Cutis is a peer-reviewed clinical journal for the dermatologist, allergist, and general practitioner published monthly since 1965. Concise clinical articles present the practical side of dermatology, helping physicians to improve patient care. Cutis is referenced in Index Medicus/MEDLINE and is written and edited by industry leaders.

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Successful Treatment of Alopecia Universalis With Alefacept: A Case Report and Review of the Literature

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Nephrogenic Systemic Fibrosis: Is Gadolinium the Missing Piece to the Puzzle? (See Erratum 2008;82:158)

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Nephrogenic fibrosing dermopathy (NFD) is an acquired idiopathic disorder seen exclusively in patients with renal failure. It was first recognized in 1997 in a group of patients following renal transplant.1,2 Symmetric, thickened, fibrotic skin with brawny hyperpigmentation develops and primarily affects the limbs, sparing the head and neck. Associated symptoms include flexion contracture, pain, paresthesia, and/or severe pruritus. Yellow palmar papules and yellow scleral plaques also have been described. Although fibrosis initially was observed in the skin, more recent evidence suggests that NFD is a systemic disorder with variable and still unclear degrees of end organ damage, particularly pulmonary fibrosis.3-7 In light of the systemic involvement and newly described, rapidly progressive, fatal cases of NFD, the name has been changed to nephrogenic systemic fibrosis (NSF).3 Since 1997, more than 200 cases have been compiled through the Yale University NSF Registry. All patients have the unifying diagnosis of renal failure, but the disease has been observed in patients independent of age, gender, dialysis history, kidney transplant status, or the underlying cause of renal failure.8,9 The majority of cases have been reported in the United States and Europe, but new cases are now being reported in non-Western populations.10,11 Given the novelty of the disease and the limited number of cases, the etiology has been elusive; however, most new diseases have some iatrogenic component. Prior to onset, many patients with NSF experienced coagulation abnormalities, transplant rejection, or some type of vascular intervention. As a result, contrast agents became suspect. Grobner12 reported 5 patients with NSF who had magnetic resonance imaging with gadolinium (Gd)–diethylenetriamine-penta-acetic acid (DTPA) contrast 2 to 4 weeks prior to the onset of fibrosis. All of the patients with NSF were acidotic, in contrast to a similar unaffected group of patients with normal acid-base status.12 Shortly after, Marckmann et al13 published a case series of 13 patients who developed NSF, all within 75 days of Gd contrast exposure; however, there was no correlation with metabolic acidosis in this study. Additional cases have been reported in association with exposure to Gd contrast.14,15 More recently, using electron microscopy with electron dispersion spectroscopy, Gd has been detected in the tissue of some patients with NSF.14,15 On June 8, 2006, the US Food and Drug Administration (FDA) released a public health advisory warning patients and physicians of the possible link between Gd-containing contrast agents and NSF.16 We report another case of NSF associated with Gd-DTPA exposure and propose a plausible explanation for the possible association and pathophysiology of NSF.


Case Report
A 54-year-old man with end-stage diabetic nephropathy status post–renal transplant was evaluated for induration and thickening of the skin. Two months prior, he presented with an infected nonhealing ulcer of the left foot and was admitted to the hospital for intravenous antibiotics. During his hospital stay, he developed an acute exacerbation of his renal failure with a peak creatinine level of 6.7 mg/dL (an increase from his baseline [2–3 mg/dL; reference range, 0.6–1.2 mg/dL]). Evaluation of the ulcer of the lower extremity included Gd-DTPA–enhanced magnetic resonance angiography (MRA) vascular imaging. The day of MRA evaluation, his bicarbonate level was low at 15 mmol/L (reference range, 21–28 mmol/L), his creatinine level was elevated at 4.4 mg/dL, his corrected calcium level was within reference range, and his phosphate level was elevated at 6.1 mg/dL (reference range, 2.5–4.5 mg/dL). The patient's renal status continued to decline over the next several days and hemodialysis was initiated. The patient recalled progressive firmness of the skin, which presented approximately 4 to 6 weeks after his Gd-DTPA exposure. He denied pain, pruritus, or loss of sensation in the affected areas. At and around the time of presentation, the patient was taking calcitriol, calcium, dapsone, darbepoetin alfa, diphenoxylate hydrochloride and atropine sulfate, guar gum, magnesium, metoprolol succinate, mycophenolate mofetil, pantoprazole sodium, prednisone, psyllium, simvastatin, tacrolimus, and warfarin sodium. He was not on an angiotensin-converting enzyme inhibitor. Physical examination revealed subtle erythema overlying woody induration of the skin extending from the bilateral mid upper arms to the hands and from the bilateral mid calves to the anterolateral thighs and flanks, with substantially reduced range of motion in the hands (Figures 1 and 2). Findings from a biopsy specimen showed an increase in cellularity of the dermis, thickened collagen bundles, and subcutaneous septae. Many cells had poorly defined cytoplasms and elongated, plump, enlarged nuclei. Evaluation with elastin stains showed thickened elastic fibers in the dermis. Alcian blue staining revealed an increase in mucin in the dermis and subcutaneous septae consistent with NSF.


