 2004; 126(3 suppl):338S–400S.
  3. Geerts WH, Heit JA, Clagett GP, et al. Prevention of venous thromboembolism. Chest 2001; 119(1 suppl):132S–175S.
  4. Zimlich RH, Fulbright BM, Friedman RJ. Current status of anticoagulation therapy after total hip and total knee arthroplasty. J Am Acad Orthop Surg 1996; 4:54–62.
  5. PEP Trial Collaborative Group. Prevention of pulmonary embolism and deep vein thrombosis with low dose aspirin: Pulmonary Embolism Prevention (PEP) trial. Lancet 2000; 355:1295–1302.
  6. Berend KR, Lombardi AV. Multimodal venous thromboembolic disease prevention for patients undergoing primary or revision total joint arthroplasty: the role of aspirin. Am J Orthop 2006; 35:24–29.
  7. Westrich GH, Bottner F, Windsor RE, Laskin RS, Haas SB, Sculco TP. VenaFlow plus Lovenox vs VenaFlow plus aspirin for thromboembolic disease prophylaxis in total knee arthroplasty. J Arthroplasty 2006; 21(6 suppl 2):139–143.
  8. Lotke PA, Lonner JH. The benefit of aspirin chemoprophylaxis for thromboembolism after total knee arthroplasty. Clin Orthop Relat Res 2006; 452:175–180.
  9. Callaghan JJ, Dorr LD, Engh GA, et al. Prophylaxis for thromboembolic disease: recommendations from the American College of Chest Physicians—are they appropriate for orthopaedic surgery? J Arthroplasty 2005; 20:273–274.
  10. Dorr LD, Gendelman V, Maheshwari AV, Boutary M, Wan Z, Long WT. Multimodal thromboprophylaxis for total hip and knee arthroplasty based on risk assessment. J Bone Joint Surg Am 2007; 89:2648–2657.
  11. American Academy of Orthopaedic Surgeons Clinical Guideline on Prevention of Symptomatic Pulmonary Embolism in Patients Undergoing Total Hip or Knee Arthroplasty: Summary of Recommendations. http://www.aaos.org/Research/guidelines/PE_summary.pdf. Accessed April 16, 2008.
  12. Parvizi J, Ghanem E, Joshi A, Sharkey PF, Hozack WJ, Rothman RH. Does “excessive” anticoagulation predispose to periprosthetic infection? J Arthroplasty 2007; 22(6 suppl 2):24–28.
  13. Bern M, Deshmukh RV, Nelson R, et al. Low-dose warfarin coupled with lower leg compression is effective prophylaxis against thromboembolic disease after hip arthroplasty. J Arthroplasty 2007; 22:644–650.
  14. Imperiale TF, Speroff T. A meta-analysis of methods to prevent venous thromboembolism following total hip replacement. JAMA 1994; 271:1780–1785.
  15. Cardiovascular Disease Educational and Research Trust; Cyprus Cardiovascular Disease Educational and Research Trust; European Venous Forum; International Surgical Thrombosis Forum; International Union of Angiology; Union Internationale de Phlébologie. Prevention and treatment of venous thromboembolism. International Consensus Statement (guidelines according to scientific evidence). Int Angiol 2006; 25:101–161.
Article PDF
Author and Disclosure Information

Steven B. Deitelzweig, MD
Ochsner Health System, New Orleans, LA

Alpesh N. Amin, MD
University of California, Irvine

Daniel J. Brotman, MD
Johns Hopkins Hospital, Baltimore, MD

Sylvia C. McKean, MD
Brigham and Women’s Hospital, Boston, MA

Alex C. Spyropoulos, MD
Lovelace Medical Center, Albuquerque, NM

Amir K. Jaffer, MD
University of Miami, Miami, FL

Issue
Cleveland Clinic Journal of Medicine - 75(7)
Publications
Topics
Page Number
471-473
Sections
Author and Disclosure Information

Steven B. Deitelzweig, MD
Ochsner Health System, New Orleans, LA

Alpesh N. Amin, MD
University of California, Irvine

Daniel J. Brotman, MD
Johns Hopkins Hospital, Baltimore, MD

Sylvia C. McKean, MD
Brigham and Women’s Hospital, Boston, MA

Alex C. Spyropoulos, MD
Lovelace Medical Center, Albuquerque, NM

Amir K. Jaffer, MD
University of Miami, Miami, FL

Author and Disclosure Information

Steven B. Deitelzweig, MD
Ochsner Health System, New Orleans, LA

Alpesh N. Amin, MD
University of California, Irvine

Daniel J. Brotman, MD
Johns Hopkins Hospital, Baltimore, MD

Sylvia C. McKean, MD
Brigham and Women’s Hospital, Boston, MA

Alex C. Spyropoulos, MD
Lovelace Medical Center, Albuquerque, NM

Amir K. Jaffer, MD
University of Miami, Miami, FL

Article PDF
Article PDF
Related Articles

Editor's Note: This letter concerns an article in a Cleveland Clinic Journal of Medicine supplement (Preventing Venous Thromboembolism Throughout the Continuum of Care) distributed to only a portion of the Journal's regular readership, owing to the terms of the grant supporting the supplement.

In Reply: We appreciate the comments by Drs. Fishmann and Boyd, but we strongly disagree with their suggestion that aspirin monotherapy is an appropriate option for the prevention of venous thromboembolism (VTE) following major orthopedic surgery.

As discussed in our original article,1 multiple large-scale clinical trials in patients undergoing elective hip arthroplasty, knee arthroplasty, or hip fracture surgery have demonstrated the thromboprophylactic efficacy of warfarin, unfractionated heparin, low-molecular-weight heparin (LMWH), fondaparinux, and oral direct thrombin inhibitors. The relative risk reduction with these agents has been greater than 50% in most studies. In contrast, in a large meta-analysis of VTE prophylaxis following total hip replacement, which included data from 56 randomized trials published between 1966 and 1993, aspirin was not beneficial in preventing DVT.14

The largest prospective randomized trial comparing aspirin with placebo for VTE prevention was conducted between 1992 and 1998 among 17,444 patients in five countries.5 It involved 13,356 patients requiring hip fracture surgery and 4,088 patients requiring elective hip arthroplasty. Patients were randomized to receive aspirin 160 mg/day or placebo for 35 days. However, additional forms of VTE prophylaxis were allowed if deemed necessary by the clinician. In fact, 26% of patients received LMWH in addition to aspirin, and dual therapy was probably more common in those patients at highest thromboembolic risk. As such, the 36% relative risk reduction in VTE ascribed to aspirin should be viewed with caution. Further, this is a smaller risk reduction than that observed in trials of other anticoagulant agents.

A large, well-designed, randomized clinical trial comparing aspirin to LMWH or fondaparinux remains to be conducted.

Dr. Fishmann cites a small study of patients undergoing knee arthroplasty who received spinal anesthesia and intermittent calf compression devices.7 In this underpowered study, 275 patients were randomized to receive aspirin 325 mg twice daily or enoxaparin 30 mg twice daily for 3 weeks. The overall DVT rates were 14.1% in the enoxaparin group vs 17.8% in the aspirin group (P = .27).7 Patients who received aspirin had significantly more postoperative drainage than those randomized to enoxaparin. In addition, the protocol for scheduling enoxaparin 48 hours postoperatively is not consistent with recommendations of the American College of Chest Physicians (ACCP) and may have reduced the efficacy of enoxaparin.

The other evidence in support of aspirin cited by Dr. Fishmann includes an editorial,9 an uncontrolled retrospective analysis,8 a single-center retrospective review,10 and a review article.6 Although there is evidence that the use of aspirin is probably associated with a modest reduction in postoperative VTE risk, it has been unequivocally surpassed in efficacy by other anticoagulants.

Both the latest (2004) ACCP guidelines on VTE2 and the 2006 International Consensus Statement on VTE prevention and treatment15 advise against aspirin monotherapy as VTE prophylaxis in any patient groups. It is likely that the upcoming 2008 ACCP guidelines will also advocate against using aspirin as well.

Lastly, the most recent guideline from the American Academy of Orthopaedic Surgeons advocating aspirin as monotherapy11 is based on the assumption that the major important clinical end point in the orthopedic surgery patient is clinical pulmonary embolism, an end point that was not included as a lone primary end point in any of the modern randomized controlled studies in major orthopedic surgery. This represents a flawed logic for the development of evidence-based guideline recommendations, and this recommendation has not been advocated by well-respected bodies such as the ACCP and the international groups that developed the International Consensus Statement. Furthermore, if this practice is going to be advocated by the American Academy of Orthopaedic Surgeons, then large rigorously designed randomized trials must be conducted to compare aspirin to currently available anticoagulants, and the type of joint surgery should be clearly defined.

Editor's Note: This letter concerns an article in a Cleveland Clinic Journal of Medicine supplement (Preventing Venous Thromboembolism Throughout the Continuum of Care) distributed to only a portion of the Journal's regular readership, owing to the terms of the grant supporting the supplement.

In Reply: We appreciate the comments by Drs. Fishmann and Boyd, but we strongly disagree with their suggestion that aspirin monotherapy is an appropriate option for the prevention of venous thromboembolism (VTE) following major orthopedic surgery.

As discussed in our original article,1 multiple large-scale clinical trials in patients undergoing elective hip arthroplasty, knee arthroplasty, or hip fracture surgery have demonstrated the thromboprophylactic efficacy of warfarin, unfractionated heparin, low-molecular-weight heparin (LMWH), fondaparinux, and oral direct thrombin inhibitors. The relative risk reduction with these agents has been greater than 50% in most studies. In contrast, in a large meta-analysis of VTE prophylaxis following total hip replacement, which included data from 56 randomized trials published between 1966 and 1993, aspirin was not beneficial in preventing DVT.14

The largest prospective randomized trial comparing aspirin with placebo for VTE prevention was conducted between 1992 and 1998 among 17,444 patients in five countries.5 It involved 13,356 patients requiring hip fracture surgery and 4,088 patients requiring elective hip arthroplasty. Patients were randomized to receive aspirin 160 mg/day or placebo for 35 days. However, additional forms of VTE prophylaxis were allowed if deemed necessary by the clinician. In fact, 26% of patients received LMWH in addition to aspirin, and dual therapy was probably more common in those patients at highest thromboembolic risk. As such, the 36% relative risk reduction in VTE ascribed to aspirin should be viewed with caution. Further, this is a smaller risk reduction than that observed in trials of other anticoagulant agents.

A large, well-designed, randomized clinical trial comparing aspirin to LMWH or fondaparinux remains to be conducted.

Dr. Fishmann cites a small study of patients undergoing knee arthroplasty who received spinal anesthesia and intermittent calf compression devices.7 In this underpowered study, 275 patients were randomized to receive aspirin 325 mg twice daily or enoxaparin 30 mg twice daily for 3 weeks. The overall DVT rates were 14.1% in the enoxaparin group vs 17.8% in the aspirin group (P = .27).7 Patients who received aspirin had significantly more postoperative drainage than those randomized to enoxaparin. In addition, the protocol for scheduling enoxaparin 48 hours postoperatively is not consistent with recommendations of the American College of Chest Physicians (ACCP) and may have reduced the efficacy of enoxaparin.

The other evidence in support of aspirin cited by Dr. Fishmann includes an editorial,9 an uncontrolled retrospective analysis,8 a single-center retrospective review,10 and a review article.6 Although there is evidence that the use of aspirin is probably associated with a modest reduction in postoperative VTE risk, it has been unequivocally surpassed in efficacy by other anticoagulants.

Both the latest (2004) ACCP guidelines on VTE2 and the 2006 International Consensus Statement on VTE prevention and treatment15 advise against aspirin monotherapy as VTE prophylaxis in any patient groups. It is likely that the upcoming 2008 ACCP guidelines will also advocate against using aspirin as well.

Lastly, the most recent guideline from the American Academy of Orthopaedic Surgeons advocating aspirin as monotherapy11 is based on the assumption that the major important clinical end point in the orthopedic surgery patient is clinical pulmonary embolism, an end point that was not included as a lone primary end point in any of the modern randomized controlled studies in major orthopedic surgery. This represents a flawed logic for the development of evidence-based guideline recommendations, and this recommendation has not been advocated by well-respected bodies such as the ACCP and the international groups that developed the International Consensus Statement. Furthermore, if this practice is going to be advocated by the American Academy of Orthopaedic Surgeons, then large rigorously designed randomized trials must be conducted to compare aspirin to currently available anticoagulants, and the type of joint surgery should be clearly defined.

References
  1. Deitelzweig SB, McKean SC, Amin AN, Brotman DJ, Jaffer AK, Spyropoulos AC. Prevention of venous thromboembolism in the orthopedic surgery patient. Cleve Clin J Med 2008; 75(suppl 3):S27–S36.
  2. Geerts WH, Pineo GF, Heit JA, et al. Prevention of venous thromboembolism: the Seventh ACCP Conference on Antithrombotic and Thrombolytic Therapy. Chest 2004; 126(3 suppl):338S–400S.
  3. Geerts WH, Heit JA, Clagett GP, et al. Prevention of venous thromboembolism. Chest 2001; 119(1 suppl):132S–175S.
  4. Zimlich RH, Fulbright BM, Friedman RJ. Current status of anticoagulation therapy after total hip and total knee arthroplasty. J Am Acad Orthop Surg 1996; 4:54–62.
  5. PEP Trial Collaborative Group. Prevention of pulmonary embolism and deep vein thrombosis with low dose aspirin: Pulmonary Embolism Prevention (PEP) trial. Lancet 2000; 355:1295–1302.
  6. Berend KR, Lombardi AV. Multimodal venous thromboembolic disease prevention for patients undergoing primary or revision total joint arthroplasty: the role of aspirin. Am J Orthop 2006; 35:24–29.
  7. Westrich GH, Bottner F, Windsor RE, Laskin RS, Haas SB, Sculco TP. VenaFlow plus Lovenox vs VenaFlow plus aspirin for thromboembolic disease prophylaxis in total knee arthroplasty. J Arthroplasty 2006; 21(6 suppl 2):139–143.
  8. Lotke PA, Lonner JH. The benefit of aspirin chemoprophylaxis for thromboembolism after total knee arthroplasty. Clin Orthop Relat Res 2006; 452:175–180.
  9. Callaghan JJ, Dorr LD, Engh GA, et al. Prophylaxis for thromboembolic disease: recommendations from the American College of Chest Physicians—are they appropriate for orthopaedic surgery? J Arthroplasty 2005; 20:273–274.
  10. Dorr LD, Gendelman V, Maheshwari AV, Boutary M, Wan Z, Long WT. Multimodal thromboprophylaxis for total hip and knee arthroplasty based on risk assessment. J Bone Joint Surg Am 2007; 89:2648–2657.
  11. American Academy of Orthopaedic Surgeons Clinical Guideline on Prevention of Symptomatic Pulmonary Embolism in Patients Undergoing Total Hip or Knee Arthroplasty: Summary of Recommendations. http://www.aaos.org/Research/guidelines/PE_summary.pdf. Accessed April 16, 2008.
  12. Parvizi J, Ghanem E, Joshi A, Sharkey PF, Hozack WJ, Rothman RH. Does “excessive” anticoagulation predispose to periprosthetic infection? J Arthroplasty 2007; 22(6 suppl 2):24–28.
  13. Bern M, Deshmukh RV, Nelson R, et al. Low-dose warfarin coupled with lower leg compression is effective prophylaxis against thromboembolic disease after hip arthroplasty. J Arthroplasty 2007; 22:644–650.
  14. Imperiale TF, Speroff T. A meta-analysis of methods to prevent venous thromboembolism following total hip replacement. JAMA 1994; 271:1780–1785.
  15. Cardiovascular Disease Educational and Research Trust; Cyprus Cardiovascular Disease Educational and Research Trust; European Venous Forum; International Surgical Thrombosis Forum; International Union of Angiology; Union Internationale de Phlébologie. Prevention and treatment of venous thromboembolism. International Consensus Statement (guidelines according to scientific evidence). Int Angiol 2006; 25:101–161.
References
  1. Deitelzweig SB, McKean SC, Amin AN, Brotman DJ, Jaffer AK, Spyropoulos AC. Prevention of venous thromboembolism in the orthopedic surgery patient. Cleve Clin J Med 2008; 75(suppl 3):S27–S36.
  2. Geerts WH, Pineo GF, Heit JA, et al. Prevention of venous thromboembolism: the Seventh ACCP Conference on Antithrombotic and Thrombolytic Therapy. Chest 2004; 126(3 suppl):338S–400S.
  3. Geerts WH, Heit JA, Clagett GP, et al. Prevention of venous thromboembolism. Chest 2001; 119(1 suppl):132S–175S.
  4. Zimlich RH, Fulbright BM, Friedman RJ. Current status of anticoagulation therapy after total hip and total knee arthroplasty. J Am Acad Orthop Surg 1996; 4:54–62.
  5. PEP Trial Collaborative Group. Prevention of pulmonary embolism and deep vein thrombosis with low dose aspirin: Pulmonary Embolism Prevention (PEP) trial. Lancet 2000; 355:1295–1302.
  6. Berend KR, Lombardi AV. Multimodal venous thromboembolic disease prevention for patients undergoing primary or revision total joint arthroplasty: the role of aspirin. Am J Orthop 2006; 35:24–29.
  7. Westrich GH, Bottner F, Windsor RE, Laskin RS, Haas SB, Sculco TP. VenaFlow plus Lovenox vs VenaFlow plus aspirin for thromboembolic disease prophylaxis in total knee arthroplasty. J Arthroplasty 2006; 21(6 suppl 2):139–143.
  8. Lotke PA, Lonner JH. The benefit of aspirin chemoprophylaxis for thromboembolism after total knee arthroplasty. Clin Orthop Relat Res 2006; 452:175–180.
  9. Callaghan JJ, Dorr LD, Engh GA, et al. Prophylaxis for thromboembolic disease: recommendations from the American College of Chest Physicians—are they appropriate for orthopaedic surgery? J Arthroplasty 2005; 20:273–274.
  10. Dorr LD, Gendelman V, Maheshwari AV, Boutary M, Wan Z, Long WT. Multimodal thromboprophylaxis for total hip and knee arthroplasty based on risk assessment. J Bone Joint Surg Am 2007; 89:2648–2657.
  11. American Academy of Orthopaedic Surgeons Clinical Guideline on Prevention of Symptomatic Pulmonary Embolism in Patients Undergoing Total Hip or Knee Arthroplasty: Summary of Recommendations. http://www.aaos.org/Research/guidelines/PE_summary.pdf. Accessed April 16, 2008.
  12. Parvizi J, Ghanem E, Joshi A, Sharkey PF, Hozack WJ, Rothman RH. Does “excessive” anticoagulation predispose to periprosthetic infection? J Arthroplasty 2007; 22(6 suppl 2):24–28.
  13. Bern M, Deshmukh RV, Nelson R, et al. Low-dose warfarin coupled with lower leg compression is effective prophylaxis against thromboembolic disease after hip arthroplasty. J Arthroplasty 2007; 22:644–650.
  14. Imperiale TF, Speroff T. A meta-analysis of methods to prevent venous thromboembolism following total hip replacement. JAMA 1994; 271:1780–1785.
  15. Cardiovascular Disease Educational and Research Trust; Cyprus Cardiovascular Disease Educational and Research Trust; European Venous Forum; International Surgical Thrombosis Forum; International Union of Angiology; Union Internationale de Phlébologie. Prevention and treatment of venous thromboembolism. International Consensus Statement (guidelines according to scientific evidence). Int Angiol 2006; 25:101–161.
Issue
Cleveland Clinic Journal of Medicine - 75(7)
Issue
Cleveland Clinic Journal of Medicine - 75(7)
Page Number
471-473
Page Number
471-473
Publications
Publications
Topics
Article Type
Display Headline
In reply: VTE prevention in major orthopedic surgery
Display Headline
In reply: VTE prevention in major orthopedic surgery
Sections
Disallow All Ads
Alternative CME
Use ProPublica
Article PDF Media

Rules of Engagement

Article Type
Changed
Mon, 01/02/2017 - 19:34
Display Headline
Peripheral arterial disease and the hospitalist: The rationale for early detection and optimal therapy

Peripheral arterial disease (PAD) is defined by the presence of stenosis or occlusion in peripheral arterial beds.1, 2 Based on large population‐based screening surveys, the prevalence of this disease ranges between 5.5% and 26.7% and is dependent on age, atherothrombotic risk factors, and the coexistence of other atherothrombotic diseases.35 Symptoms of PAD include mild to intermittent claudication, ischemic rest pain, and tissue loss.2 Disease severity is classified according to either Fontaine's stages or Rutherford categories. These categorization schema have value in improving communication between physicians, which is important in ensuring continuity of care between the inpatient and outpatient settings (Table 1).2

PAD Classification According to Fontaine's Stages and Rutherford's Categories
Stage Fontaine Rutherford
Clinical Grade Category Clinical
  • Adapted from Hirsch et al., 2006.2

I Asymptomatic 0 0 Asymptomatic
IIa Mild claudication I 1 Mild claudication
IIb Moderate‐severe claudication I 2 Moderate claudication
III Ischemic rest pain I 3 Severe claudication
IV Ulceration or gangrene II 4 Ischemic rest pain
III 5 Minor tissue loss
IV 6 Ulceration or gangrene

Patients with PAD are at increased risk of dying from or experiencing a cardiovascular event.68 Among patients diagnosed with PAD, coronary artery disease (CAD), or cerebrovascular disease (CVD), those with PAD have the highest 1‐year rate of cardiovascular death, MI, stroke, or vascular‐related hospitalization (Fig. 1).8 This risk is attributable in part to the high rate of association of PAD with other atherothrombotic diseases. The Reduction of Atherothrombosis for Continued Health (REACH) Registry found that approximately 60% of participants with documented PAD have polyvascular disease, defined by the coexistence of CAD and/or CVD. In comparison, 25% of participants with CAD and 40% of participants with CVD have polyvascular disease.8 Thus, PAD can be considered a powerful indicator of systemic atherothrombotic disease and a predictor of cardiovascular and cerebrovascular morbidity and mortality.1

Figure 1
One‐year cardiovascular event rates. The CAD, CVD, and PAD subsets overlap each other. Abbreviations: CAD, coronary artery disease; CVD, cerebrovascular disease; PAD, peripheral artery disease. Adapted from Steg et al.8

Unfortunately, asymptomatic PAD is more common than its symptomatic counterpart.3 In addition, symptomatic patients often fail to notify their physicians about PAD‐associated symptoms because they attribute them to aging.3 As a result, this disease is underdiagnosed and undertreated.1 Accordingly, several medical associations and physician task forces have called for an increase in screening for PAD in at‐risk populations that include: patients older than 70, patients older than 50 who have concomitant atherothrombotic risk factors, and patients with atherothrombotic disease of single or multiple vascular beds.1, 9 In many cases hospitalists encounter patients at high‐risk for PAD whose DRG for admission might be unrelated to this disease. Nonetheless, hospitalists have the opportunity to improve patient outcomes by being capable of screening for undiagnosed PAD and initiating appropriate interventions to reduce the risk of life‐threatening cardiovascular events.

DIAGNOSIS

Peripheral arterial disease can be diagnosed by either noninvasive or invasive methods. The ankle‐to‐brachial index (ABI) is an accurate, practical, inexpensive, and noninvasive method for detecting PAD.1 The sensitivity of ABI in detecting PAD is 95% with 99% specificity,10 which makes the method superior to other indicators (eg, absence of a pedal pulse, presence of a femoral arterial bruit, slow venous filling, or cold/abnormally colored skin) assessed during a physical examination.11 Under normal conditions, the systolic pressure at the ankle should be equal to or greater than that recorded from the upper arm. As PAD narrows arteries, the systolic pressure decreases at sites distal to the area of arterial narrowing. A resting ABI is quantified by taking 2 readings each of ankle and brachial blood pressures with a handheld Doppler device while the patient is supine and dividing the highest ankle systolic pressure by the highest brachial pressure.12

An ABI between 0.9 and 1.30 is considered normal. Ratios between 0.7 and 0.89 indicate mild PAD, 0.4 and 0.69 moderate PAD, and an ABI < 0.4 severe PAD when patients are more likely to have ischemic pain when at rest. An ABI > 1.3 usually indicates the presence of noncompressible vessels, which can be common in the elderly and patients with diabetes mellitus who have calcification of the distal arteries.1, 2 The ABI is also inversely related to the number of atherosclerotic risk factors and the risk of adverse cardiovascular events and death.6, 1316 To identify individuals with suspected or asymptomatic lower‐extremity PAD, ABI has a class I recommendation from the American College of Cardiology and American Heart Association (ACC/AHA) for patients who present with leg symptoms, who are 70 years and older, or who are 50 years and older with a history of smoking or diabetes.2 This enables physicians to make therapeutic interventions to reduce the risk of adverse vascular events in these patient cohorts.

Additional detection methods for PAD include measuring the ABI before and after exercise on a treadmill, if the patient is ambulatory, or exercise by performing 50 repetitions of raising the heels maximally off the floor, if the patient is not ambulatory. These tests determine the extent of claudication.2 Duplex ultrasound is used to establish the location and severity of stenosis and to follow PAD progression.2

Invasive evaluations for PAD are used primarily to confirm an initial diagnosis of PAD and assess its severity. These methods include a conventional angiogram, which is the most readily available and widely used technique for defining arterial stenosis. Magnetic resonance (MR) angiography with gadolinium and computed tomographic (CT) angiography are used to determine the location and degree of stenosis. Both MR and CT angiography have advantages and disadvantages but are considered interchangeable with one another in patients with contraindications to either method (Table 2).2

Clinical Benefits and Limitations of Magnetic Resonance and Computed Tomographic Angiography
Diagostic method Benefits Limitations
  • Adapted from Hirsch et al., 2006.2

Magnetic resonance angiography (MRA) Useful to assess PAD anatomy and presence of significant stenosis Tends to overestimate degree of stenosis
Useful to select patients who are candidates for endovascular of surgical revascularization May be inaccurate in arteries treated with metal stents
Cannot be used in patients with contraindication to magnetic resonance technique
Computed tomographic angiography (CTA) Useful to assess PAD anatomy and presence of significant stenosis Single‐detector CT lacks accuracy to detect stenoses
Useful to select patients who are candidates for endovascular or surgical revascularization Spatial Resolution lower than digital subtraction angiography
Helpful to provide associated soft‐tissue diagnostic information that may be associated with PAD Venous opacification can obscure arterial filling
Patients with contraindications to MRA Asymmetric opacification of legs may obscure arterial phase in some vessels
Metal clips, stents, and prostheses do not cause significant CTA artifacts Accuracy and effectiveness not as well determined as MRA
Scan times are significantly faster Treatment plans based on CTA have not been compared to those of catheter angiography
Requires contrast and radiation
Use may be limited in individuals with renal dysfunction

ANTIPLATELET THERAPY FOR REDUCTION OF VASCULAR EVENTS

Hospitalists utilize a wide array of therapies to treat and manage PAD. Acute complications of PAD may require interventions to prevent tissue loss or infection, revascularization procedures, or surgical amputation. Treatment of mild to moderate PAD focuses on atherothrombotic risk factor management, exercise therapy to improve limb function, and interventions to reduce the risk of adverse vascular events.2, 9 The remainder of this report focuses on the role of antiplatelet therapy (eg, aspirin and thienopyridines) in reducing the risk of vascular events in patients with PAD.

The Antiplatelet Trialists' Collaboration performed an overview analysis of randomized trials conducted prior to 1990 in order to determine the association of prolonged antiplatelet therapy with the occurrence of major vascular events. As a whole, therapies thought to act through inhibition of platelet aggregation, adhesion, or both reduced the incidence of vascular events by 33% in patients with PAD and those at high risk, and by 25% in all patient groups. Antiplatelet agents were also well tolerated; the absolute risk of fatal or nonmajor hemorrhage was low.17

A similar meta‐analysis was conducted of antiplatelet therapies in high‐risk patients with atherothrombosis by the Antithrombotic Trialists' Collaboration. Antiplatelet therapies taken together reduced the odds of patients experiencing vascular events by 22% (SE = 2%) across all trials and 23% (SE = 8%) in patients with PAD.18 Similar to the Antiplatelet Trialists' Collaboration study, the absolute risk of major and minor bleeding was low compared to the benefits of antiplatelet therapy.18 The results of these studies provide supporting evidence for the ACC/AHA class I recommendation for the use of antiplatelet therapy to reduce the risk of MI, stroke, or vascular death in patients with PAD.

The Antithrombotic Trialists' Collaboration also examined the risk reduction associated with a specific antiplatelet agent, aspirin. All doses of aspirin (75‐150, 160‐325, and 500‐1500 mg/day) reduced the odds by 23% (SE = 2%); high doses were no more effective than medium or low doses.18 Although the effects of aspirin was not analyzed in a subgroup analysis of patients with PAD, this study and others support the ACC/AHA class I recommendations for the use of aspirin to reduce the risk of MI, stroke, or vascular death in patients with PAD.2, 1921

The CAPRIE trial compared the efficacy of another antiplatelet agent, clopidogrel, against aspirin in patients with PAD.22 Patients with a history of recent ischemic stroke, MI, or symptomatic PAD were randomized to receive either clopidogrel (75 mg/day) or aspirin (325 mg/day) for 1‐3 years (mean follow‐up time, 1.91 years). Study outcomes were the incidence of nonfatal MI, ischemic stroke, hemorrhagic stroke, leg amputation, and vascular deaths. The absolute risk reduction for all patients was 8.7% (95% confidence interval [CI], 0.3%‐16.5%) in favor of clopidogrel over aspirin. Moreover, subgroup analysis in patients with PAD revealed that clopidogrel reduced the risk of a vascular event by 23.8% (95% CI, 8.9%‐36.2%; P = 0.0028) compared with aspirin (Fig. 2). Clopidogrel and aspirin had similar safety profiles, but other studies have revealed bleeding incidence is numerically greater in patients treated with clopidogrel.2224 Although the CAPRIE trial is the only study to date to compare the efficacy of clopidogrel over aspirin in reducing vascular event in patients with PAD, its outcomes underlie the class I ACC/AHA recommendation for clopidogrel (75 mg/day) as an effective alternative to aspirin to reduce the risk of MI, stroke, or death in patients with PAD.2

Figure 2
Relative risk reduction and 95% CI by PAD, MI, and stroke subgroups. Adapted from the CAPRIE Steering Committee.22

CONCLUSIONS

Despite the availability of accurate, practical, and inexpensive diagnostic testing, PAD remains underdiagnosed and undertreated. Early detection of PAD and subsequent intervention by hospitalists are important because peripheral arterial disease is strongly associated with an increased risk of mortality and morbidity from adverse vascular events. The ACC/AHA recommends screening for asymptomatic patients at risk for this disease so that therapies that reduce the risk of an MI, stroke, or vascular death can be administered immediately. Antiplatelet agents reduce the risk of adverse vascular events in patients with PAD. The use of aspirin or clopidogrel is recommended in this cohort of patients. However, further study is necessary to determine the efficacy and safety of combination therapy with aspirin and clopidogrel in patients with PAD. It is also important to note that coordination of care between hospitalists and cardiologists is critical in the management of patients with this disease. However, the appropriate handoff of patients between these 2 groups of physicians depends on the local expertise and support structure of these health care professionals. Thus, an interdisciplinary approach utilizing guideline‐based patient care will allow hospitalists to refer patients accordingly, ensuring optimal outcomes in patients with PAD.

References
  1. Belch JJ,Topol EJ,Agnelli G, et al.Prevention of Atherothrombotic Disease Network. Critical issues in peripheral arterial disease detection and management: a call to action.Arch Intern Med.2003;163:884892.
  2. Hirsch AT,Haskal ZJ,Hertzer NR, et al.ACC/AHA 2005 Practice Guidelines for the management of patients with peripheral arterial disease (lower extremity, renal, mesenteric, and abdominal aortic).Circulation.2006;113:e463e654.
  3. Meijer WT,Hoes AW,Rutgers D,Bots ML,Hofman A,Grobbee DE.Peripheral arterial disease in the elderly: the Rotterdam Study.Arterioscler Thromb Vasc Biol.1998;18:185192.
  4. Hirsch AT,Criqui MH,Treat‐Jacobson D, et al.Peripheral arterial disease detection, awareness, and treatment in primary care.JAMA.2001;286:13171324.
  5. Selvin E,Erlinger TP.Prevalence of and risk factors for peripheral arterial disease in the United States: Results from the National Health and Nutrition Examination Survey, 1999‐2000.Circulation.2004;110:738743.
  6. Criqui MH,Langer RD,Fronek A, et al.Mortality over a period of 10 years in patients with peripheral arterial disease.N Engl J Med.1992;326:381386.
  7. Wilterdink JI,Easton JD.Vascular event rates in patients with atherosclerotic cerebrovascular disease.Arch Neurol.1992;49:857863.
  8. Steg PG,Bhatt DL,Wilson PWF, et al.;REACH Registry Investigators. One‐year cardiovascular event rates in outpatients with atherothrombosis.JAMA.2007;297:11971206.
  9. Weitz JI,Byrne J,Clagett GP, et al.Diagnosis and treatment of chronic arterial insufficiency of the lower extremities: A critical review.Circulation.1996;94:30263049.
  10. Dormandy JA,Rutherford RB.Management of peripheral arterial disease (PAD): TASC Working Group. TransAtlantic Inter‐Society Consensus (TASC).J Vasc Surg.2000:31(1Pt 2):S1S296.
  11. McGee SR,Boyko EJ.Physical examination and chronic lower‐extremity ischemia.Arch Intern Med.1998;158:13571364.
  12. Hiatt WR.Medical treatment of peripheral artery disease and claudication.N Engl J Med.2001;344:16081621.
  13. Newman AB,Siscovick DS,Manolio TA, et al.Ankle‐arm index as a marker of atherosclerosis in the Cardiovascular Health Study. Cardiovascular Heart Study (CHS) Collaborative Research Group.Circulation.1993;88:837845.
  14. Newman AB,Sutton‐Tyrrell K,Vogt MT,Kuller H.Morbidity and mortality in hypertensive adults with a low ankle/arm blood pressure index.JAMA.1993;270:487489.
  15. Newman AB,Shemanski L,Manolio TA, et al.Ankle‐arm index as a predictor of cardiovascular disease and mortality in the Cardiovascular Health Study. The Cardiovascular Health Study Group.Arterioscler Thromb Vasc Biol.1999;19:538545.
  16. Murabito JM,Evans JC,Larson MG,Nieto K,Levy D,Wilson PWF;Framingham Study. The ankle‐brachial index in the elderly and risk of stroke, coronary disease, and death: the Framingham Study.Arch Intern Med.2003;163:19391942.
  17. Antiplatelet Trialists' Collaboration.Collaborative overview of randomized trials of antiplatelet therapy—1: Prevention of death, myocardial infarction, and stroke by prolonged antiplatelet therapy in various categories of patients.BMJ.1994;308:81106.
  18. Antithrombotic Trialists' Collaboration.Collaborative meta‐analysis of randomized trials of antiplatelet therapy for prevention of death, myocardial infarction, and stroke in high risk patients.BMJ.2002;324:7186.
  19. The Medical Research Council's General Practice Research Framework.Thrombosis prevention trial: randomised trial of low‐intensity oral anticoagulation with warfarin and low‐dose aspirin in the primary prevention of ischemic heart disease in men at increased risk.Lancet.1998;351:233241.
  20. Hansson L,Zanchetti A,Carruthers SG, for theHOT Study Group.Effects of intensive blood pressure lowering and low‐dose aspirin in patients with hypertension: principal results of the Hypertension Optimal Treatment (HOT) randomised trial.Lancet1998;280:19301935.
  21. Collaborative Group of the Primary Prevention Project (PPP).Low‐dose aspirin and vitamin E in people at cardiovascular risk: a randomized trial in general practice.Lancet.2001;357:8995.
  22. CAPRIE Steering Committee.A randomized, blinded, trial of clopidogrel versus aspirin in patients at risk of ischemic events (CAPRIE).Lancet.1996;348:13291339.
  23. Bhatt DL,Fox KAA,Hacke WB; for theCHARISMA Investigators.Clopidogrel and aspirin versus aspirin alone for the prevention of atherothrombotic events.N Engl J Med.2006;354:17061717.
  24. Diener H‐C,Boguousslavsky J,Brass LM; on behalf of theMATCH investigators.Aspirin and clopidogrel compared with clopidogrel alone after ischaemic stroke or transient ischaemic attack in high‐risk patients (MATCH): randomised, double‐blind, placebo‐controlled trial.Lancet.2004;364:331337.
Article PDF
Issue
Journal of Hospital Medicine - 3(2)
Publications
Page Number
S4-S8
Legacy Keywords
peripheral arterial disease, diagnosis, and antiplatelet therapy
Sections
Article PDF
Article PDF

Peripheral arterial disease (PAD) is defined by the presence of stenosis or occlusion in peripheral arterial beds.1, 2 Based on large population‐based screening surveys, the prevalence of this disease ranges between 5.5% and 26.7% and is dependent on age, atherothrombotic risk factors, and the coexistence of other atherothrombotic diseases.35 Symptoms of PAD include mild to intermittent claudication, ischemic rest pain, and tissue loss.2 Disease severity is classified according to either Fontaine's stages or Rutherford categories. These categorization schema have value in improving communication between physicians, which is important in ensuring continuity of care between the inpatient and outpatient settings (Table 1).2

PAD Classification According to Fontaine's Stages and Rutherford's Categories
Stage Fontaine Rutherford
Clinical Grade Category Clinical
  • Adapted from Hirsch et al., 2006.2

I Asymptomatic 0 0 Asymptomatic
IIa Mild claudication I 1 Mild claudication
IIb Moderate‐severe claudication I 2 Moderate claudication
III Ischemic rest pain I 3 Severe claudication
IV Ulceration or gangrene II 4 Ischemic rest pain
III 5 Minor tissue loss
IV 6 Ulceration or gangrene

Patients with PAD are at increased risk of dying from or experiencing a cardiovascular event.68 Among patients diagnosed with PAD, coronary artery disease (CAD), or cerebrovascular disease (CVD), those with PAD have the highest 1‐year rate of cardiovascular death, MI, stroke, or vascular‐related hospitalization (Fig. 1).8 This risk is attributable in part to the high rate of association of PAD with other atherothrombotic diseases. The Reduction of Atherothrombosis for Continued Health (REACH) Registry found that approximately 60% of participants with documented PAD have polyvascular disease, defined by the coexistence of CAD and/or CVD. In comparison, 25% of participants with CAD and 40% of participants with CVD have polyvascular disease.8 Thus, PAD can be considered a powerful indicator of systemic atherothrombotic disease and a predictor of cardiovascular and cerebrovascular morbidity and mortality.1

Figure 1
One‐year cardiovascular event rates. The CAD, CVD, and PAD subsets overlap each other. Abbreviations: CAD, coronary artery disease; CVD, cerebrovascular disease; PAD, peripheral artery disease. Adapted from Steg et al.8

Unfortunately, asymptomatic PAD is more common than its symptomatic counterpart.3 In addition, symptomatic patients often fail to notify their physicians about PAD‐associated symptoms because they attribute them to aging.3 As a result, this disease is underdiagnosed and undertreated.1 Accordingly, several medical associations and physician task forces have called for an increase in screening for PAD in at‐risk populations that include: patients older than 70, patients older than 50 who have concomitant atherothrombotic risk factors, and patients with atherothrombotic disease of single or multiple vascular beds.1, 9 In many cases hospitalists encounter patients at high‐risk for PAD whose DRG for admission might be unrelated to this disease. Nonetheless, hospitalists have the opportunity to improve patient outcomes by being capable of screening for undiagnosed PAD and initiating appropriate interventions to reduce the risk of life‐threatening cardiovascular events.

DIAGNOSIS

Peripheral arterial disease can be diagnosed by either noninvasive or invasive methods. The ankle‐to‐brachial index (ABI) is an accurate, practical, inexpensive, and noninvasive method for detecting PAD.1 The sensitivity of ABI in detecting PAD is 95% with 99% specificity,10 which makes the method superior to other indicators (eg, absence of a pedal pulse, presence of a femoral arterial bruit, slow venous filling, or cold/abnormally colored skin) assessed during a physical examination.11 Under normal conditions, the systolic pressure at the ankle should be equal to or greater than that recorded from the upper arm. As PAD narrows arteries, the systolic pressure decreases at sites distal to the area of arterial narrowing. A resting ABI is quantified by taking 2 readings each of ankle and brachial blood pressures with a handheld Doppler device while the patient is supine and dividing the highest ankle systolic pressure by the highest brachial pressure.12

An ABI between 0.9 and 1.30 is considered normal. Ratios between 0.7 and 0.89 indicate mild PAD, 0.4 and 0.69 moderate PAD, and an ABI < 0.4 severe PAD when patients are more likely to have ischemic pain when at rest. An ABI > 1.3 usually indicates the presence of noncompressible vessels, which can be common in the elderly and patients with diabetes mellitus who have calcification of the distal arteries.1, 2 The ABI is also inversely related to the number of atherosclerotic risk factors and the risk of adverse cardiovascular events and death.6, 1316 To identify individuals with suspected or asymptomatic lower‐extremity PAD, ABI has a class I recommendation from the American College of Cardiology and American Heart Association (ACC/AHA) for patients who present with leg symptoms, who are 70 years and older, or who are 50 years and older with a history of smoking or diabetes.2 This enables physicians to make therapeutic interventions to reduce the risk of adverse vascular events in these patient cohorts.

Additional detection methods for PAD include measuring the ABI before and after exercise on a treadmill, if the patient is ambulatory, or exercise by performing 50 repetitions of raising the heels maximally off the floor, if the patient is not ambulatory. These tests determine the extent of claudication.2 Duplex ultrasound is used to establish the location and severity of stenosis and to follow PAD progression.2

Invasive evaluations for PAD are used primarily to confirm an initial diagnosis of PAD and assess its severity. These methods include a conventional angiogram, which is the most readily available and widely used technique for defining arterial stenosis. Magnetic resonance (MR) angiography with gadolinium and computed tomographic (CT) angiography are used to determine the location and degree of stenosis. Both MR and CT angiography have advantages and disadvantages but are considered interchangeable with one another in patients with contraindications to either method (Table 2).2

Clinical Benefits and Limitations of Magnetic Resonance and Computed Tomographic Angiography
Diagostic method Benefits Limitations
  • Adapted from Hirsch et al., 2006.2

Magnetic resonance angiography (MRA) Useful to assess PAD anatomy and presence of significant stenosis Tends to overestimate degree of stenosis
Useful to select patients who are candidates for endovascular of surgical revascularization May be inaccurate in arteries treated with metal stents
Cannot be used in patients with contraindication to magnetic resonance technique
Computed tomographic angiography (CTA) Useful to assess PAD anatomy and presence of significant stenosis Single‐detector CT lacks accuracy to detect stenoses
Useful to select patients who are candidates for endovascular or surgical revascularization Spatial Resolution lower than digital subtraction angiography
Helpful to provide associated soft‐tissue diagnostic information that may be associated with PAD Venous opacification can obscure arterial filling
Patients with contraindications to MRA Asymmetric opacification of legs may obscure arterial phase in some vessels
Metal clips, stents, and prostheses do not cause significant CTA artifacts Accuracy and effectiveness not as well determined as MRA
Scan times are significantly faster Treatment plans based on CTA have not been compared to those of catheter angiography
Requires contrast and radiation
Use may be limited in individuals with renal dysfunction

ANTIPLATELET THERAPY FOR REDUCTION OF VASCULAR EVENTS

Hospitalists utilize a wide array of therapies to treat and manage PAD. Acute complications of PAD may require interventions to prevent tissue loss or infection, revascularization procedures, or surgical amputation. Treatment of mild to moderate PAD focuses on atherothrombotic risk factor management, exercise therapy to improve limb function, and interventions to reduce the risk of adverse vascular events.2, 9 The remainder of this report focuses on the role of antiplatelet therapy (eg, aspirin and thienopyridines) in reducing the risk of vascular events in patients with PAD.

The Antiplatelet Trialists' Collaboration performed an overview analysis of randomized trials conducted prior to 1990 in order to determine the association of prolonged antiplatelet therapy with the occurrence of major vascular events. As a whole, therapies thought to act through inhibition of platelet aggregation, adhesion, or both reduced the incidence of vascular events by 33% in patients with PAD and those at high risk, and by 25% in all patient groups. Antiplatelet agents were also well tolerated; the absolute risk of fatal or nonmajor hemorrhage was low.17

A similar meta‐analysis was conducted of antiplatelet therapies in high‐risk patients with atherothrombosis by the Antithrombotic Trialists' Collaboration. Antiplatelet therapies taken together reduced the odds of patients experiencing vascular events by 22% (SE = 2%) across all trials and 23% (SE = 8%) in patients with PAD.18 Similar to the Antiplatelet Trialists' Collaboration study, the absolute risk of major and minor bleeding was low compared to the benefits of antiplatelet therapy.18 The results of these studies provide supporting evidence for the ACC/AHA class I recommendation for the use of antiplatelet therapy to reduce the risk of MI, stroke, or vascular death in patients with PAD.

The Antithrombotic Trialists' Collaboration also examined the risk reduction associated with a specific antiplatelet agent, aspirin. All doses of aspirin (75‐150, 160‐325, and 500‐1500 mg/day) reduced the odds by 23% (SE = 2%); high doses were no more effective than medium or low doses.18 Although the effects of aspirin was not analyzed in a subgroup analysis of patients with PAD, this study and others support the ACC/AHA class I recommendations for the use of aspirin to reduce the risk of MI, stroke, or vascular death in patients with PAD.2, 1921

The CAPRIE trial compared the efficacy of another antiplatelet agent, clopidogrel, against aspirin in patients with PAD.22 Patients with a history of recent ischemic stroke, MI, or symptomatic PAD were randomized to receive either clopidogrel (75 mg/day) or aspirin (325 mg/day) for 1‐3 years (mean follow‐up time, 1.91 years). Study outcomes were the incidence of nonfatal MI, ischemic stroke, hemorrhagic stroke, leg amputation, and vascular deaths. The absolute risk reduction for all patients was 8.7% (95% confidence interval [CI], 0.3%‐16.5%) in favor of clopidogrel over aspirin. Moreover, subgroup analysis in patients with PAD revealed that clopidogrel reduced the risk of a vascular event by 23.8% (95% CI, 8.9%‐36.2%; P = 0.0028) compared with aspirin (Fig. 2). Clopidogrel and aspirin had similar safety profiles, but other studies have revealed bleeding incidence is numerically greater in patients treated with clopidogrel.2224 Although the CAPRIE trial is the only study to date to compare the efficacy of clopidogrel over aspirin in reducing vascular event in patients with PAD, its outcomes underlie the class I ACC/AHA recommendation for clopidogrel (75 mg/day) as an effective alternative to aspirin to reduce the risk of MI, stroke, or death in patients with PAD.2

Figure 2
Relative risk reduction and 95% CI by PAD, MI, and stroke subgroups. Adapted from the CAPRIE Steering Committee.22

CONCLUSIONS

Despite the availability of accurate, practical, and inexpensive diagnostic testing, PAD remains underdiagnosed and undertreated. Early detection of PAD and subsequent intervention by hospitalists are important because peripheral arterial disease is strongly associated with an increased risk of mortality and morbidity from adverse vascular events. The ACC/AHA recommends screening for asymptomatic patients at risk for this disease so that therapies that reduce the risk of an MI, stroke, or vascular death can be administered immediately. Antiplatelet agents reduce the risk of adverse vascular events in patients with PAD. The use of aspirin or clopidogrel is recommended in this cohort of patients. However, further study is necessary to determine the efficacy and safety of combination therapy with aspirin and clopidogrel in patients with PAD. It is also important to note that coordination of care between hospitalists and cardiologists is critical in the management of patients with this disease. However, the appropriate handoff of patients between these 2 groups of physicians depends on the local expertise and support structure of these health care professionals. Thus, an interdisciplinary approach utilizing guideline‐based patient care will allow hospitalists to refer patients accordingly, ensuring optimal outcomes in patients with PAD.