Comment
Our patient, like previously described patients,12 had received Gd-DTPA for an MRA a few weeks prior to the onset of NSF. Grobner12 also demonstrated that all of the patients with NSF were acidotic, in contrast to a similar unaffected group of patients with normal acid-base status. At the time of Gd-contrast exposure, we can infer that our patient likely had metabolic acidosis based on his bicarbonate level of 15 mmol/L. So the question remains: Is Gd exposure in the presence of a metabolic, or other unclear alteration, the trigger for this new and potentially lethal disorder? Gadolinium is a rare toxic metal that, as a free ion, forms precipitates with anions, such as phosphate, carbonate, hydroxyl, or chloride, and can deposit in tissue.17 To reduce the toxicity, Gd contrast is chelated with other molecules (eg, DTPA) to form soluble ligand complexes, thus stabilizing it intravascularly. Stability is dependent on multiple parameters, including the thermodynamic stability constant, molecular kinetics, solubility constant, and selectivity constants.18 The half-life of chelated Gd is approximately 1.5 to 2 hours and demonstrates a 500-fold increase in renal excretion when compared with elemental Gd.17 In the healthy kidney, approximately 90% of injected Gd-DTPA is excreted in the first 24 hours. However, in cases of renal failure, the half-life of Gd can be more than 30 hours.19,20 Prompt hemodialysis can help clear Gd, with average excretory rates of 78.2% after the first session and up to 99.5% after a fourth session.20 There are 5 Gd-based contrast agents available for clinical use in the United States; however, none have been approved by the FDA for use in MRA.16 The stability of the agents has been studied in vitro and on animal models with healthy kidney function, but stability has not been evaluated in vivo in the setting of renal failure. All of the agents use chelators with very high affinity for Gd ion, but free ion can still be released in the presence of high concentrations of competing ions (metals or acids) or with prolonged exposure.17,19,21 Gadodiamide is the agent that has been used in the majority of patients with NSF reported in the literature, but it is too early at this time to implicate one agent over another and the FDA continues to investigate all Gd-based contrast agents as potential causes of NSF.12-14,16,18 Gadolinium contrast was first approved for clinical use in magnetic resonance imaging in 1988.12 In 1996, its use was favorably reported in patients with renal insufficiency.22 Since 1996, the use of Gd in patients with renal insufficiency has increased in frequency for vascular procedures such as aortography, dialysis fistulography, and renal angiography,17 which correlates well with the initial reports of NSF in 1997 in the United States and Europe.2 Delayed adaptation of this imaging technique could explain the later presentation of NSF in non-Western countries. Although the timing may correlate, how can one explain the possible pathophysiologic link between Gd and NSF? The histopathologic findings of NSF include thickened collagen bundles with surrounding clefts and a variable increase in mucin and elastic fibers. Immunohistochemistry reveals an increased proliferation of CD34+ fibrocytes, which are bone marrow–derived cells that circulate intravascularly and are thought to play a major role in wound healing.23-25 There is increased staining of CD34+/procollagen I+ circulating fibrocytes, transforming growth factor β1, CD68+/factor XIIIa+ monocytes, and multinucleated giant cells.12,23,24 In addition, 2 separate groups have detected Gd in the tissue of patients with NSF.14,15 The first group detected Gd particles in 4 of 13 tissue specimens from 7 patients using electron dispersion spectroscopy. In addition, they noted the Gd particles were likely to be associated with macrophages.14 These results were reproduced in a case report of a patient by Boyd et al.15 It is currently hypothesized that the deposition of CD34+/procollagen I+ circulating fibrocytes plays a major role in the pathophysiology of the disease, but the exact trigger, to this point, has been unclear.3,9 It now appears that Gd also plays a central role in the pathogenesis of NSF. Wound healing is similar in any tissue that has undergone injury and occurs through a stepwise process of inflammation, proliferation, and remodeling. Studies have looked at the role of macrophages in liver injury using a rat model and gadolinium chloride hexahydrate (GdCl3) to inhibit hepatic macrophages (Kupffer cells).26 The current hypothesis is that hepatic injury activates macrophages, resulting in release of proinflammatory cytokines and the subsequent recruitment of systemic macrophages and myofibrocytes.26 With inflammation, a profibrotic response occurs with deposition of types I and III collagen by fibrocytes. During the proliferation and remodeling phases, there is a systematic reversal of many of the cellular and molecular alterations of the inflammatory phase, which is essential to the restoration of healthy liver architecture and function.26 The Kupffer cells are thought to be integral to the repair process via cytokine-mediated paracrine or cell-to-cell stimulus that causes regression of myofibroblasts and degradation of excess collagen with matrix metalloproteinases. Prior experiments have revealed GdCl3-induced macrophage toxicity.27 It is speculated that elemental Gd is turbid above a pH of 6.0 and is engulfed by macrophages. The Gd aggregates may again dissolve in the acidic environment of the endosomes and attach to components of the vesicle membrane. Recycling of endosomes to the plasma membrane may gradually change the cellular membrane causing cell death.27 With the use of GdCl3, Roggin et al26 selectively inhibited Kupffer cells and observed delayed injury repair with increased extracellular matrix, bridging fibrosis and altered collagen metabolism, including increased type I collagen over time in livers of Gd-treated rats compared with the saline-treated controls. In addition, it is believed that fibrocytes undergo several phenotypic changes over the course of wound healing, resulting in modification of their interactions with the surrounding extracellular matrix.28 In 2004, Mori et al25 used a mouse model to show that more than 60% of the circulating bone marrow–derived CD13+/collagen I+/CD45+/CD34+ fibrocytes that migrate to sites of tissue injury become α-smooth muscle actin–positive myofibroblasts by day 7 post–wound healing. They noted down-regulation of expression of CD34 as cells underwent differentiation to myofibroblasts. They concluded that circulating fibrocytes undergo rapid phenotypic change under the influence of local factors once they have migrated to sites of injury.25 Based on these previously reported data, we hypothesize that in the presence of some unclear metabolic alteration, such as acidosis, and renal failure, exposure to high-dose Gd (as in MRA) for prolonged periods of time could result in Gd ion dissociation from its chelator. The Gd ion may precipitate with other anions, such as phosphate, or other metals, such as iron, and deposit in any tissue, resulting in local macrophage recruitment to engulf the elemental Gd. This theory could explain the initial tissue injury and the presence of multinucleated giant cells. The macrophages could recruit proinflammatory cells, such as CD34+ fibrocytes; however, the elemental Gd may cause early macrophage death, as previously demonstrated.27 The loss of macrophages could result in an aberrant tissue injury response with failure to progress to the remodeling stage. The persistent proinflammatory/recruitment stage with loss of functional macrophages could explain the high proportion of CD34+ fibrocytes, as they lack macrophage-derived stimulus to undergo appropriate phenotypic/functional change. Ultimately, we propose that NSF may stem from elemental Gd–induced macrophage death (Table).