Peripheral arterial disease (PAD) is defined by the presence of stenosis or occlusion in peripheral arterial beds.1, 2 Based on large population‐based screening surveys, the prevalence of this disease ranges between 5.5% and 26.7% and is dependent on age, atherothrombotic risk factors, and the coexistence of other atherothrombotic diseases.35 Symptoms of PAD include mild to intermittent claudication, ischemic rest pain, and tissue loss.2 Disease severity is classified according to either Fontaine's stages or Rutherford categories. These categorization schema have value in improving communication between physicians, which is important in ensuring continuity of care between the inpatient and outpatient settings (Table 1).2

PAD Classification According to Fontaine's Stages and Rutherford's Categories
Stage Fontaine Rutherford
Clinical Grade Category Clinical
  • Adapted from Hirsch et al., 2006.2

I Asymptomatic 0 0 Asymptomatic
IIa Mild claudication I 1 Mild claudication
IIb Moderate‐severe claudication I 2 Moderate claudication
III Ischemic rest pain I 3 Severe claudication
IV Ulceration or gangrene II 4 Ischemic rest pain
III 5 Minor tissue loss
IV 6 Ulceration or gangrene

Patients with PAD are at increased risk of dying from or experiencing a cardiovascular event.68 Among patients diagnosed with PAD, coronary artery disease (CAD), or cerebrovascular disease (CVD), those with PAD have the highest 1‐year rate of cardiovascular death, MI, stroke, or vascular‐related hospitalization (Fig. 1).8 This risk is attributable in part to the high rate of association of PAD with other atherothrombotic diseases. The Reduction of Atherothrombosis for Continued Health (REACH) Registry found that approximately 60% of participants with documented PAD have polyvascular disease, defined by the coexistence of CAD and/or CVD. In comparison, 25% of participants with CAD and 40% of participants with CVD have polyvascular disease.8 Thus, PAD can be considered a powerful indicator of systemic atherothrombotic disease and a predictor of cardiovascular and cerebrovascular morbidity and mortality.1

Figure 1
One‐year cardiovascular event rates. The CAD, CVD, and PAD subsets overlap each other. Abbreviations: CAD, coronary artery disease; CVD, cerebrovascular disease; PAD, peripheral artery disease. Adapted from Steg et al.8

Unfortunately, asymptomatic PAD is more common than its symptomatic counterpart.3 In addition, symptomatic patients often fail to notify their physicians about PAD‐associated symptoms because they attribute them to aging.3 As a result, this disease is underdiagnosed and undertreated.1 Accordingly, several medical associations and physician task forces have called for an increase in screening for PAD in at‐risk populations that include: patients older than 70, patients older than 50 who have concomitant atherothrombotic risk factors, and patients with atherothrombotic disease of single or multiple vascular beds.1, 9 In many cases hospitalists encounter patients at high‐risk for PAD whose DRG for admission might be unrelated to this disease. Nonetheless, hospitalists have the opportunity to improve patient outcomes by being capable of screening for undiagnosed PAD and initiating appropriate interventions to reduce the risk of life‐threatening cardiovascular events.

DIAGNOSIS

Peripheral arterial disease can be diagnosed by either noninvasive or invasive methods. The ankle‐to‐brachial index (ABI) is an accurate, practical, inexpensive, and noninvasive method for detecting PAD.1 The sensitivity of ABI in detecting PAD is 95% with 99% specificity,10 which makes the method superior to other indicators (eg, absence of a pedal pulse, presence of a femoral arterial bruit, slow venous filling, or cold/abnormally colored skin) assessed during a physical examination.11 Under normal conditions, the systolic pressure at the ankle should be equal to or greater than that recorded from the upper arm. As PAD narrows arteries, the systolic pressure decreases at sites distal to the area of arterial narrowing. A resting ABI is quantified by taking 2 readings each of ankle and brachial blood pressures with a handheld Doppler device while the patient is supine and dividing the highest ankle systolic pressure by the highest brachial pressure.12

An ABI between 0.9 and 1.30 is considered normal. Ratios between 0.7 and 0.89 indicate mild PAD, 0.4 and 0.69 moderate PAD, and an ABI < 0.4 severe PAD when patients are more likely to have ischemic pain when at rest. An ABI > 1.3 usually indicates the presence of noncompressible vessels, which can be common in the elderly and patients with diabetes mellitus who have calcification of the distal arteries.1, 2 The ABI is also inversely related to the number of atherosclerotic risk factors and the risk of adverse cardiovascular events and death.6, 1316 To identify individuals with suspected or asymptomatic lower‐extremity PAD, ABI has a class I recommendation from the American College of Cardiology and American Heart Association (ACC/AHA) for patients who present with leg symptoms, who are 70 years and older, or who are 50 years and older with a history of smoking or diabetes.2 This enables physicians to make therapeutic interventions to reduce the risk of adverse vascular events in these patient cohorts.

Additional detection methods for PAD include measuring the ABI before and after exercise on a treadmill, if the patient is ambulatory, or exercise by performing 50 repetitions of raising the heels maximally off the floor, if the patient is not ambulatory. These tests determine the extent of claudication.2 Duplex ultrasound is used to establish the location and severity of stenosis and to follow PAD progression.2

Invasive evaluations for PAD are used primarily to confirm an initial diagnosis of PAD and assess its severity. These methods include a conventional angiogram, which is the most readily available and widely used technique for defining arterial stenosis. Magnetic resonance (MR) angiography with gadolinium and computed tomographic (CT) angiography are used to determine the location and degree of stenosis. Both MR and CT angiography have advantages and disadvantages but are considered interchangeable with one another in patients with contraindications to either method (Table 2).2

Clinical Benefits and Limitations of Magnetic Resonance and Computed Tomographic Angiography
Diagostic method Benefits Limitations
  • Adapted from Hirsch et al., 2006.2

Magnetic resonance angiography (MRA) Useful to assess PAD anatomy and presence of significant stenosis Tends to overestimate degree of stenosis
Useful to select patients who are candidates for endovascular of surgical revascularization May be inaccurate in arteries treated with metal stents
Cannot be used in patients with contraindication to magnetic resonance technique
Computed tomographic angiography (CTA) Useful to assess PAD anatomy and presence of significant stenosis Single‐detector CT lacks accuracy to detect stenoses
Useful to select patients who are candidates for endovascular or surgical revascularization Spatial Resolution lower than digital subtraction angiography
Helpful to provide associated soft‐tissue diagnostic information that may be associated with PAD Venous opacification can obscure arterial filling
Patients with contraindications to MRA Asymmetric opacification of legs may obscure arterial phase in some vessels
Metal clips, stents, and prostheses do not cause significant CTA artifacts Accuracy and effectiveness not as well determined as MRA
Scan times are significantly faster Treatment plans based on CTA have not been compared to those of catheter angiography
Requires contrast and radiation
Use may be limited in individuals with renal dysfunction

ANTIPLATELET THERAPY FOR REDUCTION OF VASCULAR EVENTS

Hospitalists utilize a wide array of therapies to treat and manage PAD. Acute complications of PAD may require interventions to prevent tissue loss or infection, revascularization procedures, or surgical amputation. Treatment of mild to moderate PAD focuses on atherothrombotic risk factor management, exercise therapy to improve limb function, and interventions to reduce the risk of adverse vascular events.2, 9 The remainder of this report focuses on the role of antiplatelet therapy (eg, aspirin and thienopyridines) in reducing the risk of vascular events in patients with PAD.

The Antiplatelet Trialists' Collaboration performed an overview analysis of randomized trials conducted prior to 1990 in order to determine the association of prolonged antiplatelet therapy with the occurrence of major vascular events. As a whole, therapies thought to act through inhibition of platelet aggregation, adhesion, or both reduced the incidence of vascular events by 33% in patients with PAD and those at high risk, and by 25% in all patient groups. Antiplatelet agents were also well tolerated; the absolute risk of fatal or nonmajor hemorrhage was low.17

A similar meta‐analysis was conducted of antiplatelet therapies in high‐risk patients with atherothrombosis by the Antithrombotic Trialists' Collaboration. Antiplatelet therapies taken together reduced the odds of patients experiencing vascular events by 22% (SE = 2%) across all trials and 23% (SE = 8%) in patients with PAD.18 Similar to the Antiplatelet Trialists' Collaboration study, the absolute risk of major and minor bleeding was low compared to the benefits of antiplatelet therapy.18 The results of these studies provide supporting evidence for the ACC/AHA class I recommendation for the use of antiplatelet therapy to reduce the risk of MI, stroke, or vascular death in patients with PAD.

The Antithrombotic Trialists' Collaboration also examined the risk reduction associated with a specific antiplatelet agent, aspirin. All doses of aspirin (75‐150, 160‐325, and 500‐1500 mg/day) reduced the odds by 23% (SE = 2%); high doses were no more effective than medium or low doses.18 Although the effects of aspirin was not analyzed in a subgroup analysis of patients with PAD, this study and others support the ACC/AHA class I recommendations for the use of aspirin to reduce the risk of MI, stroke, or vascular death in patients with PAD.2, 1921

The CAPRIE trial compared the efficacy of another antiplatelet agent, clopidogrel, against aspirin in patients with PAD.22 Patients with a history of recent ischemic stroke, MI, or symptomatic PAD were randomized to receive either clopidogrel (75 mg/day) or aspirin (325 mg/day) for 1‐3 years (mean follow‐up time, 1.91 years). Study outcomes were the incidence of nonfatal MI, ischemic stroke, hemorrhagic stroke, leg amputation, and vascular deaths. The absolute risk reduction for all patients was 8.7% (95% confidence interval [CI], 0.3%‐16.5%) in favor of clopidogrel over aspirin. Moreover, subgroup analysis in patients with PAD revealed that clopidogrel reduced the risk of a vascular event by 23.8% (95% CI, 8.9%‐36.2%; P = 0.0028) compared with aspirin (Fig. 2). Clopidogrel and aspirin had similar safety profiles, but other studies have revealed bleeding incidence is numerically greater in patients treated with clopidogrel.2224 Although the CAPRIE trial is the only study to date to compare the efficacy of clopidogrel over aspirin in reducing vascular event in patients with PAD, its outcomes underlie the class I ACC/AHA recommendation for clopidogrel (75 mg/day) as an effective alternative to aspirin to reduce the risk of MI, stroke, or death in patients with PAD.2

Figure 2
Relative risk reduction and 95% CI by PAD, MI, and stroke subgroups. Adapted from the CAPRIE Steering Committee.22

CONCLUSIONS

Despite the availability of accurate, practical, and inexpensive diagnostic testing, PAD remains underdiagnosed and undertreated. Early detection of PAD and subsequent intervention by hospitalists are important because peripheral arterial disease is strongly associated with an increased risk of mortality and morbidity from adverse vascular events. The ACC/AHA recommends screening for asymptomatic patients at risk for this disease so that therapies that reduce the risk of an MI, stroke, or vascular death can be administered immediately. Antiplatelet agents reduce the risk of adverse vascular events in patients with PAD. The use of aspirin or clopidogrel is recommended in this cohort of patients. However, further study is necessary to determine the efficacy and safety of combination therapy with aspirin and clopidogrel in patients with PAD. It is also important to note that coordination of care between hospitalists and cardiologists is critical in the management of patients with this disease. However, the appropriate handoff of patients between these 2 groups of physicians depends on the local expertise and support structure of these health care professionals. Thus, an interdisciplinary approach utilizing guideline‐based patient care will allow hospitalists to refer patients accordingly, ensuring optimal outcomes in patients with PAD.

References
  1. Belch JJ,Topol EJ,Agnelli G, et al.Prevention of Atherothrombotic Disease Network. Critical issues in peripheral arterial disease detection and management: a call to action.Arch Intern Med.2003;163:884892.
  2. Hirsch AT,Haskal ZJ,Hertzer NR, et al.ACC/AHA 2005 Practice Guidelines for the management of patients with peripheral arterial disease (lower extremity, renal, mesenteric, and abdominal aortic).Circulation.2006;113:e463e654.
  3. Meijer WT,Hoes AW,Rutgers D,Bots ML,Hofman A,Grobbee DE.Peripheral arterial disease in the elderly: the Rotterdam Study.Arterioscler Thromb Vasc Biol.1998;18:185192.
  4. Hirsch AT,Criqui MH,Treat‐Jacobson D, et al.Peripheral arterial disease detection, awareness, and treatment in primary care.JAMA.2001;286:13171324.
  5. Selvin E,Erlinger TP.Prevalence of and risk factors for peripheral arterial disease in the United States: Results from the National Health and Nutrition Examination Survey, 1999‐2000.Circulation.2004;110:738743.
  6. Criqui MH,Langer RD,Fronek A, et al.Mortality over a period of 10 years in patients with peripheral arterial disease.N Engl J Med.1992;326:381386.
  7. Wilterdink JI,Easton JD.Vascular event rates in patients with atherosclerotic cerebrovascular disease.Arch Neurol.1992;49:857863.
  8. Steg PG,Bhatt DL,Wilson PWF, et al.;REACH Registry Investigators. One‐year cardiovascular event rates in outpatients with atherothrombosis.JAMA.2007;297:11971206.
  9. Weitz JI,Byrne J,Clagett GP, et al.Diagnosis and treatment of chronic arterial insufficiency of the lower extremities: A critical review.Circulation.1996;94:30263049.
  10. Dormandy JA,Rutherford RB.Management of peripheral arterial disease (PAD): TASC Working Group. TransAtlantic Inter‐Society Consensus (TASC).J Vasc Surg.2000:31(1Pt 2):S1S296.
  11. McGee SR,Boyko EJ.Physical examination and chronic lower‐extremity ischemia.Arch Intern Med.1998;158:13571364.
  12. Hiatt WR.Medical treatment of peripheral artery disease and claudication.N Engl J Med.2001;344:16081621.
  13. Newman AB,Siscovick DS,Manolio TA, et al.Ankle‐arm index as a marker of atherosclerosis in the Cardiovascular Health Study. Cardiovascular Heart Study (CHS) Collaborative Research Group.Circulation.1993;88:837845.
  14. Newman AB,Sutton‐Tyrrell K,Vogt MT,Kuller H.Morbidity and mortality in hypertensive adults with a low ankle/arm blood pressure index.JAMA.1993;270:487489.
  15. Newman AB,Shemanski L,Manolio TA, et al.Ankle‐arm index as a predictor of cardiovascular disease and mortality in the Cardiovascular Health Study. The Cardiovascular Health Study Group.Arterioscler Thromb Vasc Biol.1999;19:538545.
  16. Murabito JM,Evans JC,Larson MG,Nieto K,Levy D,Wilson PWF;Framingham Study. The ankle‐brachial index in the elderly and risk of stroke, coronary disease, and death: the Framingham Study.Arch Intern Med.2003;163:19391942.
  17. Antiplatelet Trialists' Collaboration.Collaborative overview of randomized trials of antiplatelet therapy—1: Prevention of death, myocardial infarction, and stroke by prolonged antiplatelet therapy in various categories of patients.BMJ.1994;308:81106.
  18. Antithrombotic Trialists' Collaboration.Collaborative meta‐analysis of randomized trials of antiplatelet therapy for prevention of death, myocardial infarction, and stroke in high risk patients.BMJ.2002;324:7186.
  19. The Medical Research Council's General Practice Research Framework.Thrombosis prevention trial: randomised trial of low‐intensity oral anticoagulation with warfarin and low‐dose aspirin in the primary prevention of ischemic heart disease in men at increased risk.Lancet.1998;351:233241.
  20. Hansson L,Zanchetti A,Carruthers SG, for theHOT Study Group.Effects of intensive blood pressure lowering and low‐dose aspirin in patients with hypertension: principal results of the Hypertension Optimal Treatment (HOT) randomised trial.Lancet1998;280:19301935.
  21. Collaborative Group of the Primary Prevention Project (PPP).Low‐dose aspirin and vitamin E in people at cardiovascular risk: a randomized trial in general practice.Lancet.2001;357:8995.
  22. CAPRIE Steering Committee.A randomized, blinded, trial of clopidogrel versus aspirin in patients at risk of ischemic events (CAPRIE).Lancet.1996;348:13291339.
  23. Bhatt DL,Fox KAA,Hacke WB; for theCHARISMA Investigators.Clopidogrel and aspirin versus aspirin alone for the prevention of atherothrombotic events.N Engl J Med.2006;354:17061717.
  24. Diener H‐C,Boguousslavsky J,Brass LM; on behalf of theMATCH investigators.Aspirin and clopidogrel compared with clopidogrel alone after ischaemic stroke or transient ischaemic attack in high‐risk patients (MATCH): randomised, double‐blind, placebo‐controlled trial.Lancet.2004;364:331337.
References
  1. Belch JJ,Topol EJ,Agnelli G, et al.Prevention of Atherothrombotic Disease Network. Critical issues in peripheral arterial disease detection and management: a call to action.Arch Intern Med.2003;163:884892.
  2. Hirsch AT,Haskal ZJ,Hertzer NR, et al.ACC/AHA 2005 Practice Guidelines for the management of patients with peripheral arterial disease (lower extremity, renal, mesenteric, and abdominal aortic).Circulation.2006;113:e463e654.
  3. Meijer WT,Hoes AW,Rutgers D,Bots ML,Hofman A,Grobbee DE.Peripheral arterial disease in the elderly: the Rotterdam Study.Arterioscler Thromb Vasc Biol.1998;18:185192.
  4. Hirsch AT,Criqui MH,Treat‐Jacobson D, et al.Peripheral arterial disease detection, awareness, and treatment in primary care.JAMA.2001;286:13171324.
  5. Selvin E,Erlinger TP.Prevalence of and risk factors for peripheral arterial disease in the United States: Results from the National Health and Nutrition Examination Survey, 1999‐2000.Circulation.2004;110:738743.
  6. Criqui MH,Langer RD,Fronek A, et al.Mortality over a period of 10 years in patients with peripheral arterial disease.N Engl J Med.1992;326:381386.
  7. Wilterdink JI,Easton JD.Vascular event rates in patients with atherosclerotic cerebrovascular disease.Arch Neurol.1992;49:857863.
  8. Steg PG,Bhatt DL,Wilson PWF, et al.;REACH Registry Investigators. One‐year cardiovascular event rates in outpatients with atherothrombosis.JAMA.2007;297:11971206.
  9. Weitz JI,Byrne J,Clagett GP, et al.Diagnosis and treatment of chronic arterial insufficiency of the lower extremities: A critical review.Circulation.1996;94:30263049.
  10. Dormandy JA,Rutherford RB.Management of peripheral arterial disease (PAD): TASC Working Group. TransAtlantic Inter‐Society Consensus (TASC).J Vasc Surg.2000:31(1Pt 2):S1S296.
  11. McGee SR,Boyko EJ.Physical examination and chronic lower‐extremity ischemia.Arch Intern Med.1998;158:13571364.
  12. Hiatt WR.Medical treatment of peripheral artery disease and claudication.N Engl J Med.2001;344:16081621.
  13. Newman AB,Siscovick DS,Manolio TA, et al.Ankle‐arm index as a marker of atherosclerosis in the Cardiovascular Health Study. Cardiovascular Heart Study (CHS) Collaborative Research Group.Circulation.1993;88:837845.
  14. Newman AB,Sutton‐Tyrrell K,Vogt MT,Kuller H.Morbidity and mortality in hypertensive adults with a low ankle/arm blood pressure index.JAMA.1993;270:487489.
  15. Newman AB,Shemanski L,Manolio TA, et al.Ankle‐arm index as a predictor of cardiovascular disease and mortality in the Cardiovascular Health Study. The Cardiovascular Health Study Group.Arterioscler Thromb Vasc Biol.1999;19:538545.
  16. Murabito JM,Evans JC,Larson MG,Nieto K,Levy D,Wilson PWF;Framingham Study. The ankle‐brachial index in the elderly and risk of stroke, coronary disease, and death: the Framingham Study.Arch Intern Med.2003;163:19391942.
  17. Antiplatelet Trialists' Collaboration.Collaborative overview of randomized trials of antiplatelet therapy—1: Prevention of death, myocardial infarction, and stroke by prolonged antiplatelet therapy in various categories of patients.BMJ.1994;308:81106.
  18. Antithrombotic Trialists' Collaboration.Collaborative meta‐analysis of randomized trials of antiplatelet therapy for prevention of death, myocardial infarction, and stroke in high risk patients.BMJ.2002;324:7186.
  19. The Medical Research Council's General Practice Research Framework.Thrombosis prevention trial: randomised trial of low‐intensity oral anticoagulation with warfarin and low‐dose aspirin in the primary prevention of ischemic heart disease in men at increased risk.Lancet.1998;351:233241.
  20. Hansson L,Zanchetti A,Carruthers SG, for theHOT Study Group.Effects of intensive blood pressure lowering and low‐dose aspirin in patients with hypertension: principal results of the Hypertension Optimal Treatment (HOT) randomised trial.Lancet1998;280:19301935.
  21. Collaborative Group of the Primary Prevention Project (PPP).Low‐dose aspirin and vitamin E in people at cardiovascular risk: a randomized trial in general practice.Lancet.2001;357:8995.
  22. CAPRIE Steering Committee.A randomized, blinded, trial of clopidogrel versus aspirin in patients at risk of ischemic events (CAPRIE).Lancet.1996;348:13291339.
  23. Bhatt DL,Fox KAA,Hacke WB; for theCHARISMA Investigators.Clopidogrel and aspirin versus aspirin alone for the prevention of atherothrombotic events.N Engl J Med.2006;354:17061717.
  24. Diener H‐C,Boguousslavsky J,Brass LM; on behalf of theMATCH investigators.Aspirin and clopidogrel compared with clopidogrel alone after ischaemic stroke or transient ischaemic attack in high‐risk patients (MATCH): randomised, double‐blind, placebo‐controlled trial.Lancet.2004;364:331337.
Issue
Journal of Hospital Medicine - 3(2)
Issue
Journal of Hospital Medicine - 3(2)
Page Number
S4-S8
Page Number
S4-S8
Publications
Publications
Article Type
Display Headline
Peripheral arterial disease and the hospitalist: The rationale for early detection and optimal therapy
Display Headline
Peripheral arterial disease and the hospitalist: The rationale for early detection and optimal therapy
Legacy Keywords
peripheral arterial disease, diagnosis, and antiplatelet therapy
Legacy Keywords
peripheral arterial disease, diagnosis, and antiplatelet therapy
Sections
Article Source
Copyright © 2008 Society of Hospital Medicine
Disallow All Ads
Correspondence Location
Department of Emergency Medicine, Wake Forest University Baptist Medical Center, Medical Center Boulevard, Winston‐Salem, NC 27157
Content Gating
Gated (full article locked unless allowed per User)
Gating Strategy
First Peek Free
Article PDF Media

Prevention of venous thromboembolism in the hospitalized medical patient

Article Type
Changed
Tue, 09/25/2018 - 15:48
Display Headline
Prevention of venous thromboembolism in the hospitalized medical patient

The need for prophylaxis of venous thromboembolism (VTE) in hospitalized acutely ill medical patients is well established. Without prophylaxis, hospitalized medical patients develop VTE at a rate of 5% to 15%.1–3 Moreover, pulmonary embolism (PE) occurs more frequently in hospitalized medical patients than in nonmedical patients, and is a leading cause of sudden death in hospitalized medical patients.4,5 Without appropriate prophylaxis, 1 in 20 hospitalized medical patients may suffer a fatal PE.4

PROPHYLAXIS IN MEDICAL PATIENTS: UNDERUSED AND OFTEN INAPPROPRIATE

Despite these risks and the clear indications for VTE prophylaxis in hospitalized medical patients, prophylaxis of VTE is omitted more often in these patients than in hospitalized surgical patients.5 Even when prophylaxis is given, it is often used inappropriately in the medical population. So concludes a recent analysis of data from 196,104 patients with acute medical conditions who were discharged from 227 US hospitals from January 2002 to September 2005.6 Criteria for inclusion in the analysis were patient age of 40 years or older, a hospital stay of 6 days or greater, and an absence of contraindications to anticoagulation. Appropriate prophylaxis was defined in accordance with the Sixth American College of Chest Physicians (ACCP) Consensus Conference on Antithrombotic Therapy.7

The analysis revealed an overall VTE prophylaxis rate of 61.8%, but the rate of appropriate prophylaxis was only 33.9%, meaning that two-thirds of discharged patients did not receive prophylaxis in accordance with ACCP guidelines. When temporal trends were analyzed according to groups based on patients’ diagnosis at admission (acute myocardial infarction, severe lung disease, ischemic stroke, cancer, heart failure, or trauma), the rate of appropriate prophylaxis remained essentially flat from the beginning to the end of the study period for virtually all diagnosis groups.6

Similar findings have emerged from the International Medical Prevention Registry on Venous Thromboembolism (IMPROVE), an ongoing international registry of acutely ill medical patients.8 Data from the first 15,156 patients, enrolled from July 2002 through September 2006, reveal that 50% of patients received pharmacologic and/or mechanical VTE prophylaxis in the hospital, and only 60% of patients who met established criteria for VTE prophylaxis actually received it.

Analysis of the US portion of the IMPROVE data shows that 54% of the US patient sample received some form of VTE prophylaxis; 22% of US patients received intermittent pneumatic compression, 21% received unfractionated heparin (UFH), 14% received low-molecular-weight heparin (LMWH), and 3% wore compression stockings.8 Thus, despite a paucity of data supporting a benefit of intermittent pneumatic compression in this population,9 it was the most frequently used form of prophylaxis in US patients.

CLINICAL TRIALS OF PHARMACOLOGIC PROPHYLAXIS IN MEDICAL PATIENTS

Reprinted, with permission, from New England Journal of Medicine (Francis CW. Prophylaxis for thromboembolism in hospitalized medical patients. N Engl J Med 2007; 356:1438–1444.). Copyright © 2007 Massachusetts Medical Society. All rights reserved.
Figure 1. Rates of venous thromboembolism (VTE) in three large double-blind, placebo-controlled studies of pharmacologic prophylaxis of VTE in high-risk hospitalized medical patients.
The evidence in support of pharmacologic prophylaxis of VTE in high-risk hospitalized medical patients is considerable. Three large double-blind, placebo-controlled trials of anticoagulants currently available in the United States have been reported in this patient population (Figure 1).1–3

The Prophylaxis in Medical Patients with Enoxaparin (MEDENOX) trial1 randomized 1,102 hospitalized patients to one of two doses of the LMWH enoxaparin (20 mg or 40 mg once daily subcutaneously) or placebo for 6 to 14 days. Compared with placebo, the 40-mg dose of enoxaparin was associated with a 63% reduction in risk of VTE over 3 months of follow-up (P < .001) (Figure 1).

The Prospective Evaluation of Dalteparin Efficacy for Prevention of VTE in Immobilized Patients Trial (PREVENT)2 was a multicenter, randomized, double-blind study comparing the LMWH dalteparin (5,000 IU daily given subcutaneously for 14 days) with placebo in 3,706 acutely ill medical patients. Over 90 days of follow-up, the risk of VTE was reduced by 44% in patients assigned to dalteparin compared with those assigned to placebo (P = .0015) (Figure 1).

The Arixtra for Thromboembolism Prevention in a Medical Indications Study (ARTEMIS)3 randomized 849 medical patients 60 years or older to 6 to 14 days of therapy with the selective factor Xa inhibitor fondaparinux (2.5 mg once daily subcutaneously) or placebo. Compared with the placebo group, fondaparinux recipients had a 47% lower risk of developing VTE by day 15 (P = .029) (Figure 1).

Fewer events and fatal PEs, but no effect on all-cause mortality

A recent meta-analysis by Dentali et al10 further demonstrates the efficacy of anticoagulant therapy for preventing symptomatic VTE in hospitalized medical patients. This analysis included several other trials in addition to the three reviewed above,1–3 for a total of nine randomized studies (seven of which were dou-ble-blind) comprising 19,958 patients. Across the nine studies, anticoagulant prophylaxis was clearly superior to placebo in preventing fatal PE (relative risk, 0.38 [95% CI, 0.21 to 0.69]). There was a strong trend toward a reduction in symptomatic deep vein thrombosis (DVT) with prophylaxis but no effect on all-cause mortality. The meta-analysis also provided reassurance that prophylaxis does not increase the rate of major bleeding.

 

 

HOW DO THE PROPHYLAXIS OPTIONS STACK UP?

What the ACCP recommends

Current ACCP guidelines recommend the use of either LMWH or low-dose UFH (5,000 U subcutaneously two or three times daily) as a Grade 1A recommendation for VTE prophylaxis in patients with medical conditions and risk factors for VTE.9 This represents the guidelines’ highest level of recommendation, ie, one that is based on randomized controlled trials (RCTs) without important limitations. In contrast, the 2006 International Consensus Statement, developed as a collaborative effort among expert bodies on VTE, specified a more narrow dosing recommendation for UFH in this patient population (5,000 U three times daily, not twice daily) as well as specifying 40 mg once daily as the recommended dose of enoxaparin and 5,000 IU once daily as the recommended dose of dalteparin.11

For medical patients with risk factors for VTE who have a contraindication to anticoagulant prophylaxis, the ACCP guidelines recommend the use of graduated compression stockings or intermittent pneumatic compression devices as a Grade 1C+ recommendation (“no RCTs but strong RCT results can be unequivocally extrapolated, or overwhelming evidence from observational studies”9).

Current ACCP guidelines do not address the use of fondaparinux in their recommendations for VTE prophylaxis in medical patients.

Getting a handle on bleeding risk

Patient characteristics that exclude pharmacologic thromboprophylaxis due to bleeding risk are generally limited to active bleeding or coagulopathy, as demonstrated by a platelet count less than 50,000 cells/µL or an international normalized ratio greater than 1.5. Additionally, bleeding risk should be carefully assessed if an invasive procedure is planned during a patient’s hospital stay.

It is worth noting that the anticoagulant doses used for VTE prophylaxis are a fraction of those used for treatment of VTE. Thus, if a patient would be treated with full-dose anticoagulation if VTE developed, then that patient should be eligible for VTE prophylaxis.

Because the use of mechanical forms of prophylaxis in medical patients is not truly evidence-based, mechanical prophylaxis should be reserved for medical patients who have a contraindication to anticoagulants, or for use in combination with anticoagulants in patients at very high risk of VTE.

UFH vs LMWH

Two meta-analyses have compared UFH with LMWH for VTE prevention in medical patients.12,13 In a recent analysis that included 10 trials directly comparing the two therapies, 14 trials comparing UFH with control, and 11 trials comparing LMWH with control, Wein et al found a lower risk of DVT with LMWH than with UFH (relative risk, 0.68 [95% CI, 0.52 to 0.88]) but no difference between the therapies in mortality or bleeding risk.12 In an earlier and smaller analysis, Mismetti et al found no significant differences between UFH and LMWH in preventing DVT or death but did find a significant reduction in major bleeding episodes with LMWH versus three-times-daily UFH (52% relative reduction; P = .049).13

Randomized trials also reveal that enoxaparin 40 mg once daily is as efficacious as UFH 5,000 U three times daily for VTE prevention in medical patients.14,15 The above analysis by Wein et al12 and an additional meta-analysis by King and colleagues16 found that three-times-daily dosing of UFH is more efficacious than twice-daily dosing of UFH, but at the expense of more bleeding, including major bleeding.

Economic considerations

Because of differences in drug acquisition costs between UFH and the LMWH agents, several economic evaluations have compared the use of these therapies for prophylaxis in medical patients at risk of VTE.

In an analysis of hospital costs for medical patients receiving VTE prophylaxis from more than 330 US hospitals for the period 2001–2004, Burleigh et al found that mean total hospital costs were higher for patients who received UFH than for those who received LMWH ($7,615 vs $6,866) even though mean drug costs were higher for LMWH ($791 vs $569 for UFH).17 A reduction in hospital length of stay appeared to contribute to the overall savings with LMWH; other contributors may have included costs associated with heparin-induced thrombocytopenia (HIT) in UFH recipients or the extra nursing time required for administering UFH in two or three daily doses.

Leykum et al used a decision analysis model to estimate the economic effect of substituting enoxaparin for UFH in hospitalized medical patients for whom VTE prophylaxis is indicated.18 Cost data were based on Medicare reimbursement rates as well as drug and laboratory costs for a multi-institutional health system. The model assumed HIT incidence rates of 2.7% with UFH and 0.3% with enoxaparin. It also assumed the cost of a daily dose to be $4 for UFH versus $84 for enoxaparin. From the payer perspective, the model showed that substituting enoxaparin for UFH would reduce the overall cost of care by $28.61 per day on a per-patient basis, despite enoxaparin’s higher acquisition cost, and would save $4,550 per quality-adjusted life-year by reducing the incidence of HIT.

Another cost analysis confirms the association between HIT and increased hospital costs. Creekmore et al retrospectively analyzed data from 10,121 adult medical patients who received VTE prophylaxis at the University of Utah Hospital in Salt Lake City from August 2000 to November 2004.19 They found that an admission during which HIT developed incurred a mean cost of $56,364, compared with $15,231 for an admission without HIT. Because LMWH was associated with a lower incidence of HIT compared with UFH (0.084% vs 0.51%, respectively), LMWH reduced the incremental cost of VTE prophylaxis by $13.88 per patient compared with UFH.

THE EXCLAIM TRIAL: IS THERE A ROLE FOR EXTENDED PROPHYLAXIS?

Although the previously discussed studies have clearly demonstrated the benefit of in-hospital VTE prophylaxis for acutely ill medical patients, none has rigorously examined extended-duration out-of-hospital prophylaxis in these patients. This represents an important gap in the literature, since a substantial proportion of VTE develops in the outpatient setting within 3 months of a hospitalization, and most outpatient VTE episodes occur within 1 month of a preceding hospitalization.20

To begin to fill this gap, the Extended Clinical Prophylaxis in Acutely Ill Medical Patients (EXCLAIM) trial was conducted to compare extended-duration LMWH prophylaxis with a standard LMWH prophylaxis regimen in acutely ill medical patients using a prospective, multicenter, randomized, double-blind, placebo-controlled design.21

Patients and study design

Patients were eligible for enrollment if they were aged 40 years or older and had recent immobilization (≤ 3 days), a predefined acute medical illness, and either level 1 mobility (total bed rest or sedentary state) or level 2 mobility (level 1 with bathroom privileges). The predefined acute medical illnesses consisted of New York Heart Association class III/IV heart failure, acute respiratory insufficiency, or other acute medical conditions, including post-acute ischemic stroke, acute infection without septic shock, and active cancer.

All patients received open-label enoxaparin 40 mg subcutaneously once daily for 10 ± 4 days, after which they were randomized to either enoxaparin 40 mg subcutaneously once daily or placebo for an additional 28 ± 4 days.

The primary efficacy end point was the incidence of VTE events, defined as asymptomatic DVT documented by mandatory ultrasonography at the end of the double-blind treatment period (28 ± 4 days) or as symptomatic DVT, symptomatic PE, or fatal PE at any time during the double-blind period. Symptomatic DVT was confirmed by objective tests; PE was confirmed by ventilation-perfusion scan, computed tomography, angiography, or autopsy. 

Secondary efficacy end points were mortality at the end of the double-blind period, at 3 months, and at 6 months, as well as the incidence of VTE at 3 months.

The primary safety outcome measure was the incidence of major hemorrhage during the double-blind period; secondary safety measures were rates of major and minor hemorrhage, minor hemorrhage, HIT, and serious adverse events.

 

 

Population amended at planned interim analysis

After approximately half of the patients were enrolled, a planned and blinded interim analysis for futility concluded that the study was unlikely to show a statistically significant advantage of enoxaparin over placebo. The trial’s steering committee followed the suggestion of its data safety monitoring board to redefine the inclusion criteria to refocus enrollment on patients with a high risk of VTE. A blinded analysis was performed to identify this subgroup.

The resulting amended inclusion criteria were the same as above except that level 2 mobility had to be accompanied by at least one of three additional high-risk criteria: (1) age greater than 75 years, (2) history of prior VTE, or (3) diagnosis of cancer.

The trial’s main exclusion criteria were evidence of active bleeding, a contraindication to anticoagulation, receipt of prophylactic LMWH or UFH more than 72 hours prior to enrollment, treatment with an oral anticoagulant within 72 hours of enrollment, major surgery within the prior 3 months, cerebral stroke with bleeding, and persistent renal failure (creatinine clearance < 30 mL/min).

Results

The amended study population included 5,105 patients, 5,049 of whom received open-label enoxaparin. Of this group, 2,013 were randomized to active extended prophylaxis with enoxparain and 2,027 to placebo. Baseline characteristics, including level of mobility, were similar between the two groups.

Efficacy. As detailed in Table 1, VTE events occurred at a statistically significantly higher rate in the placebo arm than in the extended-duration enoxaparin arm, as did asymptomatic proximal DVT and symptomatic VTE. Rates of PE and fatal PE were also lower with enoxaparin than with placebo, but the number of events was so small that the between­group differences were not statistically significant.

The efficacy of extended prophylaxis with enoxaparin was enduring, as the cumulative incidence of VTE events at day 90 was significantly lower in enoxaparin recipients than in placebo recipients (3.0% vs 5.2%; relative reduction of 42%; P = .0115).

There was no difference in all-cause mortality at 6 months between the enoxaparin and placebo groups (10.1% vs 8.9%, respectively; P = .179).

Safety. Major hemorrhage was significantly more frequent in the enoxaparin arm, occurring in 0.60% of enoxaparin recipients compared with 0.15% of placebo recipients (P = .019). Minor bleeding was also more common with enoxaparin (5.20% vs 3.70%; P = .024).

Conclusions

The EXCLAIM trial found that an extended-duration (38-day) enoxaparin regimen significantly reduced the overall incidence of VTE relative to a 10-day enoxaparin regimen in acutely ill medical patients with reduced mobility. At the same time, the extended regimen was associated with a significant increase in the rate of major bleeding, although the incidence of major bleeding was low. The investigators concluded that the net clinical effect of extended-duration prophylaxis with enoxaparin is favorable, as only 46 patients would need to be treated to prevent one VTE event, whereas 224 patients would need to be treated to result in one major bleeding event.21

For this reason, it is reasonable to consider extended prophylaxis for hospitalized medical patients after identifying these patients’ risk factors. In keeping with the trial’s amended inclusion criteria, patients older than age 75 and those with cancer or prior VTE should receive special consideration for extended prophylaxis.

RECOMMENDED APPROACH TO VTE PREVENTION IN HOSPITALIZED MEDICAL PATIENTS

Figure 2. Algorithm for VTE prophylaxis in the hospitalized medical patient.
Given the wide gap between the evidence reviewed above and current practice worldwide,8,22,23 we propose the algorithm presented in Figure 2 for the prevention of VTE in hospitalized medical patients. Our recommended approach is guided by the principles below:

  • All hospitalized medical patients should be screened at the time of admission, and patients at risk for VTE should receive prophylaxis.
  • All patients with reduced mobility and one or more other risk factors for VTE are candidates for prophylaxis.
  • Patients should be reassessed daily for the development of VTE risk factors during their hospitalization if risk factors are absent on admission.
  • If screening or reassessment reveals any VTE risk factors, pharmacologic prophylaxis is the mainstay of therapy. If exclusion criteria for pharmacologic prophylaxis are present, mechanical prophylaxis with graduated compression stockings and intermittent compression devices should be used. For very high-risk medical patients without a contraindication to anticoagulants, combination prophylaxis with both an anticoagulant and mechanical devices is preferred.
  • In this patient population, LMWH agents are preferred as pharmacologic prophylaxis over UFH and over fondaparinux (which is not currently approved by the US Food and Drug Administration for this population).
  • If UFH is to be used in this patient population, 5,000 U three times daily is the preferred dosage.
  • Extended pharmacologic prophylaxis should be considered in patients older than age 75 and in patients with a cancer diagnosis or a prior VTE episode.

 

 

DISCUSSION: ADDITIONAL PERSPECTIVES FROM THE AUTHORS

Dr. Jaffer: Dr. Spyropoulos, are there any guidelines, other than those from the ACCP, that speak to VTE prophylaxis in hospitalized medical patients? If so, what are their take-home messages and how do they differ from the ACCP guidelines?

Dr. Spyropoulos: I was part of the group that developed the International Consensus Statement (ICS) published in International Angiology in 2006,11 which is more recent than the latest ACCP guidelines, which were published in 2004. The ICS drew on much of the same data that the ACCP did, but we did an updated review of clinical trials.

For VTE prophylaxis in hospitalized medical patients, the ICS recommendations are more specific with regard to the type, dose, and dosing frequency of anticoagulant agents. First, they specify doses for both LMWH agents in this patient setting: 40 mg once daily for enoxaparin, and 5,000 IU once daily for dalteparin.

The ICS document also states that if UFH is the choice for prophylaxis, a regimen of 5,000 U three times daily should be considered. In the past year alone, two analyses suggest that three-times-daily dosing of UFH in medical patients provides superior efficacy to twice-daily dosing, although perhaps at the expense of more bleeding episodes.12,16 It is important to remember that no large placebo-controlled trial supports the efficacy of a UFH regimen of 5,000 U twice daily in this population.

Finally, the ICS document states that fondaparinux 2.5 mg once daily is a viable option for prophylaxis in medical patients, based on the ARTEMIS trial,3 even though this represents an off-label use.

Dr. Jaffer: Real-world use of VTE prophylaxis is far from optimal, especially in medical patients, and this is partly a result of system-of-care issues. I’d like to conclude by asking each of my colleagues to offer your perspectives on how your own institutions have improved their systems of care to promote better use of VTE prophylaxis and what lessons might be shared with others. Dr. McKean, you work at Brigham and Women’s Hospital, which recently reported impressive results with an electronic alert system designed to increase clinicians’ consideration of VTE risk assessment and use of prophylaxis.24 Please tell us about that study and the alert system.

Dr. McKean: Despite many educational initiatives at Brigham and Women’s Hospital, there were still some patients at high risk for VTE who were not receiving appropriate prophylaxis. What Dr. Samuel Goldhaber and his colleagues wanted to determine was whether changing the system of care could result in a reduced incidence of VTE.24 They devised a computer software program linked to the patient database that used eight common risk factors to determine each hospitalized patient’s risk profile for VTE. Each risk factor was weighted according to a point scale, with major risk factors (cancer, prior VTE, or hypercoagulability) assigned 3 points, the intermediate risk factor of surgery assigned 2 points, and minor risk factors (advanced age, obesity, immobility, or use of hormone replacement therapy or oral contraceptives) assigned 1 point. For patients with a total risk score of 4 or greater, the computer screen generates a color-coded VTE risk alert that requires the physician to acknowledge the alert and choose one of three options: order prophylaxis as appropriate, review a 60-page document on the computer to learn more about prophylaxis, or do nothing.

The study found that hospitalized patients who were randomized to treatment under the computer alert system were significantly more likely to receive VTE prophylaxis and significantly less likely to develop VTE than were patients randomized to a control group. The alert system reduced the risk of DVT or PE at 90 days by 41% in patients considered to be at high risk. It was particularly interesting that the incidence of VTE was lower in the intervention group even when physicians chose not to use prophylaxis, which suggests that simply having this alert system in place improved outcomes, perhaps by raising awareness of the risk of VTE.24

Additional studies are needed to better understand physicians’ behavior and determine why they seem to have a disproportionate fear of the risk of bleeding relative to the risk of clotting, including fatal PE, because that is really the heart of the matter. When patients are not given prophylaxis, often it is because of fear of bleeding. It is not clear, however, why some of these patients did not receive mechanical devices as an alternative form of prophylaxis, but this seems to be the case worldwide, as shown recently by the multinational ENDORSE study.22 Meanwhile, as we await studies to better understand physician perceptions and behaviors regarding prophylaxis, we need to work hard to change the system of care.

Dr. Deitelzweig: Over the past couple of years, the Ochsner Clinic has grown from a one-hospital teaching organization to a seven-hospital system with a mix of closed and open medical staff. The challenge is how to take a process that worked well in the one center, where appropriate prophylaxis was used about 90% of the time, and transfer it to the other centers in the larger system. We have endorsed several types of performance tools, such as the change-acceleration processes used by General Electric. The aim is to share a vision of heightening awareness. To do that, we have worked to mobilize the key stakeholders, at least half of them, to build algorithms that they all will endorse. It is easier said than done, however, and we have found it essential to involve both physicians and non-physician colleagues from pharmacy and nursing who have political and organizational clout.

Dr. Brotman: At Johns Hopkins, I took a bit more draconian approach to this issue because I thought that hospitalists often knew that they should be using VTE prophylaxis but sometimes weren’t, and I am not convinced that clinicians always look at prompts. So we came up with a system that incorporates both billing and documentation simultaneously. We put a hard stop on users’ documentation so that they could not sign off on a note or bill for their care until they checked off the kind of VTE prophylaxis they were using. Since hospitalists ultimately care about billing for their work, this system has at least ensured that everybody has considered and documented VTE prophylaxis on a daily basis. There are other hard stops that can be implemented in computer order-entry systems as well, and we are considering ways to roll them out on a broader scale.

However, all of these systems can have problems because patient situations change from day to day. For instance, VTE prophylaxis is not necessarily indicated in a 38-year-old ambulatory patient who comes in with a sickle cell crisis, but you will need to reconsider if the patient ends up in acute chest syndrome in the intensive care unit. I do not yet have a good way to ensure that this is being done on a daily basis with all patients.

Dr. Amin: At the University of California, Irvine, we implemented an electronic alert system, but we locked users in so that they could not complete their admission orders until they answered questions about VTE prevention. This practice increased our VTE prophylaxis rates tremendously. Because we are a level I trauma center, we allow users to bypass the screens one time, but the next time they log in, even to get a simple lab result, they have to answer the questions about VTE prevention.

With any system you develop, you also have to continue with the education process, because clinicians sometimes get into bad habits or simply forget things.

Dr. Spyropolous: At Lovelace Medical Center, we didn’t have the sophistication of an electronic order-entry system, but we had an experienced clinical pharmacist (the director of inpatient pharmacy) who helped to develop and champion VTE prevention guidelines that have then been used throughout the system in close conjunction with our hospitalists’ rounds. This system has been used successfully for the past 7 years.