 

 

Although there appears to be a strong association between Gd exposure and NSF, potential triggers are still being evaluated. In the past decade, there has been a dramatic shift to the use of MRA with Gd contrast in patients with renal failure due to known contrast-induced nephropathy observed with iodinated contrast. Considering the number of patients with renal failure receiving Gd contrast, Gd exposure alone is unlikely to be the sole cause of NSF and is more likely a component in a multifactorial process; however, the other risk factors remain elusive. MRA technology has been lifesaving for many patients with renal failure and remains a medical necessity in many situations, but the possible link to NSF may result in a need to modify current medical practices. The FDA's public health advisory strongly recommends prompt initiation of dialysis in any patient with advanced kidney disease who undergoes MRA with Gd.16 With the potential association of the dissociation of Gd chelates in an acidic environment, it also may be prudent to consider normalizing the pH of patients with bicarbonate infusion prior to MRA. At this time, further studies evaluating the safety of Gd contrast, its possible link to NSF, and the possible role of macrophage inhibition in the pathophysiology of NSF are needed.

References

  1. Centers for Disease Control and Prevention. Fibrosing skin condition among patients with renal disease—United States and Europe, 1997-2002. MMWR Morb Mortal Wkly Rep. 2002;51:25-26.
  2. Cowper SE, Robin HS, Steinberg SM, et al. Scleromyxedema-like cutaneous diseases in renal-dialysis patients. Lancet. 2000;356:1000-1001.
  3. Cowper SE, Bucala RB, LeBoit PE. Nephrogenic fibrosing dermopathy/nephrogenic systemic fibrosis—setting the record straight [editorial]. Semin Arthritis Rheum. 2006;35:208-210.
  4. Daram SR, Cortese CM, Bastani B. Nephrogenic fibrosing dermopathy/nephrogenic systemic fibrosis: report of a new case with literature review. Am J Kidney Dis. 2005;46:754-759.
  5. Gibson SE, Farver CF, Prayson RA. Multiorgan involvement in nephrogenic fibrosing dermopathy: an autopsy case and review of the literature. Arch Pathol Lab Med. 2006;130:209-212.
  6. LeBoit PE. What nephrogenic fibrosing dermopathy might be. Arch Dermatol. 2003;139:928-930.
  7. Ting WW, Stone MS, Madison KC, et al. Nephrogenic fibrosing dermopathy with systemic involvement. Arch Dermatol. 2003;139:903-906.
  8. Cassis TB, Jackson JM, Sonnier GB, et al. Nephrogenic fibrosing dermopathy in a patient with acute renal failure never requiring dialysis. Int J Dermatol. 2006;45:56-59.
  9. Cowper SE. Nephrogenic systemic fibrosis: the nosological and conceptual evolution of nephrogenic fibrosing dermopathy. Am J Kidney Dis. 2005;46:763-765.
  10. Panda S, Bandyopadhyay D, Tarafder A. Nephrogenic fibrosing dermopathy: a series in a non-Western population. J Am Acad Dermatol. 2006;54:155-159.
  11. Tan AW, Tan SH, Lian TY, et al. A case of nephrogenic fibrosing dermopathy. Ann Acad Med Singapore. 2004;33:527-529.
  12. Grobner T. Gadolinium—a specific trigger for the development of nephrogenic fibrosing dermopathy and nephrogenic systemic fibrosis? Nephrol Dial Transplant. 2006;21:1104-1108.
  13. Marckmann P, Skov L, Rossen K, et al. Nephrogenic systemic fibrosis: suspected causative role of gadodiamide used for contrast-enhanced magnetic resonance imaging. J Am Soc Nephrol. 2006;17:2359-2362.
  14. High WA, Ayers RA, Chandler J, et al. Gadolinium is detectable within the tissue of patients with nephrogenic systemic fibrosis. J Am Acad Dermatol. 2007;56:21-26.
  15. Boyd AS, Zic JA, Abraham JL. Gadolinium deposition in nephrogenic fibrosing dermopathy. J Am Acad Dermatol. 2007;56:27-30.
  16. Public health advisory: gadolinium-containing contrast agents for magnetic resonance imaging (MRI): Omniscan, OptiMARK, Magnevist, ProHance, and MultiHance. US Food and Drug Administration Web site. http://www .fda.gov/cder/drug/advisory/gadolinium_agents.htm. Published June 8, 2006. Updated May 23, 2007. Accessed June 22, 2006.
  17. Spinosa DJ, Kaufmann JA, Hartwell GD. Gadolinium chelates in angiography and interventional radiology: a useful alternative to iodinated contrast media for angiography. Radiology. 2002;223:319-325.
  18. Sadowski EA, Bennett LK, Chan MR, et al. Nephrogenic systemic fibrosis: risk factors and incidence estimation. Radiology. 2007;243:148-157.
  19. Vorobiov M, Basok A, Tovbin D, et al. Iron-mobilizing properties of the gadolinium-DTPA complex: clinical and experimental observations. Nephrol Dial Transplant. 2003;18:884-887.