References
  1. Samama MM, Cohen AT, Darmon JY, et al. A comparison of enoxaparin with placebo for the prevention of venous thrombo-embolism in acutely ill medical patients. Prophylaxis in Medical Patients with Enoxaparin Study Group. N Engl J Med 1999; 341:793–800.
  2. Leizorovicz A, Cohen AT, Turpie AG, et al. Randomized, placebo-controlled trial of dalteparin for the prevention of venous thromboembolism in acutely ill medical patients. Circulation 2004; 110:874–879.
  3. Cohen AT, Davidson BL, Gallus AS, et al. Efficacy and safety of fondaparinux for the prevention of venous thromboembolism in older acute medical patients: randomised placebo controlled trial. BMJ 2006; 332:325–329.
  4. Baglin TP, White K, Charles A. Fatal pulmonary embolism in hos-pitalised medical patients. J Clin Pathol 1997; 50:609–610.
  5. Piazza G, Seddighzadeh A, Goldhaber SZ. Double trouble for 2,609 hospitalized medical patients who developed deep vein thrombosis: prophylaxis omitted more often and pulmonary embolism more frequent. Chest 2007; 132:554–561.
  6. Amin A, Stemkowski S, Lin J, Yang G. Thromboprophylaxis rates in US medical centers: success or failure? J Thromb Haemost 2007; 5:1610–1616.
  7. Geerts WH, Heit JA, Clagett GP, et al. Prevention of venous thromboembolism. Chest 2001; 119(1 Suppl):132S–175S.
  8. Tapson VF, Decousus H, Pini M, et al. Venous thromboembolism prophylaxis in acutely ill hospitalized medical patients: findings from the International Medical Prevention Registry on Venous Thromboembolism. Chest 2007; 132:936–945.
  9. Geerts WH, Pineo GF, Heit JA, et al. Prevention of venous thrombo-embolism: the Seventh ACCP Conference on Antithrombotic and Thrombolytic Therapy. Chest 2004; 126(3 Suppl):338S–400S.
  10. Dentali F, Douketis JD, Gianni M, Lim W, Crowther MA. Meta-analysis: anticoagulant prophylaxis to prevent symptomatic venous thromboembolism in hospitalized medical patients. Ann Intern Med 2007; 146:278–288.
  11. Cardiovascular Disease Educational and Research Trust; Cyprus Cardiovascular Disease Educational and Research Trust; European Venous Forum; International Surgical Thrombosis Forum; International Union of Angiology; Union Internationale de Phlébologie. Prevention and treatment of venous thromboembolism. International Consensus Statement (guidelines according to scientific evidence). Int Angiol 2006; 25:101–161.
  12. Wein L, Wein S, Haas SJ, Shaw J, Krum H. Pharmacological venous thromboembolism prophylaxis in hospitalized medical patients: a meta-analysis of randomized controlled trials. Arch Intern Med 2007; 167:1476–1486.
  13. Mismetti P, Laporte-Simitsidis S, Tardy B, et al. Prevention of venous thromboembolism in internal medicine with unfractionated or low-molecular-weight heparins: a meta-analysis of randomised clinical trials. Thromb Haemost 2000; 83:14–19.
  14. Lechler E, Schramm W, Flosbach CW. The venous thrombotic risk in non-surgical patients: epidemiological data and efficacy/safety profile of a low-molecular-weight heparin (enoxaparin). The Prime Study Group. Haemostasis 1996; 26(Suppl 2):49–56.
  15. Kleber FX, Witt C, Vogel G, et al; the PRINCE Study Group. Randomized comparison of enoxaparin with unfractionated heparin for the prevention of venous thromboembolism in medical patients with heart failure or severe respiratory disease. Am Heart J 2003; 145:614–621.
  16. King CS, Holley AB, Jackson JL, Shorr AF, Moores LK. Twice vs three times daily heparin dosing for thromboembolism prophylaxis in the general medical population: a meta-analysis. Chest 2007; 131:507–516.
  17. Burleigh E, Wang C, Foster D, et al. Thromboprophylaxis in medically ill patients at risk for venous thromboembolism. Am J Health Syst Pharm 2006; 63(20 Suppl 6):S23–S29.
  18. Leykum L, Pugh J, Diuguid D, Papadopoulos K. Cost utility of substituting enoxaparin for unfractionated heparin for prophylaxis of venous thrombosis in the hospitalized medical patient. J Hosp Med 2006; 1:168–176.
  19. Creekmore FM, Oderda GM, Pendleton RC, Brixner DI. Incidence and economic implications of heparin-induced thrombocytopenia in medical patients receiving prophylaxis for venous thromboembolism. Pharmacotherapy 2006; 26:1438–1445.
  20. Spencer FA, Lessard D, Emery C, Reed G, Goldberg RJ. Venous thromboembolism in the outpatient setting. Arch Intern Med 2007; 167:1471–1475.
  21. Hull RD, Schellong SM Tapson VF, et al. Extended-duration venous thromboembolism (VTE) prophylaxis in acutely ill medical patients with recent reduced mobility: the EXCLAIM study. Presentation at: International Society on Thrombosis and Haemo-stasis XXIst Congress; July 6–12, 2007; Geneva, Switzerland.
  22. Cohen AT, Tapson VF, Bergmann JF, et al. Venous thromboembolism risk and prophylaxis in the acute hospital care setting (ENDORSE study): a multinational cross-sectional study. Lancet 2008; 371:387–394.
  23. Kahn SR, Panju A, Geerts W, et al; CURVE study investigators. Multicenter evaluation of the use of venous thromboembolism prophylaxis in acutely ill medical patients in Canada. Thromb Res 2007; 119:145–155.
  24. Kucher N, Koo S, Quiroz R, et al. Electronic alerts to prevent thromboembolism among hospitalized patients. N Engl J Med 2005; 352:969–977.
  25. Anderson FA Jr, Wheeler HB, Goldberg RJ, et al. A population-based perspective of the hospital incidence and case-fatality rates of deep vein thrombosis and pulmonary embolism. The Worcester DVT Study. Arch Intern Med 1991; 151:933–938.
  26. Howell MD, Geraci JM, Knowlton AA. Congestive heart failure and outpatient risk of venous thromboembolism: a retrospective, case-control study. J Clin Epidemiol 2001; 54:810–816.
  27. Smeeth L, Cook C, Thomas S, Hall AJ, Hubbard R, Vallance P. Risk of deep vein thrombosis and pulmonary embolism after acute infection in a community setting. Lancet 2006; 367:1075–1079.
  28. Alikhan R, Cohen AT, Combe S, et al. Prevention of venous thromboembolism in medical patients with enoxaparin: a subgroup analysis of the MEDENOX study. Blood Coagul Firbinolysis 2003; 14:341–346.
  29. Anderson FA Jr, Spencer FA. Risk factors for venous thromboembolism. Circulation 2003; 107(23 Suppl 1):I9–I16.
  30. Greinacher A, Warkentin TE. Recognition, treatment, and prevention of heparin-induced thrombocytopenia: review and update. Thromb Res 2006; 118:165–176.
  31. Martel N, Lee J, Wells PS. Risk for heparin-induced thrombocytopenia with unfractionated and low-molecular-weight heparin thromboprophylaxis: a meta-analysis. Blood 2005; 106:2710–2715.
  32. Sanderink GJ, Guimart CG, Ozoux ML, Jariwala NU, Shukla UA, Boutouyrie BX. Pharmacokinetics and pharmacodynamics of the prophylactic dose of enoxaparin once daily over 4 days in patients with renal impairment. Thromb Res 2002; 105:225–231.
  33. Douketis J, Cook D, Zytaruk N, et al. Dalteparin thromboprophylaxis in critically ill patients with severe renal insufficiency: the DIRECT study [abstract]. J Thromb Haemost 2007; 5(Suppl 2): P-S-680.
  34. Scholten DJ, Hoedema RM, Scholten SE. A comparison of two different prophylactic dose regimens of low molecular weight heparin in bariatric surgery. Obes Surg 2002; 12:19–24.
Article PDF
Author and Disclosure Information

Amir K. Jaffer, MD
Associate Professor of Medicine; Chief, Division of Hospital Medicine, Department of Medicine, Leonard M. Miller School of Medicine, University of Miami, Miami, FL

Alpesh N. Amin, MD, MBA
Professor and Chief, Division of General Internal Medicine; Executive Director, Hospitalist Program; Vice Chair for Clinical Affairs & Quality, Department of Medicine, University of California, Irvine, Irvine, CA

Daniel J. Brotman, MD
Director, Hospitalist Program; Associate Professor of Medicine, Johns Hopkins Hospital, Baltimore, MD

Steven B. Deitelzweig, MD
Vice President of Medical Affairs; Chairman, Department of Hospital Medicine, Ochsner Health System, New Orleans, LA

Sylvia C. McKean, MD
Medical Director, BWH/Faulkner Hospitalist Service; Associate Professor of Medicine, Harvard Medical School and Brigham and Women’s Hospital, Boston, MA

Alex C. Spyropoulos, MD
Chair, Clinical Thrombosis Center, Lovelace Medical Center; Clinical Associate Professor of Medicine/Associate Professor of Pharmacy, University of New Mexico Health Sciences Center/College of Pharmacy, Albuquerque, NM

Correspondence: Amir K. Jaffer, MD, Chief, Division of Hospital Medicine, Leonard M. Miller School of Medicine, University of Miami, 1120 NW 14th Street, 933 CRB (C216), Miami, FL 33136; [email protected]

Dr. Jaffer reported that he has received consulting fees and honoraria for teaching/speaking from Sanofi-Aventis, consulting fees and research grant support from AstraZeneca, and consulting fees from Roche Diagnostics and Boehringer Ingelheim; he also serves on the governing board of the Society for Perioperative Assessment and Quality Improvement (SPAQI) and the board of directors of the Anticoagulation Forum.

Dr. Amin reported that he has received research funding and honoraria for speaking from Sanofi-Aventis, Eisai, and GlaxoSmithKline.

Dr. Brotman reported that he has no financial relationships with commercial interests that are relevant to this article.

Drs. Deitelzweig and McKean each reported that they have received honoraria for teaching/speaking from Sanofi-Aventis. Dr. Spyropoulos reported that he has received consulting fees from Sanofi-Aventis, Eisai, and Boehringer Ingelheim.

Each author received an honorarium for participating in the roundtable that formed the basis of this supplement. The honoraria were paid by the Cleveland Clinic Center for Continuing Education from the educational grant from Sanofi-Aventis underwriting this supplement. Sanofi-Aventis had no input on the content of the roundtable or this supplement.

Publications
Page Number
S7-S16
Author and Disclosure Information

Amir K. Jaffer, MD
Associate Professor of Medicine; Chief, Division of Hospital Medicine, Department of Medicine, Leonard M. Miller School of Medicine, University of Miami, Miami, FL

Alpesh N. Amin, MD, MBA
Professor and Chief, Division of General Internal Medicine; Executive Director, Hospitalist Program; Vice Chair for Clinical Affairs & Quality, Department of Medicine, University of California, Irvine, Irvine, CA

Daniel J. Brotman, MD
Director, Hospitalist Program; Associate Professor of Medicine, Johns Hopkins Hospital, Baltimore, MD

Steven B. Deitelzweig, MD
Vice President of Medical Affairs; Chairman, Department of Hospital Medicine, Ochsner Health System, New Orleans, LA

Sylvia C. McKean, MD
Medical Director, BWH/Faulkner Hospitalist Service; Associate Professor of Medicine, Harvard Medical School and Brigham and Women’s Hospital, Boston, MA

Alex C. Spyropoulos, MD
Chair, Clinical Thrombosis Center, Lovelace Medical Center; Clinical Associate Professor of Medicine/Associate Professor of Pharmacy, University of New Mexico Health Sciences Center/College of Pharmacy, Albuquerque, NM

Correspondence: Amir K. Jaffer, MD, Chief, Division of Hospital Medicine, Leonard M. Miller School of Medicine, University of Miami, 1120 NW 14th Street, 933 CRB (C216), Miami, FL 33136; [email protected]

Dr. Jaffer reported that he has received consulting fees and honoraria for teaching/speaking from Sanofi-Aventis, consulting fees and research grant support from AstraZeneca, and consulting fees from Roche Diagnostics and Boehringer Ingelheim; he also serves on the governing board of the Society for Perioperative Assessment and Quality Improvement (SPAQI) and the board of directors of the Anticoagulation Forum.

Dr. Amin reported that he has received research funding and honoraria for speaking from Sanofi-Aventis, Eisai, and GlaxoSmithKline.

Dr. Brotman reported that he has no financial relationships with commercial interests that are relevant to this article.

Drs. Deitelzweig and McKean each reported that they have received honoraria for teaching/speaking from Sanofi-Aventis. Dr. Spyropoulos reported that he has received consulting fees from Sanofi-Aventis, Eisai, and Boehringer Ingelheim.

Each author received an honorarium for participating in the roundtable that formed the basis of this supplement. The honoraria were paid by the Cleveland Clinic Center for Continuing Education from the educational grant from Sanofi-Aventis underwriting this supplement. Sanofi-Aventis had no input on the content of the roundtable or this supplement.

Author and Disclosure Information

Amir K. Jaffer, MD
Associate Professor of Medicine; Chief, Division of Hospital Medicine, Department of Medicine, Leonard M. Miller School of Medicine, University of Miami, Miami, FL

Alpesh N. Amin, MD, MBA
Professor and Chief, Division of General Internal Medicine; Executive Director, Hospitalist Program; Vice Chair for Clinical Affairs & Quality, Department of Medicine, University of California, Irvine, Irvine, CA

Daniel J. Brotman, MD
Director, Hospitalist Program; Associate Professor of Medicine, Johns Hopkins Hospital, Baltimore, MD

Steven B. Deitelzweig, MD
Vice President of Medical Affairs; Chairman, Department of Hospital Medicine, Ochsner Health System, New Orleans, LA

Sylvia C. McKean, MD
Medical Director, BWH/Faulkner Hospitalist Service; Associate Professor of Medicine, Harvard Medical School and Brigham and Women’s Hospital, Boston, MA

Alex C. Spyropoulos, MD
Chair, Clinical Thrombosis Center, Lovelace Medical Center; Clinical Associate Professor of Medicine/Associate Professor of Pharmacy, University of New Mexico Health Sciences Center/College of Pharmacy, Albuquerque, NM

Correspondence: Amir K. Jaffer, MD, Chief, Division of Hospital Medicine, Leonard M. Miller School of Medicine, University of Miami, 1120 NW 14th Street, 933 CRB (C216), Miami, FL 33136; [email protected]

Dr. Jaffer reported that he has received consulting fees and honoraria for teaching/speaking from Sanofi-Aventis, consulting fees and research grant support from AstraZeneca, and consulting fees from Roche Diagnostics and Boehringer Ingelheim; he also serves on the governing board of the Society for Perioperative Assessment and Quality Improvement (SPAQI) and the board of directors of the Anticoagulation Forum.

Dr. Amin reported that he has received research funding and honoraria for speaking from Sanofi-Aventis, Eisai, and GlaxoSmithKline.

Dr. Brotman reported that he has no financial relationships with commercial interests that are relevant to this article.

Drs. Deitelzweig and McKean each reported that they have received honoraria for teaching/speaking from Sanofi-Aventis. Dr. Spyropoulos reported that he has received consulting fees from Sanofi-Aventis, Eisai, and Boehringer Ingelheim.

Each author received an honorarium for participating in the roundtable that formed the basis of this supplement. The honoraria were paid by the Cleveland Clinic Center for Continuing Education from the educational grant from Sanofi-Aventis underwriting this supplement. Sanofi-Aventis had no input on the content of the roundtable or this supplement.

Article PDF
Article PDF
Related Articles

The need for prophylaxis of venous thromboembolism (VTE) in hospitalized acutely ill medical patients is well established. Without prophylaxis, hospitalized medical patients develop VTE at a rate of 5% to 15%.1–3 Moreover, pulmonary embolism (PE) occurs more frequently in hospitalized medical patients than in nonmedical patients, and is a leading cause of sudden death in hospitalized medical patients.4,5 Without appropriate prophylaxis, 1 in 20 hospitalized medical patients may suffer a fatal PE.4

PROPHYLAXIS IN MEDICAL PATIENTS: UNDERUSED AND OFTEN INAPPROPRIATE

Despite these risks and the clear indications for VTE prophylaxis in hospitalized medical patients, prophylaxis of VTE is omitted more often in these patients than in hospitalized surgical patients.5 Even when prophylaxis is given, it is often used inappropriately in the medical population. So concludes a recent analysis of data from 196,104 patients with acute medical conditions who were discharged from 227 US hospitals from January 2002 to September 2005.6 Criteria for inclusion in the analysis were patient age of 40 years or older, a hospital stay of 6 days or greater, and an absence of contraindications to anticoagulation. Appropriate prophylaxis was defined in accordance with the Sixth American College of Chest Physicians (ACCP) Consensus Conference on Antithrombotic Therapy.7

The analysis revealed an overall VTE prophylaxis rate of 61.8%, but the rate of appropriate prophylaxis was only 33.9%, meaning that two-thirds of discharged patients did not receive prophylaxis in accordance with ACCP guidelines. When temporal trends were analyzed according to groups based on patients’ diagnosis at admission (acute myocardial infarction, severe lung disease, ischemic stroke, cancer, heart failure, or trauma), the rate of appropriate prophylaxis remained essentially flat from the beginning to the end of the study period for virtually all diagnosis groups.6

Similar findings have emerged from the International Medical Prevention Registry on Venous Thromboembolism (IMPROVE), an ongoing international registry of acutely ill medical patients.8 Data from the first 15,156 patients, enrolled from July 2002 through September 2006, reveal that 50% of patients received pharmacologic and/or mechanical VTE prophylaxis in the hospital, and only 60% of patients who met established criteria for VTE prophylaxis actually received it.

Analysis of the US portion of the IMPROVE data shows that 54% of the US patient sample received some form of VTE prophylaxis; 22% of US patients received intermittent pneumatic compression, 21% received unfractionated heparin (UFH), 14% received low-molecular-weight heparin (LMWH), and 3% wore compression stockings.8 Thus, despite a paucity of data supporting a benefit of intermittent pneumatic compression in this population,9 it was the most frequently used form of prophylaxis in US patients.

CLINICAL TRIALS OF PHARMACOLOGIC PROPHYLAXIS IN MEDICAL PATIENTS

Reprinted, with permission, from New England Journal of Medicine (Francis CW. Prophylaxis for thromboembolism in hospitalized medical patients. N Engl J Med 2007; 356:1438–1444.). Copyright © 2007 Massachusetts Medical Society. All rights reserved.
Figure 1. Rates of venous thromboembolism (VTE) in three large double-blind, placebo-controlled studies of pharmacologic prophylaxis of VTE in high-risk hospitalized medical patients.
The evidence in support of pharmacologic prophylaxis of VTE in high-risk hospitalized medical patients is considerable. Three large double-blind, placebo-controlled trials of anticoagulants currently available in the United States have been reported in this patient population (Figure 1).1–3

The Prophylaxis in Medical Patients with Enoxaparin (MEDENOX) trial1 randomized 1,102 hospitalized patients to one of two doses of the LMWH enoxaparin (20 mg or 40 mg once daily subcutaneously) or placebo for 6 to 14 days. Compared with placebo, the 40-mg dose of enoxaparin was associated with a 63% reduction in risk of VTE over 3 months of follow-up (P < .001) (Figure 1).

The Prospective Evaluation of Dalteparin Efficacy for Prevention of VTE in Immobilized Patients Trial (PREVENT)2 was a multicenter, randomized, double-blind study comparing the LMWH dalteparin (5,000 IU daily given subcutaneously for 14 days) with placebo in 3,706 acutely ill medical patients. Over 90 days of follow-up, the risk of VTE was reduced by 44% in patients assigned to dalteparin compared with those assigned to placebo (P = .0015) (Figure 1).

The Arixtra for Thromboembolism Prevention in a Medical Indications Study (ARTEMIS)3 randomized 849 medical patients 60 years or older to 6 to 14 days of therapy with the selective factor Xa inhibitor fondaparinux (2.5 mg once daily subcutaneously) or placebo. Compared with the placebo group, fondaparinux recipients had a 47% lower risk of developing VTE by day 15 (P = .029) (Figure 1).

Fewer events and fatal PEs, but no effect on all-cause mortality

A recent meta-analysis by Dentali et al10 further demonstrates the efficacy of anticoagulant therapy for preventing symptomatic VTE in hospitalized medical patients. This analysis included several other trials in addition to the three reviewed above,1–3 for a total of nine randomized studies (seven of which were dou-ble-blind) comprising 19,958 patients. Across the nine studies, anticoagulant prophylaxis was clearly superior to placebo in preventing fatal PE (relative risk, 0.38 [95% CI, 0.21 to 0.69]). There was a strong trend toward a reduction in symptomatic deep vein thrombosis (DVT) with prophylaxis but no effect on all-cause mortality. The meta-analysis also provided reassurance that prophylaxis does not increase the rate of major bleeding.

 

 

HOW DO THE PROPHYLAXIS OPTIONS STACK UP?

What the ACCP recommends

Current ACCP guidelines recommend the use of either LMWH or low-dose UFH (5,000 U subcutaneously two or three times daily) as a Grade 1A recommendation for VTE prophylaxis in patients with medical conditions and risk factors for VTE.9 This represents the guidelines’ highest level of recommendation, ie, one that is based on randomized controlled trials (RCTs) without important limitations. In contrast, the 2006 International Consensus Statement, developed as a collaborative effort among expert bodies on VTE, specified a more narrow dosing recommendation for UFH in this patient population (5,000 U three times daily, not twice daily) as well as specifying 40 mg once daily as the recommended dose of enoxaparin and 5,000 IU once daily as the recommended dose of dalteparin.11

For medical patients with risk factors for VTE who have a contraindication to anticoagulant prophylaxis, the ACCP guidelines recommend the use of graduated compression stockings or intermittent pneumatic compression devices as a Grade 1C+ recommendation (“no RCTs but strong RCT results can be unequivocally extrapolated, or overwhelming evidence from observational studies”9).

Current ACCP guidelines do not address the use of fondaparinux in their recommendations for VTE prophylaxis in medical patients.

Getting a handle on bleeding risk

Patient characteristics that exclude pharmacologic thromboprophylaxis due to bleeding risk are generally limited to active bleeding or coagulopathy, as demonstrated by a platelet count less than 50,000 cells/µL or an international normalized ratio greater than 1.5. Additionally, bleeding risk should be carefully assessed if an invasive procedure is planned during a patient’s hospital stay.

It is worth noting that the anticoagulant doses used for VTE prophylaxis are a fraction of those used for treatment of VTE. Thus, if a patient would be treated with full-dose anticoagulation if VTE developed, then that patient should be eligible for VTE prophylaxis.

Because the use of mechanical forms of prophylaxis in medical patients is not truly evidence-based, mechanical prophylaxis should be reserved for medical patients who have a contraindication to anticoagulants, or for use in combination with anticoagulants in patients at very high risk of VTE.

UFH vs LMWH

Two meta-analyses have compared UFH with LMWH for VTE prevention in medical patients.12,13 In a recent analysis that included 10 trials directly comparing the two therapies, 14 trials comparing UFH with control, and 11 trials comparing LMWH with control, Wein et al found a lower risk of DVT with LMWH than with UFH (relative risk, 0.68 [95% CI, 0.52 to 0.88]) but no difference between the therapies in mortality or bleeding risk.12 In an earlier and smaller analysis, Mismetti et al found no significant differences between UFH and LMWH in preventing DVT or death but did find a significant reduction in major bleeding episodes with LMWH versus three-times-daily UFH (52% relative reduction; P = .049).13

Randomized trials also reveal that enoxaparin 40 mg once daily is as efficacious as UFH 5,000 U three times daily for VTE prevention in medical patients.14,15 The above analysis by Wein et al12 and an additional meta-analysis by King and colleagues16 found that three-times-daily dosing of UFH is more efficacious than twice-daily dosing of UFH, but at the expense of more bleeding, including major bleeding.

Economic considerations

Because of differences in drug acquisition costs between UFH and the LMWH agents, several economic evaluations have compared the use of these therapies for prophylaxis in medical patients at risk of VTE.

In an analysis of hospital costs for medical patients receiving VTE prophylaxis from more than 330 US hospitals for the period 2001–2004, Burleigh et al found that mean total hospital costs were higher for patients who received UFH than for those who received LMWH ($7,615 vs $6,866) even though mean drug costs were higher for LMWH ($791 vs $569 for UFH).17 A reduction in hospital length of stay appeared to contribute to the overall savings with LMWH; other contributors may have included costs associated with heparin-induced thrombocytopenia (HIT) in UFH recipients or the extra nursing time required for administering UFH in two or three daily doses.

Leykum et al used a decision analysis model to estimate the economic effect of substituting enoxaparin for UFH in hospitalized medical patients for whom VTE prophylaxis is indicated.18 Cost data were based on Medicare reimbursement rates as well as drug and laboratory costs for a multi-institutional health system. The model assumed HIT incidence rates of 2.7% with UFH and 0.3% with enoxaparin. It also assumed the cost of a daily dose to be $4 for UFH versus $84 for enoxaparin. From the payer perspective, the model showed that substituting enoxaparin for UFH would reduce the overall cost of care by $28.61 per day on a per-patient basis, despite enoxaparin’s higher acquisition cost, and would save $4,550 per quality-adjusted life-year by reducing the incidence of HIT.

Another cost analysis confirms the association between HIT and increased hospital costs. Creekmore et al retrospectively analyzed data from 10,121 adult medical patients who received VTE prophylaxis at the University of Utah Hospital in Salt Lake City from August 2000 to November 2004.19 They found that an admission during which HIT developed incurred a mean cost of $56,364, compared with $15,231 for an admission without HIT. Because LMWH was associated with a lower incidence of HIT compared with UFH (0.084% vs 0.51%, respectively), LMWH reduced the incremental cost of VTE prophylaxis by $13.88 per patient compared with UFH.

THE EXCLAIM TRIAL: IS THERE A ROLE FOR EXTENDED PROPHYLAXIS?

Although the previously discussed studies have clearly demonstrated the benefit of in-hospital VTE prophylaxis for acutely ill medical patients, none has rigorously examined extended-duration out-of-hospital prophylaxis in these patients. This represents an important gap in the literature, since a substantial proportion of VTE develops in the outpatient setting within 3 months of a hospitalization, and most outpatient VTE episodes occur within 1 month of a preceding hospitalization.20

To begin to fill this gap, the Extended Clinical Prophylaxis in Acutely Ill Medical Patients (EXCLAIM) trial was conducted to compare extended-duration LMWH prophylaxis with a standard LMWH prophylaxis regimen in acutely ill medical patients using a prospective, multicenter, randomized, double-blind, placebo-controlled design.21

Patients and study design

Patients were eligible for enrollment if they were aged 40 years or older and had recent immobilization (≤ 3 days), a predefined acute medical illness, and either level 1 mobility (total bed rest or sedentary state) or level 2 mobility (level 1 with bathroom privileges). The predefined acute medical illnesses consisted of New York Heart Association class III/IV heart failure, acute respiratory insufficiency, or other acute medical conditions, including post-acute ischemic stroke, acute infection without septic shock, and active cancer.

All patients received open-label enoxaparin 40 mg subcutaneously once daily for 10 ± 4 days, after which they were randomized to either enoxaparin 40 mg subcutaneously once daily or placebo for an additional 28 ± 4 days.

The primary efficacy end point was the incidence of VTE events, defined as asymptomatic DVT documented by mandatory ultrasonography at the end of the double-blind treatment period (28 ± 4 days) or as symptomatic DVT, symptomatic PE, or fatal PE at any time during the double-blind period. Symptomatic DVT was confirmed by objective tests; PE was confirmed by ventilation-perfusion scan, computed tomography, angiography, or autopsy. 

Secondary efficacy end points were mortality at the end of the double-blind period, at 3 months, and at 6 months, as well as the incidence of VTE at 3 months.

The primary safety outcome measure was the incidence of major hemorrhage during the double-blind period; secondary safety measures were rates of major and minor hemorrhage, minor hemorrhage, HIT, and serious adverse events.

 

 

Population amended at planned interim analysis

After approximately half of the patients were enrolled, a planned and blinded interim analysis for futility concluded that the study was unlikely to show a statistically significant advantage of enoxaparin over placebo. The trial’s steering committee followed the suggestion of its data safety monitoring board to redefine the inclusion criteria to refocus enrollment on patients with a high risk of VTE. A blinded analysis was performed to identify this subgroup.

The resulting amended inclusion criteria were the same as above except that level 2 mobility had to be accompanied by at least one of three additional high-risk criteria: (1) age greater than 75 years, (2) history of prior VTE, or (3) diagnosis of cancer.

The trial’s main exclusion criteria were evidence of active bleeding, a contraindication to anticoagulation, receipt of prophylactic LMWH or UFH more than 72 hours prior to enrollment, treatment with an oral anticoagulant within 72 hours of enrollment, major surgery within the prior 3 months, cerebral stroke with bleeding, and persistent renal failure (creatinine clearance < 30 mL/min).

Results

The amended study population included 5,105 patients, 5,049 of whom received open-label enoxaparin. Of this group, 2,013 were randomized to active extended prophylaxis with enoxparain and 2,027 to placebo. Baseline characteristics, including level of mobility, were similar between the two groups.

Efficacy. As detailed in Table 1, VTE events occurred at a statistically significantly higher rate in the placebo arm than in the extended-duration enoxaparin arm, as did asymptomatic proximal DVT and symptomatic VTE. Rates of PE and fatal PE were also lower with enoxaparin than with placebo, but the number of events was so small that the between­group differences were not statistically significant.

The efficacy of extended prophylaxis with enoxaparin was enduring, as the cumulative incidence of VTE events at day 90 was significantly lower in enoxaparin recipients than in placebo recipients (3.0% vs 5.2%; relative reduction of 42%; P = .0115).

There was no difference in all-cause mortality at 6 months between the enoxaparin and placebo groups (10.1% vs 8.9%, respectively; P = .179).

Safety. Major hemorrhage was significantly more frequent in the enoxaparin arm, occurring in 0.60% of enoxaparin recipients compared with 0.15% of placebo recipients (P = .019). Minor bleeding was also more common with enoxaparin (5.20% vs 3.70%; P = .024).

Conclusions

The EXCLAIM trial found that an extended-duration (38-day) enoxaparin regimen significantly reduced the overall incidence of VTE relative to a 10-day enoxaparin regimen in acutely ill medical patients with reduced mobility. At the same time, the extended regimen was associated with a significant increase in the rate of major bleeding, although the incidence of major bleeding was low. The investigators concluded that the net clinical effect of extended-duration prophylaxis with enoxaparin is favorable, as only 46 patients would need to be treated to prevent one VTE event, whereas 224 patients would need to be treated to result in one major bleeding event.21

For this reason, it is reasonable to consider extended prophylaxis for hospitalized medical patients after identifying these patients’ risk factors. In keeping with the trial’s amended inclusion criteria, patients older than age 75 and those with cancer or prior VTE should receive special consideration for extended prophylaxis.

RECOMMENDED APPROACH TO VTE PREVENTION IN HOSPITALIZED MEDICAL PATIENTS

Figure 2. Algorithm for VTE prophylaxis in the hospitalized medical patient.
Given the wide gap between the evidence reviewed above and current practice worldwide,8,22,23 we propose the algorithm presented in Figure 2 for the prevention of VTE in hospitalized medical patients. Our recommended approach is guided by the principles below:

  • All hospitalized medical patients should be screened at the time of admission, and patients at risk for VTE should receive prophylaxis.
  • All patients with reduced mobility and one or more other risk factors for VTE are candidates for prophylaxis.
  • Patients should be reassessed daily for the development of VTE risk factors during their hospitalization if risk factors are absent on admission.
  • If screening or reassessment reveals any VTE risk factors, pharmacologic prophylaxis is the mainstay of therapy. If exclusion criteria for pharmacologic prophylaxis are present, mechanical prophylaxis with graduated compression stockings and intermittent compression devices should be used. For very high-risk medical patients without a contraindication to anticoagulants, combination prophylaxis with both an anticoagulant and mechanical devices is preferred.
  • In this patient population, LMWH agents are preferred as pharmacologic prophylaxis over UFH and over fondaparinux (which is not currently approved by the US Food and Drug Administration for this population).
  • If UFH is to be used in this patient population, 5,000 U three times daily is the preferred dosage.
  • Extended pharmacologic prophylaxis should be considered in patients older than age 75 and in patients with a cancer diagnosis or a prior VTE episode.

 

 

DISCUSSION: ADDITIONAL PERSPECTIVES FROM THE AUTHORS

Dr. Jaffer: Dr. Spyropoulos, are there any guidelines, other than those from the ACCP, that speak to VTE prophylaxis in hospitalized medical patients? If so, what are their take-home messages and how do they differ from the ACCP guidelines?

Dr. Spyropoulos: I was part of the group that developed the International Consensus Statement (ICS) published in International Angiology in 2006,11 which is more recent than the latest ACCP guidelines, which were published in 2004. The ICS drew on much of the same data that the ACCP did, but we did an updated review of clinical trials.

For VTE prophylaxis in hospitalized medical patients, the ICS recommendations are more specific with regard to the type, dose, and dosing frequency of anticoagulant agents. First, they specify doses for both LMWH agents in this patient setting: 40 mg once daily for enoxaparin, and 5,000 IU once daily for dalteparin.

The ICS document also states that if UFH is the choice for prophylaxis, a regimen of 5,000 U three times daily should be considered. In the past year alone, two analyses suggest that three-times-daily dosing of UFH in medical patients provides superior efficacy to twice-daily dosing, although perhaps at the expense of more bleeding episodes.12,16 It is important to remember that no large placebo-controlled trial supports the efficacy of a UFH regimen of 5,000 U twice daily in this population.

Finally, the ICS document states that fondaparinux 2.5 mg once daily is a viable option for prophylaxis in medical patients, based on the ARTEMIS trial,3 even though this represents an off-label use.

Dr. Jaffer: Real-world use of VTE prophylaxis is far from optimal, especially in medical patients, and this is partly a result of system-of-care issues. I’d like to conclude by asking each of my colleagues to offer your perspectives on how your own institutions have improved their systems of care to promote better use of VTE prophylaxis and what lessons might be shared with others. Dr. McKean, you work at Brigham and Women’s Hospital, which recently reported impressive results with an electronic alert system designed to increase clinicians’ consideration of VTE risk assessment and use of prophylaxis.24 Please tell us about that study and the alert system.

Dr. McKean: Despite many educational initiatives at Brigham and Women’s Hospital, there were still some patients at high risk for VTE who were not receiving appropriate prophylaxis. What Dr. Samuel Goldhaber and his colleagues wanted to determine was whether changing the system of care could result in a reduced incidence of VTE.24 They devised a computer software program linked to the patient database that used eight common risk factors to determine each hospitalized patient’s risk profile for VTE. Each risk factor was weighted according to a point scale, with major risk factors (cancer, prior VTE, or hypercoagulability) assigned 3 points, the intermediate risk factor of surgery assigned 2 points, and minor risk factors (advanced age, obesity, immobility, or use of hormone replacement therapy or oral contraceptives) assigned 1 point. For patients with a total risk score of 4 or greater, the computer screen generates a color-coded VTE risk alert that requires the physician to acknowledge the alert and choose one of three options: order prophylaxis as appropriate, review a 60-page document on the computer to learn more about prophylaxis, or do nothing.

The study found that hospitalized patients who were randomized to treatment under the computer alert system were significantly more likely to receive VTE prophylaxis and significantly less likely to develop VTE than were patients randomized to a control group. The alert system reduced the risk of DVT or PE at 90 days by 41% in patients considered to be at high risk. It was particularly interesting that the incidence of VTE was lower in the intervention group even when physicians chose not to use prophylaxis, which suggests that simply having this alert system in place improved outcomes, perhaps by raising awareness of the risk of VTE.24

Additional studies are needed to better understand physicians’ behavior and determine why they seem to have a disproportionate fear of the risk of bleeding relative to the risk of clotting, including fatal PE, because that is really the heart of the matter. When patients are not given prophylaxis, often it is because of fear of bleeding. It is not clear, however, why some of these patients did not receive mechanical devices as an alternative form of prophylaxis, but this seems to be the case worldwide, as shown recently by the multinational ENDORSE study.22 Meanwhile, as we await studies to better understand physician perceptions and behaviors regarding prophylaxis, we need to work hard to change the system of care.

Dr. Deitelzweig: Over the past couple of years, the Ochsner Clinic has grown from a one-hospital teaching organization to a seven-hospital system with a mix of closed and open medical staff. The challenge is how to take a process that worked well in the one center, where appropriate prophylaxis was used about 90% of the time, and transfer it to the other centers in the larger system. We have endorsed several types of performance tools, such as the change-acceleration processes used by General Electric. The aim is to share a vision of heightening awareness. To do that, we have worked to mobilize the key stakeholders, at least half of them, to build algorithms that they all will endorse. It is easier said than done, however, and we have found it essential to involve both physicians and non-physician colleagues from pharmacy and nursing who have political and organizational clout.

Dr. Brotman: At Johns Hopkins, I took a bit more draconian approach to this issue because I thought that hospitalists often knew that they should be using VTE prophylaxis but sometimes weren’t, and I am not convinced that clinicians always look at prompts. So we came up with a system that incorporates both billing and documentation simultaneously. We put a hard stop on users’ documentation so that they could not sign off on a note or bill for their care until they checked off the kind of VTE prophylaxis they were using. Since hospitalists ultimately care about billing for their work, this system has at least ensured that everybody has considered and documented VTE prophylaxis on a daily basis. There are other hard stops that can be implemented in computer order-entry systems as well, and we are considering ways to roll them out on a broader scale.

However, all of these systems can have problems because patient situations change from day to day. For instance, VTE prophylaxis is not necessarily indicated in a 38-year-old ambulatory patient who comes in with a sickle cell crisis, but you will need to reconsider if the patient ends up in acute chest syndrome in the intensive care unit. I do not yet have a good way to ensure that this is being done on a daily basis with all patients.

Dr. Amin: At the University of California, Irvine, we implemented an electronic alert system, but we locked users in so that they could not complete their admission orders until they answered questions about VTE prevention. This practice increased our VTE prophylaxis rates tremendously. Because we are a level I trauma center, we allow users to bypass the screens one time, but the next time they log in, even to get a simple lab result, they have to answer the questions about VTE prevention.

With any system you develop, you also have to continue with the education process, because clinicians sometimes get into bad habits or simply forget things.

Dr. Spyropolous: At Lovelace Medical Center, we didn’t have the sophistication of an electronic order-entry system, but we had an experienced clinical pharmacist (the director of inpatient pharmacy) who helped to develop and champion VTE prevention guidelines that have then been used throughout the system in close conjunction with our hospitalists’ rounds. This system has been used successfully for the past 7 years.

The need for prophylaxis of venous thromboembolism (VTE) in hospitalized acutely ill medical patients is well established. Without prophylaxis, hospitalized medical patients develop VTE at a rate of 5% to 15%.1–3 Moreover, pulmonary embolism (PE) occurs more frequently in hospitalized medical patients than in nonmedical patients, and is a leading cause of sudden death in hospitalized medical patients.4,5 Without appropriate prophylaxis, 1 in 20 hospitalized medical patients may suffer a fatal PE.4

PROPHYLAXIS IN MEDICAL PATIENTS: UNDERUSED AND OFTEN INAPPROPRIATE

Despite these risks and the clear indications for VTE prophylaxis in hospitalized medical patients, prophylaxis of VTE is omitted more often in these patients than in hospitalized surgical patients.5 Even when prophylaxis is given, it is often used inappropriately in the medical population. So concludes a recent analysis of data from 196,104 patients with acute medical conditions who were discharged from 227 US hospitals from January 2002 to September 2005.6 Criteria for inclusion in the analysis were patient age of 40 years or older, a hospital stay of 6 days or greater, and an absence of contraindications to anticoagulation. Appropriate prophylaxis was defined in accordance with the Sixth American College of Chest Physicians (ACCP) Consensus Conference on Antithrombotic Therapy.7

The analysis revealed an overall VTE prophylaxis rate of 61.8%, but the rate of appropriate prophylaxis was only 33.9%, meaning that two-thirds of discharged patients did not receive prophylaxis in accordance with ACCP guidelines. When temporal trends were analyzed according to groups based on patients’ diagnosis at admission (acute myocardial infarction, severe lung disease, ischemic stroke, cancer, heart failure, or trauma), the rate of appropriate prophylaxis remained essentially flat from the beginning to the end of the study period for virtually all diagnosis groups.6

Similar findings have emerged from the International Medical Prevention Registry on Venous Thromboembolism (IMPROVE), an ongoing international registry of acutely ill medical patients.8 Data from the first 15,156 patients, enrolled from July 2002 through September 2006, reveal that 50% of patients received pharmacologic and/or mechanical VTE prophylaxis in the hospital, and only 60% of patients who met established criteria for VTE prophylaxis actually received it.

Analysis of the US portion of the IMPROVE data shows that 54% of the US patient sample received some form of VTE prophylaxis; 22% of US patients received intermittent pneumatic compression, 21% received unfractionated heparin (UFH), 14% received low-molecular-weight heparin (LMWH), and 3% wore compression stockings.8 Thus, despite a paucity of data supporting a benefit of intermittent pneumatic compression in this population,9 it was the most frequently used form of prophylaxis in US patients.

CLINICAL TRIALS OF PHARMACOLOGIC PROPHYLAXIS IN MEDICAL PATIENTS

Reprinted, with permission, from New England Journal of Medicine (Francis CW. Prophylaxis for thromboembolism in hospitalized medical patients. N Engl J Med 2007; 356:1438–1444.). Copyright © 2007 Massachusetts Medical Society. All rights reserved.
Figure 1. Rates of venous thromboembolism (VTE) in three large double-blind, placebo-controlled studies of pharmacologic prophylaxis of VTE in high-risk hospitalized medical patients.
The evidence in support of pharmacologic prophylaxis of VTE in high-risk hospitalized medical patients is considerable. Three large double-blind, placebo-controlled trials of anticoagulants currently available in the United States have been reported in this patient population (Figure 1).1–3

The Prophylaxis in Medical Patients with Enoxaparin (MEDENOX) trial1 randomized 1,102 hospitalized patients to one of two doses of the LMWH enoxaparin (20 mg or 40 mg once daily subcutaneously) or placebo for 6 to 14 days. Compared with placebo, the 40-mg dose of enoxaparin was associated with a 63% reduction in risk of VTE over 3 months of follow-up (P < .001) (Figure 1).

The Prospective Evaluation of Dalteparin Efficacy for Prevention of VTE in Immobilized Patients Trial (PREVENT)2 was a multicenter, randomized, double-blind study comparing the LMWH dalteparin (5,000 IU daily given subcutaneously for 14 days) with placebo in 3,706 acutely ill medical patients. Over 90 days of follow-up, the risk of VTE was reduced by 44% in patients assigned to dalteparin compared with those assigned to placebo (P = .0015) (Figure 1).

The Arixtra for Thromboembolism Prevention in a Medical Indications Study (ARTEMIS)3 randomized 849 medical patients 60 years or older to 6 to 14 days of therapy with the selective factor Xa inhibitor fondaparinux (2.5 mg once daily subcutaneously) or placebo. Compared with the placebo group, fondaparinux recipients had a 47% lower risk of developing VTE by day 15 (P = .029) (Figure 1).

Fewer events and fatal PEs, but no effect on all-cause mortality

A recent meta-analysis by Dentali et al10 further demonstrates the efficacy of anticoagulant therapy for preventing symptomatic VTE in hospitalized medical patients. This analysis included several other trials in addition to the three reviewed above,1–3 for a total of nine randomized studies (seven of which were dou-ble-blind) comprising 19,958 patients. Across the nine studies, anticoagulant prophylaxis was clearly superior to placebo in preventing fatal PE (relative risk, 0.38 [95% CI, 0.21 to 0.69]). There was a strong trend toward a reduction in symptomatic deep vein thrombosis (DVT) with prophylaxis but no effect on all-cause mortality. The meta-analysis also provided reassurance that prophylaxis does not increase the rate of major bleeding.

 

 

HOW DO THE PROPHYLAXIS OPTIONS STACK UP?

What the ACCP recommends

Current ACCP guidelines recommend the use of either LMWH or low-dose UFH (5,000 U subcutaneously two or three times daily) as a Grade 1A recommendation for VTE prophylaxis in patients with medical conditions and risk factors for VTE.9 This represents the guidelines’ highest level of recommendation, ie, one that is based on randomized controlled trials (RCTs) without important limitations. In contrast, the 2006 International Consensus Statement, developed as a collaborative effort among expert bodies on VTE, specified a more narrow dosing recommendation for UFH in this patient population (5,000 U three times daily, not twice daily) as well as specifying 40 mg once daily as the recommended dose of enoxaparin and 5,000 IU once daily as the recommended dose of dalteparin.11

For medical patients with risk factors for VTE who have a contraindication to anticoagulant prophylaxis, the ACCP guidelines recommend the use of graduated compression stockings or intermittent pneumatic compression devices as a Grade 1C+ recommendation (“no RCTs but strong RCT results can be unequivocally extrapolated, or overwhelming evidence from observational studies”9).

Current ACCP guidelines do not address the use of fondaparinux in their recommendations for VTE prophylaxis in medical patients.

Getting a handle on bleeding risk

Patient characteristics that exclude pharmacologic thromboprophylaxis due to bleeding risk are generally limited to active bleeding or coagulopathy, as demonstrated by a platelet count less than 50,000 cells/µL or an international normalized ratio greater than 1.5. Additionally, bleeding risk should be carefully assessed if an invasive procedure is planned during a patient’s hospital stay.

It is worth noting that the anticoagulant doses used for VTE prophylaxis are a fraction of those used for treatment of VTE. Thus, if a patient would be treated with full-dose anticoagulation if VTE developed, then that patient should be eligible for VTE prophylaxis.

Because the use of mechanical forms of prophylaxis in medical patients is not truly evidence-based, mechanical prophylaxis should be reserved for medical patients who have a contraindication to anticoagulants, or for use in combination with anticoagulants in patients at very high risk of VTE.

UFH vs LMWH

Two meta-analyses have compared UFH with LMWH for VTE prevention in medical patients.12,13 In a recent analysis that included 10 trials directly comparing the two therapies, 14 trials comparing UFH with control, and 11 trials comparing LMWH with control, Wein et al found a lower risk of DVT with LMWH than with UFH (relative risk, 0.68 [95% CI, 0.52 to 0.88]) but no difference between the therapies in mortality or bleeding risk.12 In an earlier and smaller analysis, Mismetti et al found no significant differences between UFH and LMWH in preventing DVT or death but did find a significant reduction in major bleeding episodes with LMWH versus three-times-daily UFH (52% relative reduction; P = .049).13

Randomized trials also reveal that enoxaparin 40 mg once daily is as efficacious as UFH 5,000 U three times daily for VTE prevention in medical patients.14,15 The above analysis by Wein et al12 and an additional meta-analysis by King and colleagues16 found that three-times-daily dosing of UFH is more efficacious than twice-daily dosing of UFH, but at the expense of more bleeding, including major bleeding.

Economic considerations

Because of differences in drug acquisition costs between UFH and the LMWH agents, several economic evaluations have compared the use of these therapies for prophylaxis in medical patients at risk of VTE.

In an analysis of hospital costs for medical patients receiving VTE prophylaxis from more than 330 US hospitals for the period 2001–2004, Burleigh et al found that mean total hospital costs were higher for patients who received UFH than for those who received LMWH ($7,615 vs $6,866) even though mean drug costs were higher for LMWH ($791 vs $569 for UFH).17 A reduction in hospital length of stay appeared to contribute to the overall savings with LMWH; other contributors may have included costs associated with heparin-induced thrombocytopenia (HIT) in UFH recipients or the extra nursing time required for administering UFH in two or three daily doses.

Leykum et al used a decision analysis model to estimate the economic effect of substituting enoxaparin for UFH in hospitalized medical patients for whom VTE prophylaxis is indicated.18 Cost data were based on Medicare reimbursement rates as well as drug and laboratory costs for a multi-institutional health system. The model assumed HIT incidence rates of 2.7% with UFH and 0.3% with enoxaparin. It also assumed the cost of a daily dose to be $4 for UFH versus $84 for enoxaparin. From the payer perspective, the model showed that substituting enoxaparin for UFH would reduce the overall cost of care by $28.61 per day on a per-patient basis, despite enoxaparin’s higher acquisition cost, and would save $4,550 per quality-adjusted life-year by reducing the incidence of HIT.

Another cost analysis confirms the association between HIT and increased hospital costs. Creekmore et al retrospectively analyzed data from 10,121 adult medical patients who received VTE prophylaxis at the University of Utah Hospital in Salt Lake City from August 2000 to November 2004.19 They found that an admission during which HIT developed incurred a mean cost of $56,364, compared with $15,231 for an admission without HIT. Because LMWH was associated with a lower incidence of HIT compared with UFH (0.084% vs 0.51%, respectively), LMWH reduced the incremental cost of VTE prophylaxis by $13.88 per patient compared with UFH.

THE EXCLAIM TRIAL: IS THERE A ROLE FOR EXTENDED PROPHYLAXIS?

Although the previously discussed studies have clearly demonstrated the benefit of in-hospital VTE prophylaxis for acutely ill medical patients, none has rigorously examined extended-duration out-of-hospital prophylaxis in these patients. This represents an important gap in the literature, since a substantial proportion of VTE develops in the outpatient setting within 3 months of a hospitalization, and most outpatient VTE episodes occur within 1 month of a preceding hospitalization.20

To begin to fill this gap, the Extended Clinical Prophylaxis in Acutely Ill Medical Patients (EXCLAIM) trial was conducted to compare extended-duration LMWH prophylaxis with a standard LMWH prophylaxis regimen in acutely ill medical patients using a prospective, multicenter, randomized, double-blind, placebo-controlled design.21

Patients and study design

Patients were eligible for enrollment if they were aged 40 years or older and had recent immobilization (≤ 3 days), a predefined acute medical illness, and either level 1 mobility (total bed rest or sedentary state) or level 2 mobility (level 1 with bathroom privileges). The predefined acute medical illnesses consisted of New York Heart Association class III/IV heart failure, acute respiratory insufficiency, or other acute medical conditions, including post-acute ischemic stroke, acute infection without septic shock, and active cancer.

All patients received open-label enoxaparin 40 mg subcutaneously once daily for 10 ± 4 days, after which they were randomized to either enoxaparin 40 mg subcutaneously once daily or placebo for an additional 28 ± 4 days.