  20. Okada S, Katagiri K, Kumazaki T, et al. Safety of gadolinium contrast agent in hemodialysis patients. Acta Radiol. 2001;42:339-341.
  21. Mann JS. Stability of gadolinium complexes in vitro and in vivo. J Comput Assist Tomogr. 1993;17:(suppl 1):S19-S23.
  22. Kaufman JA, Geller SC, Waltman AC. Renal insufficiency: gadopentetate dimeglumine as a radiographic contrast a
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Drs. Bennett and Garrett report no conflict of interest. The authors discuss the off-label use of gadolinium-based contrast agents for magnetic resonance angiography. Dr. Bennett is a resident, Departments of Dermatology and Internal Medicine, University of Wisconsin, Madison. Dr. Garrett is a dermatologist, Department of Dermatology, Dean Health System, Madison.

Lindsey K. Bennett, MD; Andrea L. Garrett, MD

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Drs. Bennett and Garrett report no conflict of interest. The authors discuss the off-label use of gadolinium-based contrast agents for magnetic resonance angiography. Dr. Bennett is a resident, Departments of Dermatology and Internal Medicine, University of Wisconsin, Madison. Dr. Garrett is a dermatologist, Department of Dermatology, Dean Health System, Madison.

Lindsey K. Bennett, MD; Andrea L. Garrett, MD

Author and Disclosure Information

Drs. Bennett and Garrett report no conflict of interest. The authors discuss the off-label use of gadolinium-based contrast agents for magnetic resonance angiography. Dr. Bennett is a resident, Departments of Dermatology and Internal Medicine, University of Wisconsin, Madison. Dr. Garrett is a dermatologist, Department of Dermatology, Dean Health System, Madison.

Lindsey K. Bennett, MD; Andrea L. Garrett, MD

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Nephrogenic fibrosing dermopathy (NFD) is an acquired idiopathic disorder seen exclusively in patients with renal failure. It was first recognized in 1997 in a group of patients following renal transplant.1,2 Symmetric, thickened, fibrotic skin with brawny hyperpigmentation develops and primarily affects the limbs, sparing the head and neck. Associated symptoms include flexion contracture, pain, paresthesia, and/or severe pruritus. Yellow palmar papules and yellow scleral plaques also have been described. Although fibrosis initially was observed in the skin, more recent evidence suggests that NFD is a systemic disorder with variable and still unclear degrees of end organ damage, particularly pulmonary fibrosis.3-7 In light of the systemic involvement and newly described, rapidly progressive, fatal cases of NFD, the name has been changed to nephrogenic systemic fibrosis (NSF).3 Since 1997, more than 200 cases have been compiled through the Yale University NSF Registry. All patients have the unifying diagnosis of renal failure, but the disease has been observed in patients independent of age, gender, dialysis history, kidney transplant status, or the underlying cause of renal failure.8,9 The majority of cases have been reported in the United States and Europe, but new cases are now being reported in non-Western populations.10,11 Given the novelty of the disease and the limited number of cases, the etiology has been elusive; however, most new diseases have some iatrogenic component. Prior to onset, many patients with NSF experienced coagulation abnormalities, transplant rejection, or some type of vascular intervention. As a result, contrast agents became suspect. Grobner12 reported 5 patients with NSF who had magnetic resonance imaging with gadolinium (Gd)–diethylenetriamine-penta-acetic acid (DTPA) contrast 2 to 4 weeks prior to the onset of fibrosis. All of the patients with NSF were acidotic, in contrast to a similar unaffected group of patients with normal acid-base status.12 Shortly after, Marckmann et al13 published a case series of 13 patients who developed NSF, all within 75 days of Gd contrast exposure; however, there was no correlation with metabolic acidosis in this study. Additional cases have been reported in association with exposure to Gd contrast.14,15 More recently, using electron microscopy with electron dispersion spectroscopy, Gd has been detected in the tissue of some patients with NSF.14,15 On June 8, 2006, the US Food and Drug Administration (FDA) released a public health advisory warning patients and physicians of the possible link between Gd-containing contrast agents and NSF.16 We report another case of NSF associated with Gd-DTPA exposure and propose a plausible explanation for the possible association and pathophysiology of NSF.


Case Report
A 54-year-old man with end-stage diabetic nephropathy status post–renal transplant was evaluated for induration and thickening of the skin. Two months prior, he presented with an infected nonhealing ulcer of the left foot and was admitted to the hospital for intravenous antibiotics. During his hospital stay, he developed an acute exacerbation of his renal failure with a peak creatinine level of 6.7 mg/dL (an increase from his baseline [2–3 mg/dL; reference range, 0.6–1.2 mg/dL]). Evaluation of the ulcer of the lower extremity included Gd-DTPA–enhanced magnetic resonance angiography (MRA) vascular imaging. The day of MRA evaluation, his bicarbonate level was low at 15 mmol/L (reference range, 21–28 mmol/L), his creatinine level was elevated at 4.4 mg/dL, his corrected calcium level was within reference range, and his phosphate level was elevated at 6.1 mg/dL (reference range, 2.5–4.5 mg/dL). The patient's renal status continued to decline over the next several days and hemodialysis was initiated. The patient recalled progressive firmness of the skin, which presented approximately 4 to 6 weeks after his Gd-DTPA exposure. He denied pain, pruritus, or loss of sensation in the affected areas. At and around the time of presentation, the patient was taking calcitriol, calcium, dapsone, darbepoetin alfa, diphenoxylate hydrochloride and atropine sulfate, guar gum, magnesium, metoprolol succinate, mycophenolate mofetil, pantoprazole sodium, prednisone, psyllium, simvastatin, tacrolimus, and warfarin sodium. He was not on an angiotensin-converting enzyme inhibitor. Physical examination revealed subtle erythema overlying woody induration of the skin extending from the bilateral mid upper arms to the hands and from the bilateral mid calves to the anterolateral thighs and flanks, with substantially reduced range of motion in the hands (Figures 1 and 2). Findings from a biopsy specimen showed an increase in cellularity of the dermis, thickened collagen bundles, and subcutaneous septae. Many cells had poorly defined cytoplasms and elongated, plump, enlarged nuclei. Evaluation with elastin stains showed thickened elastic fibers in the dermis. Alcian blue staining revealed an increase in mucin in the dermis and subcutaneous septae consistent with NSF.