The primary efficacy end point was the incidence of VTE events, defined as asymptomatic DVT documented by mandatory ultrasonography at the end of the double-blind treatment period (28 ± 4 days) or as symptomatic DVT, symptomatic PE, or fatal PE at any time during the double-blind period. Symptomatic DVT was confirmed by objective tests; PE was confirmed by ventilation-perfusion scan, computed tomography, angiography, or autopsy. 

Secondary efficacy end points were mortality at the end of the double-blind period, at 3 months, and at 6 months, as well as the incidence of VTE at 3 months.

The primary safety outcome measure was the incidence of major hemorrhage during the double-blind period; secondary safety measures were rates of major and minor hemorrhage, minor hemorrhage, HIT, and serious adverse events.

 

 

Population amended at planned interim analysis

After approximately half of the patients were enrolled, a planned and blinded interim analysis for futility concluded that the study was unlikely to show a statistically significant advantage of enoxaparin over placebo. The trial’s steering committee followed the suggestion of its data safety monitoring board to redefine the inclusion criteria to refocus enrollment on patients with a high risk of VTE. A blinded analysis was performed to identify this subgroup.

The resulting amended inclusion criteria were the same as above except that level 2 mobility had to be accompanied by at least one of three additional high-risk criteria: (1) age greater than 75 years, (2) history of prior VTE, or (3) diagnosis of cancer.

The trial’s main exclusion criteria were evidence of active bleeding, a contraindication to anticoagulation, receipt of prophylactic LMWH or UFH more than 72 hours prior to enrollment, treatment with an oral anticoagulant within 72 hours of enrollment, major surgery within the prior 3 months, cerebral stroke with bleeding, and persistent renal failure (creatinine clearance < 30 mL/min).

Results

The amended study population included 5,105 patients, 5,049 of whom received open-label enoxaparin. Of this group, 2,013 were randomized to active extended prophylaxis with enoxparain and 2,027 to placebo. Baseline characteristics, including level of mobility, were similar between the two groups.

Efficacy. As detailed in Table 1, VTE events occurred at a statistically significantly higher rate in the placebo arm than in the extended-duration enoxaparin arm, as did asymptomatic proximal DVT and symptomatic VTE. Rates of PE and fatal PE were also lower with enoxaparin than with placebo, but the number of events was so small that the between­group differences were not statistically significant.

The efficacy of extended prophylaxis with enoxaparin was enduring, as the cumulative incidence of VTE events at day 90 was significantly lower in enoxaparin recipients than in placebo recipients (3.0% vs 5.2%; relative reduction of 42%; P = .0115).

There was no difference in all-cause mortality at 6 months between the enoxaparin and placebo groups (10.1% vs 8.9%, respectively; P = .179).

Safety. Major hemorrhage was significantly more frequent in the enoxaparin arm, occurring in 0.60% of enoxaparin recipients compared with 0.15% of placebo recipients (P = .019). Minor bleeding was also more common with enoxaparin (5.20% vs 3.70%; P = .024).

Conclusions

The EXCLAIM trial found that an extended-duration (38-day) enoxaparin regimen significantly reduced the overall incidence of VTE relative to a 10-day enoxaparin regimen in acutely ill medical patients with reduced mobility. At the same time, the extended regimen was associated with a significant increase in the rate of major bleeding, although the incidence of major bleeding was low. The investigators concluded that the net clinical effect of extended-duration prophylaxis with enoxaparin is favorable, as only 46 patients would need to be treated to prevent one VTE event, whereas 224 patients would need to be treated to result in one major bleeding event.21

For this reason, it is reasonable to consider extended prophylaxis for hospitalized medical patients after identifying these patients’ risk factors. In keeping with the trial’s amended inclusion criteria, patients older than age 75 and those with cancer or prior VTE should receive special consideration for extended prophylaxis.

RECOMMENDED APPROACH TO VTE PREVENTION IN HOSPITALIZED MEDICAL PATIENTS

Figure 2. Algorithm for VTE prophylaxis in the hospitalized medical patient.
Given the wide gap between the evidence reviewed above and current practice worldwide,8,22,23 we propose the algorithm presented in Figure 2 for the prevention of VTE in hospitalized medical patients. Our recommended approach is guided by the principles below:

  • All hospitalized medical patients should be screened at the time of admission, and patients at risk for VTE should receive prophylaxis.
  • All patients with reduced mobility and one or more other risk factors for VTE are candidates for prophylaxis.
  • Patients should be reassessed daily for the development of VTE risk factors during their hospitalization if risk factors are absent on admission.
  • If screening or reassessment reveals any VTE risk factors, pharmacologic prophylaxis is the mainstay of therapy. If exclusion criteria for pharmacologic prophylaxis are present, mechanical prophylaxis with graduated compression stockings and intermittent compression devices should be used. For very high-risk medical patients without a contraindication to anticoagulants, combination prophylaxis with both an anticoagulant and mechanical devices is preferred.
  • In this patient population, LMWH agents are preferred as pharmacologic prophylaxis over UFH and over fondaparinux (which is not currently approved by the US Food and Drug Administration for this population).
  • If UFH is to be used in this patient population, 5,000 U three times daily is the preferred dosage.
  • Extended pharmacologic prophylaxis should be considered in patients older than age 75 and in patients with a cancer diagnosis or a prior VTE episode.

 

 

DISCUSSION: ADDITIONAL PERSPECTIVES FROM THE AUTHORS

Dr. Jaffer: Dr. Spyropoulos, are there any guidelines, other than those from the ACCP, that speak to VTE prophylaxis in hospitalized medical patients? If so, what are their take-home messages and how do they differ from the ACCP guidelines?

Dr. Spyropoulos: I was part of the group that developed the International Consensus Statement (ICS) published in International Angiology in 2006,11 which is more recent than the latest ACCP guidelines, which were published in 2004. The ICS drew on much of the same data that the ACCP did, but we did an updated review of clinical trials.

For VTE prophylaxis in hospitalized medical patients, the ICS recommendations are more specific with regard to the type, dose, and dosing frequency of anticoagulant agents. First, they specify doses for both LMWH agents in this patient setting: 40 mg once daily for enoxaparin, and 5,000 IU once daily for dalteparin.

The ICS document also states that if UFH is the choice for prophylaxis, a regimen of 5,000 U three times daily should be considered. In the past year alone, two analyses suggest that three-times-daily dosing of UFH in medical patients provides superior efficacy to twice-daily dosing, although perhaps at the expense of more bleeding episodes.12,16 It is important to remember that no large placebo-controlled trial supports the efficacy of a UFH regimen of 5,000 U twice daily in this population.

Finally, the ICS document states that fondaparinux 2.5 mg once daily is a viable option for prophylaxis in medical patients, based on the ARTEMIS trial,3 even though this represents an off-label use.

Dr. Jaffer: Real-world use of VTE prophylaxis is far from optimal, especially in medical patients, and this is partly a result of system-of-care issues. I’d like to conclude by asking each of my colleagues to offer your perspectives on how your own institutions have improved their systems of care to promote better use of VTE prophylaxis and what lessons might be shared with others. Dr. McKean, you work at Brigham and Women’s Hospital, which recently reported impressive results with an electronic alert system designed to increase clinicians’ consideration of VTE risk assessment and use of prophylaxis.24 Please tell us about that study and the alert system.

Dr. McKean: Despite many educational initiatives at Brigham and Women’s Hospital, there were still some patients at high risk for VTE who were not receiving appropriate prophylaxis. What Dr. Samuel Goldhaber and his colleagues wanted to determine was whether changing the system of care could result in a reduced incidence of VTE.24 They devised a computer software program linked to the patient database that used eight common risk factors to determine each hospitalized patient’s risk profile for VTE. Each risk factor was weighted according to a point scale, with major risk factors (cancer, prior VTE, or hypercoagulability) assigned 3 points, the intermediate risk factor of surgery assigned 2 points, and minor risk factors (advanced age, obesity, immobility, or use of hormone replacement therapy or oral contraceptives) assigned 1 point. For patients with a total risk score of 4 or greater, the computer screen generates a color-coded VTE risk alert that requires the physician to acknowledge the alert and choose one of three options: order prophylaxis as appropriate, review a 60-page document on the computer to learn more about prophylaxis, or do nothing.

The study found that hospitalized patients who were randomized to treatment under the computer alert system were significantly more likely to receive VTE prophylaxis and significantly less likely to develop VTE than were patients randomized to a control group. The alert system reduced the risk of DVT or PE at 90 days by 41% in patients considered to be at high risk. It was particularly interesting that the incidence of VTE was lower in the intervention group even when physicians chose not to use prophylaxis, which suggests that simply having this alert system in place improved outcomes, perhaps by raising awareness of the risk of VTE.24

Additional studies are needed to better understand physicians’ behavior and determine why they seem to have a disproportionate fear of the risk of bleeding relative to the risk of clotting, including fatal PE, because that is really the heart of the matter. When patients are not given prophylaxis, often it is because of fear of bleeding. It is not clear, however, why some of these patients did not receive mechanical devices as an alternative form of prophylaxis, but this seems to be the case worldwide, as shown recently by the multinational ENDORSE study.22 Meanwhile, as we await studies to better understand physician perceptions and behaviors regarding prophylaxis, we need to work hard to change the system of care.

Dr. Deitelzweig: Over the past couple of years, the Ochsner Clinic has grown from a one-hospital teaching organization to a seven-hospital system with a mix of closed and open medical staff. The challenge is how to take a process that worked well in the one center, where appropriate prophylaxis was used about 90% of the time, and transfer it to the other centers in the larger system. We have endorsed several types of performance tools, such as the change-acceleration processes used by General Electric. The aim is to share a vision of heightening awareness. To do that, we have worked to mobilize the key stakeholders, at least half of them, to build algorithms that they all will endorse. It is easier said than done, however, and we have found it essential to involve both physicians and non-physician colleagues from pharmacy and nursing who have political and organizational clout.

Dr. Brotman: At Johns Hopkins, I took a bit more draconian approach to this issue because I thought that hospitalists often knew that they should be using VTE prophylaxis but sometimes weren’t, and I am not convinced that clinicians always look at prompts. So we came up with a system that incorporates both billing and documentation simultaneously. We put a hard stop on users’ documentation so that they could not sign off on a note or bill for their care until they checked off the kind of VTE prophylaxis they were using. Since hospitalists ultimately care about billing for their work, this system has at least ensured that everybody has considered and documented VTE prophylaxis on a daily basis. There are other hard stops that can be implemented in computer order-entry systems as well, and we are considering ways to roll them out on a broader scale.

However, all of these systems can have problems because patient situations change from day to day. For instance, VTE prophylaxis is not necessarily indicated in a 38-year-old ambulatory patient who comes in with a sickle cell crisis, but you will need to reconsider if the patient ends up in acute chest syndrome in the intensive care unit. I do not yet have a good way to ensure that this is being done on a daily basis with all patients.

Dr. Amin: At the University of California, Irvine, we implemented an electronic alert system, but we locked users in so that they could not complete their admission orders until they answered questions about VTE prevention. This practice increased our VTE prophylaxis rates tremendously. Because we are a level I trauma center, we allow users to bypass the screens one time, but the next time they log in, even to get a simple lab result, they have to answer the questions about VTE prevention.

With any system you develop, you also have to continue with the education process, because clinicians sometimes get into bad habits or simply forget things.

Dr. Spyropolous: At Lovelace Medical Center, we didn’t have the sophistication of an electronic order-entry system, but we had an experienced clinical pharmacist (the director of inpatient pharmacy) who helped to develop and champion VTE prevention guidelines that have then been used throughout the system in close conjunction with our hospitalists’ rounds. This system has been used successfully for the past 7 years.

References
  1. Samama MM, Cohen AT, Darmon JY, et al. A comparison of enoxaparin with placebo for the prevention of venous thrombo-embolism in acutely ill medical patients. Prophylaxis in Medical Patients with Enoxaparin Study Group. N Engl J Med 1999; 341:793–800.
  2. Leizorovicz A, Cohen AT, Turpie AG, et al. Randomized, placebo-controlled trial of dalteparin for the prevention of venous thromboembolism in acutely ill medical patients. Circulation 2004; 110:874–879.
  3. Cohen AT, Davidson BL, Gallus AS, et al. Efficacy and safety of fondaparinux for the prevention of venous thromboembolism in older acute medical patients: randomised placebo controlled trial. BMJ 2006; 332:325–329.
  4. Baglin TP, White K, Charles A. Fatal pulmonary embolism in hos-pitalised medical patients. J Clin Pathol 1997; 50:609–610.
  5. Piazza G, Seddighzadeh A, Goldhaber SZ. Double trouble for 2,609 hospitalized medical patients who developed deep vein thrombosis: prophylaxis omitted more often and pulmonary embolism more frequent. Chest 2007; 132:554–561.
  6. Amin A, Stemkowski S, Lin J, Yang G. Thromboprophylaxis rates in US medical centers: success or failure? J Thromb Haemost 2007; 5:1610–1616.
  7. Geerts WH, Heit JA, Clagett GP, et al. Prevention of venous thromboembolism. Chest 2001; 119(1 Suppl):132S–175S.
  8. Tapson VF, Decousus H, Pini M, et al. Venous thromboembolism prophylaxis in acutely ill hospitalized medical patients: findings from the International Medical Prevention Registry on Venous Thromboembolism. Chest 2007; 132:936–945.
  9. Geerts WH, Pineo GF, Heit JA, et al. Prevention of venous thrombo-embolism: the Seventh ACCP Conference on Antithrombotic and Thrombolytic Therapy. Chest 2004; 126(3 Suppl):338S–400S.
  10. Dentali F, Douketis JD, Gianni M, Lim W, Crowther MA. Meta-analysis: anticoagulant prophylaxis to prevent symptomatic venous thromboembolism in hospitalized medical patients. Ann Intern Med 2007; 146:278–288.
  11. Cardiovascular Disease Educational and Research Trust; Cyprus Cardiovascular Disease Educational and Research Trust; European Venous Forum; International Surgical Thrombosis Forum; International Union of Angiology; Union Internationale de Phlébologie. Prevention and treatment of venous thromboembolism. International Consensus Statement (guidelines according to scientific evidence). Int Angiol 2006; 25:101–161.
  12. Wein L, Wein S, Haas SJ, Shaw J, Krum H. Pharmacological venous thromboembolism prophylaxis in hospitalized medical patients: a meta-analysis of randomized controlled trials. Arch Intern Med 2007; 167:1476–1486.
  13. Mismetti P, Laporte-Simitsidis S, Tardy B, et al. Prevention of venous thromboembolism in internal medicine with unfractionated or low-molecular-weight heparins: a meta-analysis of randomised clinical trials. Thromb Haemost 2000; 83:14–19.
  14. Lechler E, Schramm W, Flosbach CW. The venous thrombotic risk in non-surgical patients: epidemiological data and efficacy/safety profile of a low-molecular-weight heparin (enoxaparin). The Prime Study Group. Haemostasis 1996; 26(Suppl 2):49–56.
  15. Kleber FX, Witt C, Vogel G, et al; the PRINCE Study Group. Randomized comparison of enoxaparin with unfractionated heparin for the prevention of venous thromboembolism in medical patients with heart failure or severe respiratory disease. Am Heart J 2003; 145:614–621.
  16. King CS, Holley AB, Jackson JL, Shorr AF, Moores LK. Twice vs three times daily heparin dosing for thromboembolism prophylaxis in the general medical population: a meta-analysis. Chest 2007; 131:507–516.
  17. Burleigh E, Wang C, Foster D, et al. Thromboprophylaxis in medically ill patients at risk for venous thromboembolism. Am J Health Syst Pharm 2006; 63(20 Suppl 6):S23–S29.
  18. Leykum L, Pugh J, Diuguid D, Papadopoulos K. Cost utility of substituting enoxaparin for unfractionated heparin for prophylaxis of venous thrombosis in the hospitalized medical patient. J Hosp Med 2006; 1:168–176.
  19. Creekmore FM, Oderda GM, Pendleton RC, Brixner DI. Incidence and economic implications of heparin-induced thrombocytopenia in medical patients receiving prophylaxis for venous thromboembolism. Pharmacotherapy 2006; 26:1438–1445.
  20. Spencer FA, Lessard D, Emery C, Reed G, Goldberg RJ. Venous thromboembolism in the outpatient setting. Arch Intern Med 2007; 167:1471–1475.
  21. Hull RD, Schellong SM Tapson VF, et al. Extended-duration venous thromboembolism (VTE) prophylaxis in acutely ill medical patients with recent reduced mobility: the EXCLAIM study. Presentation at: International Society on Thrombosis and Haemo-stasis XXIst Congress; July 6–12, 2007; Geneva, Switzerland.
  22. Cohen AT, Tapson VF, Bergmann JF, et al. Venous thromboembolism risk and prophylaxis in the acute hospital care setting (ENDORSE study): a multinational cross-sectional study. Lancet 2008; 371:387–394.
  23. Kahn SR, Panju A, Geerts W, et al; CURVE study investigators. Multicenter evaluation of the use of venous thromboembolism prophylaxis in acutely ill medical patients in Canada. Thromb Res 2007; 119:145–155.
  24. Kucher N, Koo S, Quiroz R, et al. Electronic alerts to prevent thromboembolism among hospitalized patients. N Engl J Med 2005; 352:969–977.
  25. Anderson FA Jr, Wheeler HB, Goldberg RJ, et al. A population-based perspective of the hospital incidence and case-fatality rates of deep vein thrombosis and pulmonary embolism. The Worcester DVT Study. Arch Intern Med 1991; 151:933–938.
  26. Howell MD, Geraci JM, Knowlton AA. Congestive heart failure and outpatient risk of venous thromboembolism: a retrospective, case-control study. J Clin Epidemiol 2001; 54:810–816.
  27. Smeeth L, Cook C, Thomas S, Hall AJ, Hubbard R, Vallance P. Risk of deep vein thrombosis and pulmonary embolism after acute infection in a community setting. Lancet 2006; 367:1075–1079.
  28. Alikhan R, Cohen AT, Combe S, et al. Prevention of venous thromboembolism in medical patients with enoxaparin: a subgroup analysis of the MEDENOX study. Blood Coagul Firbinolysis 2003; 14:341–346.
  29. Anderson FA Jr, Spencer FA. Risk factors for venous thromboembolism. Circulation 2003; 107(23 Suppl 1):I9–I16.
  30. Greinacher A, Warkentin TE. Recognition, treatment, and prevention of heparin-induced thrombocytopenia: review and update. Thromb Res 2006; 118:165–176.
  31. Martel N, Lee J, Wells PS. Risk for heparin-induced thrombocytopenia with unfractionated and low-molecular-weight heparin thromboprophylaxis: a meta-analysis. Blood 2005; 106:2710–2715.
  32. Sanderink GJ, Guimart CG, Ozoux ML, Jariwala NU, Shukla UA, Boutouyrie BX. Pharmacokinetics and pharmacodynamics of the prophylactic dose of enoxaparin once daily over 4 days in patients with renal impairment. Thromb Res 2002; 105:225–231.
  33. Douketis J, Cook D, Zytaruk N, et al. Dalteparin thromboprophylaxis in critically ill patients with severe renal insufficiency: the DIRECT study [abstract]. J Thromb Haemost 2007; 5(Suppl 2): P-S-680.
  34. Scholten DJ, Hoedema RM, Scholten SE. A comparison of two different prophylactic dose regimens of low molecular weight heparin in bariatric surgery. Obes Surg 2002; 12:19–24.
References
  1. Samama MM, Cohen AT, Darmon JY, et al. A comparison of enoxaparin with placebo for the prevention of venous thrombo-embolism in acutely ill medical patients. Prophylaxis in Medical Patients with Enoxaparin Study Group. N Engl J Med 1999; 341:793–800.
  2. Leizorovicz A, Cohen AT, Turpie AG, et al. Randomized, placebo-controlled trial of dalteparin for the prevention of venous thromboembolism in acutely ill medical patients. Circulation 2004; 110:874–879.
  3. Cohen AT, Davidson BL, Gallus AS, et al. Efficacy and safety of fondaparinux for the prevention of venous thromboembolism in older acute medical patients: randomised placebo controlled trial. BMJ 2006; 332:325–329.
  4. Baglin TP, White K, Charles A. Fatal pulmonary embolism in hos-pitalised medical patients. J Clin Pathol 1997; 50:609–610.
  5. Piazza G, Seddighzadeh A, Goldhaber SZ. Double trouble for 2,609 hospitalized medical patients who developed deep vein thrombosis: prophylaxis omitted more often and pulmonary embolism more frequent. Chest 2007; 132:554–561.
  6. Amin A, Stemkowski S, Lin J, Yang G. Thromboprophylaxis rates in US medical centers: success or failure? J Thromb Haemost 2007; 5:1610–1616.
  7. Geerts WH, Heit JA, Clagett GP, et al. Prevention of venous thromboembolism. Chest 2001; 119(1 Suppl):132S–175S.
  8. Tapson VF, Decousus H, Pini M, et al. Venous thromboembolism prophylaxis in acutely ill hospitalized medical patients: findings from the International Medical Prevention Registry on Venous Thromboembolism. Chest 2007; 132:936–945.
  9. Geerts WH, Pineo GF, Heit JA, et al. Prevention of venous thrombo-embolism: the Seventh ACCP Conference on Antithrombotic and Thrombolytic Therapy. Chest 2004; 126(3 Suppl):338S–400S.
  10. Dentali F, Douketis JD, Gianni M, Lim W, Crowther MA. Meta-analysis: anticoagulant prophylaxis to prevent symptomatic venous thromboembolism in hospitalized medical patients. Ann Intern Med 2007; 146:278–288.
  11. Cardiovascular Disease Educational and Research Trust; Cyprus Cardiovascular Disease Educational and Research Trust; European Venous Forum; International Surgical Thrombosis Forum; International Union of Angiology; Union Internationale de Phlébologie. Prevention and treatment of venous thromboembolism. International Consensus Statement (guidelines according to scientific evidence). Int Angiol 2006; 25:101–161.
  12. Wein L, Wein S, Haas SJ, Shaw J, Krum H. Pharmacological venous thromboembolism prophylaxis in hospitalized medical patients: a meta-analysis of randomized controlled trials. Arch Intern Med 2007; 167:1476–1486.
  13. Mismetti P, Laporte-Simitsidis S, Tardy B, et al. Prevention of venous thromboembolism in internal medicine with unfractionated or low-molecular-weight heparins: a meta-analysis of randomised clinical trials. Thromb Haemost 2000; 83:14–19.
  14. Lechler E, Schramm W, Flosbach CW. The venous thrombotic risk in non-surgical patients: epidemiological data and efficacy/safety profile of a low-molecular-weight heparin (enoxaparin). The Prime Study Group. Haemostasis 1996; 26(Suppl 2):49–56.
  15. Kleber FX, Witt C, Vogel G, et al; the PRINCE Study Group. Randomized comparison of enoxaparin with unfractionated heparin for the prevention of venous thromboembolism in medical patients with heart failure or severe respiratory disease. Am Heart J 2003; 145:614–621.
  16. King CS, Holley AB, Jackson JL, Shorr AF, Moores LK. Twice vs three times daily heparin dosing for thromboembolism prophylaxis in the general medical population: a meta-analysis. Chest 2007; 131:507–516.
  17. Burleigh E, Wang C, Foster D, et al. Thromboprophylaxis in medically ill patients at risk for venous thromboembolism. Am J Health Syst Pharm 2006; 63(20 Suppl 6):S23–S29.
  18. Leykum L, Pugh J, Diuguid D, Papadopoulos K. Cost utility of substituting enoxaparin for unfractionated heparin for prophylaxis of venous thrombosis in the hospitalized medical patient. J Hosp Med 2006; 1:168–176.
  19. Creekmore FM, Oderda GM, Pendleton RC, Brixner DI. Incidence and economic implications of heparin-induced thrombocytopenia in medical patients receiving prophylaxis for venous thromboembolism. Pharmacotherapy 2006; 26:1438–1445.
  20. Spencer FA, Lessard D, Emery C, Reed G, Goldberg RJ. Venous thromboembolism in the outpatient setting. Arch Intern Med 2007; 167:1471–1475.
  21. Hull RD, Schellong SM Tapson VF, et al. Extended-duration venous thromboembolism (VTE) prophylaxis in acutely ill medical patients with recent reduced mobility: the EXCLAIM study. Presentation at: International Society on Thrombosis and Haemo-stasis XXIst Congress; July 6–12, 2007; Geneva, Switzerland.
  22. Cohen AT, Tapson VF, Bergmann JF, et al. Venous thromboembolism risk and prophylaxis in the acute hospital care setting (ENDORSE study): a multinational cross-sectional study. Lancet 2008; 371:387–394.
  23. Kahn SR, Panju A, Geerts W, et al; CURVE study investigators. Multicenter evaluation of the use of venous thromboembolism prophylaxis in acutely ill medical patients in Canada. Thromb Res 2007; 119:145–155.
  24. Kucher N, Koo S, Quiroz R, et al. Electronic alerts to prevent thromboembolism among hospitalized patients. N Engl J Med 2005; 352:969–977.
  25. Anderson FA Jr, Wheeler HB, Goldberg RJ, et al. A population-based perspective of the hospital incidence and case-fatality rates of deep vein thrombosis and pulmonary embolism. The Worcester DVT Study. Arch Intern Med 1991; 151:933–938.
  26. Howell MD, Geraci JM, Knowlton AA. Congestive heart failure and outpatient risk of venous thromboembolism: a retrospective, case-control study. J Clin Epidemiol 2001; 54:810–816.
  27. Smeeth L, Cook C, Thomas S, Hall AJ, Hubbard R, Vallance P. Risk of deep vein thrombosis and pulmonary embolism after acute infection in a community setting. Lancet 2006; 367:1075–1079.
  28. Alikhan R, Cohen AT, Combe S, et al. Prevention of venous thromboembolism in medical patients with enoxaparin: a subgroup analysis of the MEDENOX study. Blood Coagul Firbinolysis 2003; 14:341–346.
  29. Anderson FA Jr, Spencer FA. Risk factors for venous thromboembolism. Circulation 2003; 107(23 Suppl 1):I9–I16.
  30. Greinacher A, Warkentin TE. Recognition, treatment, and prevention of heparin-induced thrombocytopenia: review and update. Thromb Res 2006; 118:165–176.
  31. Martel N, Lee J, Wells PS. Risk for heparin-induced thrombocytopenia with unfractionated and low-molecular-weight heparin thromboprophylaxis: a meta-analysis. Blood 2005; 106:2710–2715.
  32. Sanderink GJ, Guimart CG, Ozoux ML, Jariwala NU, Shukla UA, Boutouyrie BX. Pharmacokinetics and pharmacodynamics of the prophylactic dose of enoxaparin once daily over 4 days in patients with renal impairment. Thromb Res 2002; 105:225–231.
  33. Douketis J, Cook D, Zytaruk N, et al. Dalteparin thromboprophylaxis in critically ill patients with severe renal insufficiency: the DIRECT study [abstract]. J Thromb Haemost 2007; 5(Suppl 2): P-S-680.
  34. Scholten DJ, Hoedema RM, Scholten SE. A comparison of two different prophylactic dose regimens of low molecular weight heparin in bariatric surgery. Obes Surg 2002; 12:19–24.
Page Number
S7-S16
Page Number
S7-S16
Publications
Publications
Article Type
Display Headline
Prevention of venous thromboembolism in the hospitalized medical patient
Display Headline
Prevention of venous thromboembolism in the hospitalized medical patient
Citation Override
Cleveland Clinic Journal of Medicine 2008 April;75(suppl 3):S7-S16
Disallow All Ads
Alternative CME
Use ProPublica
Article PDF Media

Prevention of venous thromboembolism in the cancer surgery patient

Article Type
Changed
Tue, 09/25/2018 - 15:49
Display Headline
Prevention of venous thromboembolism in the cancer surgery patient

Venous thromboembolism (VTE) is a major complication of cancer, occurring in 4% to 20% of patients,1 and is one of the leading causes of death in cancer patients, although these figures are believed to be underestimates, given the low autopsy rates among cancer patients.2 In hospitalized cancer patients specifically, VTE is the second leading cause of death.3,4 The risk of VTE in cancer patients undergoing surgery is three to five times greater than that in surgical patients without cancer.4 Moreover, cancer patients with symptomatic deep vein thrombosis (DVT) exhibit a high risk of recurrent VTE that may persist for many years after the index event.5

VTE PREVENTION POSES PARTICULAR CHALLENGES IN CANCER PATIENTS

Until recently, data on VTE prevention specific to cancer patients have been sparse. Cancer patients have represented only a small subset (< 20%) of participants in most of the largest clinical trials of VTE prophylaxis. Until the past 2 or 3 years, clinicians largely have had to extrapolate their approach to VTE prophylaxis in cancer patients from data in patients without cancer, bearing in mind that cancer patients are among the populations at highest risk of developing VTE.

High rates of VTE, even with prophylaxis

What has been clear is that VTE prevention is a formidable challenge in this population, even when thromboprophylaxis is used. Despite thromboprophylaxis, cancer patients undergoing surgery have twice the risk of VTE and nonfatal pulmonary embolism (PE) and three times the risk of fatal PE compared with other surgical patients (Table 1).6,7

Further insights have come from the @RISTOS project, a Web-based prospective registry of patients undergoing general, urologic, or gynecologic surgery for cancer at multiple centers in Italy.8 Of the 2,372 patients tracked in this study, 82% received in-hospital VTE prophylaxis and 31% received prophylaxis following discharge. Despite this relatively high frequency of prophylaxis, however, the incidence of clinically overt VTE was 2.1% and the incidence of fatal VTE was 0.8%. Notably, most VTE events occurred after hospital discharge, and VTE was the most common cause of 30-day postoperative death in this registry.

RISK FACTORS: CANCER TYPE AND TREATMENT LOOM LARGE

Both the type and stage of a patient’s cancer are important in assessing the risk of VTE. For men, cancers of the prostate, colon, brain, and lung have been associated with an increased risk of VTE. Among women, cancers of the breast, ovary, and lung have been especially implicated as risk factors for VTE.9,10

The type of cancer therapy also influences VTE risk:

  • Surgery. Among patients who undergo cancer-related surgery, the rate of proximal DVT is 10% to 20%, the rate of clinically evident PE is 4% to 10%, and the incidence of fatal PE is 0.2% to 5%.8,11
  • Systemic treatments, including chemotherapy and hormone therapy, are also associated with an increased risk of VTE.12–15
  • Central venous catheters. Approximately 4% of cancer patients who have central venous catheters placed develop clinically relevant VTE.16,17

In addition to the above risks related to cancer treatments, the following have been identified as risk factors for VTE in surgical oncology patients:

  • Age greater than 40 years (risk also increases steeply after age 60 and again after age 75)
  • Cancer procoagulants
  • Thrombophilia
  • Length and complications of cancer surgery (ie, often involving tissue trauma and immobilization)
  • Debilitation and slow recovery.

Another risk factor worth noting is perioperative transfusion, as illustrated in a recent study of 14,104 adults undergoing colorectal cancer resection.18 The overall incidence of VTE in these patients was 1.0%, and the risk of death was nearly four times as great in patients who developed VTE as in those who did not. Notably, the need for transfusion was a marker of increased risk of VTE, particularly in women: women who received perioperative transfusions had almost double the risk of developing VTE compared with women who did not receive transfusions (P = .004).

CLINICAL TRIALS OF PROPHYLAXIS IN CANCER SURGERY PATIENTS

LMWH vs UFH for in-hospital prophylaxis

Two large randomized, double-blind trials have compared low-molecular-weight heparin (LMWH) with low-dose unfractionated heparin (UFH) for VTE prophylaxis in surgical patients with cancer—the Enoxaparin and Cancer (ENOXACAN) study19 and the Canadian Colorectal Surgery DVT Prophylaxis Trial.20 Patients in these studies underwent surgery for abdominal or pelvic cancer (mostly colorectal cancer). Both studies compared 40 mg of the LMWH enoxaparin given once daily with 5,000 U of UFH given three times daily for 7 to 10 days postoperatively. Outcome measures were the presence of DVT determined by venography on day 7 to 10 and the incidence of symptomatic VTE. Rates of VTE were statistically equivalent between the two treatment arms in both ENOXACAN (14.7% with LMWH vs 18.2% with UFH) and the Canadian Colorectal Surgery study (9.4% with both therapies), as were rates of major bleeding (4.1% with LMWH vs 2.9% with UFH in ENOXACAN; 2.7% with LMWH vs 1.5% with UFH in the Canadian study).

These findings are consistent with a 2001 meta-analysis by Mismetti et al of all available randomized trials comparing LMWH with placebo or with UFH for VTE prophylaxis in general surgery.21 This analysis found no differences in rates of asymptomatic DVT, clinical PE, clinical thromboembolism, death, major hemorrhage, total hemorrhage, wound hematoma, or need for transfusion between LMWH and UFH in patients undergoing either cancer-related surgery or surgery not related to cancer.

Fondaparinux for in-hospital prophylaxis

Subgroup analysis of the large randomized trial known as PEGASUS22 sheds some light on the efficacy of the factor Xa inhibitor fondaparinux relative to LMWH for thromboprophylaxis in cancer surgery patients. PEGASUS compared fondaparinux 2.5 mg once daily with the LMWH dalteparin 5,000 IU once daily for 5 to 9 days in patients undergoing high-risk abdominal surgery. Among the study’s 1,408 patients undergoing surgery for cancer, rates of VTE were 4.7% in the fondaparinux group compared with 7.7% in the LMWH group, a relative risk reduction of 38.6% with fondaparinux (95% CI, 6.7% to 59.6%). In contrast, in the rest of the PEGASUS population (patients undergoing abdominal surgery for reasons other than cancer), LMWH was nonsignificantly more efficacious at preventing VTE than was fondaparinux. Rates of major bleeding in this cancer subgroup were comparable between the two treatments.

 

 

Extended prophylaxis

Two additional randomized trials have evaluated extended prophylaxis with LMWH in surgical cancer patients—ENOXACAN II23 and the Fragmin After Major Abdominal Surgery (FAME) study.24

In ENOXACAN II, patients undergoing surgery for abdominal or pelvic cancer first received 6 to 10 days of prophylaxis with enoxaparin 40 mg once daily and then were randomized in a double-blind fashion to an additional 21 days of enoxaparin or placebo.23 Among 332 patients in the intent-to-treat analysis, the rate of VTE at the end of the double-blind phase was reduced from 12.0% with placebo to 4.8% with extended-duration enoxaparin (P = .02), an effect that was maintained at 3-month follow-up (P = .01). There was no significant difference between the two groups in rates of major bleeding events or any bleeding events.

In FAME, patients received 5,000 IU of dalteparin once daily for 1 week following major abdominal surgery and then were randomized in open-label fashion to either placebo or extended prophylaxis with dalteparin for 3 more weeks; a subanalysis examined outcomes in the 198 FAME participants whose abdominal surgery was for cancer.24 Among these 198 cancer surgery patients, the rate of venography-documented VTE at 4 weeks was reduced from 19.6% with placebo to 8.8% with extended-duration dalteparin, a relative reduction of 55% (P = .03). The rate of proximal DVT was reduced from 10.4% to 2.2% with extended prophylaxis, a relative reduction of 79% (P = .02).

The number needed to treat with extended LMWH prophylaxis to prevent one VTE event was 14 in ENOXACAN II23 and 9 in the FAME subanalysis of cancer surgery patients.24

New systematic review of relevant trials

Leonardi et al recently published a systematic review of 26 randomized controlled trials of DVT prophylaxis in 7,639 cancer surgery patients.25 They found the overall incidence of DVT to be 12.7% in those who received pharmacologic prophylaxis compared with 35.2% in controls. They also found high-dose LMWH therapy (> 3,400 U daily) to be associated with a significantly lower incidence of DVT than low-dose LMWH therapy (≤ 3,400 U daily) (7.9% vs 14.5%, respectively; P < .01). No differences were demonstrated between LMWH and UFH in preventing DVT, DVT location, or bleeding. Bleeding complications requiring discontinuation of pharmacologic prophylaxis occurred in 3% of patients overall.

Implications of HIT

The sequelae of heparin-induced thrombocytopenia (HIT) can have major consequences for cancer surgery patients. The incidence of HIT is markedly lower with LMWH than with UFH, as demonstrated in a nested case-control study by Creekmore et al.26 These researchers also found that the average cost of an admission during which HIT developed was nearly four times as great as the average cost of an admission during which UFH or LMWH was given without development of HIT ($56,364 vs $15,231; P < .001).

EVIDENCE IN SPECIFIC ONCOLOGIC POPULATIONS

Most of the patients in the trials reviewed above underwent abdominal surgery for malignancy. Although studies of VTE prophylaxis in patients undergoing nonabdominal cancer surgery are relatively few, some data are available for a few other specific oncologic populations, as reviewed below.

Surgery for gynecologic cancer

There is a paucity of randomized controlled trials or prospective observational studies on VTE and its prevention in the gynecologic cancer surgery population. Based on small historical studies, the postoperative risk of VTE in this population varies from 12% to 35%.27,28 Twice-daily administration of UFH 5,000 U appears to be ineffective as VTE prophylaxis in this population, but increasing the frequency to three times daily reduces VTE risk by 50% to 60% compared with placebo. Once-daily LMWH is comparable to three-times-daily UFH in efficacy and safety in this population.

A systematic Cochrane review of eight randomized controlled trials in patients undergoing major gynecologic surgery revealed that heparin prophylaxis (either UFH or LMWH) reduces the risk of DVT by 70% compared with no prophylaxis, with an identical risk reduction specifically among women with malignancy (odds ratio, 0.30; 95% CI, 0.10 to 0.89).29 This review found no evidence that anticoagulation reduces the risk of PE following major gynecologic surgery. LMWH and UFH were similar in efficacy for preventing DVT and had a comparable risk of bleeding complications.

Surgery for urologic cancer

The risk of VTE and the benefits of thromboprophylaxis also are poorly studied in patients undergoing surgery for urologic cancer.

The risk of VTE varies with the type of urologic surgery and the method used to diagnose VTE. For instance, patients undergoing radical retropubic prostatectomy have been reported to develop DVT at rates of 1% to 3%, PE at rates of 1% to 3%, and fatal PE at a rate of 0.6%, whereas the incidences of these events are somewhat higher in patients undergoing cystectomy: 8% for DVT, 2% to 4% for PE, and 2% for fatal PE. Radiologic diagnosis of thromboembolism in pelvic surgery patients has yielded higher incidences, with DVT rates of 21% to 51% and PE rates of 11% to 22%.30

Small studies suggest that prophylaxis with either low-dose UFH or LMWH is both effective in reducing VTE risk and safe in urologic cancer surgery patients, although pharmacologic prophylaxis poses a possible increased risk of pelvic hematoma and lymphocele formation in this population.30

Neurosurgery

Most neurosurgical procedures are performed for malignancies. The risk of venography-confirmed VTE in patients undergoing neurosurgery is approximately 30% to 40%.31,32 Likewise, the risks of intracranial or intraspinal hemorrhage in these patients are high. For this reason, mechanical methods of VTE prophylaxis are preferred in these patients. The use of anticoagulant prophylaxis remains controversial in this setting, although more recent data suggest that it might be safer than previously recognized.

A meta-analysis of studies of pharmacologic prophylaxis of VTE in neurosurgery included three randomized controlled trials that compared LMWH, with or without mechanical prophylaxis, to placebo plus mechanical prophylaxis or placebo alone in a total of 922 neurosurgery patients.33 As detailed in Table 2, the analysis demonstrated statistically significant reductions in the risks of VTE and proximal DVT in favor of LMWH, with a statistically significant doubling in the risk of any bleeding and a nonsignificant 70% increase in the risk of major bleeding with LMWH therapy. The number needed to treat to prevent 1 proximal DVT was 16, while the number needed to treat to cause 1 major bleeding event was 115. A risk-benefit analysis showed that the use of LMWH in neurosurgery patients was associated with 1 major nonfatal bleeding event for every 7 proximal DVTs prevented. When a fourth randomized trial was included in the analysis, comparing UFH 5,000 U three times daily with no prophylaxis, rates of VTE and bleeding events remained similar to those for the LMWH trials alone.

 

 

GUIDELINES FOR VTE PROPHYLAXIS IN THE CANCER SURGERY PATIENT

American College of Chest Physicians

The American College of Chest Physicians’ Seventh ACCP Conference on Antithrombotic and Thrombolytic Therapy makes a number of recommendations regarding VTE prevention in patients undergoing surgery for cancer, as outlined in Table 3.34

National Comprehensive Cancer Network

The National Comprehensive Cancer Network (NCCN) recently published clinical practice guidelines on venous thromboembolic disease in cancer patients.35 The defined at-risk population for these guidelines is the adult cancer inpatient with a diagnosis of (or clinical suspicion for) cancer. The guidelines recommend prophylactic anticoagulation (category 1 recommendation) with or without a sequential compression device as initial prophylaxis, unless the patient has a relative contraindication to anticoagulation, in which case mechanical prophylaxis (sequential compression device or graduated compression stockings) is recommended. (A category 1 recommendation indicates “uniform NCCN consensus, based on high-level evidence.”)

The NCCN guidelines include a specific recommended risk-factor assessment, which includes noting the patient’s age (VTE risk increases beginning at age 40 and then steeply again at age 75), any prior VTE, the presence of familial thrombophilia or active cancer, the use of medications associated with increased VTE risk (chemotherapy, exogenous estrogen compounds, and thalidomide or lenalidomide), and a number of other risk factors for VTE as outlined in the prior two articles in this supplement. The NCCN guidelines explicitly call for assessment of modifiable risk factors for VTE (ie, smoking or other tobacco use, obesity, and a low level of activity or lack of exercise) and call for active patient education on these factors.

American Society of Clinical Oncology

The American Society of Clinical Oncology (ASCO) recently released guidelines on VTE prevention and treatment in patients with cancer;1 their key recommendations for prevention are summarized in Table 4. Notable differences from the recommendations of the Seventh ACCP Conference are the ASCO guidelines’ inclusion of fondaparinux among recommended prophylactic options for this population and more explicit recommendations on the prophylactic use of LMWH. Also, for treatment of cancer patients with established VTE, ASCO specifies that LMWH is the preferred anticoagulant for both initial and continuing treatment.

Our recommended algorithm

Figure 1. Algorithm for VTE prophylaxis in the patient undergoing major surgery for cancer.
Drawing from the above formal society guidelines and the published literature, we recommend the algorithm in Figure 1 as a practical approach to VTE prevention in patients undergoing major surgery for cancer.

LINGERING CHALLENGE OF UNDERUTILIZATION

Despite this consensus on ways to reduce thromboembolic risk in this population and the clear evidence of the benefit of VTE prophylaxis in patients with cancer, data from several registries confirm a persistently low utilization of prophylaxis in patients with cancer.36–38 The global Fundamental Research in Oncology and Thrombosis (FRONTLINE) study surveyed 3,891 clinicians who treat cancer patients regarding their practices with respect to VTE in those patients.36 The survey found that only 52% of respondents routinely used thromboprophylaxis for their surgical patients with cancer. More striking, however, was the finding that most respondents routinely considered thrombo-prophylaxis in only 5% of their medical oncology patients. These data are echoed by findings of other retrospective medical record reviews in patients undergoing major abdominal or abdominothoracic surgery (in many cases for cancer), with VTE prophylaxis rates ranging from 38% to 75%.37,38

SUMMARY

Patients undergoing surgery for cancer have an increased risk of VTE and fatal PE, even when throm­boprophylaxis is used. Nevertheless, prophylaxis with either LMWH or UFH does reduce venographic VTE event rates in these patients. If UFH is chosen for prophylaxis, a three-times-daily regimen should be used in this population. In specific surgical cancer populations, especially those undergoing abdominal surgery, out-of-hospital prophylaxis with once-daily LMWH is warranted. Current registries reveal that compliance with established guidelines for VTE prophylaxis in this population is low.

 

 

DISCUSSION: ADDITIONAL PERSPECTIVES FROM THE AUTHORS

Dr. Jaffer: Dr. Amin, based on your study on thrombo-prophylaxis rates in US medical centers, will you comment on rates of prophylaxis for cancer surgery patients?

Dr. Amin: The overall study included approximately 200,000 medical patients and about 80,000 surgical patients enrolled over more than a 3-year period between 2002 and 2005.39,40 Our goal was to assess rates of prophylaxis and, when it was provided, whether it was appropriate (in terms of type, dosage, and duration) based on the ACCP guidelines. A subanalysis assessed medical cancer patients and surgical cancer patients separately. Medical cancer patients received thromboprophylaxis 56% of the time but received appropriate prophylaxis only 28% of the time. Among surgical cancer patients, appropriate prophylaxis was given only about 24% of the time for those undergoing gynecologic surgery and about 12% of the time for those undergoing neurosurgery. These percentages are consistent with data from other national registries, such as the IMPROVE registry, which documented prophylaxis rates on the order of 45% in medical patients with cancer.41 We also analyzed the data according to individual practitioners and found that medical oncologists use prophylaxis about 25% of the time, which is relatively consistent with other providers, such as internists and surgeons.

So there is a huge opportunity to improve rates of prophylaxis for this group of patients that national guidelines say are at high risk. Why is prophylaxis so underutilized in the cancer population? One factor may be a misperception about the risk of bleeding with anticoagulants. Yet several studies have shown that the rate of bleeding from prophylaxis is extremely low, whether LMWH or UFH is used, so more awareness of actual bleeding risk is needed. Another factor is the obvious focus among internists and oncologists on treating the patient, with perhaps a reduced consideration of prophylaxis and prevention. A third factor may be a concern about thrombocytopenia. However, in our study of prophylaxis rates in US medical centers, we excluded patients who had thrombocytopenia, yet rates of prophylaxis were still low. Nothing in the literature indicates that anticoagulants cannot be used in patients with platelet counts of 50,000 to 150,000 cells/µL or higher, so this suggests that we need to do more education.

Dr. Jaffer: Dr. Brotman, can you tell us more about how clinicians in practice should use prophylaxis in their neurosurgery patients, such as those undergoing craniotomy or spine surgery for cancer? What is the safest and most efficacious way to prevent DVT in these patients?

Dr. Brotman: First, it’s important to recognize that some sort of prophylaxis needs to be used. Neurosurgery patients are at an extremely high risk for thromboembolic events, and such events are often fatal in these patients. Having said that, the jury is still out on whether the prophylaxis in these patients should be compression devices or anticoagulation. This gives physicians some latitude in their decisions. They can decide not to use pharmacologic prophylaxis so long as they use pneumatic compression devices consistently, perhaps even starting during the operation and certainly throughout hospitalization when the patient is immobilized.

Certainly, the concerns about using full-dose anticoagulation in the immediate postoperative setting in neurosurgery patients are valid. Yet these patients are at very high risk for thromboembolic events, and if we take too cautious an approach to prophylaxis in the immediate perioperative setting, more patients are going to have thromboembolic events, at which point management decisions become much more difficult. The risk of intracranial bleeding with anticoagulation to treat a patient who develops a DVT at postoperative day 10 will certainly be higher than it would have been with lower-dose perioperative prophylactic anticoagulation. Plus, if you put in a filter at that point, the outcomes tend to be poor. Therefore, I believe there is some degree of risk that we should be willing to take with regard to perioperative bleeding, even in neurosurgery patients.

Dr. McKean: I’d like to make a point about combination prophylaxis. At many institutions, compression stockings and sequential compression devices are used preoperatively and intraoperatively, and then pharmacologic prophylaxis—for example, twice-daily UFH—is used postoperatively. There is concern that these patients are hypercoagulable, and most clinicians believe that mechanical prophylaxis alone, even with sequential compression devices plus compression stockings, is not aggressive enough in these high-risk patients.

Dr. Jaffer: Dr. Spyropoulos, what is the optimal duration of pharmacologic prophylaxis for cancer surgery patients?