Comment
Our patient, like previously described patients,12 had received Gd-DTPA for an MRA a few weeks prior to the onset of NSF. Grobner12 also demonstrated that all of the patients with NSF were acidotic, in contrast to a similar unaffected group of patients with normal acid-base status. At the time of Gd-contrast exposure, we can infer that our patient likely had metabolic acidosis based on his bicarbonate level of 15 mmol/L. So the question remains: Is Gd exposure in the presence of a metabolic, or other unclear alteration, the trigger for this new and potentially lethal disorder? Gadolinium is a rare toxic metal that, as a free ion, forms precipitates with anions, such as phosphate, carbonate, hydroxyl, or chloride, and can deposit in tissue.17 To reduce the toxicity, Gd contrast is chelated with other molecules (eg, DTPA) to form soluble ligand complexes, thus stabilizing it intravascularly. Stability is dependent on multiple parameters, including the thermodynamic stability constant, molecular kinetics, solubility constant, and selectivity constants.18 The half-life of chelated Gd is approximately 1.5 to 2 hours and demonstrates a 500-fold increase in renal excretion when compared with elemental Gd.17 In the healthy kidney, approximately 90% of injected Gd-DTPA is excreted in the first 24 hours. However, in cases of renal failure, the half-life of Gd can be more than 30 hours.19,20 Prompt hemodialysis can help clear Gd, with average excretory rates of 78.2% after the first session and up to 99.5% after a fourth session.20 There are 5 Gd-based contrast agents available for clinical use in the United States; however, none have been approved by the FDA for use in MRA.16 The stability of the agents has been studied in vitro and on animal models with healthy kidney function, but stability has not been evaluated in vivo in the setting of renal failure. All of the agents use chelators with very high affinity for Gd ion, but free ion can still be released in the presence of high concentrations of competing ions (metals or acids) or with prolonged exposure.17,19,21 Gadodiamide is the agent that has been used in the majority of patients with NSF reported in the literature, but it is too early at this time to implicate one agent over another and the FDA continues to investigate all Gd-based contrast agents as potential causes of NSF.12-14,16,18 Gadolinium contrast was first approved for clinical use in magnetic resonance imaging in 1988.12 In 1996, its use was favorably reported in patients with renal insufficiency.22 Since 1996, the use of Gd in patients with renal insufficiency has increased in frequency for vascular procedures such as aortography, dialysis fistulography, and renal angiography,17 which correlates well with the initial reports of NSF in 1997 in the United States and Europe.2 Delayed adaptation of this imaging technique could explain the later presentation of NSF in non-Western countries. Although the timing may correlate, how can one explain the possible pathophysiologic link between Gd and NSF? The histopathologic findings of NSF include thickened collagen bundles with surrounding clefts and a variable increase in mucin and elastic fibers. Immunohistochemistry reveals an increased proliferation of CD34+ fibrocytes, which are bone marrow–derived cells that circulate intravascularly and are thought to play a major role in wound healing.23-25 There is increased staining of CD34+/procollagen I+ circulating fibrocytes, transforming growth factor β1, CD68+/factor XIIIa+ monocytes, and multinucleated giant cells.12,23,24 In addition, 2 separate groups have detected Gd in the tissue of patients with NSF.14,15 The first group detected Gd particles in 4 of 13 tissue specimens from 7 patients using electron dispersion spectroscopy. In addition, they noted the Gd particles were likely to be associated with macrophages.14 These results were reproduced in a case report of a patient by Boyd et al.15 It is currently hypothesized that the deposition of CD34+/procollagen I+ circulating fibrocytes plays a major role in the pathophysiology of the disease, but the exact trigger, to this point, has been unclear.3,9 It now appears that Gd also plays a central role in the pathogenesis of NSF. Wound healing is similar in any tissue that has undergone injury and occurs through a stepwise process of inflammation, proliferation, and remodeling. Studies have looked at the role of macrophages in liver injury using a rat model and gadolinium chloride hexahydrate (GdCl3) to inhibit hepatic macrophages (Kupffer cells).26 The current hypothesis is that hepatic injury activates macrophages, resulting in release of proinflammatory cytokines and the subsequent recruitment of systemic macrophages and myofibrocytes.26 With inflammation, a profibrotic response occurs with deposition of types I and III collagen by fibrocytes. During the proliferation and remodeling phases, there is a systematic reversal of many of the cellular and molecular alterations of the inflammatory phase, which is essential to the restoration of healthy liver architecture and function.26 The Kupffer cells are thought to be integral to the repair process via cytokine-mediated paracrine or cell-to-cell stimulus that causes regression of myofibroblasts and degradation of excess collagen with matrix metalloproteinases. Prior experiments have revealed GdCl3-induced macrophage toxicity.27 It is speculated that elemental Gd is turbid above a pH of 6.0 and is engulfed by macrophages. The Gd aggregates may again dissolve in the acidic environment of the endosomes and attach to components of the vesicle membrane. Recycling of endosomes to the plasma membrane may gradually change the cellular membrane causing cell death.27 With the use of GdCl3, Roggin et al26 selectively inhibited Kupffer cells and observed delayed injury repair with increased extracellular matrix, bridging fibrosis and altered collagen metabolism, including increased type I collagen over time in livers of Gd-treated rats compared with the saline-treated controls. In addition, it is believed that fibrocytes undergo several phenotypic changes over the course of wound healing, resulting in modification of their interactions with the surrounding extracellular matrix.28 In 2004, Mori et al25 used a mouse model to show that more than 60% of the circulating bone marrow–derived CD13+/collagen I+/CD45+/CD34+ fibrocytes that migrate to sites of tissue injury become α-smooth muscle actin–positive myofibroblasts by day 7 post–wound healing. They noted down-regulation of expression of CD34 as cells underwent differentiation to myofibroblasts. They concluded that circulating fibrocytes undergo rapid phenotypic change under the influence of local factors once they have migrated to sites of injury.25 Based on these previously reported data, we hypothesize that in the presence of some unclear metabolic alteration, such as acidosis, and renal failure, exposure to high-dose Gd (as in MRA) for prolonged periods of time could result in Gd ion dissociation from its chelator. The Gd ion may precipitate with other anions, such as phosphate, or other metals, such as iron, and deposit in any tissue, resulting in local macrophage recruitment to engulf the elemental Gd. This theory could explain the initial tissue injury and the presence of multinucleated giant cells. The macrophages could recruit proinflammatory cells, such as CD34+ fibrocytes; however, the elemental Gd may cause early macrophage death, as previously demonstrated.27 The loss of macrophages could result in an aberrant tissue injury response with failure to progress to the remodeling stage. The persistent proinflammatory/recruitment stage with loss of functional macrophages could explain the high proportion of CD34+ fibrocytes, as they lack macrophage-derived stimulus to undergo appropriate phenotypic/functional change. Ultimately, we propose that NSF may stem from elemental Gd–induced macrophage death (Table).