Dr. Spyropoulos: First let’s consider in-hospital prophylaxis. The supportive data for in-hospital prophylaxis are strong, and the duration of therapy used in the major in-hospital prophylaxis trials was 7 to 10 days. With regard to extended prophylaxis, we have at least two moderately sized randomized controlled trials, ENOXACAN II23 and the substudy of FAME,24 that demonstrated that extending prophylaxis with LMWH at doses of 3,400 U once daily (5,000 IU of dalteparin; 40 mg of enoxaparin) reduces VTE risk at postoperative day 30. Also, recent data from the @RISTOS registry show that in cancer surgery patients, especially those having abdominal or pelvic procedures, the leading cause of 30-day mortality was VTE.8 This registry also shows that despite prophylaxis, the rate of symptomatic VTE can be as high as 2%, with the rate of fatal VTE approaching 1%. Thus, in cancer patients undergoing abdominal or pelvic surgery, physicians should strongly consider prophylaxis of up to 30 days’ duration.

Dr. Jaffer: One striking finding from the @RISTOS registry was that 40% of VTE events in these cancer surgery patients occurred after postoperative day 21. This really underscores the need to consider prophylaxis for at least 4 weeks in these patients in real-world practice.

Dr. Brotman: The other striking finding from that registry was that the in-hospital prophylaxis rate was quite high, about 80%, and the rate of extended prophylaxis approached 35%. These are rates that are rarely achieved in clinical practice. Yet despite these high levels of prophylaxis, patients in this registry still had a high incidence of morbidity and mortality from VTE. This suggests that we need to improve our out-of-hospital VTE prevention paradigms.

Dr. Jaffer: Dr. Deitelzweig, oncologists and internists are often unsure about whether their ambulatory cancer patients who are receiving chemotherapy should be on any form of prophylaxis. What is your opinion?

Dr. Deitelzweig: That question comes up regularly because these patients are encountered across many medical specialties. At this point, all of the large organizations, including ASCO and NCCN, are advocating that prophylaxis is not indicated for such patients.

References
  1. Lyman GH, Khorana AA, Falanga A, et al. American Society of Clinical Oncology guideline: recommendations for venous thromboembolism prophylaxis and treatment in patients with cancer. J Clin Oncol 2007; 25:5490–5505.
  2. Khorana AA, Francis CW, Culakova E, et al. Thromboembolism is a leading cause of death in cancer patients receiving outpatient chemotherapy. J Thromb Haemost 2007; 5:632–634.
  3. Ambrus JL, Ambrus CM, Mink IB, Pickren JW. Causes of death in cancer patients. J Med 1975; 6:61–64.
  4. Donati MB. Cancer and thrombosis. Haemostasis 1994; 24:128–131.
  5. Prandoni P, Lensing AW, Cogo A, et al. The long-term clinical course of acute deep venous thrombosis. Ann Intern Med 1996; 125:1–7.
  6. Haas S, Wolf H, Kakkar AK, Fareed J, Encke A. Prevention of fatal pulmonary embolism and mortality in surgical patients: a randomized double-blind comparison of LMWH with unfractionated heparin. Thromb Haemost 2005; 94:814–819.
  7. Kakkar AK, Haas S, Wolf H, Encke A. Evaluation of perioperative fatal pulmonary embolism and death in cancer surgical patients: the MC-4 cancer substudy. Thromb Haemost 2005; 94:867–871.
  8. Agnelli G, Bolis G, Capussotti L, et al. A clinical outcome-based prospective study on venous thromboembolism after cancer surgery: the @RISTOS project. Ann Surg 2006; 243:89–95.
  9. Levitan N, Dowlati A, Remick SC, et al. Rates of initial and recurrent thromboembolic disease among patients with malignancy versus those without malignancy: risk analysis using Medicare claims data. Medicine (Baltimore) 1999; 78:285–291.
  10. Levine M, Gent M, Hirsh J, et al. A comparison of low-molecular-weight heparin administered primarily at home with unfractionated heparin administered in the hospital for proximal deep-vein thrombosis. N Engl J Med 1996; 334:677–681.
  11. Bergqvist D. Risk of venous thromboembolism in patients undergoing cancer surgery and options for thromboprophylaxis. J Surg Oncol 2007; 95:167–174.
  12. Heit JA, Silverstein MD, Mohr DN, et al. Risk factors for deep vein thrombosis and pulmonary embolism: a population-based case-control study. Arch Intern Med 2000; 160:809–815.
  13. Sallah S, Wan JY, Nguyen NP. Venous thrombosis in patients with solid tumors: determination of frequency and characteristics. Thromb Haemost 2002; 87:575–579.
  14. Kröger K, Weiland D, Ose C, et al. Risk factors for venous thromboembolic events in cancer patients. Ann Oncol 2006; 17:297–303.
  15. Blom JW, Vanderschoot JP, Oostindiër MJ, et al. Incidence of venous thrombosis in a large cohort of 66,329 cancer patients: results of a record linkage study. J Thromb Haemost 2006; 4:529–535.
  16. Couban S, Simpson DR, Barnett MJ, et al. A randomized multicenter comparison of bone marrow and peripheral blood in recipients of matched sibling allogeneic transplants for myeloid malignancies. Blood 2002; 100:1525–1531.
  17. Walshe LJ, Malak SF, Eagan J, Sepkowitz KA. Complication rates among cancer patients with peripherally inserted central catheters. J Clin Oncol 2002; 20:3276–3281.
  18. Nilsson KR, Berenholtz SM, Garrett-Mayer E, et al. Association between venous thromboembolism and perioperative allogeneic transfusion. Arch Surg 2007; 142:126–133.
  19. Efficacy and safety of enoxaparin versus unfractionated heparin for prevention of deep vein thrombosis in elective cancer surgery: a double-blind randomized multicentre trial with venographic assessment. ENOXACAN Study Group. Br J Surg 1997; 84:1099–1103.
  20. McLeod RS, Geerts WH, Sniderman KW, et al. Subcutaneous heparin versus low-molecular-weight heparin as thromboprophylaxis in patients undergoing colorectal surgery: results of the Canadian Colorectal DVT Prophylaxis Trial: a randomized, double-blind trial. Ann Surg 2001; 233:438–444.
  21. Mismetti P, Laporte S, Darmon JY, Buchmüller A, Decousus H. Meta-analysis of low molecular weight heparin in the prevention of venous thromboembolism in general surgery. Br J Surg 2001; 88:913–930.
  22. Agnelli G, Bergqvist D, Cohen AT, et al, on behalf of the PEGASUS investigators. Randomized clinical trial of postoperative fondaparinux versus perioperative dalteparin for prevention of venous thromboembolism in high-risk abdominal surgery. Br J Surg 2005; 92:1212–1220.
  23. Bergqvist D, Agnelli G, Cohen AT, et al. Duration of prophylaxis against venous thromboembolism with enoxaparin after surgery for cancer. N Engl J Med 2002; 346:975–980.
  24. Rasmussen MS, Wille-Jorgensen P, Jorgensen LN, et al. Prolonged thromboprophylaxis with low molecular weight heparin (dalteparin) following major abdominal surgery for malignancy [abstract 186]. Blood 2003; 102:56a.
  25. Leonardi MJ, McGory ML, Ko CY. A systematic review of deep venous thrombosis prophylaxis in cancer patients: implications for improving quality. Ann Surg Oncol 2007; 14:929–936.
  26. Creekmore FM, Oderda GM, Pendleton RC, Brixner DI. Incidence and economic implications of heparin-induced thrombocytopenia in medical patients receiving prophylaxis for venous thromboembolism. Pharmacotherapy 2006; 26:1438–1445.
  27. Walsh JJ, Bonnar J, Wright FW. A study of pulmonary embolism and deep leg vein thrombosis after major gynaecological surgery using labeled fibrinogen-phlebography and lung scanning. J Obstet Gynaecol Br Commonw 1974; 81:311–316.
  28. Clarke-Pearson DL, Synan IS, Coleman RE, et al. The natural history of postoperative venous thromboemboli in gynecologic oncology: a prospective study of 382 patients. Am J Obstet Gynecol 1984; 148:1051–1054.
  29. Oates-Whitehead RM, D’Angelo A, Mol B. Anticoagulant and aspirin prophylaxis for preventing thromboembolism after major gynaecological surgery. Cochrane Database Syst Rev 2003; (4):CD003679.
  30. Kibel AS, Loughlin KR. Pathogenesis and prophylaxis of postoperative thromboembolic disease in urological pelvic surgery. J Urol 1995; 153:1763–1774.
  31. Agnelli G, Piovella F, Buoncristiani P, et al. Enoxaparin plus compression stockings compared with compression stockings alone in the prevention of venous thromboembolism after elective neurosurgery. N Engl J Med 1998; 339:80–85.
  32. Semrad TJ, O’Donnell R, Wun T, et al. Epidemiology of venous thromboembolism in 9489 patients with malignant glioma. J Neurosurg 2007; 106:601–608.
  33. Iorio A, Agnelli G. Low-molecular-weight and unfractionated heparin for prevention of venous thromboembolism in neurosurgery: a meta-analysis. Arch Intern Med 2000; 160:2327–2332.
  34. Geerts WH, Pineo GF, Heit JA, et al. Prevention of venous thromboembolism: the Seventh ACCP Conference on Antithrombotic and Thrombolytic Therapy. Chest 2004; 126(3 Suppl):338S–400S.
  35. National Comprehensive Cancer Network. NCCN Clinical Practice Guidelines in Oncology. Venous thromboembolic disease. V.1.2007. http://www.nccn.org/professionals/physician_gls/PDF/vte.pdf. Accessed December 5, 2007.
  36. Kakkar AK, Levine M, Pinedo HM, Wolff R, Wong J. Venous thrombosis in cancer patients: insights from the FRONTLINE survey. Oncologist 2003; 8:381–388.
  37. Stratton MA, Anderson FA, Bussey HI, et al. Prevention of venous thromboembolism: adherence to the 1995 American College of Chest Physicians consensus guidelines for surgical patients. Arch Intern Med 2000; 160:334–340.
  38. Bratzler DW, Raskob GE, Murray CK, Bumpus LJ, Piatt DS. Underuse of venous thromboembolism prophylaxis for general surgery patients: physician practices in the community hospital setting. Arch Intern Med 1998; 158:1909–1912.
  39. Amin A, Stemkowski S, Lin J, et al. Thromboprophylaxis rates in US medical centers: success or failure? J Thromb Haemost 2007; 5:1610–1616.
  40. Amin A, Stemkowski S, Lin J, Yang G. Thromboprophylaxis in US hospitals: adherence to the 6th American College of Chest Physicians’ recommendations for at-risk medical and surgical patients. Abstract presented at: 41st Midyear Clinical Meeting of the American Society of Health-System Pharmacists; December 3–7, 2006; Anaheim, CA.
  41. Tapson VF, Decousus H, Pini M, et al. Venous thromboembolism prophylaxis in acutely ill hospitalized medical patients: findings from the International Medical Prevention Registry on Venous Thromboembolism. Chest 2007; 132:936–945.
  42. Clarke-Pearson DL, Synan IS, Dodge R, et al. A randomized trial of low-dose heparin and intermittent pneumatic calf compression for the prevention of deep venous thrombosis after gynecologic oncology surgery. Am J Obstet Gynecol 1993; 168:1146–1154.
  43. Einstein MH, Pritts EA, Hartenbach EM. Venous thromboembolism prevention in gynecologic cancer surgery: a systematic review. Gynecol Oncol 2007; 105:813–819.
  44. Clarke-Pearson DL, Synan IS, Hinshaw WM, Coleman RE, Creasman WT. Prevention of postoperative venous thromboembolism by external pneumatic calf compression in patients with gynecologic malignancy. Obstet Gynecol 1984; 63:92–98.
  45. Ruff RL, Posner JB. Incidence and treatment of peripheral venous thrombosis in patients with glioma. Ann Neurol 1983; 13:334–336.
  46. Levin JM, Schiff D, Loeffler JS, Fine HA, Black PM, Wen PY. Complications of therapy for venous thromboembolic disease in patients with brain tumors. Neurology 1993; 43:1111–1114.
Article PDF
Author and Disclosure Information

Alex C. Spyropoulos, MD
Chair, Clinical Thrombosis Center, Lovelace Medical Center; Clinical Associate Professor of Medicine/Associate Professor of Pharmacy, University of New Mexico Health Sciences Center/College of Pharmacy, Albuquerque, NM

Daniel J. Brotman, MD
Director, Hospitalist Program; Associate Professor of Medicine, Johns Hopkins Hospital, Baltimore, MD

Alpesh N. Amin, MD, MBA
Professor and Chief, Division of General Internal Medicine; Executive Director, Hospitalist Program; Vice Chair for Clinical Affairs & Quality, Department of Medicine, University of California, Irvine, Irvine, CA

Steven B. Deitelzweig, MD
Vice President of Medical Affairs; Chairman, Department of Hospital Medicine, Ochsner Health System, New Orleans, LA

Amir K. Jaffer, MD
Associate Professor of Medicine; Chief, Division of Hospital Medicine, Department of Medicine, Leonard M. Miller School of Medicine, University of Miami, Miami, FL

Sylvia C. McKean, MD
Medical Director, BWH/Faulkner Hospitalist Service; Associate Professor of Medicine, Harvard Medical School and Brigham and Women’s Hospital, Boston, MA

Correspondence: Alex C. Spyropoulos, MD, Chair, Clinical Thrombosis Center, Lovelace Medical Center, 500 Walter Street NE, Suite 301, Albuquerque, NM 87108; [email protected]

Dr. Spyropoulos reported that he has received consulting fees from Sanofi-Aventis, Eisai, and Boehringer Ingelheim.

Dr. Brotman reported that he has no financial relationships with commercial interests that are relevant to this article.

Dr. Amin reported that he has received research funding and honoraria for speaking from Sanofi-Aventis, Eisai, and GlaxoSmithKline.

Drs. Deitelzweig and McKean each reported that they have received honoraria for teaching/speaking from Sanofi-Aventis.

Dr. Jaffer reported that he has received consulting fees and honoraria for teaching/speaking from Sanofi-Aventis, consulting fees and research grant support from AstraZeneca, and consulting fees from Roche Diagnostics and Boehringer Ingelheim; he also serves on the governing board of the Society for Perioperative Assessment and Quality Improvement (SPAQI) and the board of directors of the Anticoagulation Forum.

Each author received an honorarium for participating in the roundtable that formed the basis of this supplement. The honoraria were paid by the Cleveland Clinic Center for Continuing Education from the educational grant from Sanofi-Aventis underwriting this supplement. Sanofi-Aventis had no input on the content of the roundtable or this supplement.

Publications
Page Number
S17-S26
Author and Disclosure Information

Alex C. Spyropoulos, MD
Chair, Clinical Thrombosis Center, Lovelace Medical Center; Clinical Associate Professor of Medicine/Associate Professor of Pharmacy, University of New Mexico Health Sciences Center/College of Pharmacy, Albuquerque, NM

Daniel J. Brotman, MD
Director, Hospitalist Program; Associate Professor of Medicine, Johns Hopkins Hospital, Baltimore, MD

Alpesh N. Amin, MD, MBA
Professor and Chief, Division of General Internal Medicine; Executive Director, Hospitalist Program; Vice Chair for Clinical Affairs & Quality, Department of Medicine, University of California, Irvine, Irvine, CA

Steven B. Deitelzweig, MD
Vice President of Medical Affairs; Chairman, Department of Hospital Medicine, Ochsner Health System, New Orleans, LA

Amir K. Jaffer, MD
Associate Professor of Medicine; Chief, Division of Hospital Medicine, Department of Medicine, Leonard M. Miller School of Medicine, University of Miami, Miami, FL

Sylvia C. McKean, MD
Medical Director, BWH/Faulkner Hospitalist Service; Associate Professor of Medicine, Harvard Medical School and Brigham and Women’s Hospital, Boston, MA

Correspondence: Alex C. Spyropoulos, MD, Chair, Clinical Thrombosis Center, Lovelace Medical Center, 500 Walter Street NE, Suite 301, Albuquerque, NM 87108; [email protected]

Dr. Spyropoulos reported that he has received consulting fees from Sanofi-Aventis, Eisai, and Boehringer Ingelheim.

Dr. Brotman reported that he has no financial relationships with commercial interests that are relevant to this article.

Dr. Amin reported that he has received research funding and honoraria for speaking from Sanofi-Aventis, Eisai, and GlaxoSmithKline.

Drs. Deitelzweig and McKean each reported that they have received honoraria for teaching/speaking from Sanofi-Aventis.

Dr. Jaffer reported that he has received consulting fees and honoraria for teaching/speaking from Sanofi-Aventis, consulting fees and research grant support from AstraZeneca, and consulting fees from Roche Diagnostics and Boehringer Ingelheim; he also serves on the governing board of the Society for Perioperative Assessment and Quality Improvement (SPAQI) and the board of directors of the Anticoagulation Forum.

Each author received an honorarium for participating in the roundtable that formed the basis of this supplement. The honoraria were paid by the Cleveland Clinic Center for Continuing Education from the educational grant from Sanofi-Aventis underwriting this supplement. Sanofi-Aventis had no input on the content of the roundtable or this supplement.

Author and Disclosure Information

Alex C. Spyropoulos, MD
Chair, Clinical Thrombosis Center, Lovelace Medical Center; Clinical Associate Professor of Medicine/Associate Professor of Pharmacy, University of New Mexico Health Sciences Center/College of Pharmacy, Albuquerque, NM

Daniel J. Brotman, MD
Director, Hospitalist Program; Associate Professor of Medicine, Johns Hopkins Hospital, Baltimore, MD

Alpesh N. Amin, MD, MBA
Professor and Chief, Division of General Internal Medicine; Executive Director, Hospitalist Program; Vice Chair for Clinical Affairs & Quality, Department of Medicine, University of California, Irvine, Irvine, CA

Steven B. Deitelzweig, MD
Vice President of Medical Affairs; Chairman, Department of Hospital Medicine, Ochsner Health System, New Orleans, LA

Amir K. Jaffer, MD
Associate Professor of Medicine; Chief, Division of Hospital Medicine, Department of Medicine, Leonard M. Miller School of Medicine, University of Miami, Miami, FL

Sylvia C. McKean, MD
Medical Director, BWH/Faulkner Hospitalist Service; Associate Professor of Medicine, Harvard Medical School and Brigham and Women’s Hospital, Boston, MA

Correspondence: Alex C. Spyropoulos, MD, Chair, Clinical Thrombosis Center, Lovelace Medical Center, 500 Walter Street NE, Suite 301, Albuquerque, NM 87108; [email protected]

Dr. Spyropoulos reported that he has received consulting fees from Sanofi-Aventis, Eisai, and Boehringer Ingelheim.

Dr. Brotman reported that he has no financial relationships with commercial interests that are relevant to this article.

Dr. Amin reported that he has received research funding and honoraria for speaking from Sanofi-Aventis, Eisai, and GlaxoSmithKline.

Drs. Deitelzweig and McKean each reported that they have received honoraria for teaching/speaking from Sanofi-Aventis.

Dr. Jaffer reported that he has received consulting fees and honoraria for teaching/speaking from Sanofi-Aventis, consulting fees and research grant support from AstraZeneca, and consulting fees from Roche Diagnostics and Boehringer Ingelheim; he also serves on the governing board of the Society for Perioperative Assessment and Quality Improvement (SPAQI) and the board of directors of the Anticoagulation Forum.

Each author received an honorarium for participating in the roundtable that formed the basis of this supplement. The honoraria were paid by the Cleveland Clinic Center for Continuing Education from the educational grant from Sanofi-Aventis underwriting this supplement. Sanofi-Aventis had no input on the content of the roundtable or this supplement.

Article PDF
Article PDF
Related Articles

Venous thromboembolism (VTE) is a major complication of cancer, occurring in 4% to 20% of patients,1 and is one of the leading causes of death in cancer patients, although these figures are believed to be underestimates, given the low autopsy rates among cancer patients.2 In hospitalized cancer patients specifically, VTE is the second leading cause of death.3,4 The risk of VTE in cancer patients undergoing surgery is three to five times greater than that in surgical patients without cancer.4 Moreover, cancer patients with symptomatic deep vein thrombosis (DVT) exhibit a high risk of recurrent VTE that may persist for many years after the index event.5

VTE PREVENTION POSES PARTICULAR CHALLENGES IN CANCER PATIENTS

Until recently, data on VTE prevention specific to cancer patients have been sparse. Cancer patients have represented only a small subset (< 20%) of participants in most of the largest clinical trials of VTE prophylaxis. Until the past 2 or 3 years, clinicians largely have had to extrapolate their approach to VTE prophylaxis in cancer patients from data in patients without cancer, bearing in mind that cancer patients are among the populations at highest risk of developing VTE.

High rates of VTE, even with prophylaxis

What has been clear is that VTE prevention is a formidable challenge in this population, even when thromboprophylaxis is used. Despite thromboprophylaxis, cancer patients undergoing surgery have twice the risk of VTE and nonfatal pulmonary embolism (PE) and three times the risk of fatal PE compared with other surgical patients (Table 1).6,7

Further insights have come from the @RISTOS project, a Web-based prospective registry of patients undergoing general, urologic, or gynecologic surgery for cancer at multiple centers in Italy.8 Of the 2,372 patients tracked in this study, 82% received in-hospital VTE prophylaxis and 31% received prophylaxis following discharge. Despite this relatively high frequency of prophylaxis, however, the incidence of clinically overt VTE was 2.1% and the incidence of fatal VTE was 0.8%. Notably, most VTE events occurred after hospital discharge, and VTE was the most common cause of 30-day postoperative death in this registry.

RISK FACTORS: CANCER TYPE AND TREATMENT LOOM LARGE

Both the type and stage of a patient’s cancer are important in assessing the risk of VTE. For men, cancers of the prostate, colon, brain, and lung have been associated with an increased risk of VTE. Among women, cancers of the breast, ovary, and lung have been especially implicated as risk factors for VTE.9,10

The type of cancer therapy also influences VTE risk:

  • Surgery. Among patients who undergo cancer-related surgery, the rate of proximal DVT is 10% to 20%, the rate of clinically evident PE is 4% to 10%, and the incidence of fatal PE is 0.2% to 5%.8,11
  • Systemic treatments, including chemotherapy and hormone therapy, are also associated with an increased risk of VTE.12–15
  • Central venous catheters. Approximately 4% of cancer patients who have central venous catheters placed develop clinically relevant VTE.16,17

In addition to the above risks related to cancer treatments, the following have been identified as risk factors for VTE in surgical oncology patients:

  • Age greater than 40 years (risk also increases steeply after age 60 and again after age 75)
  • Cancer procoagulants
  • Thrombophilia
  • Length and complications of cancer surgery (ie, often involving tissue trauma and immobilization)
  • Debilitation and slow recovery.

Another risk factor worth noting is perioperative transfusion, as illustrated in a recent study of 14,104 adults undergoing colorectal cancer resection.18 The overall incidence of VTE in these patients was 1.0%, and the risk of death was nearly four times as great in patients who developed VTE as in those who did not. Notably, the need for transfusion was a marker of increased risk of VTE, particularly in women: women who received perioperative transfusions had almost double the risk of developing VTE compared with women who did not receive transfusions (P = .004).

CLINICAL TRIALS OF PROPHYLAXIS IN CANCER SURGERY PATIENTS

LMWH vs UFH for in-hospital prophylaxis

Two large randomized, double-blind trials have compared low-molecular-weight heparin (LMWH) with low-dose unfractionated heparin (UFH) for VTE prophylaxis in surgical patients with cancer—the Enoxaparin and Cancer (ENOXACAN) study19 and the Canadian Colorectal Surgery DVT Prophylaxis Trial.20 Patients in these studies underwent surgery for abdominal or pelvic cancer (mostly colorectal cancer). Both studies compared 40 mg of the LMWH enoxaparin given once daily with 5,000 U of UFH given three times daily for 7 to 10 days postoperatively. Outcome measures were the presence of DVT determined by venography on day 7 to 10 and the incidence of symptomatic VTE. Rates of VTE were statistically equivalent between the two treatment arms in both ENOXACAN (14.7% with LMWH vs 18.2% with UFH) and the Canadian Colorectal Surgery study (9.4% with both therapies), as were rates of major bleeding (4.1% with LMWH vs 2.9% with UFH in ENOXACAN; 2.7% with LMWH vs 1.5% with UFH in the Canadian study).

These findings are consistent with a 2001 meta-analysis by Mismetti et al of all available randomized trials comparing LMWH with placebo or with UFH for VTE prophylaxis in general surgery.21 This analysis found no differences in rates of asymptomatic DVT, clinical PE, clinical thromboembolism, death, major hemorrhage, total hemorrhage, wound hematoma, or need for transfusion between LMWH and UFH in patients undergoing either cancer-related surgery or surgery not related to cancer.

Fondaparinux for in-hospital prophylaxis

Subgroup analysis of the large randomized trial known as PEGASUS22 sheds some light on the efficacy of the factor Xa inhibitor fondaparinux relative to LMWH for thromboprophylaxis in cancer surgery patients. PEGASUS compared fondaparinux 2.5 mg once daily with the LMWH dalteparin 5,000 IU once daily for 5 to 9 days in patients undergoing high-risk abdominal surgery. Among the study’s 1,408 patients undergoing surgery for cancer, rates of VTE were 4.7% in the fondaparinux group compared with 7.7% in the LMWH group, a relative risk reduction of 38.6% with fondaparinux (95% CI, 6.7% to 59.6%). In contrast, in the rest of the PEGASUS population (patients undergoing abdominal surgery for reasons other than cancer), LMWH was nonsignificantly more efficacious at preventing VTE than was fondaparinux. Rates of major bleeding in this cancer subgroup were comparable between the two treatments.

 

 

Extended prophylaxis

Two additional randomized trials have evaluated extended prophylaxis with LMWH in surgical cancer patients—ENOXACAN II23 and the Fragmin After Major Abdominal Surgery (FAME) study.24

In ENOXACAN II, patients undergoing surgery for abdominal or pelvic cancer first received 6 to 10 days of prophylaxis with enoxaparin 40 mg once daily and then were randomized in a double-blind fashion to an additional 21 days of enoxaparin or placebo.23 Among 332 patients in the intent-to-treat analysis, the rate of VTE at the end of the double-blind phase was reduced from 12.0% with placebo to 4.8% with extended-duration enoxaparin (P = .02), an effect that was maintained at 3-month follow-up (P = .01). There was no significant difference between the two groups in rates of major bleeding events or any bleeding events.

In FAME, patients received 5,000 IU of dalteparin once daily for 1 week following major abdominal surgery and then were randomized in open-label fashion to either placebo or extended prophylaxis with dalteparin for 3 more weeks; a subanalysis examined outcomes in the 198 FAME participants whose abdominal surgery was for cancer.24 Among these 198 cancer surgery patients, the rate of venography-documented VTE at 4 weeks was reduced from 19.6% with placebo to 8.8% with extended-duration dalteparin, a relative reduction of 55% (P = .03). The rate of proximal DVT was reduced from 10.4% to 2.2% with extended prophylaxis, a relative reduction of 79% (P = .02).

The number needed to treat with extended LMWH prophylaxis to prevent one VTE event was 14 in ENOXACAN II23 and 9 in the FAME subanalysis of cancer surgery patients.24

New systematic review of relevant trials

Leonardi et al recently published a systematic review of 26 randomized controlled trials of DVT prophylaxis in 7,639 cancer surgery patients.25 They found the overall incidence of DVT to be 12.7% in those who received pharmacologic prophylaxis compared with 35.2% in controls. They also found high-dose LMWH therapy (> 3,400 U daily) to be associated with a significantly lower incidence of DVT than low-dose LMWH therapy (≤ 3,400 U daily) (7.9% vs 14.5%, respectively; P < .01). No differences were demonstrated between LMWH and UFH in preventing DVT, DVT location, or bleeding. Bleeding complications requiring discontinuation of pharmacologic prophylaxis occurred in 3% of patients overall.

Implications of HIT

The sequelae of heparin-induced thrombocytopenia (HIT) can have major consequences for cancer surgery patients. The incidence of HIT is markedly lower with LMWH than with UFH, as demonstrated in a nested case-control study by Creekmore et al.26 These researchers also found that the average cost of an admission during which HIT developed was nearly four times as great as the average cost of an admission during which UFH or LMWH was given without development of HIT ($56,364 vs $15,231; P < .001).

EVIDENCE IN SPECIFIC ONCOLOGIC POPULATIONS

Most of the patients in the trials reviewed above underwent abdominal surgery for malignancy. Although studies of VTE prophylaxis in patients undergoing nonabdominal cancer surgery are relatively few, some data are available for a few other specific oncologic populations, as reviewed below.

Surgery for gynecologic cancer

There is a paucity of randomized controlled trials or prospective observational studies on VTE and its prevention in the gynecologic cancer surgery population. Based on small historical studies, the postoperative risk of VTE in this population varies from 12% to 35%.27,28 Twice-daily administration of UFH 5,000 U appears to be ineffective as VTE prophylaxis in this population, but increasing the frequency to three times daily reduces VTE risk by 50% to 60% compared with placebo. Once-daily LMWH is comparable to three-times-daily UFH in efficacy and safety in this population.

A systematic Cochrane review of eight randomized controlled trials in patients undergoing major gynecologic surgery revealed that heparin prophylaxis (either UFH or LMWH) reduces the risk of DVT by 70% compared with no prophylaxis, with an identical risk reduction specifically among women with malignancy (odds ratio, 0.30; 95% CI, 0.10 to 0.89).29 This review found no evidence that anticoagulation reduces the risk of PE following major gynecologic surgery. LMWH and UFH were similar in efficacy for preventing DVT and had a comparable risk of bleeding complications.

Surgery for urologic cancer

The risk of VTE and the benefits of thromboprophylaxis also are poorly studied in patients undergoing surgery for urologic cancer.

The risk of VTE varies with the type of urologic surgery and the method used to diagnose VTE. For instance, patients undergoing radical retropubic prostatectomy have been reported to develop DVT at rates of 1% to 3%, PE at rates of 1% to 3%, and fatal PE at a rate of 0.6%, whereas the incidences of these events are somewhat higher in patients undergoing cystectomy: 8% for DVT, 2% to 4% for PE, and 2% for fatal PE. Radiologic diagnosis of thromboembolism in pelvic surgery patients has yielded higher incidences, with DVT rates of 21% to 51% and PE rates of 11% to 22%.30

Small studies suggest that prophylaxis with either low-dose UFH or LMWH is both effective in reducing VTE risk and safe in urologic cancer surgery patients, although pharmacologic prophylaxis poses a possible increased risk of pelvic hematoma and lymphocele formation in this population.30

Neurosurgery

Most neurosurgical procedures are performed for malignancies. The risk of venography-confirmed VTE in patients undergoing neurosurgery is approximately 30% to 40%.31,32 Likewise, the risks of intracranial or intraspinal hemorrhage in these patients are high. For this reason, mechanical methods of VTE prophylaxis are preferred in these patients. The use of anticoagulant prophylaxis remains controversial in this setting, although more recent data suggest that it might be safer than previously recognized.

A meta-analysis of studies of pharmacologic prophylaxis of VTE in neurosurgery included three randomized controlled trials that compared LMWH, with or without mechanical prophylaxis, to placebo plus mechanical prophylaxis or placebo alone in a total of 922 neurosurgery patients.33 As detailed in Table 2, the analysis demonstrated statistically significant reductions in the risks of VTE and proximal DVT in favor of LMWH, with a statistically significant doubling in the risk of any bleeding and a nonsignificant 70% increase in the risk of major bleeding with LMWH therapy. The number needed to treat to prevent 1 proximal DVT was 16, while the number needed to treat to cause 1 major bleeding event was 115. A risk-benefit analysis showed that the use of LMWH in neurosurgery patients was associated with 1 major nonfatal bleeding event for every 7 proximal DVTs prevented. When a fourth randomized trial was included in the analysis, comparing UFH 5,000 U three times daily with no prophylaxis, rates of VTE and bleeding events remained similar to those for the LMWH trials alone.

 

 

GUIDELINES FOR VTE PROPHYLAXIS IN THE CANCER SURGERY PATIENT

American College of Chest Physicians

The American College of Chest Physicians’ Seventh ACCP Conference on Antithrombotic and Thrombolytic Therapy makes a number of recommendations regarding VTE prevention in patients undergoing surgery for cancer, as outlined in Table 3.34

National Comprehensive Cancer Network

The National Comprehensive Cancer Network (NCCN) recently published clinical practice guidelines on venous thromboembolic disease in cancer patients.35 The defined at-risk population for these guidelines is the adult cancer inpatient with a diagnosis of (or clinical suspicion for) cancer. The guidelines recommend prophylactic anticoagulation (category 1 recommendation) with or without a sequential compression device as initial prophylaxis, unless the patient has a relative contraindication to anticoagulation, in which case mechanical prophylaxis (sequential compression device or graduated compression stockings) is recommended. (A category 1 recommendation indicates “uniform NCCN consensus, based on high-level evidence.”)

The NCCN guidelines include a specific recommended risk-factor assessment, which includes noting the patient’s age (VTE risk increases beginning at age 40 and then steeply again at age 75), any prior VTE, the presence of familial thrombophilia or active cancer, the use of medications associated with increased VTE risk (chemotherapy, exogenous estrogen compounds, and thalidomide or lenalidomide), and a number of other risk factors for VTE as outlined in the prior two articles in this supplement. The NCCN guidelines explicitly call for assessment of modifiable risk factors for VTE (ie, smoking or other tobacco use, obesity, and a low level of activity or lack of exercise) and call for active patient education on these factors.

American Society of Clinical Oncology

The American Society of Clinical Oncology (ASCO) recently released guidelines on VTE prevention and treatment in patients with cancer;1 their key recommendations for prevention are summarized in Table 4. Notable differences from the recommendations of the Seventh ACCP Conference are the ASCO guidelines’ inclusion of fondaparinux among recommended prophylactic options for this population and more explicit recommendations on the prophylactic use of LMWH. Also, for treatment of cancer patients with established VTE, ASCO specifies that LMWH is the preferred anticoagulant for both initial and continuing treatment.

Our recommended algorithm

Figure 1. Algorithm for VTE prophylaxis in the patient undergoing major surgery for cancer.
Drawing from the above formal society guidelines and the published literature, we recommend the algorithm in Figure 1 as a practical approach to VTE prevention in patients undergoing major surgery for cancer.

LINGERING CHALLENGE OF UNDERUTILIZATION

Despite this consensus on ways to reduce thromboembolic risk in this population and the clear evidence of the benefit of VTE prophylaxis in patients with cancer, data from several registries confirm a persistently low utilization of prophylaxis in patients with cancer.36–38 The global Fundamental Research in Oncology and Thrombosis (FRONTLINE) study surveyed 3,891 clinicians who treat cancer patients regarding their practices with respect to VTE in those patients.36 The survey found that only 52% of respondents routinely used thromboprophylaxis for their surgical patients with cancer. More striking, however, was the finding that most respondents routinely considered thrombo-prophylaxis in only 5% of their medical oncology patients. These data are echoed by findings of other retrospective medical record reviews in patients undergoing major abdominal or abdominothoracic surgery (in many cases for cancer), with VTE prophylaxis rates ranging from 38% to 75%.37,38

SUMMARY

Patients undergoing surgery for cancer have an increased risk of VTE and fatal PE, even when throm­boprophylaxis is used. Nevertheless, prophylaxis with either LMWH or UFH does reduce venographic VTE event rates in these patients. If UFH is chosen for prophylaxis, a three-times-daily regimen should be used in this population. In specific surgical cancer populations, especially those undergoing abdominal surgery, out-of-hospital prophylaxis with once-daily LMWH is warranted. Current registries reveal that compliance with established guidelines for VTE prophylaxis in this population is low.

 

 

DISCUSSION: ADDITIONAL PERSPECTIVES FROM THE AUTHORS

Dr. Jaffer: Dr. Amin, based on your study on thrombo-prophylaxis rates in US medical centers, will you comment on rates of prophylaxis for cancer surgery patients?

Dr. Amin: The overall study included approximately 200,000 medical patients and about 80,000 surgical patients enrolled over more than a 3-year period between 2002 and 2005.39,40 Our goal was to assess rates of prophylaxis and, when it was provided, whether it was appropriate (in terms of type, dosage, and duration) based on the ACCP guidelines. A subanalysis assessed medical cancer patients and surgical cancer patients separately. Medical cancer patients received thromboprophylaxis 56% of the time but received appropriate prophylaxis only 28% of the time. Among surgical cancer patients, appropriate prophylaxis was given only about 24% of the time for those undergoing gynecologic surgery and about 12% of the time for those undergoing neurosurgery. These percentages are consistent with data from other national registries, such as the IMPROVE registry, which documented prophylaxis rates on the order of 45% in medical patients with cancer.41 We also analyzed the data according to individual practitioners and found that medical oncologists use prophylaxis about 25% of the time, which is relatively consistent with other providers, such as internists and surgeons.

So there is a huge opportunity to improve rates of prophylaxis for this group of patients that national guidelines say are at high risk. Why is prophylaxis so underutilized in the cancer population? One factor may be a misperception about the risk of bleeding with anticoagulants. Yet several studies have shown that the rate of bleeding from prophylaxis is extremely low, whether LMWH or UFH is used, so more awareness of actual bleeding risk is needed. Another factor is the obvious focus among internists and oncologists on treating the patient, with perhaps a reduced consideration of prophylaxis and prevention. A third factor may be a concern about thrombocytopenia. However, in our study of prophylaxis rates in US medical centers, we excluded patients who had thrombocytopenia, yet rates of prophylaxis were still low. Nothing in the literature indicates that anticoagulants cannot be used in patients with platelet counts of 50,000 to 150,000 cells/µL or higher, so this suggests that we need to do more education.

Dr. Jaffer: Dr. Brotman, can you tell us more about how clinicians in practice should use prophylaxis in their neurosurgery patients, such as those undergoing craniotomy or spine surgery for cancer? What is the safest and most efficacious way to prevent DVT in these patients?

Dr. Brotman: First, it’s important to recognize that some sort of prophylaxis needs to be used. Neurosurgery patients are at an extremely high risk for thromboembolic events, and such events are often fatal in these patients. Having said that, the jury is still out on whether the prophylaxis in these patients should be compression devices or anticoagulation. This gives physicians some latitude in their decisions. They can decide not to use pharmacologic prophylaxis so long as they use pneumatic compression devices consistently, perhaps even starting during the operation and certainly throughout hospitalization when the patient is immobilized.

Certainly, the concerns about using full-dose anticoagulation in the immediate postoperative setting in neurosurgery patients are valid. Yet these patients are at very high risk for thromboembolic events, and if we take too cautious an approach to prophylaxis in the immediate perioperative setting, more patients are going to have thromboembolic events, at which point management decisions become much more difficult. The risk of intracranial bleeding with anticoagulation to treat a patient who develops a DVT at postoperative day 10 will certainly be higher than it would have been with lower-dose perioperative prophylactic anticoagulation. Plus, if you put in a filter at that point, the outcomes tend to be poor. Therefore, I believe there is some degree of risk that we should be willing to take with regard to perioperative bleeding, even in neurosurgery patients.

Dr. McKean: I’d like to make a point about combination prophylaxis. At many institutions, compression stockings and sequential compression devices are used preoperatively and intraoperatively, and then pharmacologic prophylaxis—for example, twice-daily UFH—is used postoperatively. There is concern that these patients are hypercoagulable, and most clinicians believe that mechanical prophylaxis alone, even with sequential compression devices plus compression stockings, is not aggressive enough in these high-risk patients.

Dr. Jaffer: Dr. Spyropoulos, what is the optimal duration of pharmacologic prophylaxis for cancer surgery patients?

Dr. Spyropoulos: First let’s consider in-hospital prophylaxis. The supportive data for in-hospital prophylaxis are strong, and the duration of therapy used in the major in-hospital prophylaxis trials was 7 to 10 days. With regard to extended prophylaxis, we have at least two moderately sized randomized controlled trials, ENOXACAN II23 and the substudy of FAME,24 that demonstrated that extending prophylaxis with LMWH at doses of 3,400 U once daily (5,000 IU of dalteparin; 40 mg of enoxaparin) reduces VTE risk at postoperative day 30. Also, recent data from the @RISTOS registry show that in cancer surgery patients, especially those having abdominal or pelvic procedures, the leading cause of 30-day mortality was VTE.8 This registry also shows that despite prophylaxis, the rate of symptomatic VTE can be as high as 2%, with the rate of fatal VTE approaching 1%. Thus, in cancer patients undergoing abdominal or pelvic surgery, physicians should strongly consider prophylaxis of up to 30 days’ duration.

Dr. Jaffer: One striking finding from the @RISTOS registry was that 40% of VTE events in these cancer surgery patients occurred after postoperative day 21. This really underscores the need to consider prophylaxis for at least 4 weeks in these patients in real-world practice.

Dr. Brotman: The other striking finding from that registry was that the in-hospital prophylaxis rate was quite high, about 80%, and the rate of extended prophylaxis approached 35%. These are rates that are rarely achieved in clinical practice. Yet despite these high levels of prophylaxis, patients in this registry still had a high incidence of morbidity and mortality from VTE. This suggests that we need to improve our out-of-hospital VTE prevention paradigms.

Dr. Jaffer: Dr. Deitelzweig, oncologists and internists are often unsure about whether their ambulatory cancer patients who are receiving chemotherapy should be on any form of prophylaxis. What is your opinion?

Dr. Deitelzweig: That question comes up regularly because these patients are encountered across many medical specialties. At this point, all of the large organizations, including ASCO and NCCN, are advocating that prophylaxis is not indicated for such patients.

Venous thromboembolism (VTE) is a major complication of cancer, occurring in 4% to 20% of patients,1 and is one of the leading causes of death in cancer patients, although these figures are believed to be underestimates, given the low autopsy rates among cancer patients.2 In hospitalized cancer patients specifically, VTE is the second leading cause of death.3,4 The risk of VTE in cancer patients undergoing surgery is three to five times greater than that in surgical patients without cancer.4 Moreover, cancer patients with symptomatic deep vein thrombosis (DVT) exhibit a high risk of recurrent VTE that may persist for many years after the index event.5

VTE PREVENTION POSES PARTICULAR CHALLENGES IN CANCER PATIENTS

Until recently, data on VTE prevention specific to cancer patients have been sparse. Cancer patients have represented only a small subset (< 20%) of participants in most of the largest clinical trials of VTE prophylaxis. Until the past 2 or 3 years, clinicians largely have had to extrapolate their approach to VTE prophylaxis in cancer patients from data in patients without cancer, bearing in mind that cancer patients are among the populations at highest risk of developing VTE.

High rates of VTE, even with prophylaxis

What has been clear is that VTE prevention is a formidable challenge in this population, even when thromboprophylaxis is used. Despite thromboprophylaxis, cancer patients undergoing surgery have twice the risk of VTE and nonfatal pulmonary embolism (PE) and three times the risk of fatal PE compared with other surgical patients (Table 1).6,7

Further insights have come from the @RISTOS project, a Web-based prospective registry of patients undergoing general, urologic, or gynecologic surgery for cancer at multiple centers in Italy.8 Of the 2,372 patients tracked in this study, 82% received in-hospital VTE prophylaxis and 31% received prophylaxis following discharge. Despite this relatively high frequency of prophylaxis, however, the incidence of clinically overt VTE was 2.1% and the incidence of fatal VTE was 0.8%. Notably, most VTE events occurred after hospital discharge, and VTE was the most common cause of 30-day postoperative death in this registry.

RISK FACTORS: CANCER TYPE AND TREATMENT LOOM LARGE

Both the type and stage of a patient’s cancer are important in assessing the risk of VTE. For men, cancers of the prostate, colon, brain, and lung have been associated with an increased risk of VTE. Among women, cancers of the breast, ovary, and lung have been especially implicated as risk factors for VTE.9,10

The type of cancer therapy also influences VTE risk:

  • Surgery. Among patients who undergo cancer-related surgery, the rate of proximal DVT is 10% to 20%, the rate of clinically evident PE is 4% to 10%, and the incidence of fatal PE is 0.2% to 5%.8,11
  • Systemic treatments, including chemotherapy and hormone therapy, are also associated with an increased risk of VTE.12–15
  • Central venous catheters. Approximately 4% of cancer patients who have central venous catheters placed develop clinically relevant VTE.16,17

In addition to the above risks related to cancer treatments, the following have been identified as risk factors for VTE in surgical oncology patients:

  • Age greater than 40 years (risk also increases steeply after age 60 and again after age 75)
  • Cancer procoagulants
  • Thrombophilia
  • Length and complications of cancer surgery (ie, often involving tissue trauma and immobilization)
  • Debilitation and slow recovery.

Another risk factor worth noting is perioperative transfusion, as illustrated in a recent study of 14,104 adults undergoing colorectal cancer resection.18 The overall incidence of VTE in these patients was 1.0%, and the risk of death was nearly four times as great in patients who developed VTE as in those who did not. Notably, the need for transfusion was a marker of increased risk of VTE, particularly in women: women who received perioperative transfusions had almost double the risk of developing VTE compared with women who did not receive transfusions (P = .004).

CLINICAL TRIALS OF PROPHYLAXIS IN CANCER SURGERY PATIENTS

LMWH vs UFH for in-hospital prophylaxis

Two large randomized, double-blind trials have compared low-molecular-weight heparin (LMWH) with low-dose unfractionated heparin (UFH) for VTE prophylaxis in surgical patients with cancer—the Enoxaparin and Cancer (ENOXACAN) study19 and the Canadian Colorectal Surgery DVT Prophylaxis Trial.20 Patients in these studies underwent surgery for abdominal or pelvic cancer (mostly colorectal cancer). Both studies compared 40 mg of the LMWH enoxaparin given once daily with 5,000 U of UFH given three times daily for 7 to 10 days postoperatively. Outcome measures were the presence of DVT determined by venography on day 7 to 10 and the incidence of symptomatic VTE. Rates of VTE were statistically equivalent between the two treatment arms in both ENOXACAN (14.7% with LMWH vs 18.2% with UFH) and the Canadian Colorectal Surgery study (9.4% with both therapies), as were rates of major bleeding (4.1% with LMWH vs 2.9% with UFH in ENOXACAN; 2.7% with LMWH vs 1.5% with UFH in the Canadian study).

These findings are consistent with a 2001 meta-analysis by Mismetti et al of all available randomized trials comparing LMWH with placebo or with UFH for VTE prophylaxis in general surgery.21 This analysis found no differences in rates of asymptomatic DVT, clinical PE, clinical thromboembolism, death, major hemorrhage, total hemorrhage, wound hematoma, or need for transfusion between LMWH and UFH in patients undergoing either cancer-related surgery or surgery not related to cancer.

Fondaparinux for in-hospital prophylaxis

Subgroup analysis of the large randomized trial known as PEGASUS22 sheds some light on the efficacy of the factor Xa inhibitor fondaparinux relative to LMWH for thromboprophylaxis in cancer surgery patients. PEGASUS compared fondaparinux 2.5 mg once daily with the LMWH dalteparin 5,000 IU once daily for 5 to 9 days in patients undergoing high-risk abdominal surgery. Among the study’s 1,408 patients undergoing surgery for cancer, rates of VTE were 4.7% in the fondaparinux group compared with 7.7% in the LMWH group, a relative risk reduction of 38.6% with fondaparinux (95% CI, 6.7% to 59.6%). In contrast, in the rest of the PEGASUS population (patients undergoing abdominal surgery for reasons other than cancer), LMWH was nonsignificantly more efficacious at preventing VTE than was fondaparinux. Rates of major bleeding in this cancer subgroup were comparable between the two treatments.

 

 

Extended prophylaxis

Two additional randomized trials have evaluated extended prophylaxis with LMWH in surgical cancer patients—ENOXACAN II23 and the Fragmin After Major Abdominal Surgery (FAME) study.24

In ENOXACAN II, patients undergoing surgery for abdominal or pelvic cancer first received 6 to 10 days of prophylaxis with enoxaparin 40 mg once daily and then were randomized in a double-blind fashion to an additional 21 days of enoxaparin or placebo.23 Among 332 patients in the intent-to-treat analysis, the rate of VTE at the end of the double-blind phase was reduced from 12.0% with placebo to 4.8% with extended-duration enoxaparin (P = .02), an effect that was maintained at 3-month follow-up (P = .01). There was no significant difference between the two groups in rates of major bleeding events or any bleeding events.

In FAME, patients received 5,000 IU of dalteparin once daily for 1 week following major abdominal surgery and then were randomized in open-label fashion to either placebo or extended prophylaxis with dalteparin for 3 more weeks; a subanalysis examined outcomes in the 198 FAME participants whose abdominal surgery was for cancer.24 Among these 198 cancer surgery patients, the rate of venography-documented VTE at 4 weeks was reduced from 19.6% with placebo to 8.8% with extended-duration dalteparin, a relative reduction of 55% (P = .03). The rate of proximal DVT was reduced from 10.4% to 2.2% with extended prophylaxis, a relative reduction of 79% (P = .02).

The number needed to treat with extended LMWH prophylaxis to prevent one VTE event was 14 in ENOXACAN II23 and 9 in the FAME subanalysis of cancer surgery patients.24

New systematic review of relevant trials

Leonardi et al recently published a systematic review of 26 randomized controlled trials of DVT prophylaxis in 7,639 cancer surgery patients.25 They found the overall incidence of DVT to be 12.7% in those who received pharmacologic prophylaxis compared with 35.2% in controls. They also found high-dose LMWH therapy (> 3,400 U daily) to be associated with a significantly lower incidence of DVT than low-dose LMWH therapy (≤ 3,400 U daily) (7.9% vs 14.5%, respectively; P < .01). No differences were demonstrated between LMWH and UFH in preventing DVT, DVT location, or bleeding. Bleeding complications requiring discontinuation of pharmacologic prophylaxis occurred in 3% of patients overall.

Implications of HIT

The sequelae of heparin-induced thrombocytopenia (HIT) can have major consequences for cancer surgery patients. The incidence of HIT is markedly lower with LMWH than with UFH, as demonstrated in a nested case-control study by Creekmore et al.26 These researchers also found that the average cost of an admission during which HIT developed was nearly four times as great as the average cost of an admission during which UFH or LMWH was given without development of HIT ($56,364 vs $15,231; P < .001).

EVIDENCE IN SPECIFIC ONCOLOGIC POPULATIONS

Most of the patients in the trials reviewed above underwent abdominal surgery for malignancy. Although studies of VTE prophylaxis in patients undergoing nonabdominal cancer surgery are relatively few, some data are available for a few other specific oncologic populations, as reviewed below.

Surgery for gynecologic cancer

There is a paucity of randomized controlled trials or prospective observational studies on VTE and its prevention in the gynecologic cancer surgery population. Based on small historical studies, the postoperative risk of VTE in this population varies from 12% to 35%.27,28 Twice-daily administration of UFH 5,000 U appears to be ineffective as VTE prophylaxis in this population, but increasing the frequency to three times daily reduces VTE risk by 50% to 60% compared with placebo. Once-daily LMWH is comparable to three-times-daily UFH in efficacy and safety in this population.

A systematic Cochrane review of eight randomized controlled trials in patients undergoing major gynecologic surgery revealed that heparin prophylaxis (either UFH or LMWH) reduces the risk of DVT by 70% compared with no prophylaxis, with an identical risk reduction specifically among women with malignancy (odds ratio, 0.30; 95% CI, 0.10 to 0.89).29 This review found no evidence that anticoagulation reduces the risk of PE following major gynecologic surgery. LMWH and UFH were similar in efficacy for preventing DVT and had a comparable risk of bleeding complications.

Surgery for urologic cancer

The risk of VTE and the benefits of thromboprophylaxis also are poorly studied in patients undergoing surgery for urologic cancer.

The risk of VTE varies with the type of urologic surgery and the method used to diagnose VTE. For instance, patients undergoing radical retropubic prostatectomy have been reported to develop DVT at rates of 1% to 3%, PE at rates of 1% to 3%, and fatal PE at a rate of 0.6%, whereas the incidences of these events are somewhat higher in patients undergoing cystectomy: 8% for DVT, 2% to 4% for PE, and 2% for fatal PE. Radiologic diagnosis of thromboembolism in pelvic surgery patients has yielded higher incidences, with DVT rates of 21% to 51% and PE rates of 11% to 22%.30

Small studies suggest that prophylaxis with either low-dose UFH or LMWH is both effective in reducing VTE risk and safe in urologic cancer surgery patients, although pharmacologic prophylaxis poses a possible increased risk of pelvic hematoma and lymphocele formation in this population.30

Neurosurgery

Most neurosurgical procedures are performed for malignancies. The risk of venography-confirmed VTE in patients undergoing neurosurgery is approximately 30% to 40%.31,32 Likewise, the risks of intracranial or intraspinal hemorrhage in these patients are high. For this reason, mechanical methods of VTE prophylaxis are preferred in these patients. The use of anticoagulant prophylaxis remains controversial in this setting, although more recent data suggest that it might be safer than previously recognized.

A meta-analysis of studies of pharmacologic prophylaxis of VTE in neurosurgery included three randomized controlled trials that compared LMWH, with or without mechanical prophylaxis, to placebo plus mechanical prophylaxis or placebo alone in a total of 922 neurosurgery patients.33 As detailed in Table 2, the analysis demonstrated statistically significant reductions in the risks of VTE and proximal DVT in favor of LMWH, with a statistically significant doubling in the risk of any bleeding and a nonsignificant 70% increase in the risk of major bleeding with LMWH therapy. The number needed to treat to prevent 1 proximal DVT was 16, while the number needed to treat to cause 1 major bleeding event was 115. A risk-benefit analysis showed that the use of LMWH in neurosurgery patients was associated with 1 major nonfatal bleeding event for every 7 proximal DVTs prevented. When a fourth randomized trial was included in the analysis, comparing UFH 5,000 U three times daily with no prophylaxis, rates of VTE and bleeding events remained similar to those for the LMWH trials alone.

 

 

GUIDELINES FOR VTE PROPHYLAXIS IN THE CANCER SURGERY PATIENT

American College of Chest Physicians

The American College of Chest Physicians’ Seventh ACCP Conference on Antithrombotic and Thrombolytic Therapy makes a number of recommendations regarding VTE prevention in patients undergoing surgery for cancer, as outlined in Table 3.34

National Comprehensive Cancer Network

The National Comprehensive Cancer Network (NCCN) recently published clinical practice guidelines on venous thromboembolic disease in cancer patients.35 The defined at-risk population for these guidelines is the adult cancer inpatient with a diagnosis of (or clinical suspicion for) cancer. The guidelines recommend prophylactic anticoagulation (category 1 recommendation) with or without a sequential compression device as initial prophylaxis, unless the patient has a relative contraindication to anticoagulation, in which case mechanical prophylaxis (sequential compression device or graduated compression stockings) is recommended. (A category 1 recommendation indicates “uniform NCCN consensus, based on high-level evidence.”)

The NCCN guidelines include a specific recommended risk-factor assessment, which includes noting the patient’s age (VTE risk increases beginning at age 40 and then steeply again at age 75), any prior VTE, the presence of familial thrombophilia or active cancer, the use of medications associated with increased VTE risk (chemotherapy, exogenous estrogen compounds, and thalidomide or lenalidomide), and a number of other risk factors for VTE as outlined in the prior two articles in this supplement. The NCCN guidelines explicitly call for assessment of modifiable risk factors for VTE (ie, smoking or other tobacco use, obesity, and a low level of activity or lack of exercise) and call for active patient education on these factors.

American Society of Clinical Oncology

The American Society of Clinical Oncology (ASCO) recently released guidelines on VTE prevention and treatment in patients with cancer;1 their key recommendations for prevention are summarized in Table 4. Notable differences from the recommendations of the Seventh ACCP Conference are the ASCO guidelines’ inclusion of fondaparinux among recommended prophylactic options for this population and more explicit recommendations on the prophylactic use of LMWH. Also, for treatment of cancer patients with established VTE, ASCO specifies that LMWH is the preferred anticoagulant for both initial and continuing treatment.

Our recommended algorithm

Figure 1. Algorithm for VTE prophylaxis in the patient undergoing major surgery for cancer.
Drawing from the above formal society guidelines and the published literature, we recommend the algorithm in Figure 1 as a practical approach to VTE prevention in patients undergoing major surgery for cancer.

LINGERING CHALLENGE OF UNDERUTILIZATION

Despite this consensus on ways to reduce thromboembolic risk in this population and the clear evidence of the benefit of VTE prophylaxis in patients with cancer, data from several registries confirm a persistently low utilization of prophylaxis in patients with cancer.36–38 The global Fundamental Research in Oncology and Thrombosis (FRONTLINE) study surveyed 3,891 clinicians who treat cancer patients regarding their practices with respect to VTE in those patients.36 The survey found that only 52% of respondents routinely used thromboprophylaxis for their surgical patients with cancer. More striking, however, was the finding that most respondents routinely considered thrombo-prophylaxis in only 5% of their medical oncology patients. These data are echoed by findings of other retrospective medical record reviews in patients undergoing major abdominal or abdominothoracic surgery (in many cases for cancer), with VTE prophylaxis rates ranging from 38% to 75%.37,38

SUMMARY

Patients undergoing surgery for cancer have an increased risk of VTE and fatal PE, even when throm­boprophylaxis is used. Nevertheless, prophylaxis with either LMWH or UFH does reduce venographic VTE event rates in these patients. If UFH is chosen for prophylaxis, a three-times-daily regimen should be used in this population. In specific surgical cancer populations, especially those undergoing abdominal surgery, out-of-hospital prophylaxis with once-daily LMWH is warranted. Current registries reveal that compliance with established guidelines for VTE prophylaxis in this population is low.

 

 

DISCUSSION: ADDITIONAL PERSPECTIVES FROM THE AUTHORS

Dr. Jaffer: Dr. Amin, based on your study on thrombo-prophylaxis rates in US medical centers, will you comment on rates of prophylaxis for cancer surgery patients?

Dr. Amin: The overall study included approximately 200,000 medical patients and about 80,000 surgical patients enrolled over more than a 3-year period between 2002 and 2005.39,40 Our goal was to assess rates of prophylaxis and, when it was provided, whether it was appropriate (in terms of type, dosage, and duration) based on the ACCP guidelines. A subanalysis assessed medical cancer patients and surgical cancer patients separately. Medical cancer patients received thromboprophylaxis 56% of the time but received appropriate prophylaxis only 28% of the time. Among surgical cancer patients, appropriate prophylaxis was given only about 24% of the time for those undergoing gynecologic surgery and about 12% of the time for those undergoing neurosurgery. These percentages are consistent with data from other national registries, such as the IMPROVE registry, which documented prophylaxis rates on the order of 45% in medical patients with cancer.41 We also analyzed the data according to individual practitioners and found that medical oncologists use prophylaxis about 25% of the time, which is relatively consistent with other providers, such as internists and surgeons.

So there is a huge opportunity to improve rates of prophylaxis for this group of patients that national guidelines say are at high risk. Why is prophylaxis so underutilized in the cancer population? One factor may be a misperception about the risk of bleeding with anticoagulants. Yet several studies have shown that the rate of bleeding from prophylaxis is extremely low, whether LMWH or UFH is used, so more awareness of actual bleeding risk is needed. Another factor is the obvious focus among internists and oncologists on treating the patient, with perhaps a reduced consideration of prophylaxis and prevention. A third factor may be a concern about thrombocytopenia. However, in our study of prophylaxis rates in US medical centers, we excluded patients who had thrombocytopenia, yet rates of prophylaxis were still low. Nothing in the literature indicates that anticoagulants cannot be used in patients with platelet counts of 50,000 to 150,000 cells/µL or higher, so this suggests that we need to do more education.

Dr. Jaffer: Dr. Brotman, can you tell us more about how clinicians in practice should use prophylaxis in their neurosurgery patients, such as those undergoing craniotomy or spine surgery for cancer? What is the safest and most efficacious way to prevent DVT in these patients?

Dr. Brotman: First, it’s important to recognize that some sort of prophylaxis needs to be used. Neurosurgery patients are at an extremely high risk for thromboembolic events, and such events are often fatal in these patients. Having said that, the jury is still out on whether the prophylaxis in these patients should be compression devices or anticoagulation. This gives physicians some latitude in their decisions. They can decide not to use pharmacologic prophylaxis so long as they use pneumatic compression devices consistently, perhaps even starting during the operation and certainly throughout hospitalization when the patient is immobilized.

Certainly, the concerns about using full-dose anticoagulation in the immediate postoperative setting in neurosurgery patients are valid. Yet these patients are at very high risk for thromboembolic events, and if we take too cautious an approach to prophylaxis in the immediate perioperative setting, more patients are going to have thromboembolic events, at which point management decisions become much more difficult. The risk of intracranial bleeding with anticoagulation to treat a patient who develops a DVT at postoperative day 10 will certainly be higher than it would have been with lower-dose perioperative prophylactic anticoagulation. Plus, if you put in a filter at that point, the outcomes tend to be poor. Therefore, I believe there is some degree of risk that we should be willing to take with regard to perioperative bleeding, even in neurosurgery patients.

Dr. McKean: I’d like to make a point about combination prophylaxis. At many institutions, compression stockings and sequential compression devices are used preoperatively and intraoperatively, and then pharmacologic prophylaxis—for example, twice-daily UFH—is used postoperatively. There is concern that these patients are hypercoagulable, and most clinicians believe that mechanical prophylaxis alone, even with sequential compression devices plus compression stockings, is not aggressive enough in these high-risk patients.

Dr. Jaffer: Dr. Spyropoulos, what is the optimal duration of pharmacologic prophylaxis for cancer surgery patients?

Dr. Spyropoulos: First let’s consider in-hospital prophylaxis. The supportive data for in-hospital prophylaxis are strong, and the duration of therapy used in the major in-hospital prophylaxis trials was 7 to 10 days. With regard to extended prophylaxis, we have at least two moderately sized randomized controlled trials, ENOXACAN II23 and the substudy of FAME,24 that demonstrated that extending prophylaxis with LMWH at doses of 3,400 U once daily (5,000 IU of dalteparin; 40 mg of enoxaparin) reduces VTE risk at postoperative day 30. Also, recent data from the @RISTOS registry show that in cancer surgery patients, especially those having abdominal or pelvic procedures, the leading cause of 30-day mortality was VTE.8 This registry also shows that despite prophylaxis, the rate of symptomatic VTE can be as high as 2%, with the rate of fatal VTE approaching 1%. Thus, in cancer patients undergoing abdominal or pelvic surgery, physicians should strongly consider prophylaxis of up to 30 days’ duration.

Dr. Jaffer: One striking finding from the @RISTOS registry was that 40% of VTE events in these cancer surgery patients occurred after postoperative day 21. This really underscores the need to consider prophylaxis for at least 4 weeks in these patients in real-world practice.

Dr. Brotman: The other striking finding from that registry was that the in-hospital prophylaxis rate was quite high, about 80%, and the rate of extended prophylaxis approached 35%. These are rates that are rarely achieved in clinical practice. Yet despite these high levels of prophylaxis, patients in this registry still had a high incidence of morbidity and mortality from VTE. This suggests that we need to improve our out-of-hospital VTE prevention paradigms.

Dr. Jaffer: Dr. Deitelzweig, oncologists and internists are often unsure about whether their ambulatory cancer patients who are receiving chemotherapy should be on any form of prophylaxis. What is your opinion?

Dr. Deitelzweig: That question comes up regularly because these patients are encountered across many medical specialties. At this point, all of the large organizations, including ASCO and NCCN, are advocating that prophylaxis is not indicated for such patients.

References
  1. Lyman GH, Khorana AA, Falanga A, et al. American Society of Clinical Oncology guideline: recommendations for venous thromboembolism prophylaxis and treatment in patients with cancer. J Clin Oncol 2007; 25:5490–5505.
  2. Khorana AA, Francis CW, Culakova E, et al. Thromboembolism is a leading cause of death in cancer patients receiving outpatient chemotherapy. J Thromb Haemost 2007; 5:632–634.
  3. Ambrus JL, Ambrus CM, Mink IB, Pickren JW. Causes of death in cancer patients. J Med 1975; 6:61–64.
  4. Donati MB. Cancer and thrombosis. Haemostasis 1994; 24:128–131.
  5. Prandoni P, Lensing AW, Cogo A, et al. The long-term clinical course of acute deep venous thrombosis. Ann Intern Med 1996; 125:1–7.
  6. Haas S, Wolf H, Kakkar AK, Fareed J, Encke A. Prevention of fatal pulmonary embolism and mortality in surgical patients: a randomized double-blind comparison of LMWH with unfractionated heparin. Thromb Haemost 2005; 94:814–819.
  7. Kakkar AK, Haas S, Wolf H, Encke A. Evaluation of perioperative fatal pulmonary embolism and death in cancer surgical patients: the MC-4 cancer substudy. Thromb Haemost 2005; 94:867–871.
  8. Agnelli G, Bolis G, Capussotti L, et al. A clinical outcome-based prospective study on venous thromboembolism after cancer surgery: the @RISTOS project. Ann Surg 2006; 243:89–95.
  9. Levitan N, Dowlati A, Remick SC, et al. Rates of initial and recurrent thromboembolic disease among patients with malignancy versus those without malignancy: risk analysis using Medicare claims data. Medicine (Baltimore) 1999; 78:285–291.
  10. Levine M, Gent M, Hirsh J, et al. A comparison of low-molecular-weight heparin administered primarily at home with unfractionated heparin administered in the hospital for proximal deep-vein thrombosis. N Engl J Med 1996; 334:677–681.
  11. Bergqvist D. Risk of venous thromboembolism in patients undergoing cancer surgery and options for thromboprophylaxis. J Surg Oncol 2007; 95:167–174.
  12. Heit JA, Silverstein MD, Mohr DN, et al. Risk factors for deep vein thrombosis and pulmonary embolism: a population-based case-control study. Arch Intern Med 2000; 160:809–815.
  13. Sallah S, Wan JY, Nguyen NP. Venous thrombosis in patients with solid tumors: determination of frequency and characteristics. Thromb Haemost 2002; 87:575–579.
  14. Kröger K, Weiland D, Ose C, et al. Risk factors for venous thromboembolic events in cancer patients. Ann Oncol 2006; 17:297–303.
  15. Blom JW, Vanderschoot JP, Oostindiër MJ, et al. Incidence of venous thrombosis in a large cohort of 66,329 cancer patients: results of a record linkage study. J Thromb Haemost 2006; 4:529–535.
  16. Couban S, Simpson DR, Barnett MJ, et al. A randomized multicenter comparison of bone marrow and peripheral blood in recipients of matched sibling allogeneic transplants for myeloid malignancies. Blood 2002; 100:1525–1531.
  17. Walshe LJ, Malak SF, Eagan J, Sepkowitz KA. Complication rates among cancer patients with peripherally inserted central catheters. J Clin Oncol 2002; 20:3276–3281.
  18. Nilsson KR, Berenholtz SM, Garrett-Mayer E, et al. Association between venous thromboembolism and perioperative allogeneic transfusion. Arch Surg 2007; 142:126–133.
  19. Efficacy and safety of enoxaparin versus unfractionated heparin for prevention of deep vein thrombosis in elective cancer surgery: a double-blind randomized multicentre trial with venographic assessment. ENOXACAN Study Group. Br J Surg 1997; 84:1099–1103.
  20. McLeod RS, Geerts WH, Sniderman KW, et al. Subcutaneous heparin versus low-molecular-weight heparin as thromboprophylaxis in patients undergoing colorectal surgery: results of the Canadian Colorectal DVT Prophylaxis Trial: a randomized, double-blind trial. Ann Surg 2001; 233:438–444.
  21. Mismetti P, Laporte S, Darmon JY, Buchmüller A, Decousus H. Meta-analysis of low molecular weight heparin in the prevention of venous thromboembolism in general surgery. Br J Surg 2001; 88:913–930.
  22. Agnelli G, Bergqvist D, Cohen AT, et al, on behalf of the PEGASUS investigators. Randomized clinical trial of postoperative fondaparinux versus perioperative dalteparin for prevention of venous thromboembolism in high-risk abdominal surgery. Br J Surg 2005; 92:1212–1220.
  23. Bergqvist D, Agnelli G, Cohen AT, et al. Duration of prophylaxis against venous thromboembolism with enoxaparin after surgery for cancer. N Engl J Med 2002; 346:975–980.
  24. Rasmussen MS, Wille-Jorgensen P, Jorgensen LN, et al. Prolonged thromboprophylaxis with low molecular weight heparin (dalteparin) following major abdominal surgery for malignancy [abstract 186]. Blood 2003; 102:56a.
  25. Leonardi MJ, McGory ML, Ko CY. A systematic review of deep venous thrombosis prophylaxis in cancer patients: implications for improving quality. Ann Surg Oncol 2007; 14:929–936.
  26. Creekmore FM, Oderda GM, Pendleton RC, Brixner DI. Incidence and economic implications of heparin-induced thrombocytopenia in medical patients receiving prophylaxis for venous thromboembolism. Pharmacotherapy 2006; 26:1438–1445.
  27. Walsh JJ, Bonnar J, Wright FW. A study of pulmonary embolism and deep leg vein thrombosis after major gynaecological surgery using labeled fibrinogen-phlebography and lung scanning. J Obstet Gynaecol Br Commonw 1974; 81:311–316.
  28. Clarke-Pearson DL, Synan IS, Coleman RE, et al. The natural history of postoperative venous thromboemboli in gynecologic oncology: a prospective study of 382 patients. Am J Obstet Gynecol 1984; 148:1051–1054.
  29. Oates-Whitehead RM, D’Angelo A, Mol B. Anticoagulant and aspirin prophylaxis for preventing thromboembolism after major gynaecological surgery. Cochrane Database Syst Rev 2003; (4):CD003679.
  30. Kibel AS, Loughlin KR. Pathogenesis and prophylaxis of postoperative thromboembolic disease in urological pelvic surgery. J Urol 1995; 153:1763–1774.
  31. Agnelli G, Piovella F, Buoncristiani P, et al. Enoxaparin plus compression stockings compared with compression stockings alone in the prevention of venous thromboembolism after elective neurosurgery. N Engl J Med 1998; 339:80–85.
  32. Semrad TJ, O’Donnell R, Wun T, et al. Epidemiology of venous thromboembolism in 9489 patients with malignant glioma. J Neurosurg 2007; 106:601–608.
  33. Iorio A, Agnelli G. Low-molecular-weight and unfractionated heparin for prevention of venous thromboembolism in neurosurgery: a meta-analysis. Arch Intern Med 2000; 160:2327–2332.
  34. Geerts WH, Pineo GF, Heit JA, et al. Prevention of venous thromboembolism: the Seventh ACCP Conference on Antithrombotic and Thrombolytic Therapy. Chest 2004; 126(3 Suppl):338S–400S.
  35. National Comprehensive Cancer Network. NCCN Clinical Practice Guidelines in Oncology. Venous thromboembolic disease. V.1.2007. http://www.nccn.org/professionals/physician_gls/PDF/vte.pdf. Accessed December 5, 2007.
  36. Kakkar AK, Levine M, Pinedo HM, Wolff R, Wong J. Venous thrombosis in cancer patients: insights from the FRONTLINE survey. Oncologist 2003; 8:381–388.
  37. Stratton MA, Anderson FA, Bussey HI, et al. Prevention of venous thromboembolism: adherence to the 1995 American College of Chest Physicians consensus guidelines for surgical patients. Arch Intern Med 2000; 160:334–340.
  38. Bratzler DW, Raskob GE, Murray CK, Bumpus LJ, Piatt DS. Underuse of venous thromboembolism prophylaxis for general surgery patients: physician practices in the community hospital setting. Arch Intern Med 1998; 158:1909–1912.
  39. Amin A, Stemkowski S, Lin J, et al. Thromboprophylaxis rates in US medical centers: success or failure? J Thromb Haemost 2007; 5:1610–1616.
  40. Amin A, Stemkowski S, Lin J, Yang G. Thromboprophylaxis in US hospitals: adherence to the 6th American College of Chest Physicians’ recommendations for at-risk medical and surgical patients. Abstract presented at: 41st Midyear Clinical Meeting of the American Society of Health-System Pharmacists; December 3–7, 2006; Anaheim, CA.
  41. Tapson VF, Decousus H, Pini M, et al. Venous thromboembolism prophylaxis in acutely ill hospitalized medical patients: findings from the International Medical Prevention Registry on Venous Thromboembolism. Chest 2007; 132:936–945.
  42. Clarke-Pearson DL, Synan IS, Dodge R, et al. A randomized trial of low-dose heparin and intermittent pneumatic calf compression for the prevention of deep venous thrombosis after gynecologic oncology surgery. Am J Obstet Gynecol 1993; 168:1146–1154.
  43. Einstein MH, Pritts EA, Hartenbach EM. Venous thromboembolism prevention in gynecologic cancer surgery: a systematic review. Gynecol Oncol 2007; 105:813–819.
  44. Clarke-Pearson DL, Synan IS, Hinshaw WM, Coleman RE, Creasman WT. Prevention of postoperative venous thromboembolism by external pneumatic calf compression in patients with gynecologic malignancy. Obstet Gynecol 1984; 63:92–98.
  45. Ruff RL, Posner JB. Incidence and treatment of peripheral venous thrombosis in patients with glioma. Ann Neurol 1983; 13:334–336.
  46. Levin JM, Schiff D, Loeffler JS, Fine HA, Black PM, Wen PY. Complications of therapy for venous thromboembolic disease in patients with brain tumors. Neurology 1993; 43:1111–1114.
References
  1. Lyman GH, Khorana AA, Falanga A, et al. American Society of Clinical Oncology guideline: recommendations for venous thromboembolism prophylaxis and treatment in patients with cancer. J Clin Oncol 2007; 25:5490–5505.
  2. Khorana AA, Francis CW, Culakova E, et al. Thromboembolism is a leading cause of death in cancer patients receiving outpatient chemotherapy. J Thromb Haemost 2007; 5:632–634.
  3. Ambrus JL, Ambrus CM, Mink IB, Pickren JW. Causes of death in cancer patients. J Med 1975; 6:61–64.
  4. Donati MB. Cancer and thrombosis. Haemostasis 1994; 24:128–131.
  5. Prandoni P, Lensing AW, Cogo A, et al. The long-term clinical course of acute deep venous thrombosis. Ann Intern Med 1996; 125:1–7.
  6. Haas S, Wolf H, Kakkar AK, Fareed J, Encke A. Prevention of fatal pulmonary embolism and mortality in surgical patients: a randomized double-blind comparison of LMWH with unfractionated heparin. Thromb Haemost 2005; 94:814–819.
  7. Kakkar AK, Haas S, Wolf H, Encke A. Evaluation of perioperative fatal pulmonary embolism and death in cancer surgical patients: the MC-4 cancer substudy. Thromb Haemost 2005; 94:867–871.
  8. Agnelli G, Bolis G, Capussotti L, et al. A clinical outcome-based prospective study on venous thromboembolism after cancer surgery: the @RISTOS project. Ann Surg 2006; 243:89–95.
  9. Levitan N, Dowlati A, Remick SC, et al. Rates of initial and recurrent thromboembolic disease among patients with malignancy versus those without malignancy: risk analysis using Medicare claims data. Medicine (Baltimore) 1999; 78:285–291.
  10. Levine M, Gent M, Hirsh J, et al. A comparison of low-molecular-weight heparin administered primarily at home with unfractionated heparin administered in the hospital for proximal deep-vein thrombosis. N Engl J Med 1996; 334:677–681.
  11. Bergqvist D. Risk of venous thromboembolism in patients undergoing cancer surgery and options for thromboprophylaxis. J Surg Oncol 2007; 95:167–174.
  12. Heit JA, Silverstein MD, Mohr DN, et al. Risk factors for deep vein thrombosis and pulmonary embolism: a population-based case-control study. Arch Intern Med 2000; 160:809–815.
  13. Sallah S, Wan JY, Nguyen NP. Venous thrombosis in patients with solid tumors: determination of frequency and characteristics. Thromb Haemost 2002; 87:575–579.
  14. Kröger K, Weiland D, Ose C, et al. Risk factors for venous thromboembolic events in cancer patients. Ann Oncol 2006; 17:297–303.
  15. Blom JW, Vanderschoot JP, Oostindiër MJ, et al. Incidence of venous thrombosis in a large cohort of 66,329 cancer patients: results of a record linkage study. J Thromb Haemost 2006; 4:529–535.
  16. Couban S, Simpson DR, Barnett MJ, et al. A randomized multicenter comparison of bone marrow and peripheral blood in recipients of matched sibling allogeneic transplants for myeloid malignancies. Blood 2002; 100:1525–1531.
  17. Walshe LJ, Malak SF, Eagan J, Sepkowitz KA. Complication rates among cancer patients with peripherally inserted central catheters. J Clin Oncol 2002; 20:3276–3281.
  18. Nilsson KR, Berenholtz SM, Garrett-Mayer E, et al. Association between venous thromboembolism and perioperative allogeneic transfusion. Arch Surg 2007; 142:126–133.
  19. Efficacy and safety of enoxaparin versus unfractionated heparin for prevention of deep vein thrombosis in elective cancer surgery: a double-blind randomized multicentre trial with venographic assessment. ENOXACAN Study Group. Br J Surg 1997; 84:1099–1103.
  20. McLeod RS, Geerts WH, Sniderman KW, et al. Subcutaneous heparin versus low-molecular-weight heparin as thromboprophylaxis in patients undergoing colorectal surgery: results of the Canadian Colorectal DVT Prophylaxis Trial: a randomized, double-blind trial. Ann Surg 2001; 233:438–444.
  21. Mismetti P, Laporte S, Darmon JY, Buchmüller A, Decousus H. Meta-analysis of low molecular weight heparin in the prevention of venous thromboembolism in general surgery. Br J Surg 2001; 88:913–930.
  22. Agnelli G, Bergqvist D, Cohen AT, et al, on behalf of the PEGASUS investigators. Randomized clinical trial of postoperative fondaparinux versus perioperative dalteparin for prevention of venous thromboembolism in high-risk abdominal surgery. Br J Surg 2005; 92:1212–1220.
  23. Bergqvist D, Agnelli G, Cohen AT, et al. Duration of prophylaxis against venous thromboembolism with enoxaparin after surgery for cancer. N Engl J Med 2002; 346:975–980.
  24. Rasmussen MS, Wille-Jorgensen P, Jorgensen LN, et al. Prolonged thromboprophylaxis with low molecular weight heparin (dalteparin) following major abdominal surgery for malignancy [abstract 186]. Blood 2003; 102:56a.
  25. Leonardi MJ, McGory ML, Ko CY. A systematic review of deep venous thrombosis prophylaxis in cancer patients: implications for improving quality. Ann Surg Oncol 2007; 14:929–936.
  26. Creekmore FM, Oderda GM, Pendleton RC, Brixner DI. Incidence and economic implications of heparin-induced thrombocytopenia in medical patients receiving prophylaxis for venous thromboembolism. Pharmacotherapy 2006; 26:1438–1445.
  27. Walsh JJ, Bonnar J, Wright FW. A study of pulmonary embolism and deep leg vein thrombosis after major gynaecological surgery using labeled fibrinogen-phlebography and lung scanning. J Obstet Gynaecol Br Commonw 1974; 81:311–316.
  28. Clarke-Pearson DL, Synan IS, Coleman RE, et al. The natural history of postoperative venous thromboemboli in gynecologic oncology: a prospective study of 382 patients. Am J Obstet Gynecol 1984; 148:1051–1054.
  29. Oates-Whitehead RM, D’Angelo A, Mol B. Anticoagulant and aspirin prophylaxis for preventing thromboembolism after major gynaecological surgery. Cochrane Database Syst Rev 2003; (4):CD003679.
  30. Kibel AS, Loughlin KR. Pathogenesis and prophylaxis of postoperative thromboembolic disease in urological pelvic surgery. J Urol 1995; 153:1763–1774.
  31. Agnelli G, Piovella F, Buoncristiani P, et al. Enoxaparin plus compression stockings compared with compression stockings alone in the prevention of venous thromboembolism after elective neurosurgery. N Engl J Med 1998; 339:80–85.
  32. Semrad TJ, O’Donnell R, Wun T, et al. Epidemiology of venous thromboembolism in 9489 patients with malignant glioma. J Neurosurg 2007; 106:601–608.
  33. Iorio A, Agnelli G. Low-molecular-weight and unfractionated heparin for prevention of venous thromboembolism in neurosurgery: a meta-analysis. Arch Intern Med 2000; 160:2327–2332.
  34. Geerts WH, Pineo GF, Heit JA, et al. Prevention of venous thromboembolism: the Seventh ACCP Conference on Antithrombotic and Thrombolytic Therapy. Chest 2004; 126(3 Suppl):338S–400S.
  35. National Comprehensive Cancer Network. NCCN Clinical Practice Guidelines in Oncology. Venous thromboembolic disease. V.1.2007. http://www.nccn.org/professionals/physician_gls/PDF/vte.pdf. Accessed December 5, 2007.
  36. Kakkar AK, Levine M, Pinedo HM, Wolff R, Wong J. Venous thrombosis in cancer patients: insights from the FRONTLINE survey. Oncologist 2003; 8:381–388.
  37. Stratton MA, Anderson FA, Bussey HI, et al. Prevention of venous thromboembolism: adherence to the 1995 American College of Chest Physicians consensus guidelines for surgical patients. Arch Intern Med 2000; 160:334–340.
  38. Bratzler DW, Raskob GE, Murray CK, Bumpus LJ, Piatt DS. Underuse of venous thromboembolism prophylaxis for general surgery patients: physician practices in the community hospital setting. Arch Intern Med 1998; 158:1909–1912.
  39. Amin A, Stemkowski S, Lin J, et al. Thromboprophylaxis rates in US medical centers: success or failure? J Thromb Haemost 2007; 5:1610–1616.
  40. Amin A, Stemkowski S, Lin J, Yang G. Thromboprophylaxis in US hospitals: adherence to the 6th American College of Chest Physicians’ recommendations for at-risk medical and surgical patients. Abstract presented at: 41st Midyear Clinical Meeting of the American Society of Health-System Pharmacists; December 3–7, 2006; Anaheim, CA.
  41. Tapson VF, Decousus H, Pini M, et al. Venous thromboembolism prophylaxis in acutely ill hospitalized medical patients: findings from the International Medical Prevention Registry on Venous Thromboembolism. Chest 2007; 132:936–945.
  42. Clarke-Pearson DL, Synan IS, Dodge R, et al. A randomized trial of low-dose heparin and intermittent pneumatic calf compression for the prevention of deep venous thrombosis after gynecologic oncology surgery. Am J Obstet Gynecol 1993; 168:1146–1154.
  43. Einstein MH, Pritts EA, Hartenbach EM. Venous thromboembolism prevention in gynecologic cancer surgery: a systematic review. Gynecol Oncol 2007; 105:813–819.
  44. Clarke-Pearson DL, Synan IS, Hinshaw WM, Coleman RE, Creasman WT. Prevention of postoperative venous thromboembolism by external pneumatic calf compression in patients with gynecologic malignancy. Obstet Gynecol 1984; 63:92–98.
  45. Ruff RL, Posner JB. Incidence and treatment of peripheral venous thrombosis in patients with glioma. Ann Neurol 1983; 13:334–336.
  46. Levin JM, Schiff D, Loeffler JS, Fine HA, Black PM, Wen PY. Complications of therapy for venous thromboembolic disease in patients with brain tumors. Neurology 1993; 43:1111–1114.
Page Number
S17-S26
Page Number
S17-S26
Publications
Publications
Article Type
Display Headline
Prevention of venous thromboembolism in the cancer surgery patient
Display Headline
Prevention of venous thromboembolism in the cancer surgery patient
Citation Override
Cleveland Clinic Journal of Medicine 2008 April;75(suppl 3):S17-S26
Disallow All Ads
Alternative CME
Use ProPublica
Article PDF Media

Prevention of venous thromboembolism in the orthopedic surgery patient

Article Type
Changed
Tue, 09/25/2018 - 15:49
Display Headline
Prevention of venous thromboembolism in the orthopedic surgery patient

Nearly half of orthopedic surgery patients do not receive appropriate prophylaxis for venous thromboembolism (VTE), as defined by American College of Chest Physicians (ACCP) consensus guidelines, according to a recent analysis of a nationwide database of hospital admissions.1 Even in teaching hospitals, compliance with consensus guidelines for thromboprophylaxis is suboptimal. In a study of adherence to the ACCP guidelines for VTE prevention among 1,907 surgical patients at 10 teaching hospitals, only 45.2% of hip fracture patients received optimal VTE prophylaxis.2 Rates of optimal prophylaxis were higher among patients undergoing hip arthroplasty and knee arthroplasty—84.3% and 75.9%, respectively—but were still in need of improvement.2

GROWING INTEREST IN POSTOPERATIVE VTE PROPHYLAXIS AS A QUALITY INDICATOR

As noted in the introductory article in this supplement, the Joint Commission on Accreditation of Healthcare Organizations has taken notice of these shortcomings and has proposed national consensus standards for VTE prevention and treatment.3 Among its proposed standards are two related to risk assessment and prophylaxis: whether risk assessment/prophylaxis is ordered within 24 hours of hospital admission and within 24 hours of transfer to the intensive care unit.

Other quality-monitoring initiatives are focused specifically on VTE in the surgical population. The Surgical Care Improvement Project (SCIP) has approved two quality measures with respect to VTE prevention: (1) the proportion of surgical patients for whom recommended VTE prophylaxis is ordered, and (2) the proportion of patients who receive appropriate VTE prophylaxis (based on ACCP guideline recommendations) within 24 hours before or after surgery.4

In the future, two other VTE-related quality measures from SCIP may be implemented by the Centers for Medicare and Medicaid Services: (1) how often intra- or postoperative pulmonary embolism (PE) is diagnosed during the index hospitalization and within 30 days of surgery, and (2) how often intra- or postoperative deep vein thrombosis (DVT) is diagnosed during the index hospitalization and within 30 days of surgery.5

VTE RISK IN ORTHOPEDIC SURGERY

Surgical patients can be stratified into four VTE risk levels—low, moderate, high, and highest—based on age, surgery type, surgery duration, duration of immobilization, and other risk factors.6 For patients undergoing orthopedic surgery, these levels may be defined according to the following patient and surgical characteristics:

  • Low risk—surgery duration of less than 30 minutes, age less than 40 years, repair of small fractures
  • Moderate risk—age of 40 to 60 years, arthroscopy or repair of lower leg fractures, postoperative plaster cast
  • High risk—age greater than 60 years, or age 40 to 60 years with additional VTE risk factors, or immobilization for greater than 4 days
  • Highest risk—hip or knee arthroplasty, hip fracture repair, repair of open lower leg fractures, major trauma or spinal cord injury, or multiple risk factors for VTE (age > 40 years, prior VTE, cancer, or hypercoagulable state).

For patients in the low-risk category, no specific prophylaxis is indicated beyond early and aggressive ambulation.6 For those in all other risk categories, prophylaxis with pharmacologic anticoagulant agents and/or mechanical devices is indicated, as reviewed below.

All major orthopedic procedures confer highest risk level

Notably, the “highest risk” category includes any patient undergoing hip or knee arthroplasty or hip fracture repair. Among orthopedic surgery patients in this highest-risk category, rates of VTE events in the absence of prophylaxis are as follows:6

  • Calf DVT, 40% to 80%
  • Proximal DVT, 10% to 20%
  • Clinical PE, 4% to 10%
  • Fatal PE, 0.2% to 5%.

Hip replacement poses greater risk than knee replacement

Within this overall highest-risk category, thromboembolic risk in the absence of prophylaxis differs among procedures. Although patients undergoing hip replacement and those undergoing knee replacement have similar rates of DVT of any type,6,7 hip replacement is associated with higher rates of the more clinically important events, specifically proximal DVT and PE. In the absence of prophylaxis, proximal DVT occurs in 23% to 36% of hip replacement patients as opposed to 9% to 20% of knee replacement patients; similarly, PE occurs in 0.7% to 30% of hip replacement patients as compared with 1.8% to 7.0% of knee replacement patients.6,7

What about bleeding risk?

For many orthopedic surgeons, the risk of bleeding as a result of anticoagulant prophylaxis of VTE looms larger than the risk of VTE itself. This is likely because bleeding, when it does occur, is likely to occur more acutely than VTE does and may directly compromise the result of the operation. For this reason, orthopedic surgeons may be more likely to actually witness bleeding events than VTE events (especially fatal PEs) while their patients are still under their care, leading to a misperception of the relative risks of anticoagulation-related bleeding and thromboembolism.

In reality, rates of major bleeding with pharmacologic prophylaxis of VTE are a tiny fraction of the above-listed rates of VTE events in the absence of prophylaxis in patients undergoing major orthopedic surgery. Reported 30-day rates of major bleeding in patients receiving VTE prophylaxis with heparins range from 0.2% to 1.7%; these rates barely differ from the rates among placebo recipients in the same VTE prophylaxis trials, which range from 0.2% to 1.5%.8,9 Additionally, within the continuum of risk of major bleeding from various medical interventions, VTE prophylaxis with heparins is one of the lowest-risk interventions, posing far less risk than, for example, the use of warfarin in ischemic stroke patients or in patients older than 75 years.

 

 

PHARMACOLOGIC OPTIONS FOR VTE PROPHYLAXIS IN ORTHOPEDIC SURGERY

As reviewed in the introductory article of this supplement, the arsenal of anticoagulants for use in VTE prophylaxis includes low-dose unfractionated heparin (UFH), low-molecular-weight heparin (LMWH) agents such as dalteparin and enoxaparin, and the factor Xa inhibitor fondaparinux. A few additional comments about these and other anticoagulant options is warranted in the specific context of orthopedic surgery.

Fondaparinux. Because most of its formal US indications are for use as VTE prophylaxis in major orthopedic surgery—including hip replacement, knee replacement, and hip fracture repair—fondaparinux has been studied more widely in orthopedic surgery patients than in the other populations reviewed earlier in this supplement. Nevertheless, its use even in these settings has remained somewhat limited. This may be because of concerns over possible increased bleeding risk relative to some other anticoagulants. Because of bleeding risk, fondaparinux is contraindicated in patients who weigh less than 50 kg, and its package insert recommends caution when it is used in the elderly due to an increased risk of bleeding in patients aged 65 or older. Additionally, the Pentasaccharide in Major Knee Surgery (PENTAMAKS) study found fondaparinux to be associated with a significantly higher incidence of major bleeding compared with enoxaparin (2.1% vs 0.2%; P = .006) in major knee surgery, although it was superior to enoxaparin in preventing VTE.10 Other possible reasons for slow adoption of fondaparinux include its long half-life, which results in a sustained antithrombotic effect, its lack of easy reversibility, and a contraindication in patients with renal insufficiency.11

Limited role for UFH. Low-dose UFH has a more limited role in orthopedic surgery than in other settings requiring VTE prophylaxis, as current ACCP guidelines for VTE prevention recognize it only as a possible option in hip fracture surgery and state that it is not to be considered as sole prophylaxis in patients undergoing hip or knee replacement.6

Warfarin. Although not indicated for use in other VTE prophylaxis settings, the vitamin K antagonist warfarin is recommended as an option for all three major orthopedic surgery indications—knee replacement, hip replacement, and hip fracture repair.6

The key to effective prophylaxis with warfarin is achieving the appropriate intensity of anticoagulation. In two separate analyses, Hylek et al demonstrated a balance between safety and efficacy with warfarin therapy targeted to an international normalized ratio (INR) of 2.0 to 3.0.12,13 An INR greater than 4.0 greatly increased the risk of intracranial hemorrhage, whereas thrombosis was not effectively prevented with an INR less than 2.0.12,13 This latter point should be stressed to orthopedic surgeons, who sometimes aim for INR values below 2.0.

Although anticoagulation clinics are superior to usual care at maintaining the INR within the window of 2.0 to 3.0, only about one-third of patients nationally who take warfarin receive care in such clinics.14 Even with optimal care in anticoagulation clinics, some patients will still receive subtherapeutic or supertherapeutic levels of warfarin, which is one of this agent’s limitations.

Aspirin not recommended as sole agent. Although aspirin is still used as thromboprophylaxis in orthopedic surgery patients, current ACCP guidelines recommend against its use as the sole means of VTE prophylaxis in any patient group.6 The limitations of the evidence for aspirin in this setting are illustrated by the Pulmonary Embolism Prevention study, a multicenter randomized trial in patients undergoing hip fracture (n = 13,356) or hip/knee replacement (n = 4,088).15 Patients received aspirin 160 mg/day or placebo for 5 weeks, starting preoperatively, and were evaluated for outcomes at day 35. Among the hip fracture patients, the rate of symptomatic DVT was lower in the aspirin group than in the placebo group (1.0% vs 1.5%; P = .03), as was the rate of PE (0.7% vs 1.2%, respectively; P = .002), but there was no significant difference in outcomes between the groups among the patients undergoing hip or knee replacement. Notably, 40% of patients in the study also received UFH or LMWH. Further confounding the results, some patients received nonpharmacologic VTE prophylaxis modalities, and others received nonsteroidal anti-inflammatory drugs other than aspirin.

Heparin-induced thrombocytopenia. As noted earlier in this supplement, the incidence of heparin-induced thrombocytopenia (HIT) is markedly higher in patients who receive UFH than in those who receive LMWH. This difference in frequency, which constitutes about a sixfold to eightfold differential, is due to the relationship between standard heparin and platelet factor IV, which can induce formation of IgG antibodies.16 A 50% or greater reduction in platelet count in heparin recipients should prompt consideration of HIT.

Oral direct thrombin inhibitors. Although the oral direct thrombin inhibitor ximelagatran was rejected for approval by the US Food and Drug Administration (FDA) and recently withdrawn from the market world­wide as a result of hepatic risks, other oral direct thrombin inhibitors are in phase 3 studies for use in orthopedic surgery and may be commercially available options for postoperative VTE prophylaxis before long.

GUIDELINES FOR VTE PROPHYLAXIS IN ORTHOPEDIC SURGERY

The ACCP guidelines referred to throughout this article are widely recognized as a practice standard for VTE prevention and treatment, and have been regularly updated throughout recent decades. The most recent version, issued in 2004, is formally known as the Seventh ACCP Conference on Antithrombotic and Thrombolytic Therapy.6 Key orthopedic surgery-related recommendations and notable changes from the previous version of the guidelines, issued in 2001, are outlined below, along with pertinent supportive or illustrative studies.