 

 

Although there appears to be a strong association between Gd exposure and NSF, potential triggers are still being evaluated. In the past decade, there has been a dramatic shift to the use of MRA with Gd contrast in patients with renal failure due to known contrast-induced nephropathy observed with iodinated contrast. Considering the number of patients with renal failure receiving Gd contrast, Gd exposure alone is unlikely to be the sole cause of NSF and is more likely a component in a multifactorial process; however, the other risk factors remain elusive. MRA technology has been lifesaving for many patients with renal failure and remains a medical necessity in many situations, but the possible link to NSF may result in a need to modify current medical practices. The FDA's public health advisory strongly recommends prompt initiation of dialysis in any patient with advanced kidney disease who undergoes MRA with Gd.16 With the potential association of the dissociation of Gd chelates in an acidic environment, it also may be prudent to consider normalizing the pH of patients with bicarbonate infusion prior to MRA. At this time, further studies evaluating the safety of Gd contrast, its possible link to NSF, and the possible role of macrophage inhibition in the pathophysiology of NSF are needed.

Nephrogenic fibrosing dermopathy (NFD) is an acquired idiopathic disorder seen exclusively in patients with renal failure. It was first recognized in 1997 in a group of patients following renal transplant.1,2 Symmetric, thickened, fibrotic skin with brawny hyperpigmentation develops and primarily affects the limbs, sparing the head and neck. Associated symptoms include flexion contracture, pain, paresthesia, and/or severe pruritus. Yellow palmar papules and yellow scleral plaques also have been described. Although fibrosis initially was observed in the skin, more recent evidence suggests that NFD is a systemic disorder with variable and still unclear degrees of end organ damage, particularly pulmonary fibrosis.3-7 In light of the systemic involvement and newly described, rapidly progressive, fatal cases of NFD, the name has been changed to nephrogenic systemic fibrosis (NSF).3 Since 1997, more than 200 cases have been compiled through the Yale University NSF Registry. All patients have the unifying diagnosis of renal failure, but the disease has been observed in patients independent of age, gender, dialysis history, kidney transplant status, or the underlying cause of renal failure.8,9 The majority of cases have been reported in the United States and Europe, but new cases are now being reported in non-Western populations.10,11 Given the novelty of the disease and the limited number of cases, the etiology has been elusive; however, most new diseases have some iatrogenic component. Prior to onset, many patients with NSF experienced coagulation abnormalities, transplant rejection, or some type of vascular intervention. As a result, contrast agents became suspect. Grobner12 reported 5 patients with NSF who had magnetic resonance imaging with gadolinium (Gd)–diethylenetriamine-penta-acetic acid (DTPA) contrast 2 to 4 weeks prior to the onset of fibrosis. All of the patients with NSF were acidotic, in contrast to a similar unaffected group of patients with normal acid-base status.12 Shortly after, Marckmann et al13 published a case series of 13 patients who developed NSF, all within 75 days of Gd contrast exposure; however, there was no correlation with metabolic acidosis in this study. Additional cases have been reported in association with exposure to Gd contrast.14,15 More recently, using electron microscopy with electron dispersion spectroscopy, Gd has been detected in the tissue of some patients with NSF.14,15 On June 8, 2006, the US Food and Drug Administration (FDA) released a public health advisory warning patients and physicians of the possible link between Gd-containing contrast agents and NSF.16 We report another case of NSF associated with Gd-DTPA exposure and propose a plausible explanation for the possible association and pathophysiology of NSF.


Case Report
A 54-year-old man with end-stage diabetic nephropathy status post–renal transplant was evaluated for induration and thickening of the skin. Two months prior, he presented with an infected nonhealing ulcer of the left foot and was admitted to the hospital for intravenous antibiotics. During his hospital stay, he developed an acute exacerbation of his renal failure with a peak creatinine level of 6.7 mg/dL (an increase from his baseline [2–3 mg/dL; reference range, 0.6–1.2 mg/dL]). Evaluation of the ulcer of the lower extremity included Gd-DTPA–enhanced magnetic resonance angiography (MRA) vascular imaging. The day of MRA evaluation, his bicarbonate level was low at 15 mmol/L (reference range, 21–28 mmol/L), his creatinine level was elevated at 4.4 mg/dL, his corrected calcium level was within reference range, and his phosphate level was elevated at 6.1 mg/dL (reference range, 2.5–4.5 mg/dL). The patient's renal status continued to decline over the next several days and hemodialysis was initiated. The patient recalled progressive firmness of the skin, which presented approximately 4 to 6 weeks after his Gd-DTPA exposure. He denied pain, pruritus, or loss of sensation in the affected areas. At and around the time of presentation, the patient was taking calcitriol, calcium, dapsone, darbepoetin alfa, diphenoxylate hydrochloride and atropine sulfate, guar gum, magnesium, metoprolol succinate, mycophenolate mofetil, pantoprazole sodium, prednisone, psyllium, simvastatin, tacrolimus, and warfarin sodium. He was not on an angiotensin-converting enzyme inhibitor. Physical examination revealed subtle erythema overlying woody induration of the skin extending from the bilateral mid upper arms to the hands and from the bilateral mid calves to the anterolateral thighs and flanks, with substantially reduced range of motion in the hands (Figures 1 and 2). Findings from a biopsy specimen showed an increase in cellularity of the dermis, thickened collagen bundles, and subcutaneous septae. Many cells had poorly defined cytoplasms and elongated, plump, enlarged nuclei. Evaluation with elastin stains showed thickened elastic fibers in the dermis. Alcian blue staining revealed an increase in mucin in the dermis and subcutaneous septae consistent with NSF.