Hip replacement surgery

For all patients undergoing elective hip replacement surgery, routine use of either LMWH, fondaparinux, or warfarin is recommended (see Table 1 for recommended dosing). Each of these options is given a Grade 1A recommendation, the guidelines’ highest level of endorsement, indicating evidence from randomized controlled trials (RCTs) without important limitations. None of these options is recommended as superior to the other two. The guidelines recommend against the use of any other option, including UFH and mechanical devices, as the sole method of prophylaxis in these patients.6

In a change from the previous guidelines, the Seventh ACCP Conference recommends extended prophylaxis, for up to 28 to 35 days after surgery, for patients undergoing hip replacement or hip fracture surgery. For hip replacement surgery, this is a Grade 1A recommendation for prophylaxis with either LMWH or warfarin and a Grade 1C+ recommendation (“no RCTs but strong RCT results can be unequivocally extrapolated, or overwhelming evidence from observational studies”) for prophylaxis with fondaparinux.6

Reprinted, with permission, from Annals of Internal Medicine (Hull et al, 2001).17
Figure 1. Relative risk (and 95% confidence intervals) for all deep vein thrombosis during the out-of-hospital time interval (up to 28 to 35 days after surgery) with extended-duration low-molecular-weight heparin (LMWH) therapy compared with standard-duration LMWH therapy. Results are from six randomized trials of extended prophylaxis in patients undergoing total hip replacement. The risk reduction with extended-duration prophylaxis was statistically significant in all six trials.
The compelling evidence base for extended prophylaxis with LMWH in this setting was demonstrated in a systematic review of six double-blind, randomized, placebo-controlled trials, as illustrated in Figure 1.17 Additionally, a Belgian cost-utility analysis in patients who underwent total hip or knee replacement showed that extended prophylaxis with enoxaparin (30 days) carried an incremental cost of $6,386 (US dollars) per quality-adjusted life-year compared with standard-duration enoxaparin prophylaxis (12 days), a cost that was well below the “willingness to pay” threshold of $18,200 per quality-adjusted life-year used in European guidelines for cost-effectiveness.18

 

 

Knee replacement surgery

The same three anticoagulant options that received Grade 1A recommendations for patients undergoing total hip replacement—LMWH, fondaparinux, and adjusted-dose warfarin—are also given Grade 1A recommendations as routine thromboprophylaxis in patients undergoing elective knee replacement (see Table 1 for dosing). In addition, optimal use of intermittent pneumatic compression devices is recommended as an alternative option to anticoagulant prophylaxis in these patients (Grade 1B, indicating a “strong recommendation” based on RCTs with important limitations). Use of UFH as the sole agent for prophylaxis is recommended against.6

For both hip and knee replacement surgery, the Seventh ACCP Conference does not endorse superiority of any one of its three recommended prophylaxis options—LMWH, fondaparinux, and adjusted-dose warfarin—over the other two. However, at least four large randomized trials have directly compared LMWH and adjusted-dose warfarin in the setting of arthroplasty—two in total hip replacement surgery19,20 and two in total knee replacement surgery.21,22 Each of these four studies found LMWH to be significantly more effective than warfarin in preventing VTE. In three of the four trials, there was no significant difference between the therapies in rates of major bleeding.19,21,22 In the remaining trial, which was conducted in hip replacement surgery patients and compared postoperative warfarin with dalteparin initiated either immediately before or early after surgery, patients who received preoperative dalteparin initiation (but not those who received postoperative dalteparin initiation) had an increased rate of major bleeding compared with warfarin recipients (P = .01).20

Hip fracture surgery

The supportive evidence for anticoagulant prophylaxis in hip fracture surgery is less robust than that in hip and knee replacement surgery. As a result, only fondaparinux has a Grade 1A recommendation as routine prophylaxis in patients undergoing hip fracture surgery. Options with less definitive recommendations are LMWH (Grade 1C+), low-dose UFH (Grade 1B), and adjusted-dose warfarin (Grade 2B, indicating a “weak recommendation” based on RCTs with important limitations) (see Table 1 for dosing of all agents).6

These differing recommendations are supported by the double-blind Pentasaccharide in Hip Fracture Surgery Study (PENTHIFRA) of 1,711 consecutive patients undergoing surgery for hip fracture repair.23 Patients were randomized to at least 5 days of fondaparinux 2.5 mg once daily, initiated postoperatively, or enoxaparin 40 mg once daily, initiated preoperatively. The incidence of DVT or PE by postoperative day 11 was 8.3% in the fondaparinux arm versus 19.1% in the enoxaparin arm, a statistically significant difference (P < .001) in favor of fondaparinux. There were no differences between the groups in rates of death or clinically relevant bleeding.

As noted above, the newly added recommendation in the Seventh ACCP Conference for extended prophylaxis, for up to 28 to 35 days after surgery, applies to patients undergoing hip fracture surgery as well as those undergoing hip replacement surgery. In the setting of hip fracture repair, extended prophylaxis is a Grade 1A recommendation with the use of fondaparinux and a Grade 1C+ recommendation with the use of either LMWH or adjusted-dose warfarin.6

Lower extremity fractures and trauma

Although lower extremity fractures are very common, the risk of DVT has been poorly studied in this setting. For patients with isolated lower extremity fractures, the Seventh ACCP Conference recommends that clinicians not use thromboprophylaxis routinely (Grade 2A, indicating an “intermediate-strength recommendation” based on RCTs without important limitations).6

Trauma patients, in contrast, are well recognized as being at very high risk for DVT and PE. The Seventh ACCP Conference gives a Grade 1A recommendation to thromboprophylaxis for all trauma patients who have at least one risk factor for VTE. LMWH is recommended (Grade 1A) as the agent of choice for this purpose, provided there are no contraindications to its use, and should be administered as soon as safely possible. Mechanical modalities are reserved for trauma patients with active bleeding or high risk for hemorrhage (Grade 1B). The guidelines recommend against use of inferior vena cava (IVC) filters as primary thromboprophylaxis in trauma patients (Grade 1C, indicating an “intermediate-strength recommendation” based on observational studies).6

Use of ultrasonography

Duplex ultrasonographic screening is recommended in orthopedic trauma patients who are at high risk for VTE and have received suboptimal or no prophylaxis (Grade 1C). In contrast, the Seventh ACCP Conference recommends against routine use of duplex ultrasonography to screen for VTE at hospital discharge in asymptomatic patients following major orthopedic surgery (Grade 1A).6

Knee arthroscopy

Arthroscopic knee procedures are increasing in frequency and raise the specter of a potential role for thromboprophylaxis. However, the clinical diagnosis of DVT is unreliable, and even diagnosis by ultrasonography is unreliable following knee arthroscopy, as interpreting scans of veins below the knee is challenging in this setting.24

The Seventh ACCP Conference recommends that clinicians not use routine thromboprophylaxis, other than early mobilization, for patients who undergo knee arthroscopy (Grade 2B). However, for arthroscopy patients who have inherent risk factors for VTE or who undergo a prolonged or complicated arthroscopy procedure, thromboprophylaxis with LMWH is suggested (Grade 2B).6

RECOMMENDED APPROACH TO VTE PROPHYLAXIS IN ORTHOPEDIC SURGERY

Drawing on the ACCP guidelines and the evidence reviewed above, we have outlined our evidence-based recommendations for pharmacologic VTE prophylaxis in patients undergoing orthopedic surgery, as presented in Table 1. All patients undergoing major orthopedic surgical procedures (ie, procedures other than arthroscopy) should routinely receive anticoagulant prophylaxis unless they have contraindications to anticoagulation. Recommended agents and their duration of use vary according to the type of surgery, as detailed in Table 1.

Extended-duration prophylaxis is recommended for patients undergoing total hip replacement and hip fracture surgery. Aspirin is not recommended as the sole agent for prophylaxis in any orthopedic surgery setting.

Importance of a postoperative prophylaxis protocol

In addition to these broad pharmacologic recommendations, it is important that a postoperative VTE prophylaxis protocol be in place at all hospitals.

At the Ochsner Medical Center in New Orleans, where one of us (S.B.D.) practices, postoperative orders include antithrombotic therapy for surgical patients, starting with placement of thigh-high antiembolism stockings on both legs on the day of surgery for patients undergoing hip replacement and on postoperative day 1 in those undergoing knee replacement. Plantar pneumatic compression devices are applied to both legs in the recovery room and kept on except when the patient is walking. The hospitalist team dictates further anticoagulation orders. If extended prophylaxis is prescribed, the discharge planner sets up drug delivery and reimbursement, provides a LMWH discharge kit, and teaches the patient to self-inject. If there is concern about increasing swelling at the surgical site while anticoagulant therapy continues, the protocol calls for prompt notification of the responsible physician. To minimize the risk that spinal or epidural hematomas will develop, all agents that increase bleeding propensity should be recognized and ordered accordingly.

 

 

SUMMARY

VTE in patients undergoing major orthopedic surgery is a serious health problem that is highly preventable, yet VTE prophylaxis remains underused in this patient population. Despite the availability of practice guidelines for VTE prevention in the orthopedic surgery setting, recommendations are not widely implemented in clinical practice. Recommended prophylactic options differ somewhat among various orthopedic procedures, and the supportive evidence differs for various anticoagulant options.

DISCUSSION: ADDITIONAL PERSPECTIVES FROM THE AUTHORS

Dr. Jaffer: The ACCP recommends against the routine use of aspirin as primary prophylaxis against VTE in major orthopedic surgery, yet orthopedic surgeons across the country still continue to use aspirin in this setting. What are your thoughts on this, Dr. McKean?

Dr. McKean: We agree with the ACCP’s recommendation against aspirin as primary VTE prophylaxis in orthopedic patients. The percentage of US knee arthroplasty patients who develop VTE after receiving no prophylaxis at all is roughly 64%; this percentage declines only slightly (to 56%) for knee arthroplasty patients who receive prophylaxis with aspirin.25 Since we clearly want to reduce VTE risk as much as possible, I would not use aspirin alone. I would use it only if the patient were already on aspirin, but then I would add either LMWH or fondaparinux.

Dr. Jaffer: Warfarin is another agent that is widely used for prophylaxis in major orthopedic surgery. In fact, the large registries of VTE prevention in major orthopedic surgery suggest that the use of warfarin may be slightly higher than the use of LMWH. If clinicians choose to use warfarin in their practice, what are your recommendations, Dr. Deitelzweig?

Dr. Deitelzweig: As primary prophylaxis for orthopedic surgery patients, warfarin must be dosed to achieve an INR of 2.0 to 3.0; the need for a value in this range is unequivocal. This is a challenging target to attain in the hospital setting.

Dr. Brotman: A study I was involved with a few years ago suggested that warfarin may be inadequate for VTE prevention in the first few days after orthopedic surgery.26 Orthopedic surgeons at the Cleveland Clinic, where I was practicing at the time, routinely used systematic ultrasonography to assess for thrombosis on postoperative day 2 or 3 following hip or knee arthroplasty, so we conducted a secondary analysis of a case-control study in these ultrasonographically screened arthroplasty patients to assess rates of early VTE and look for any associations with the type of prophylaxis used. We found that there was about a tenfold increase in the risk of VTE, both distal and proximal, on postoperative day 2 or 3 among patients who received warfarin compared with those who received LMWH. We concluded that warfarin’s delayed antithrombotic effects may not provide sufficient VTE prophylaxis in the immediate postoperative setting.26

Dr. Deitelzweig: That’s a good point. Although it’s important to achieve a therapeutic level of warfarin, we now have evidence that it takes some time to achieve that level, and in the interim, bad things can happen to patients.

Dr. Jaffer: Orthopedic surgery encompasses several types of procedures. Dr. Amin, which specific orthopedic surgery patients stand to benefit from extended prophylaxis, and how long should extended prophylaxis last?

Dr. Amin: Major orthopedic surgery comprises hip fracture repair, total hip replacement, and total knee replacement. For hip fracture, there are strong data to support the use of extended prophylaxis with fondaparinux 2.5 mg/day, which showed about an 88% relative reduction in the risk of symptomatic VTE compared with standard-duration fondaparinux (6 to 8 days) followed by matching placebo for the extended phase.27 The total duration of fondaparinux therapy in the extended-duration arm was 4 to 5 weeks.

Likewise, data support extended prophylaxis in hip arthroplasty patients, for whom the recommended duration is also 4 to 5 weeks. The systematic review by Hull et al17 demonstrated a 0.41 relative risk of DVT with extended-duration LMWH prophylaxis versus placebo in hip replacement patients (Figure 1), which was a highly statistically significant result.

In contrast, we do not yet have good data to support extended prophylaxis for patients undergoing total knee replacement, which is a bit surprising. In this setting, prophylaxis is recommended for 7 to 14 days but not beyond that.

Dr. Jaffer: Arthroscopy is probably the most common orthopedic procedure performed in the United States today. Dr. Brotman, what is the role of prophylaxis in patients undergoing arthroscopy?

Dr. Brotman: Minor surgery such as arthroscopy can typically be performed safely without routine prophylaxis, other than having the patient ambulate as soon as possible after the procedure. There may be exceptions to this rule, however. I believe that there is potentially a role for pharmacologic prophylaxis in arthroscopy patients who have major risk factors for VTE, such as a personal history of VTE, or who are not expected to become mobile again in a normal rapid fashion after the operation, but prophylaxis has not been studied systematically in such patients.

Dr. Jaffer: Dr. Spyropoulos, there are several new anticoagulants in the pipeline, specifically agents such as the oral direct factor Xa inhibitors and the direct thrombin inhibitors. What do recent clinical trials suggest with regard to the efficacy of these two drug classes for thromboprophylaxis in major orthopedic surgery?

Dr. Spyropoulos: The agents with the most available data are the oral direct factor Xa inhibitors apixaban and rivaroxaban and the oral direct thrombin inhibitor dabigatran. For prophylaxis in orthopedic surgery populations, phase 2 studies have been completed for apixaban and phase 3 trials have been completed for rivaroxaban and dabigatran.

It appears that the factor Xa inhibitors, apixaban and rivaroxaban, are efficacious in comparison with both adjusted-dose warfarin and LMWH, which is the gold standard for this group of patients.28,29 So these indeed appear to be promising agents. Rivaroxaban has been submitted to European regulatory agencies for approval for the prevention of VTE in patients undergoing major orthopedic surgery, and its developer plans to submit it to the FDA in 2008 for a similar indication in the United States.

The data are more equivocal with dabigatran. There have been several positive phase 3 studies in orthopedic surgery comparing two dabigatran dosing schemes, 150 and 220 mg once daily, with the European regimen of enoxaparin (40 mg once daily),30 but a recent study that compared these doses with the North American enoxaparin regimen (30 mg twice daily) failed to meet the criteria for noninferiority.31 Further clinical trial development is necessary for dabigatran, although in January 2008 the European Medicines Agency recommended its marketing approval for thromboprophylaxis in patients undergoing orthopedic procedures.32

I believe that in the next 3 to 5 years our armamentarium will see the addition of at least one, if not more, of these new agents that offer the promise of oral anticoagulation with highly predictable pharmacokinetics and pharmacodynamics and no need for monitoring.

References
  1. Yu HT, Dylan ML, Lin J, Dubois RW. Hospitals’ compliance with prophylaxis guidelines for venous thromboembolism. Am J Health Syst Pharm 2007; 64:69–76.
  2. Stratton MA, Anderson FA, Bussey HI, et al. Prevention of venous thromboembolism: adherence to the 1995 ACCP consensus guidelines for surgical patients. Arch Intern Med 2000; 160:334–340.
  3. National Consensus Standards for Prevention and Care of Venous Thromboembolism (VTE). The Joint Commission Web site. http://www.jointcommission.org/PerformanceMeasurement/Perform anceMeasurement/VTE.htm. Accessed January 8, 2008.
  4. Surgical Care Improvement Project. MedQIC Web site. http://www.medqic.org/scip. Accessed January 8, 2008.
  5. SCIP process and outcome measures, October 2005. MedQIC Web site. http://www.medqic.org. Accessed January 1, 2007.
  6. Geerts WH, Pineo GF, Heit JA, et al. Prevention of venous thromboembolism: the Seventh ACCP Conference on Antithrombotic and Thrombolytic Therapy. Chest 2004; 126(3 Suppl):338S–400S.
  7. Zimlich RH, Fulbright BM, Friedman RJ. Current status of anticoagulation therapy after total hip and total knee arthroplasty.J Am Acad Orthop Surg 1996; 4:54–62.
  8. Planes A, Vochelle N, Mazas F, et al. Prevention of postoperative venous thrombosis: a randomized trial comparing unfractionated heparin with low molecular weight heparin in patients undergoing total hip replacement. Thromb Haemost 1988; 60:407–410.
  9. Colwell CW Jr, Spiro TE, Trowbridge AA, et al. Efficacy and safety of enoxaparin versus unfractionated heparin for prevention of deep venous thrombosis after elective knee arthroplasty. Clin Orthop Relat Res 1995; 321:19–27.
  10. Bauer KA, Eriksson BI, Lassen MR, Turpie AG. Fondaparinux compared with enoxaparin for the prevention of venous thromboembolism after elective major knee surgery. N Engl J Med 2001; 345:1305–1310.
  11. Turpie AGG. Pentasaccharide Org31540/SR90107A clinical trials update: lessons for practice. Am Heart J 2001; 142(Suppl):S9–S15.
  12. Hylek EM, Singer DE. Risk factors for intracranial hemorrhage in outpatients taking warfarin. Ann Intern Med 1994; 120:897–902.
  13. Hylek EM, Skates SJ, Sheehan MA, Singer DE. An analysis of the lowest effective intensity of prophylactic anticoagulation for patients with nonrheumatic atrial fibrillation. N Engl J Med 1996; 335:540–546.
  14. Samsa GP, Matchar DB, Goldstein LB, et al. Quality of anticoagulation management among patients with atrial fibrillation: review of medical records from 2 communities. Arch Intern Med 2000; 160:967–973.
  15. PEP Trial Collaborative Group. Prevention of pulmonary embolism and deep vein thrombosis with low dose aspirin: Pulmonary Embolism Prevention (PEP) trial. Lancet 2000; 355:1295–1302.
  16. Warkentin TE. Heparin-induced thrombocytopenia: pathogenesis and management. Br J Haemotol 2003; 121:535–555.
  17. Hull RD, Pineo GF, Stein PD, et al. Extended out-of-hospital low-molecular-weight heparin prophylaxis against deep venous thrombosis in patients after elective hip arthroplasty: a systematic review. Ann Intern Med 2001; 135:858–869.
  18. Haentjens P, De Groote K, Annemans L. Prolonged enoxaparin therapy to prevent venous thromboembolism after primary hip or knee replacement: a cost-utility analysis. Arch Orthop Trauma Surg 2004; 124:507–517.
  19. Colwell CW Jr, Collis DK, Paulson R, et al. Comparison of enoxaparin and warfarin for the prevention of venous thromboembolic disease after total hip arthroplasty: evaluation during hospitalization and three months after discharge. J Bone Joint Surg Am 1999; 81:932–940.
  20. Hull RD, Pineo GF, Francis C, et al. Low-molecular-weight heparin prophylaxis using dalteparin in close proximity to surgery vs warfarin in hip arthroplasty patients: a double-blind, randomized comparison. Arch Intern Med 2000; 160:2199–2207.
  21. Leclerc JR, Geerts WH, Desjardins L, et al. Prevention of venous thromboembolism after knee arthroplasty: a randomized, double-blind trial comparing enoxaparin with warfarin. Ann Intern Med 1996; 124:619–626.
  22. Fitzgerald RH Jr, Spiro TE, Trowbridge AA, et al. Prevention of venous thromboembolic disease following primary total knee arthroplasty: a randomized, multicenter, open-label, parallel-group comparison of enoxaparin and warfarin. J Bone Joint Surg Am 2001; 83-A:900–906.
  23. Eriksson BI, Bauer KA, Lassen MR, Turpie AG, Steering Committee of the Pentasaccharide in Hip-Fracture Surgery Study. Fondaparinux compared with enoxaparin for the prevention of venous thromboembolism after hip-fracture surgery. N Engl J Med 2001; 345:1298–1304.
  24. Demers C, Marcoux S, Ginsberg JS, Laroche F, Cloutier R, Poulin J. Incidence of venographically proved deep vein thrombosis after knee arthroscopy. Arch Intern Med 1998; 158:47–50.
  25. Geerts WH, Heit JA, Clagett GP, et al. Prevention of venous thromboembolism. Chest 2001; 119(1 Suppl):132S–175S.
  26. Brotman DJ, Jaffer AK, Hurbanek JG, Morra N. Warfarin prophylaxis and venous thromboembolism in the first 5 days following hip and knee arthroplasty. Thromb Haemost 2004; 92:1012–1017.
  27. Eriksson BI, Lassen MR; Pentasaccharide in Hip-Fracture Surgery Plus Investigators. Duration of prophylaxis against venous thromboembolism with fondaparinux after hip fracture surgery: a multicenter, randomized, placebo-controlled, double-blind study. Arch Intern Med 2003; 163:1337–1342.
  28. The Botticelli Investigators. Late-breaking clinical trial: a dose-finding study of the oral direct factor Xa inhibitor apixaban in the treatment of patients with acute symptomatic deep vein thrombosis [abstract]. Presented at the 21st Congress of the International Society on Thrombosis and Haemostasis; July 2007; Geneva, Switzerland.
  29. Fisher WD, Eriksson BI, Bauer KA, et al. Rivaroxaban for thromboprophylaxis after orthopaedic surgery: pooled analysis of two studies. Thromb Haemost 2007; 97:931–937.
  30. Haas S. New oral Xa and IIa inhibitors: updates on clinical trial results. J Thromb Thrombolysis 2008; 25:52–60.
  31. Friedman RJ, Caprini JA, Comp PC, et al. Dabigatran etexilate vs enoxaparin in preventing venous thromboembolism following total knee arthroplasty. Presented at: 2007 Congress of the International Society on Thrombosis and Haemostasis; July 7–13, 2007; Geneva, Switzerland.
  32. Committee for Medicinal Products for Human Use summary of positive opinion for Pradaxa [news release]. London, UK: European Medicines Agency. January 24, 2008. http://www.emea.europa.eu/pdfs/human/ opinion/Pradaxa_3503008en.pdf. Accessed February 21, 2008.
  33. Goldhaber SZ, Grodstein F, Stampfer MJ. A prospective study of risk factors for pulmonary embolism in women. JAMA 1997; 277:642–645.
  34. Turpie AGG, Bauer KA, Eriksson BI, Lassen MR, for the Steering Committees of the Pentasaccharide Orthopedic Prophylaxis Studies. Fondaparinux vs enoxaparin for the prevention of venous thromboembolism in major orthopedic surgery. Arch Intern Med 2002; 162:1833–1840.
  35. Stein PD, Beemath A, Matta F, et al. Clinical characteristics of patients with acute pulmonary embolism: data from PIOPED II. Am J Med 2007; 120:871–879.
  36. Goldhaber SZ. Diagnosis of acute pulmonary embolism: always be vigilant. Am J Med 2007; 120:827–828.
  37. American Academy of Orthopaedic Surgeons Clinical Guideline on Prevention of Symptomatic Pulmonary Embolism in Patients Undergoing Total Hip or Knee Arthroplasty: Summary of Recommendations. http://www.aaos.org/Research/guidelines/PE_ summary.pdf. Accessed December 10, 2007.
Article PDF
Author and Disclosure Information

Steven B. Deitelzweig, MD
Vice President of Medical Affairs; Chairman, Department of Hospital Medicine, Ochsner Health System, New Orleans, LA

Sylvia C. McKean, MD
Medical Director, BWH/Faulkner Hospitalist Service; Associate Professor of Medicine, Harvard Medical School and Brigham and Women’s Hospital, Boston, MA

Alpesh N. Amin, MD, MBA
Professor and Chief, Division of General Internal Medicine; Executive Director, Hospitalist Program; Vice Chair for Clinical Affairs & Quality, Department of Medicine, University of California, Irvine, Irvine, CA

Daniel J. Brotman, MD
Director, Hospitalist Program; Associate Professor of Medicine, Johns Hopkins Hospital, Baltimore, MD

Amir K. Jaffer, MD
Associate Professor of Medicine; Chief, Division of Hospital Medicine, Department of Medicine, Leonard M. Miller School of Medicine, University of Miami, Miami, FL

Alex C. Spyropoulos, MD
Chair, Clinical Thrombosis Center, Lovelace Medical Center; Clinical Associate Professor of Medicine/Associate Professor of Pharmacy, University of New Mexico Health Sciences Center/College of Pharmacy, Albuquerque, NM

Correspondence: Steven B. Deitelzweig, MD, Vice President of Medical Affairs and Chairman, Department of Hospital Medicine, Ochsner Health System, 1514 Jefferson Highway, New Orleans, LA 70121; [email protected]

Drs. Deitelzweig and McKean each reported that they have received honoraria for teaching/speaking from Sanofi-Aventis.

Dr. Amin reported that he has received research funding and honoraria for speaking from Sanofi-Aventis, Eisai, and GlaxoSmithKline.

Dr. Brotman reported that he has no financial relationships with commercial interests that are relevant to this article.

Dr. Jaffer reported that he has received consulting fees and honoraria for teaching/speaking from Sanofi-Aventis, consulting fees and research grant support from AstraZeneca, and consulting fees from Roche Diagnostics and Boehringer Ingelheim; he also serves on the governing board of the Society for Perioperative Assessment and Quality Improvement (SPAQI) and the board of directors of the Anticoagulation Forum.

Dr. Spyropoulos reported that he has received consulting fees from Sanofi-Aventis, Eisai, and Boehringer Ingelheim.

Each author received an honorarium for participating in the roundtable that formed the basis of this supplement. The honoraria were paid by the Cleveland Clinic Center for Continuing Education from the educational grant from Sanofi-Aventis underwriting this supplement. Sanofi-Aventis had no input on the content of the roundtable or this supplement.

Publications
Page Number
S27-S36
Author and Disclosure Information

Steven B. Deitelzweig, MD
Vice President of Medical Affairs; Chairman, Department of Hospital Medicine, Ochsner Health System, New Orleans, LA

Sylvia C. McKean, MD
Medical Director, BWH/Faulkner Hospitalist Service; Associate Professor of Medicine, Harvard Medical School and Brigham and Women’s Hospital, Boston, MA

Alpesh N. Amin, MD, MBA
Professor and Chief, Division of General Internal Medicine; Executive Director, Hospitalist Program; Vice Chair for Clinical Affairs & Quality, Department of Medicine, University of California, Irvine, Irvine, CA

Daniel J. Brotman, MD
Director, Hospitalist Program; Associate Professor of Medicine, Johns Hopkins Hospital, Baltimore, MD

Amir K. Jaffer, MD
Associate Professor of Medicine; Chief, Division of Hospital Medicine, Department of Medicine, Leonard M. Miller School of Medicine, University of Miami, Miami, FL

Alex C. Spyropoulos, MD
Chair, Clinical Thrombosis Center, Lovelace Medical Center; Clinical Associate Professor of Medicine/Associate Professor of Pharmacy, University of New Mexico Health Sciences Center/College of Pharmacy, Albuquerque, NM

Correspondence: Steven B. Deitelzweig, MD, Vice President of Medical Affairs and Chairman, Department of Hospital Medicine, Ochsner Health System, 1514 Jefferson Highway, New Orleans, LA 70121; [email protected]

Drs. Deitelzweig and McKean each reported that they have received honoraria for teaching/speaking from Sanofi-Aventis.

Dr. Amin reported that he has received research funding and honoraria for speaking from Sanofi-Aventis, Eisai, and GlaxoSmithKline.

Dr. Brotman reported that he has no financial relationships with commercial interests that are relevant to this article.

Dr. Jaffer reported that he has received consulting fees and honoraria for teaching/speaking from Sanofi-Aventis, consulting fees and research grant support from AstraZeneca, and consulting fees from Roche Diagnostics and Boehringer Ingelheim; he also serves on the governing board of the Society for Perioperative Assessment and Quality Improvement (SPAQI) and the board of directors of the Anticoagulation Forum.

Dr. Spyropoulos reported that he has received consulting fees from Sanofi-Aventis, Eisai, and Boehringer Ingelheim.

Each author received an honorarium for participating in the roundtable that formed the basis of this supplement. The honoraria were paid by the Cleveland Clinic Center for Continuing Education from the educational grant from Sanofi-Aventis underwriting this supplement. Sanofi-Aventis had no input on the content of the roundtable or this supplement.

Author and Disclosure Information

Steven B. Deitelzweig, MD
Vice President of Medical Affairs; Chairman, Department of Hospital Medicine, Ochsner Health System, New Orleans, LA

Sylvia C. McKean, MD
Medical Director, BWH/Faulkner Hospitalist Service; Associate Professor of Medicine, Harvard Medical School and Brigham and Women’s Hospital, Boston, MA

Alpesh N. Amin, MD, MBA
Professor and Chief, Division of General Internal Medicine; Executive Director, Hospitalist Program; Vice Chair for Clinical Affairs & Quality, Department of Medicine, University of California, Irvine, Irvine, CA

Daniel J. Brotman, MD
Director, Hospitalist Program; Associate Professor of Medicine, Johns Hopkins Hospital, Baltimore, MD

Amir K. Jaffer, MD
Associate Professor of Medicine; Chief, Division of Hospital Medicine, Department of Medicine, Leonard M. Miller School of Medicine, University of Miami, Miami, FL

Alex C. Spyropoulos, MD
Chair, Clinical Thrombosis Center, Lovelace Medical Center; Clinical Associate Professor of Medicine/Associate Professor of Pharmacy, University of New Mexico Health Sciences Center/College of Pharmacy, Albuquerque, NM

Correspondence: Steven B. Deitelzweig, MD, Vice President of Medical Affairs and Chairman, Department of Hospital Medicine, Ochsner Health System, 1514 Jefferson Highway, New Orleans, LA 70121; [email protected]

Drs. Deitelzweig and McKean each reported that they have received honoraria for teaching/speaking from Sanofi-Aventis.

Dr. Amin reported that he has received research funding and honoraria for speaking from Sanofi-Aventis, Eisai, and GlaxoSmithKline.

Dr. Brotman reported that he has no financial relationships with commercial interests that are relevant to this article.

Dr. Jaffer reported that he has received consulting fees and honoraria for teaching/speaking from Sanofi-Aventis, consulting fees and research grant support from AstraZeneca, and consulting fees from Roche Diagnostics and Boehringer Ingelheim; he also serves on the governing board of the Society for Perioperative Assessment and Quality Improvement (SPAQI) and the board of directors of the Anticoagulation Forum.

Dr. Spyropoulos reported that he has received consulting fees from Sanofi-Aventis, Eisai, and Boehringer Ingelheim.

Each author received an honorarium for participating in the roundtable that formed the basis of this supplement. The honoraria were paid by the Cleveland Clinic Center for Continuing Education from the educational grant from Sanofi-Aventis underwriting this supplement. Sanofi-Aventis had no input on the content of the roundtable or this supplement.

Article PDF
Article PDF
Related Articles

Nearly half of orthopedic surgery patients do not receive appropriate prophylaxis for venous thromboembolism (VTE), as defined by American College of Chest Physicians (ACCP) consensus guidelines, according to a recent analysis of a nationwide database of hospital admissions.1 Even in teaching hospitals, compliance with consensus guidelines for thromboprophylaxis is suboptimal. In a study of adherence to the ACCP guidelines for VTE prevention among 1,907 surgical patients at 10 teaching hospitals, only 45.2% of hip fracture patients received optimal VTE prophylaxis.2 Rates of optimal prophylaxis were higher among patients undergoing hip arthroplasty and knee arthroplasty—84.3% and 75.9%, respectively—but were still in need of improvement.2

GROWING INTEREST IN POSTOPERATIVE VTE PROPHYLAXIS AS A QUALITY INDICATOR

As noted in the introductory article in this supplement, the Joint Commission on Accreditation of Healthcare Organizations has taken notice of these shortcomings and has proposed national consensus standards for VTE prevention and treatment.3 Among its proposed standards are two related to risk assessment and prophylaxis: whether risk assessment/prophylaxis is ordered within 24 hours of hospital admission and within 24 hours of transfer to the intensive care unit.

Other quality-monitoring initiatives are focused specifically on VTE in the surgical population. The Surgical Care Improvement Project (SCIP) has approved two quality measures with respect to VTE prevention: (1) the proportion of surgical patients for whom recommended VTE prophylaxis is ordered, and (2) the proportion of patients who receive appropriate VTE prophylaxis (based on ACCP guideline recommendations) within 24 hours before or after surgery.4

In the future, two other VTE-related quality measures from SCIP may be implemented by the Centers for Medicare and Medicaid Services: (1) how often intra- or postoperative pulmonary embolism (PE) is diagnosed during the index hospitalization and within 30 days of surgery, and (2) how often intra- or postoperative deep vein thrombosis (DVT) is diagnosed during the index hospitalization and within 30 days of surgery.5

VTE RISK IN ORTHOPEDIC SURGERY

Surgical patients can be stratified into four VTE risk levels—low, moderate, high, and highest—based on age, surgery type, surgery duration, duration of immobilization, and other risk factors.6 For patients undergoing orthopedic surgery, these levels may be defined according to the following patient and surgical characteristics:

  • Low risk—surgery duration of less than 30 minutes, age less than 40 years, repair of small fractures
  • Moderate risk—age of 40 to 60 years, arthroscopy or repair of lower leg fractures, postoperative plaster cast
  • High risk—age greater than 60 years, or age 40 to 60 years with additional VTE risk factors, or immobilization for greater than 4 days
  • Highest risk—hip or knee arthroplasty, hip fracture repair, repair of open lower leg fractures, major trauma or spinal cord injury, or multiple risk factors for VTE (age > 40 years, prior VTE, cancer, or hypercoagulable state).

For patients in the low-risk category, no specific prophylaxis is indicated beyond early and aggressive ambulation.6 For those in all other risk categories, prophylaxis with pharmacologic anticoagulant agents and/or mechanical devices is indicated, as reviewed below.

All major orthopedic procedures confer highest risk level

Notably, the “highest risk” category includes any patient undergoing hip or knee arthroplasty or hip fracture repair. Among orthopedic surgery patients in this highest-risk category, rates of VTE events in the absence of prophylaxis are as follows:6

  • Calf DVT, 40% to 80%
  • Proximal DVT, 10% to 20%
  • Clinical PE, 4% to 10%
  • Fatal PE, 0.2% to 5%.

Hip replacement poses greater risk than knee replacement

Within this overall highest-risk category, thromboembolic risk in the absence of prophylaxis differs among procedures. Although patients undergoing hip replacement and those undergoing knee replacement have similar rates of DVT of any type,6,7 hip replacement is associated with higher rates of the more clinically important events, specifically proximal DVT and PE. In the absence of prophylaxis, proximal DVT occurs in 23% to 36% of hip replacement patients as opposed to 9% to 20% of knee replacement patients; similarly, PE occurs in 0.7% to 30% of hip replacement patients as compared with 1.8% to 7.0% of knee replacement patients.6,7

What about bleeding risk?

For many orthopedic surgeons, the risk of bleeding as a result of anticoagulant prophylaxis of VTE looms larger than the risk of VTE itself. This is likely because bleeding, when it does occur, is likely to occur more acutely than VTE does and may directly compromise the result of the operation. For this reason, orthopedic surgeons may be more likely to actually witness bleeding events than VTE events (especially fatal PEs) while their patients are still under their care, leading to a misperception of the relative risks of anticoagulation-related bleeding and thromboembolism.

In reality, rates of major bleeding with pharmacologic prophylaxis of VTE are a tiny fraction of the above-listed rates of VTE events in the absence of prophylaxis in patients undergoing major orthopedic surgery. Reported 30-day rates of major bleeding in patients receiving VTE prophylaxis with heparins range from 0.2% to 1.7%; these rates barely differ from the rates among placebo recipients in the same VTE prophylaxis trials, which range from 0.2% to 1.5%.8,9 Additionally, within the continuum of risk of major bleeding from various medical interventions, VTE prophylaxis with heparins is one of the lowest-risk interventions, posing far less risk than, for example, the use of warfarin in ischemic stroke patients or in patients older than 75 years.

 

 

PHARMACOLOGIC OPTIONS FOR VTE PROPHYLAXIS IN ORTHOPEDIC SURGERY

As reviewed in the introductory article of this supplement, the arsenal of anticoagulants for use in VTE prophylaxis includes low-dose unfractionated heparin (UFH), low-molecular-weight heparin (LMWH) agents such as dalteparin and enoxaparin, and the factor Xa inhibitor fondaparinux. A few additional comments about these and other anticoagulant options is warranted in the specific context of orthopedic surgery.

Fondaparinux. Because most of its formal US indications are for use as VTE prophylaxis in major orthopedic surgery—including hip replacement, knee replacement, and hip fracture repair—fondaparinux has been studied more widely in orthopedic surgery patients than in the other populations reviewed earlier in this supplement. Nevertheless, its use even in these settings has remained somewhat limited. This may be because of concerns over possible increased bleeding risk relative to some other anticoagulants. Because of bleeding risk, fondaparinux is contraindicated in patients who weigh less than 50 kg, and its package insert recommends caution when it is used in the elderly due to an increased risk of bleeding in patients aged 65 or older. Additionally, the Pentasaccharide in Major Knee Surgery (PENTAMAKS) study found fondaparinux to be associated with a significantly higher incidence of major bleeding compared with enoxaparin (2.1% vs 0.2%; P = .006) in major knee surgery, although it was superior to enoxaparin in preventing VTE.10 Other possible reasons for slow adoption of fondaparinux include its long half-life, which results in a sustained antithrombotic effect, its lack of easy reversibility, and a contraindication in patients with renal insufficiency.11

Limited role for UFH. Low-dose UFH has a more limited role in orthopedic surgery than in other settings requiring VTE prophylaxis, as current ACCP guidelines for VTE prevention recognize it only as a possible option in hip fracture surgery and state that it is not to be considered as sole prophylaxis in patients undergoing hip or knee replacement.6

Warfarin. Although not indicated for use in other VTE prophylaxis settings, the vitamin K antagonist warfarin is recommended as an option for all three major orthopedic surgery indications—knee replacement, hip replacement, and hip fracture repair.6

The key to effective prophylaxis with warfarin is achieving the appropriate intensity of anticoagulation. In two separate analyses, Hylek et al demonstrated a balance between safety and efficacy with warfarin therapy targeted to an international normalized ratio (INR) of 2.0 to 3.0.12,13 An INR greater than 4.0 greatly increased the risk of intracranial hemorrhage, whereas thrombosis was not effectively prevented with an INR less than 2.0.12,13 This latter point should be stressed to orthopedic surgeons, who sometimes aim for INR values below 2.0.

Although anticoagulation clinics are superior to usual care at maintaining the INR within the window of 2.0 to 3.0, only about one-third of patients nationally who take warfarin receive care in such clinics.14 Even with optimal care in anticoagulation clinics, some patients will still receive subtherapeutic or supertherapeutic levels of warfarin, which is one of this agent’s limitations.

Aspirin not recommended as sole agent. Although aspirin is still used as thromboprophylaxis in orthopedic surgery patients, current ACCP guidelines recommend against its use as the sole means of VTE prophylaxis in any patient group.6 The limitations of the evidence for aspirin in this setting are illustrated by the Pulmonary Embolism Prevention study, a multicenter randomized trial in patients undergoing hip fracture (n = 13,356) or hip/knee replacement (n = 4,088).15 Patients received aspirin 160 mg/day or placebo for 5 weeks, starting preoperatively, and were evaluated for outcomes at day 35. Among the hip fracture patients, the rate of symptomatic DVT was lower in the aspirin group than in the placebo group (1.0% vs 1.5%; P = .03), as was the rate of PE (0.7% vs 1.2%, respectively; P = .002), but there was no significant difference in outcomes between the groups among the patients undergoing hip or knee replacement. Notably, 40% of patients in the study also received UFH or LMWH. Further confounding the results, some patients received nonpharmacologic VTE prophylaxis modalities, and others received nonsteroidal anti-inflammatory drugs other than aspirin.

Heparin-induced thrombocytopenia. As noted earlier in this supplement, the incidence of heparin-induced thrombocytopenia (HIT) is markedly higher in patients who receive UFH than in those who receive LMWH. This difference in frequency, which constitutes about a sixfold to eightfold differential, is due to the relationship between standard heparin and platelet factor IV, which can induce formation of IgG antibodies.16 A 50% or greater reduction in platelet count in heparin recipients should prompt consideration of HIT.

Oral direct thrombin inhibitors. Although the oral direct thrombin inhibitor ximelagatran was rejected for approval by the US Food and Drug Administration (FDA) and recently withdrawn from the market world­wide as a result of hepatic risks, other oral direct thrombin inhibitors are in phase 3 studies for use in orthopedic surgery and may be commercially available options for postoperative VTE prophylaxis before long.

GUIDELINES FOR VTE PROPHYLAXIS IN ORTHOPEDIC SURGERY

The ACCP guidelines referred to throughout this article are widely recognized as a practice standard for VTE prevention and treatment, and have been regularly updated throughout recent decades. The most recent version, issued in 2004, is formally known as the Seventh ACCP Conference on Antithrombotic and Thrombolytic Therapy.6 Key orthopedic surgery-related recommendations and notable changes from the previous version of the guidelines, issued in 2001, are outlined below, along with pertinent supportive or illustrative studies.

Hip replacement surgery

For all patients undergoing elective hip replacement surgery, routine use of either LMWH, fondaparinux, or warfarin is recommended (see Table 1 for recommended dosing). Each of these options is given a Grade 1A recommendation, the guidelines’ highest level of endorsement, indicating evidence from randomized controlled trials (RCTs) without important limitations. None of these options is recommended as superior to the other two. The guidelines recommend against the use of any other option, including UFH and mechanical devices, as the sole method of prophylaxis in these patients.6

In a change from the previous guidelines, the Seventh ACCP Conference recommends extended prophylaxis, for up to 28 to 35 days after surgery, for patients undergoing hip replacement or hip fracture surgery. For hip replacement surgery, this is a Grade 1A recommendation for prophylaxis with either LMWH or warfarin and a Grade 1C+ recommendation (“no RCTs but strong RCT results can be unequivocally extrapolated, or overwhelming evidence from observational studies”) for prophylaxis with fondaparinux.6

Reprinted, with permission, from Annals of Internal Medicine (Hull et al, 2001).17
Figure 1. Relative risk (and 95% confidence intervals) for all deep vein thrombosis during the out-of-hospital time interval (up to 28 to 35 days after surgery) with extended-duration low-molecular-weight heparin (LMWH) therapy compared with standard-duration LMWH therapy. Results are from six randomized trials of extended prophylaxis in patients undergoing total hip replacement. The risk reduction with extended-duration prophylaxis was statistically significant in all six trials.
The compelling evidence base for extended prophylaxis with LMWH in this setting was demonstrated in a systematic review of six double-blind, randomized, placebo-controlled trials, as illustrated in Figure 1.17 Additionally, a Belgian cost-utility analysis in patients who underwent total hip or knee replacement showed that extended prophylaxis with enoxaparin (30 days) carried an incremental cost of $6,386 (US dollars) per quality-adjusted life-year compared with standard-duration enoxaparin prophylaxis (12 days), a cost that was well below the “willingness to pay” threshold of $18,200 per quality-adjusted life-year used in European guidelines for cost-effectiveness.18

 

 

Knee replacement surgery

The same three anticoagulant options that received Grade 1A recommendations for patients undergoing total hip replacement—LMWH, fondaparinux, and adjusted-dose warfarin—are also given Grade 1A recommendations as routine thromboprophylaxis in patients undergoing elective knee replacement (see Table 1 for dosing). In addition, optimal use of intermittent pneumatic compression devices is recommended as an alternative option to anticoagulant prophylaxis in these patients (Grade 1B, indicating a “strong recommendation” based on RCTs with important limitations). Use of UFH as the sole agent for prophylaxis is recommended against.6

For both hip and knee replacement surgery, the Seventh ACCP Conference does not endorse superiority of any one of its three recommended prophylaxis options—LMWH, fondaparinux, and adjusted-dose warfarin—over the other two. However, at least four large randomized trials have directly compared LMWH and adjusted-dose warfarin in the setting of arthroplasty—two in total hip replacement surgery19,20 and two in total knee replacement surgery.21,22 Each of these four studies found LMWH to be significantly more effective than warfarin in preventing VTE. In three of the four trials, there was no significant difference between the therapies in rates of major bleeding.19,21,22 In the remaining trial, which was conducted in hip replacement surgery patients and compared postoperative warfarin with dalteparin initiated either immediately before or early after surgery, patients who received preoperative dalteparin initiation (but not those who received postoperative dalteparin initiation) had an increased rate of major bleeding compared with warfarin recipients (P = .01).20

Hip fracture surgery

The supportive evidence for anticoagulant prophylaxis in hip fracture surgery is less robust than that in hip and knee replacement surgery. As a result, only fondaparinux has a Grade 1A recommendation as routine prophylaxis in patients undergoing hip fracture surgery. Options with less definitive recommendations are LMWH (Grade 1C+), low-dose UFH (Grade 1B), and adjusted-dose warfarin (Grade 2B, indicating a “weak recommendation” based on RCTs with important limitations) (see Table 1 for dosing of all agents).6

These differing recommendations are supported by the double-blind Pentasaccharide in Hip Fracture Surgery Study (PENTHIFRA) of 1,711 consecutive patients undergoing surgery for hip fracture repair.23 Patients were randomized to at least 5 days of fondaparinux 2.5 mg once daily, initiated postoperatively, or enoxaparin 40 mg once daily, initiated preoperatively. The incidence of DVT or PE by postoperative day 11 was 8.3% in the fondaparinux arm versus 19.1% in the enoxaparin arm, a statistically significant difference (P < .001) in favor of fondaparinux. There were no differences between the groups in rates of death or clinically relevant bleeding.

As noted above, the newly added recommendation in the Seventh ACCP Conference for extended prophylaxis, for up to 28 to 35 days after surgery, applies to patients undergoing hip fracture surgery as well as those undergoing hip replacement surgery. In the setting of hip fracture repair, extended prophylaxis is a Grade 1A recommendation with the use of fondaparinux and a Grade 1C+ recommendation with the use of either LMWH or adjusted-dose warfarin.6

Lower extremity fractures and trauma

Although lower extremity fractures are very common, the risk of DVT has been poorly studied in this setting. For patients with isolated lower extremity fractures, the Seventh ACCP Conference recommends that clinicians not use thromboprophylaxis routinely (Grade 2A, indicating an “intermediate-strength recommendation” based on RCTs without important limitations).6

Trauma patients, in contrast, are well recognized as being at very high risk for DVT and PE. The Seventh ACCP Conference gives a Grade 1A recommendation to thromboprophylaxis for all trauma patients who have at least one risk factor for VTE. LMWH is recommended (Grade 1A) as the agent of choice for this purpose, provided there are no contraindications to its use, and should be administered as soon as safely possible. Mechanical modalities are reserved for trauma patients with active bleeding or high risk for hemorrhage (Grade 1B). The guidelines recommend against use of inferior vena cava (IVC) filters as primary thromboprophylaxis in trauma patients (Grade 1C, indicating an “intermediate-strength recommendation” based on observational studies).6

Use of ultrasonography

Duplex ultrasonographic screening is recommended in orthopedic trauma patients who are at high risk for VTE and have received suboptimal or no prophylaxis (Grade 1C). In contrast, the Seventh ACCP Conference recommends against routine use of duplex ultrasonography to screen for VTE at hospital discharge in asymptomatic patients following major orthopedic surgery (Grade 1A).6

Knee arthroscopy

Arthroscopic knee procedures are increasing in frequency and raise the specter of a potential role for thromboprophylaxis. However, the clinical diagnosis of DVT is unreliable, and even diagnosis by ultrasonography is unreliable following knee arthroscopy, as interpreting scans of veins below the knee is challenging in this setting.24

The Seventh ACCP Conference recommends that clinicians not use routine thromboprophylaxis, other than early mobilization, for patients who undergo knee arthroscopy (Grade 2B). However, for arthroscopy patients who have inherent risk factors for VTE or who undergo a prolonged or complicated arthroscopy procedure, thromboprophylaxis with LMWH is suggested (Grade 2B).6

RECOMMENDED APPROACH TO VTE PROPHYLAXIS IN ORTHOPEDIC SURGERY

Drawing on the ACCP guidelines and the evidence reviewed above, we have outlined our evidence-based recommendations for pharmacologic VTE prophylaxis in patients undergoing orthopedic surgery, as presented in Table 1. All patients undergoing major orthopedic surgical procedures (ie, procedures other than arthroscopy) should routinely receive anticoagulant prophylaxis unless they have contraindications to anticoagulation. Recommended agents and their duration of use vary according to the type of surgery, as detailed in Table 1.

Extended-duration prophylaxis is recommended for patients undergoing total hip replacement and hip fracture surgery. Aspirin is not recommended as the sole agent for prophylaxis in any orthopedic surgery setting.

Importance of a postoperative prophylaxis protocol

In addition to these broad pharmacologic recommendations, it is important that a postoperative VTE prophylaxis protocol be in place at all hospitals.

At the Ochsner Medical Center in New Orleans, where one of us (S.B.D.) practices, postoperative orders include antithrombotic therapy for surgical patients, starting with placement of thigh-high antiembolism stockings on both legs on the day of surgery for patients undergoing hip replacement and on postoperative day 1 in those undergoing knee replacement. Plantar pneumatic compression devices are applied to both legs in the recovery room and kept on except when the patient is walking. The hospitalist team dictates further anticoagulation orders. If extended prophylaxis is prescribed, the discharge planner sets up drug delivery and reimbursement, provides a LMWH discharge kit, and teaches the patient to self-inject. If there is concern about increasing swelling at the surgical site while anticoagulant therapy continues, the protocol calls for prompt notification of the responsible physician. To minimize the risk that spinal or epidural hematomas will develop, all agents that increase bleeding propensity should be recognized and ordered accordingly.

 

 

SUMMARY

VTE in patients undergoing major orthopedic surgery is a serious health problem that is highly preventable, yet VTE prophylaxis remains underused in this patient population. Despite the availability of practice guidelines for VTE prevention in the orthopedic surgery setting, recommendations are not widely implemented in clinical practice. Recommended prophylactic options differ somewhat among various orthopedic procedures, and the supportive evidence differs for various anticoagulant options.

DISCUSSION: ADDITIONAL PERSPECTIVES FROM THE AUTHORS

Dr. Jaffer: The ACCP recommends against the routine use of aspirin as primary prophylaxis against VTE in major orthopedic surgery, yet orthopedic surgeons across the country still continue to use aspirin in this setting. What are your thoughts on this, Dr. McKean?

Dr. McKean: We agree with the ACCP’s recommendation against aspirin as primary VTE prophylaxis in orthopedic patients. The percentage of US knee arthroplasty patients who develop VTE after receiving no prophylaxis at all is roughly 64%; this percentage declines only slightly (to 56%) for knee arthroplasty patients who receive prophylaxis with aspirin.25 Since we clearly want to reduce VTE risk as much as possible, I would not use aspirin alone. I would use it only if the patient were already on aspirin, but then I would add either LMWH or fondaparinux.

Dr. Jaffer: Warfarin is another agent that is widely used for prophylaxis in major orthopedic surgery. In fact, the large registries of VTE prevention in major orthopedic surgery suggest that the use of warfarin may be slightly higher than the use of LMWH. If clinicians choose to use warfarin in their practice, what are your recommendations, Dr. Deitelzweig?

Dr. Deitelzweig: As primary prophylaxis for orthopedic surgery patients, warfarin must be dosed to achieve an INR of 2.0 to 3.0; the need for a value in this range is unequivocal. This is a challenging target to attain in the hospital setting.

Dr. Brotman: A study I was involved with a few years ago suggested that warfarin may be inadequate for VTE prevention in the first few days after orthopedic surgery.26 Orthopedic surgeons at the Cleveland Clinic, where I was practicing at the time, routinely used systematic ultrasonography to assess for thrombosis on postoperative day 2 or 3 following hip or knee arthroplasty, so we conducted a secondary analysis of a case-control study in these ultrasonographically screened arthroplasty patients to assess rates of early VTE and look for any associations with the type of prophylaxis used. We found that there was about a tenfold increase in the risk of VTE, both distal and proximal, on postoperative day 2 or 3 among patients who received warfarin compared with those who received LMWH. We concluded that warfarin’s delayed antithrombotic effects may not provide sufficient VTE prophylaxis in the immediate postoperative setting.26

Dr. Deitelzweig: That’s a good point. Although it’s important to achieve a therapeutic level of warfarin, we now have evidence that it takes some time to achieve that level, and in the interim, bad things can happen to patients.

Dr. Jaffer: Orthopedic surgery encompasses several types of procedures. Dr. Amin, which specific orthopedic surgery patients stand to benefit from extended prophylaxis, and how long should extended prophylaxis last?

Dr. Amin: Major orthopedic surgery comprises hip fracture repair, total hip replacement, and total knee replacement. For hip fracture, there are strong data to support the use of extended prophylaxis with fondaparinux 2.5 mg/day, which showed about an 88% relative reduction in the risk of symptomatic VTE compared with standard-duration fondaparinux (6 to 8 days) followed by matching placebo for the extended phase.27 The total duration of fondaparinux therapy in the extended-duration arm was 4 to 5 weeks.

Likewise, data support extended prophylaxis in hip arthroplasty patients, for whom the recommended duration is also 4 to 5 weeks. The systematic review by Hull et al17 demonstrated a 0.41 relative risk of DVT with extended-duration LMWH prophylaxis versus placebo in hip replacement patients (Figure 1), which was a highly statistically significant result.

In contrast, we do not yet have good data to support extended prophylaxis for patients undergoing total knee replacement, which is a bit surprising. In this setting, prophylaxis is recommended for 7 to 14 days but not beyond that.

Dr. Jaffer: Arthroscopy is probably the most common orthopedic procedure performed in the United States today. Dr. Brotman, what is the role of prophylaxis in patients undergoing arthroscopy?

Dr. Brotman: Minor surgery such as arthroscopy can typically be performed safely without routine prophylaxis, other than having the patient ambulate as soon as possible after the procedure. There may be exceptions to this rule, however. I believe that there is potentially a role for pharmacologic prophylaxis in arthroscopy patients who have major risk factors for VTE, such as a personal history of VTE, or who are not expected to become mobile again in a normal rapid fashion after the operation, but prophylaxis has not been studied systematically in such patients.

Dr. Jaffer: Dr. Spyropoulos, there are several new anticoagulants in the pipeline, specifically agents such as the oral direct factor Xa inhibitors and the direct thrombin inhibitors. What do recent clinical trials suggest with regard to the efficacy of these two drug classes for thromboprophylaxis in major orthopedic surgery?

Dr. Spyropoulos: The agents with the most available data are the oral direct factor Xa inhibitors apixaban and rivaroxaban and the oral direct thrombin inhibitor dabigatran. For prophylaxis in orthopedic surgery populations, phase 2 studies have been completed for apixaban and phase 3 trials have been completed for rivaroxaban and dabigatran.

It appears that the factor Xa inhibitors, apixaban and rivaroxaban, are efficacious in comparison with both adjusted-dose warfarin and LMWH, which is the gold standard for this group of patients.28,29 So these indeed appear to be promising agents. Rivaroxaban has been submitted to European regulatory agencies for approval for the prevention of VTE in patients undergoing major orthopedic surgery, and its developer plans to submit it to the FDA in 2008 for a similar indication in the United States.

The data are more equivocal with dabigatran. There have been several positive phase 3 studies in orthopedic surgery comparing two dabigatran dosing schemes, 150 and 220 mg once daily, with the European regimen of enoxaparin (40 mg once daily),30 but a recent study that compared these doses with the North American enoxaparin regimen (30 mg twice daily) failed to meet the criteria for noninferiority.31 Further clinical trial development is necessary for dabigatran, although in January 2008 the European Medicines Agency recommended its marketing approval for thromboprophylaxis in patients undergoing orthopedic procedures.32

I believe that in the next 3 to 5 years our armamentarium will see the addition of at least one, if not more, of these new agents that offer the promise of oral anticoagulation with highly predictable pharmacokinetics and pharmacodynamics and no need for monitoring.

Nearly half of orthopedic surgery patients do not receive appropriate prophylaxis for venous thromboembolism (VTE), as defined by American College of Chest Physicians (ACCP) consensus guidelines, according to a recent analysis of a nationwide database of hospital admissions.1 Even in teaching hospitals, compliance with consensus guidelines for thromboprophylaxis is suboptimal. In a study of adherence to the ACCP guidelines for VTE prevention among 1,907 surgical patients at 10 teaching hospitals, only 45.2% of hip fracture patients received optimal VTE prophylaxis.2 Rates of optimal prophylaxis were higher among patients undergoing hip arthroplasty and knee arthroplasty—84.3% and 75.9%, respectively—but were still in need of improvement.2

GROWING INTEREST IN POSTOPERATIVE VTE PROPHYLAXIS AS A QUALITY INDICATOR

As noted in the introductory article in this supplement, the Joint Commission on Accreditation of Healthcare Organizations has taken notice of these shortcomings and has proposed national consensus standards for VTE prevention and treatment.3 Among its proposed standards are two related to risk assessment and prophylaxis: whether risk assessment/prophylaxis is ordered within 24 hours of hospital admission and within 24 hours of transfer to the intensive care unit.

Other quality-monitoring initiatives are focused specifically on VTE in the surgical population. The Surgical Care Improvement Project (SCIP) has approved two quality measures with respect to VTE prevention: (1) the proportion of surgical patients for whom recommended VTE prophylaxis is ordered, and (2) the proportion of patients who receive appropriate VTE prophylaxis (based on ACCP guideline recommendations) within 24 hours before or after surgery.4

In the future, two other VTE-related quality measures from SCIP may be implemented by the Centers for Medicare and Medicaid Services: (1) how often intra- or postoperative pulmonary embolism (PE) is diagnosed during the index hospitalization and within 30 days of surgery, and (2) how often intra- or postoperative deep vein thrombosis (DVT) is diagnosed during the index hospitalization and within 30 days of surgery.5

VTE RISK IN ORTHOPEDIC SURGERY

Surgical patients can be stratified into four VTE risk levels—low, moderate, high, and highest—based on age, surgery type, surgery duration, duration of immobilization, and other risk factors.6 For patients undergoing orthopedic surgery, these levels may be defined according to the following patient and surgical characteristics:

  • Low risk—surgery duration of less than 30 minutes, age less than 40 years, repair of small fractures
  • Moderate risk—age of 40 to 60 years, arthroscopy or repair of lower leg fractures, postoperative plaster cast
  • High risk—age greater than 60 years, or age 40 to 60 years with additional VTE risk factors, or immobilization for greater than 4 days
  • Highest risk—hip or knee arthroplasty, hip fracture repair, repair of open lower leg fractures, major trauma or spinal cord injury, or multiple risk factors for VTE (age > 40 years, prior VTE, cancer, or hypercoagulable state).

For patients in the low-risk category, no specific prophylaxis is indicated beyond early and aggressive ambulation.6 For those in all other risk categories, prophylaxis with pharmacologic anticoagulant agents and/or mechanical devices is indicated, as reviewed below.

All major orthopedic procedures confer highest risk level

Notably, the “highest risk” category includes any patient undergoing hip or knee arthroplasty or hip fracture repair. Among orthopedic surgery patients in this highest-risk category, rates of VTE events in the absence of prophylaxis are as follows:6

  • Calf DVT, 40% to 80%
  • Proximal DVT, 10% to 20%
  • Clinical PE, 4% to 10%
  • Fatal PE, 0.2% to 5%.

Hip replacement poses greater risk than knee replacement

Within this overall highest-risk category, thromboembolic risk in the absence of prophylaxis differs among procedures. Although patients undergoing hip replacement and those undergoing knee replacement have similar rates of DVT of any type,6,7 hip replacement is associated with higher rates of the more clinically important events, specifically proximal DVT and PE. In the absence of prophylaxis, proximal DVT occurs in 23% to 36% of hip replacement patients as opposed to 9% to 20% of knee replacement patients; similarly, PE occurs in 0.7% to 30% of hip replacement patients as compared with 1.8% to 7.0% of knee replacement patients.6,7

What about bleeding risk?

For many orthopedic surgeons, the risk of bleeding as a result of anticoagulant prophylaxis of VTE looms larger than the risk of VTE itself. This is likely because bleeding, when it does occur, is likely to occur more acutely than VTE does and may directly compromise the result of the operation. For this reason, orthopedic surgeons may be more likely to actually witness bleeding events than VTE events (especially fatal PEs) while their patients are still under their care, leading to a misperception of the relative risks of anticoagulation-related bleeding and thromboembolism.

In reality, rates of major bleeding with pharmacologic prophylaxis of VTE are a tiny fraction of the above-listed rates of VTE events in the absence of prophylaxis in patients undergoing major orthopedic surgery. Reported 30-day rates of major bleeding in patients receiving VTE prophylaxis with heparins range from 0.2% to 1.7%; these rates barely differ from the rates among placebo recipients in the same VTE prophylaxis trials, which range from 0.2% to 1.5%.8,9 Additionally, within the continuum of risk of major bleeding from various medical interventions, VTE prophylaxis with heparins is one of the lowest-risk interventions, posing far less risk than, for example, the use of warfarin in ischemic stroke patients or in patients older than 75 years.

 

 

PHARMACOLOGIC OPTIONS FOR VTE PROPHYLAXIS IN ORTHOPEDIC SURGERY

As reviewed in the introductory article of this supplement, the arsenal of anticoagulants for use in VTE prophylaxis includes low-dose unfractionated heparin (UFH), low-molecular-weight heparin (LMWH) agents such as dalteparin and enoxaparin, and the factor Xa inhibitor fondaparinux. A few additional comments about these and other anticoagulant options is warranted in the specific context of orthopedic surgery.

Fondaparinux. Because most of its formal US indications are for use as VTE prophylaxis in major orthopedic surgery—including hip replacement, knee replacement, and hip fracture repair—fondaparinux has been studied more widely in orthopedic surgery patients than in the other populations reviewed earlier in this supplement. Nevertheless, its use even in these settings has remained somewhat limited. This may be because of concerns over possible increased bleeding risk relative to some other anticoagulants. Because of bleeding risk, fondaparinux is contraindicated in patients who weigh less than 50 kg, and its package insert recommends caution when it is used in the elderly due to an increased risk of bleeding in patients aged 65 or older. Additionally, the Pentasaccharide in Major Knee Surgery (PENTAMAKS) study found fondaparinux to be associated with a significantly higher incidence of major bleeding compared with enoxaparin (2.1% vs 0.2%; P = .006) in major knee surgery, although it was superior to enoxaparin in preventing VTE.10 Other possible reasons for slow adoption of fondaparinux include its long half-life, which results in a sustained antithrombotic effect, its lack of easy reversibility, and a contraindication in patients with renal insufficiency.11

Limited role for UFH. Low-dose UFH has a more limited role in orthopedic surgery than in other settings requiring VTE prophylaxis, as current ACCP guidelines for VTE prevention recognize it only as a possible option in hip fracture surgery and state that it is not to be considered as sole prophylaxis in patients undergoing hip or knee replacement.6

Warfarin. Although not indicated for use in other VTE prophylaxis settings, the vitamin K antagonist warfarin is recommended as an option for all three major orthopedic surgery indications—knee replacement, hip replacement, and hip fracture repair.6

The key to effective prophylaxis with warfarin is achieving the appropriate intensity of anticoagulation. In two separate analyses, Hylek et al demonstrated a balance between safety and efficacy with warfarin therapy targeted to an international normalized ratio (INR) of 2.0 to 3.0.12,13 An INR greater than 4.0 greatly increased the risk of intracranial hemorrhage, whereas thrombosis was not effectively prevented with an INR less than 2.0.12,13 This latter point should be stressed to orthopedic surgeons, who sometimes aim for INR values below 2.0.

Although anticoagulation clinics are superior to usual care at maintaining the INR within the window of 2.0 to 3.0, only about one-third of patients nationally who take warfarin receive care in such clinics.14 Even with optimal care in anticoagulation clinics, some patients will still receive subtherapeutic or supertherapeutic levels of warfarin, which is one of this agent’s limitations.

Aspirin not recommended as sole agent. Although aspirin is still used as thromboprophylaxis in orthopedic surgery patients, current ACCP guidelines recommend against its use as the sole means of VTE prophylaxis in any patient group.6 The limitations of the evidence for aspirin in this setting are illustrated by the Pulmonary Embolism Prevention study, a multicenter randomized trial in patients undergoing hip fracture (n = 13,356) or hip/knee replacement (n = 4,088).15 Patients received aspirin 160 mg/day or placebo for 5 weeks, starting preoperatively, and were evaluated for outcomes at day 35. Among the hip fracture patients, the rate of symptomatic DVT was lower in the aspirin group than in the placebo group (1.0% vs 1.5%; P = .03), as was the rate of PE (0.7% vs 1.2%, respectively; P = .002), but there was no significant difference in outcomes between the groups among the patients undergoing hip or knee replacement. Notably, 40% of patients in the study also received UFH or LMWH. Further confounding the results, some patients received nonpharmacologic VTE prophylaxis modalities, and others received nonsteroidal anti-inflammatory drugs other than aspirin.

Heparin-induced thrombocytopenia. As noted earlier in this supplement, the incidence of heparin-induced thrombocytopenia (HIT) is markedly higher in patients who receive UFH than in those who receive LMWH. This difference in frequency, which constitutes about a sixfold to eightfold differential, is due to the relationship between standard heparin and platelet factor IV, which can induce formation of IgG antibodies.16 A 50% or greater reduction in platelet count in heparin recipients should prompt consideration of HIT.

Oral direct thrombin inhibitors. Although the oral direct thrombin inhibitor ximelagatran was rejected for approval by the US Food and Drug Administration (FDA) and recently withdrawn from the market world­wide as a result of hepatic risks, other oral direct thrombin inhibitors are in phase 3 studies for use in orthopedic surgery and may be commercially available options for postoperative VTE prophylaxis before long.

GUIDELINES FOR VTE PROPHYLAXIS IN ORTHOPEDIC SURGERY

The ACCP guidelines referred to throughout this article are widely recognized as a practice standard for VTE prevention and treatment, and have been regularly updated throughout recent decades. The most recent version, issued in 2004, is formally known as the Seventh ACCP Conference on Antithrombotic and Thrombolytic Therapy.6 Key orthopedic surgery-related recommendations and notable changes from the previous version of the guidelines, issued in 2001, are outlined below, along with pertinent supportive or illustrative studies.

Hip replacement surgery

For all patients undergoing elective hip replacement surgery, routine use of either LMWH, fondaparinux, or warfarin is recommended (see Table 1 for recommended dosing). Each of these options is given a Grade 1A recommendation, the guidelines’ highest level of endorsement, indicating evidence from randomized controlled trials (RCTs) without important limitations. None of these options is recommended as superior to the other two. The guidelines recommend against the use of any other option, including UFH and mechanical devices, as the sole method of prophylaxis in these patients.6

In a change from the previous guidelines, the Seventh ACCP Conference recommends extended prophylaxis, for up to 28 to 35 days after surgery, for patients undergoing hip replacement or hip fracture surgery. For hip replacement surgery, this is a Grade 1A recommendation for prophylaxis with either LMWH or warfarin and a Grade 1C+ recommendation (“no RCTs but strong RCT results can be unequivocally extrapolated, or overwhelming evidence from observational studies”) for prophylaxis with fondaparinux.6

Reprinted, with permission, from Annals of Internal Medicine (Hull et al, 2001).17
Figure 1. Relative risk (and 95% confidence intervals) for all deep vein thrombosis during the out-of-hospital time interval (up to 28 to 35 days after surgery) with extended-duration low-molecular-weight heparin (LMWH) therapy compared with standard-duration LMWH therapy. Results are from six randomized trials of extended prophylaxis in patients undergoing total hip replacement. The risk reduction with extended-duration prophylaxis was statistically significant in all six trials.
The compelling evidence base for extended prophylaxis with LMWH in this setting was demonstrated in a systematic review of six double-blind, randomized, placebo-controlled trials, as illustrated in Figure 1.17 Additionally, a Belgian cost-utility analysis in patients who underwent total hip or knee replacement showed that extended prophylaxis with enoxaparin (30 days) carried an incremental cost of $6,386 (US dollars) per quality-adjusted life-year compared with standard-duration enoxaparin prophylaxis (12 days), a cost that was well below the “willingness to pay” threshold of $18,200 per quality-adjusted life-year used in European guidelines for cost-effectiveness.18

 

 

Knee replacement surgery

The same three anticoagulant options that received Grade 1A recommendations for patients undergoing total hip replacement—LMWH, fondaparinux, and adjusted-dose warfarin—are also given Grade 1A recommendations as routine thromboprophylaxis in patients undergoing elective knee replacement (see Table 1 for dosing). In addition, optimal use of intermittent pneumatic compression devices is recommended as an alternative option to anticoagulant prophylaxis in these patients (Grade 1B, indicating a “strong recommendation” based on RCTs with important limitations). Use of UFH as the sole agent for prophylaxis is recommended against.6

For both hip and knee replacement surgery, the Seventh ACCP Conference does not endorse superiority of any one of its three recommended prophylaxis options—LMWH, fondaparinux, and adjusted-dose warfarin—over the other two. However, at least four large randomized trials have directly compared LMWH and adjusted-dose warfarin in the setting of arthroplasty—two in total hip replacement surgery19,20 and two in total knee replacement surgery.21,22 Each of these four studies found LMWH to be significantly more effective than warfarin in preventing VTE. In three of the four trials, there was no significant difference between the therapies in rates of major bleeding.19,21,22 In the remaining trial, which was conducted in hip replacement surgery patients and compared postoperative warfarin with dalteparin initiated either immediately before or early after surgery, patients who received preoperative dalteparin initiation (but not those who received postoperative dalteparin initiation) had an increased rate of major bleeding compared with warfarin recipients (P = .01).20

Hip fracture surgery

The supportive evidence for anticoagulant prophylaxis in hip fracture surgery is less robust than that in hip and knee replacement surgery. As a result, only fondaparinux has a Grade 1A recommendation as routine prophylaxis in patients undergoing hip fracture surgery. Options with less definitive recommendations are LMWH (Grade 1C+), low-dose UFH (Grade 1B), and adjusted-dose warfarin (Grade 2B, indicating a “weak recommendation” based on RCTs with important limitations) (see Table 1 for dosing of all agents).6

These differing recommendations are supported by the double-blind Pentasaccharide in Hip Fracture Surgery Study (PENTHIFRA) of 1,711 consecutive patients undergoing surgery for hip fracture repair.23 Patients were randomized to at least 5 days of fondaparinux 2.5 mg once daily, initiated postoperatively, or enoxaparin 40 mg once daily, initiated preoperatively. The incidence of DVT or PE by postoperative day 11 was 8.3% in the fondaparinux arm versus 19.1% in the enoxaparin arm, a statistically significant difference (P < .001) in favor of fondaparinux. There were no differences between the groups in rates of death or clinically relevant bleeding.

As noted above, the newly added recommendation in the Seventh ACCP Conference for extended prophylaxis, for up to 28 to 35 days after surgery, applies to patients undergoing hip fracture surgery as well as those undergoing hip replacement surgery. In the setting of hip fracture repair, extended prophylaxis is a Grade 1A recommendation with the use of fondaparinux and a Grade 1C+ recommendation with the use of either LMWH or adjusted-dose warfarin.6

Lower extremity fractures and trauma

Although lower extremity fractures are very common, the risk of DVT has been poorly studied in this setting. For patients with isolated lower extremity fractures, the Seventh ACCP Conference recommends that clinicians not use thromboprophylaxis routinely (Grade 2A, indicating an “intermediate-strength recommendation” based on RCTs without important limitations).6

Trauma patients, in contrast, are well recognized as being at very high risk for DVT and PE. The Seventh ACCP Conference gives a Grade 1A recommendation to thromboprophylaxis for all trauma patients who have at least one risk factor for VTE. LMWH is recommended (Grade 1A) as the agent of choice for this purpose, provided there are no contraindications to its use, and should be administered as soon as safely possible. Mechanical modalities are reserved for trauma patients with active bleeding or high risk for hemorrhage (Grade 1B). The guidelines recommend against use of inferior vena cava (IVC) filters as primary thromboprophylaxis in trauma patients (Grade 1C, indicating an “intermediate-strength recommendation” based on observational studies).6

Use of ultrasonography

Duplex ultrasonographic screening is recommended in orthopedic trauma patients who are at high risk for VTE and have received suboptimal or no prophylaxis (Grade 1C). In contrast, the Seventh ACCP Conference recommends against routine use of duplex ultrasonography to screen for VTE at hospital discharge in asymptomatic patients following major orthopedic surgery (Grade 1A).6

Knee arthroscopy

Arthroscopic knee procedures are increasing in frequency and raise the specter of a potential role for thromboprophylaxis. However, the clinical diagnosis of DVT is unreliable, and even diagnosis by ultrasonography is unreliable following knee arthroscopy, as interpreting scans of veins below the knee is challenging in this setting.24

The Seventh ACCP Conference recommends that clinicians not use routine thromboprophylaxis, other than early mobilization, for patients who undergo knee arthroscopy (Grade 2B). However, for arthroscopy patients who have inherent risk factors for VTE or who undergo a prolonged or complicated arthroscopy procedure, thromboprophylaxis with LMWH is suggested (Grade 2B).6

RECOMMENDED APPROACH TO VTE PROPHYLAXIS IN ORTHOPEDIC SURGERY

Drawing on the ACCP guidelines and the evidence reviewed above, we have outlined our evidence-based recommendations for pharmacologic VTE prophylaxis in patients undergoing orthopedic surgery, as presented in Table 1. All patients undergoing major orthopedic surgical procedures (ie, procedures other than arthroscopy) should routinely receive anticoagulant prophylaxis unless they have contraindications to anticoagulation. Recommended agents and their duration of use vary according to the type of surgery, as detailed in Table 1.

Extended-duration prophylaxis is recommended for patients undergoing total hip replacement and hip fracture surgery. Aspirin is not recommended as the sole agent for prophylaxis in any orthopedic surgery setting.

Importance of a postoperative prophylaxis protocol

In addition to these broad pharmacologic recommendations, it is important that a postoperative VTE prophylaxis protocol be in place at all hospitals.

At the Ochsner Medical Center in New Orleans, where one of us (S.B.D.) practices, postoperative orders include antithrombotic therapy for surgical patients, starting with placement of thigh-high antiembolism stockings on both legs on the day of surgery for patients undergoing hip replacement and on postoperative day 1 in those undergoing knee replacement. Plantar pneumatic compression devices are applied to both legs in the recovery room and kept on except when the patient is walking. The hospitalist team dictates further anticoagulation orders. If extended prophylaxis is prescribed, the discharge planner sets up drug delivery and reimbursement, provides a LMWH discharge kit, and teaches the patient to self-inject. If there is concern about increasing swelling at the surgical site while anticoagulant therapy continues, the protocol calls for prompt notification of the responsible physician. To minimize the risk that spinal or epidural hematomas will develop, all agents that increase bleeding propensity should be recognized and ordered accordingly.

 

 

SUMMARY

VTE in patients undergoing major orthopedic surgery is a serious health problem that is highly preventable, yet VTE prophylaxis remains underused in this patient population. Despite the availability of practice guidelines for VTE prevention in the orthopedic surgery setting, recommendations are not widely implemented in clinical practice. Recommended prophylactic options differ somewhat among various orthopedic procedures, and the supportive evidence differs for various anticoagulant options.

DISCUSSION: ADDITIONAL PERSPECTIVES FROM THE AUTHORS

Dr. Jaffer: The ACCP recommends against the routine use of aspirin as primary prophylaxis against VTE in major orthopedic surgery, yet orthopedic surgeons across the country still continue to use aspirin in this setting. What are your thoughts on this, Dr. McKean?

Dr. McKean: We agree with the ACCP’s recommendation against aspirin as primary VTE prophylaxis in orthopedic patients. The percentage of US knee arthroplasty patients who develop VTE after receiving no prophylaxis at all is roughly 64%; this percentage declines only slightly (to 56%) for knee arthroplasty patients who receive prophylaxis with aspirin.25 Since we clearly want to reduce VTE risk as much as possible, I would not use aspirin alone. I would use it only if the patient were already on aspirin, but then I would add either LMWH or fondaparinux.

Dr. Jaffer: Warfarin is another agent that is widely used for prophylaxis in major orthopedic surgery. In fact, the large registries of VTE prevention in major orthopedic surgery suggest that the use of warfarin may be slightly higher than the use of LMWH. If clinicians choose to use warfarin in their practice, what are your recommendations, Dr. Deitelzweig?

Dr. Deitelzweig: As primary prophylaxis for orthopedic surgery patients, warfarin must be dosed to achieve an INR of 2.0 to 3.0; the need for a value in this range is unequivocal. This is a challenging target to attain in the hospital setting.

Dr. Brotman: A study I was involved with a few years ago suggested that warfarin may be inadequate for VTE prevention in the first few days after orthopedic surgery.26 Orthopedic surgeons at the Cleveland Clinic, where I was practicing at the time, routinely used systematic ultrasonography to assess for thrombosis on postoperative day 2 or 3 following hip or knee arthroplasty, so we conducted a secondary analysis of a case-control study in these ultrasonographically screened arthroplasty patients to assess rates of early VTE and look for any associations with the type of prophylaxis used. We found that there was about a tenfold increase in the risk of VTE, both distal and proximal, on postoperative day 2 or 3 among patients who received warfarin compared with those who received LMWH. We concluded that warfarin’s delayed antithrombotic effects may not provide sufficient VTE prophylaxis in the immediate postoperative setting.26

Dr. Deitelzweig: That’s a good point. Although it’s important to achieve a therapeutic level of warfarin, we now have evidence that it takes some time to achieve that level, and in the interim, bad things can happen to patients.

Dr. Jaffer: Orthopedic surgery encompasses several types of procedures. Dr. Amin, which specific orthopedic surgery patients stand to benefit from extended prophylaxis, and how long should extended prophylaxis last?

Dr. Amin: Major orthopedic surgery comprises hip fracture repair, total hip replacement, and total knee replacement. For hip fracture, there are strong data to support the use of extended prophylaxis with fondaparinux 2.5 mg/day, which showed about an 88% relative reduction in the risk of symptomatic VTE compared with standard-duration fondaparinux (6 to 8 days) followed by matching placebo for the extended phase.27 The total duration of fondaparinux therapy in the extended-duration arm was 4 to 5 weeks.

Likewise, data support extended prophylaxis in hip arthroplasty patients, for whom the recommended duration is also 4 to 5 weeks. The systematic review by Hull et al17 demonstrated a 0.41 relative risk of DVT with extended-duration LMWH prophylaxis versus placebo in hip replacement patients (Figure 1), which was a highly statistically significant result.

In contrast, we do not yet have good data to support extended prophylaxis for patients undergoing total knee replacement, which is a bit surprising. In this setting, prophylaxis is recommended for 7 to 14 days but not beyond that.

Dr. Jaffer: Arthroscopy is probably the most common orthopedic procedure performed in the United States today. Dr. Brotman, what is the role of prophylaxis in patients undergoing arthroscopy?

Dr. Brotman: Minor surgery such as arthroscopy can typically be performed safely without routine prophylaxis, other than having the patient ambulate as soon as possible after the procedure. There may be exceptions to this rule, however. I believe that there is potentially a role for pharmacologic prophylaxis in arthroscopy patients who have major risk factors for VTE, such as a personal history of VTE, or who are not expected to become mobile again in a normal rapid fashion after the operation, but prophylaxis has not been studied systematically in such patients.

Dr. Jaffer: Dr. Spyropoulos, there are several new anticoagulants in the pipeline, specifically agents such as the oral direct factor Xa inhibitors and the direct thrombin inhibitors. What do recent clinical trials suggest with regard to the efficacy of these two drug classes for thromboprophylaxis in major orthopedic surgery?

Dr. Spyropoulos: The agents with the most available data are the oral direct factor Xa inhibitors apixaban and rivaroxaban and the oral direct thrombin inhibitor dabigatran. For prophylaxis in orthopedic surgery populations, phase 2 studies have been completed for apixaban and phase 3 trials have been completed for rivaroxaban and dabigatran.

It appears that the factor Xa inhibitors, apixaban and rivaroxaban, are efficacious in comparison with both adjusted-dose warfarin and LMWH, which is the gold standard for this group of patients.28,29 So these indeed appear to be promising agents. Rivaroxaban has been submitted to European regulatory agencies for approval for the prevention of VTE in patients undergoing major orthopedic surgery, and its developer plans to submit it to the FDA in 2008 for a similar indication in the United States.

The data are more equivocal with dabigatran. There have been several positive phase 3 studies in orthopedic surgery comparing two dabigatran dosing schemes, 150 and 220 mg once daily, with the European regimen of enoxaparin (40 mg once daily),30 but a recent study that compared these doses with the North American enoxaparin regimen (30 mg twice daily) failed to meet the criteria for noninferiority.31 Further clinical trial development is necessary for dabigatran, although in January 2008 the European Medicines Agency recommended its marketing approval for thromboprophylaxis in patients undergoing orthopedic procedures.32

I believe that in the next 3 to 5 years our armamentarium will see the addition of at least one, if not more, of these new agents that offer the promise of oral anticoagulation with highly predictable pharmacokinetics and pharmacodynamics and no need for monitoring.

References
  1. Yu HT, Dylan ML, Lin J, Dubois RW. Hospitals’ compliance with prophylaxis guidelines for venous thromboembolism. Am J Health Syst Pharm 2007; 64:69–76.
  2. Stratton MA, Anderson FA, Bussey HI, et al. Prevention of venous thromboembolism: adherence to the 1995 ACCP consensus guidelines for surgical patients. Arch Intern Med 2000; 160:334–340.
  3. National Consensus Standards for Prevention and Care of Venous Thromboembolism (VTE). The Joint Commission Web site. http://www.jointcommission.org/PerformanceMeasurement/Perform anceMeasurement/VTE.htm. Accessed January 8, 2008.
  4. Surgical Care Improvement Project. MedQIC Web site. http://www.medqic.org/scip. Accessed January 8, 2008.
  5. SCIP process and outcome measures, October 2005. MedQIC Web site. http://www.medqic.org. Accessed January 1, 2007.
  6. Geerts WH, Pineo GF, Heit JA, et al. Prevention of venous thromboembolism: the Seventh ACCP Conference on Antithrombotic and Thrombolytic Therapy. Chest 2004; 126(3 Suppl):338S–400S.
  7. Zimlich RH, Fulbright BM, Friedman RJ. Current status of anticoagulation therapy after total hip and total knee arthroplasty.J Am Acad Orthop Surg 1996; 4:54–62.
  8. Planes A, Vochelle N, Mazas F, et al. Prevention of postoperative venous thrombosis: a randomized trial comparing unfractionated heparin with low molecular weight heparin in patients undergoing total hip replacement. Thromb Haemost 1988; 60:407–410.
  9. Colwell CW Jr, Spiro TE, Trowbridge AA, et al. Efficacy and safety of enoxaparin versus unfractionated heparin for prevention of deep venous thrombosis after elective knee arthroplasty. Clin Orthop Relat Res 1995; 321:19–27.
  10. Bauer KA, Eriksson BI, Lassen MR, Turpie AG. Fondaparinux compared with enoxaparin for the prevention of venous thromboembolism after elective major knee surgery. N Engl J Med 2001; 345:1305–1310.
  11. Turpie AGG. Pentasaccharide Org31540/SR90107A clinical trials update: lessons for practice. Am Heart J 2001; 142(Suppl):S9–S15.
  12. Hylek EM, Singer DE. Risk factors for intracranial hemorrhage in outpatients taking warfarin. Ann Intern Med 1994; 120:897–902.
  13. Hylek EM, Skates SJ, Sheehan MA, Singer DE. An analysis of the lowest effective intensity of prophylactic anticoagulation for patients with nonrheumatic atrial fibrillation. N Engl J Med 1996; 335:540–546.
  14. Samsa GP, Matchar DB, Goldstein LB, et al. Quality of anticoagulation management among patients with atrial fibrillation: review of medical records from 2 communities. Arch Intern Med 2000; 160:967–973.
  15. PEP Trial Collaborative Group. Prevention of pulmonary embolism and deep vein thrombosis with low dose aspirin: Pulmonary Embolism Prevention (PEP) trial. Lancet 2000; 355:1295–1302.
  16. Warkentin TE. Heparin-induced thrombocytopenia: pathogenesis and management. Br J Haemotol 2003; 121:535–555.
  17. Hull RD, Pineo GF, Stein PD, et al. Extended out-of-hospital low-molecular-weight heparin prophylaxis against deep venous thrombosis in patients after elective hip arthroplasty: a systematic review. Ann Intern Med 2001; 135:858–869.
  18. Haentjens P, De Groote K, Annemans L. Prolonged enoxaparin therapy to prevent venous thromboembolism after primary hip or knee replacement: a cost-utility analysis. Arch Orthop Trauma Surg 2004; 124:507–517.
  19. Colwell CW Jr, Collis DK, Paulson R, et al. Comparison of enoxaparin and warfarin for the prevention of venous thromboembolic disease after total hip arthroplasty: evaluation during hospitalization and three months after discharge. J Bone Joint Surg Am 1999; 81:932–940.
  20. Hull RD, Pineo GF, Francis C, et al. Low-molecular-weight heparin prophylaxis using dalteparin in close proximity to surgery vs warfarin in hip arthroplasty patients: a double-blind, randomized comparison. Arch Intern Med 2000; 160:2199–2207.
  21. Leclerc JR, Geerts WH, Desjardins L, et al. Prevention of venous thromboembolism after knee arthroplasty: a randomized, double-blind trial comparing enoxaparin with warfarin. Ann Intern Med 1996; 124:619–626.
  22. Fitzgerald RH Jr, Spiro TE, Trowbridge AA, et al. Prevention of venous thromboembolic disease following primary total knee arthroplasty: a randomized, multicenter, open-label, parallel-group comparison of enoxaparin and warfarin. J Bone Joint Surg Am 2001; 83-A:900–906.
  23. Eriksson BI, Bauer KA, Lassen MR, Turpie AG, Steering Committee of the Pentasaccharide in Hip-Fracture Surgery Study. Fondaparinux compared with enoxaparin for the prevention of venous thromboembolism after hip-fracture surgery. N Engl J Med 2001; 345:1298–1304.
  24. Demers C, Marcoux S, Ginsberg JS, Laroche F, Cloutier R, Poulin J. Incidence of venographically proved deep vein thrombosis after knee arthroscopy. Arch Intern Med 1998; 158:47–50.
  25. Geerts WH, Heit JA, Clagett GP, et al. Prevention of venous thromboembolism. Chest 2001; 119(1 Suppl):132S–175S.
  26. Brotman DJ, Jaffer AK, Hurbanek JG, Morra N. Warfarin prophylaxis and venous thromboembolism in the first 5 days following hip and knee arthroplasty. Thromb Haemost 2004; 92:1012–1017.
  27. Eriksson BI, Lassen MR; Pentasaccharide in Hip-Fracture Surgery Plus Investigators. Duration of prophylaxis against venous thromboembolism with fondaparinux after hip fracture surgery: a multicenter, randomized, placebo-controlled, double-blind study. Arch Intern Med 2003; 163:1337–1342.
  28. The Botticelli Investigators. Late-breaking clinical trial: a dose-finding study of the oral direct factor Xa inhibitor apixaban in the treatment of patients with acute symptomatic deep vein thrombosis [abstract]. Presented at the 21st Congress of the International Society on Thrombosis and Haemostasis; July 2007; Geneva, Switzerland.
  29. Fisher WD, Eriksson BI, Bauer KA, et al. Rivaroxaban for thromboprophylaxis after orthopaedic surgery: pooled analysis of two studies. Thromb Haemost 2007; 97:931–937.
  30. Haas S. New oral Xa and IIa inhibitors: updates on clinical trial results. J Thromb Thrombolysis 2008; 25:52–60.
  31. Friedman RJ, Caprini JA, Comp PC, et al. Dabigatran etexilate vs enoxaparin in preventing venous thromboembolism following total knee arthroplasty. Presented at: 2007 Congress of the International Society on Thrombosis and Haemostasis; July 7–13, 2007; Geneva, Switzerland.
  32. Committee for Medicinal Products for Human Use summary of positive opinion for Pradaxa [news release]. London, UK: European Medicines Agency. January 24, 2008. http://www.emea.europa.eu/pdfs/human/ opinion/Pradaxa_3503008en.pdf. Accessed February 21, 2008.
  33. Goldhaber SZ, Grodstein F, Stampfer MJ. A prospective study of risk factors for pulmonary embolism in women. JAMA 1997; 277:642–645.
  34. Turpie AGG, Bauer KA, Eriksson BI, Lassen MR, for the Steering Committees of the Pentasaccharide Orthopedic Prophylaxis Studies. Fondaparinux vs enoxaparin for the prevention of venous thromboembolism in major orthopedic surgery. Arch Intern Med 2002; 162:1833–1840.
  35. Stein PD, Beemath A, Matta F, et al. Clinical characteristics of patients with acute pulmonary embolism: data from PIOPED II. Am J Med 2007; 120:871–879.
  36. Goldhaber SZ. Diagnosis of acute pulmonary embolism: always be vigilant. Am J Med 2007; 120:827–828.
  37. American Academy of Orthopaedic Surgeons Clinical Guideline on Prevention of Symptomatic Pulmonary Embolism in Patients Undergoing Total Hip or Knee Arthroplasty: Summary of Recommendations. http://www.aaos.org/Research/guidelines/PE_ summary.pdf. Accessed December 10, 2007.
References
  1. Yu HT, Dylan ML, Lin J, Dubois RW. Hospitals’ compliance with prophylaxis guidelines for venous thromboembolism. Am J Health Syst Pharm 2007; 64:69–76.
  2. Stratton MA, Anderson FA, Bussey HI, et al. Prevention of venous thromboembolism: adherence to the 1995 ACCP consensus guidelines for surgical patients. Arch Intern Med 2000; 160:334–340.
  3. National Consensus Standards for Prevention and Care of Venous Thromboembolism (VTE). The Joint Commission Web site. http://www.jointcommission.org/PerformanceMeasurement/Perform anceMeasurement/VTE.htm. Accessed January 8, 2008.
  4. Surgical Care Improvement Project. MedQIC Web site. http://www.medqic.org/scip. Accessed January 8, 2008.
  5. SCIP process and outcome measures, October 2005. MedQIC Web site. http://www.medqic.org. Accessed January 1, 2007.
  6. Geerts WH, Pineo GF, Heit JA, et al. Prevention of venous thromboembolism: the Seventh ACCP Conference on Antithrombotic and Thrombolytic Therapy. Chest 2004; 126(3 Suppl):338S–400S.
  7. Zimlich RH, Fulbright BM, Friedman RJ. Current status of anticoagulation therapy after total hip and total knee arthroplasty.J Am Acad Orthop Surg 1996; 4:54–62.
  8. Planes A, Vochelle N, Mazas F, et al. Prevention of postoperative venous thrombosis: a randomized trial comparing unfractionated heparin with low molecular weight heparin in patients undergoing total hip replacement. Thromb Haemost 1988; 60:407–410.
  9. Colwell CW Jr, Spiro TE, Trowbridge AA, et al. Efficacy and safety of enoxaparin versus unfractionated heparin for prevention of deep venous thrombosis after elective knee arthroplasty. Clin Orthop Relat Res 1995; 321:19–27.
  10. Bauer KA, Eriksson BI, Lassen MR, Turpie AG. Fondaparinux compared with enoxaparin for the prevention of venous thromboembolism after elective major knee surgery. N Engl J Med 2001; 345:1305–1310.
  11. Turpie AGG. Pentasaccharide Org31540/SR90107A clinical trials update: lessons for practice. Am Heart J 2001; 142(Suppl):S9–S15.
  12. Hylek EM, Singer DE. Risk factors for intracranial hemorrhage in outpatients taking warfarin. Ann Intern Med 1994; 120:897–902.
  13. Hylek EM, Skates SJ, Sheehan MA, Singer DE. An analysis of the lowest effective intensity of prophylactic anticoagulation for patients with nonrheumatic atrial fibrillation. N Engl J Med 1996; 335:540–546.
  14. Samsa GP, Matchar DB, Goldstein LB, et al. Quality of anticoagulation management among patients with atrial fibrillation: review of medical records from 2 communities. Arch Intern Med 2000; 160:967–973.
  15. PEP Trial Collaborative Group. Prevention of pulmonary embolism and deep vein thrombosis with low dose aspirin: Pulmonary Embolism Prevention (PEP) trial. Lancet 2000; 355:1295–1302.
  16. Warkentin TE. Heparin-induced thrombocytopenia: pathogenesis and management. Br J Haemotol 2003; 121:535–555.
  17. Hull RD, Pineo GF, Stein PD, et al. Extended out-of-hospital low-molecular-weight heparin prophylaxis against deep venous thrombosis in patients after elective hip arthroplasty: a systematic review. Ann Intern Med 2001; 135:858–869.
  18. Haentjens P, De Groote K, Annemans L. Prolonged enoxaparin therapy to prevent venous thromboembolism after primary hip or knee replacement: a cost-utility analysis. Arch Orthop Trauma Surg 2004; 124:507–517.
  19. Colwell CW Jr, Collis DK, Paulson R, et al. Comparison of enoxaparin and warfarin for the prevention of venous thromboembolic disease after total hip arthroplasty: evaluation during hospitalization and three months after discharge. J Bone Joint Surg Am 1999; 81:932–940.
  20. Hull RD, Pineo GF, Francis C, et al. Low-molecular-weight heparin prophylaxis using dalteparin in close proximity to surgery vs warfarin in hip arthroplasty patients: a double-blind, randomized comparison. Arch Intern Med 2000; 160:2199–2207.
  21. Leclerc JR, Geerts WH, Desjardins L, et al. Prevention of venous thromboembolism after knee arthroplasty: a randomized, double-blind trial comparing enoxaparin with warfarin. Ann Intern Med 1996; 124:619–626.
  22. Fitzgerald RH Jr, Spiro TE, Trowbridge AA, et al. Prevention of venous thromboembolic disease following primary total knee arthroplasty: a randomized, multicenter, open-label, parallel-group comparison of enoxaparin and warfarin. J Bone Joint Surg Am 2001; 83-A:900–906.
  23. Eriksson BI, Bauer KA, Lassen MR, Turpie AG, Steering Committee of the Pentasaccharide in Hip-Fracture Surgery Study. Fondaparinux compared with enoxaparin for the prevention of venous thromboembolism after hip-fracture surgery. N Engl J Med 2001; 345:1298–1304.
  24. Demers C, Marcoux S, Ginsberg JS, Laroche F, Cloutier R, Poulin J. Incidence of venographically proved deep vein thrombosis after knee arthroscopy. Arch Intern Med 1998; 158:47–50.
  25. Geerts WH, Heit JA, Clagett GP, et al. Prevention of venous thromboembolism. Chest 2001; 119(1 Suppl):132S–175S.
  26. Brotman DJ, Jaffer AK, Hurbanek JG, Morra N. Warfarin prophylaxis and venous thromboembolism in the first 5 days following hip and knee arthroplasty. Thromb Haemost 2004; 92:1012–1017.
  27. Eriksson BI, Lassen MR; Pentasaccharide in Hip-Fracture Surgery Plus Investigators. Duration of prophylaxis against venous thromboembolism with fondaparinux after hip fracture surgery: a multicenter, randomized, placebo-controlled, double-blind study. Arch Intern Med 2003; 163:1337–1342.
  28. The Botticelli Investigators. Late-breaking clinical trial: a dose-finding study of the oral direct factor Xa inhibitor apixaban in the treatment of patients with acute symptomatic deep vein thrombosis [abstract]. Presented at the 21st Congress of the International Society on Thrombosis and Haemostasis; July 2007; Geneva, Switzerland.
  29. Fisher WD, Eriksson BI, Bauer KA, et al. Rivaroxaban for thromboprophylaxis after orthopaedic surgery: pooled analysis of two studies. Thromb Haemost 2007; 97:931–937.
  30. Haas S. New oral Xa and IIa inhibitors: updates on clinical trial results. J Thromb Thrombolysis 2008; 25:52–60.
  31. Friedman RJ, Caprini JA, Comp PC, et al. Dabigatran etexilate vs enoxaparin in preventing venous thromboembolism following total knee arthroplasty. Presented at: 2007 Congress of the International Society on Thrombosis and Haemostasis; July 7–13, 2007; Geneva, Switzerland.
  32. Committee for Medicinal Products for Human Use summary of positive opinion for Pradaxa [news release]. London, UK: European Medicines Agency. January 24, 2008. http://www.emea.europa.eu/pdfs/human/ opinion/Pradaxa_3503008en.pdf. Accessed February 21, 2008.
  33. Goldhaber SZ, Grodstein F, Stampfer MJ. A prospective study of risk factors for pulmonary embolism in women. JAMA 1997; 277:642–645.
  34. Turpie AGG, Bauer KA, Eriksson BI, Lassen MR, for the Steering Committees of the Pentasaccharide Orthopedic Prophylaxis Studies. Fondaparinux vs enoxaparin for the prevention of venous thromboembolism in major orthopedic surgery. Arch Intern Med 2002; 162:1833–1840.
  35. Stein PD, Beemath A, Matta F, et al. Clinical characteristics of patients with acute pulmonary embolism: data from PIOPED II. Am J Med 2007; 120:871–879.
  36. Goldhaber SZ. Diagnosis of acute pulmonary embolism: always be vigilant. Am J Med 2007; 120:827–828.
  37. American Academy of Orthopaedic Surgeons Clinical Guideline on Prevention of Symptomatic Pulmonary Embolism in Patients Undergoing Total Hip or Knee Arthroplasty: Summary of Recommendations. http://www.aaos.org/Research/guidelines/PE_ summary.pdf. Accessed December 10, 2007.
Page Number
S27-S36
Page Number
S27-S36
Publications
Publications
Article Type
Display Headline
Prevention of venous thromboembolism in the orthopedic surgery patient
Display Headline
Prevention of venous thromboembolism in the orthopedic surgery patient
Citation Override
Cleveland Clinic Journal of Medicine 2008 April;75(suppl 3):S27-S36
PURLs Copyright

Disallow All Ads
Alternative CME
Use ProPublica
Article PDF Media