Comment
Our patient, like previously described patients,12 had received Gd-DTPA for an MRA a few weeks prior to the onset of NSF. Grobner12 also demonstrated that all of the patients with NSF were acidotic, in contrast to a similar unaffected group of patients with normal acid-base status. At the time of Gd-contrast exposure, we can infer that our patient likely had metabolic acidosis based on his bicarbonate level of 15 mmol/L. So the question remains: Is Gd exposure in the presence of a metabolic, or other unclear alteration, the trigger for this new and potentially lethal disorder? Gadolinium is a rare toxic metal that, as a free ion, forms precipitates with anions, such as phosphate, carbonate, hydroxyl, or chloride, and can deposit in tissue.17 To reduce the toxicity, Gd contrast is chelated with other molecules (eg, DTPA) to form soluble ligand complexes, thus stabilizing it intravascularly. Stability is dependent on multiple parameters, including the thermodynamic stability constant, molecular kinetics, solubility constant, and selectivity constants.18 The half-life of chelated Gd is approximately 1.5 to 2 hours and demonstrates a 500-fold increase in renal excretion when compared with elemental Gd.17 In the healthy kidney, approximately 90% of injected Gd-DTPA is excreted in the first 24 hours. However, in cases of renal failure, the half-life of Gd can be more than 30 hours.19,20 Prompt hemodialysis can help clear Gd, with average excretory rates of 78.2% after the first session and up to 99.5% after a fourth session.20 There are 5 Gd-based contrast agents available for clinical use in the United States; however, none have been approved by the FDA for use in MRA.16 The stability of the agents has been studied in vitro and on animal models with healthy kidney function, but stability has not been evaluated in vivo in the setting of renal failure. All of the agents use chelators with very high affinity for Gd ion, but free ion can still be released in the presence of high concentrations of competing ions (metals or acids) or with prolonged exposure.17,19,21 Gadodiamide is the agent that has been used in the majority of patients with NSF reported in the literature, but it is too early at this time to implicate one agent over another and the FDA continues to investigate all Gd-based contrast agents as potential causes of NSF.12-14,16,18 Gadolinium contrast was first approved for clinical use in magnetic resonance imaging in 1988.12 In 1996, its use was favorably reported in patients with renal insufficiency.22 Since 1996, the use of Gd in patients with renal insufficiency has increased in frequency for vascular procedures such as aortography, dialysis fistulography, and renal angiography,17 which correlates well with the initial reports of NSF in 1997 in the United States and Europe.2 Delayed adaptation of this imaging technique could explain the later presentation of NSF in non-Western countries. Although the timing may correlate, how can one explain the possible pathophysiologic link between Gd and NSF? The histopathologic findings of NSF include thickened collagen bundles with surrounding clefts and a variable increase in mucin and elastic fibers. Immunohistochemistry reveals an increased proliferation of CD34+ fibrocytes, which are bone marrow–derived cells that circulate intravascularly and are thought to play a major role in wound healing.23-25 There is increased staining of CD34+/procollagen I+ circulating fibrocytes, transforming growth factor β1, CD68+/factor XIIIa+ monocytes, and multinucleated giant cells.12,23,24 In addition, 2 separate groups have detected Gd in the tissue of patients with NSF.14,15 The first group detected Gd particles in 4 of 13 tissue specimens from 7 patients using electron dispersion spectroscopy. In addition, they noted the Gd particles were likely to be associated with macrophages.14 These results were reproduced in a case report of a patient by Boyd et al.15 It is currently hypothesized that the deposition of CD34+/procollagen I+ circulating fibrocytes plays a major role in the pathophysiology of the disease, but the exact trigger, to this point, has been unclear.3,9 It now appears that Gd also plays a central role in the pathogenesis of NSF. Wound healing is similar in any tissue that has undergone injury and occurs through a stepwise process of inflammation, proliferation, and remodeling. Studies have looked at the role of macrophages in liver injury using a rat model and gadolinium chloride hexahydrate (GdCl3) to inhibit hepatic macrophages (Kupffer cells).26 The current hypothesis is that hepatic injury activates macrophages, resulting in release of proinflammatory cytokines and the subsequent recruitment of systemic macrophages and myofibrocytes.26 With inflammation, a profibrotic response occurs with deposition of types I and III collagen by fibrocytes. During the proliferation and remodeling phases, there is a systematic reversal of many of the cellular and molecular alterations of the inflammatory phase, which is essential to the restoration of healthy liver architecture and function.26 The Kupffer cells are thought to be integral to the repair process via cytokine-mediated paracrine or cell-to-cell stimulus that causes regression of myofibroblasts and degradation of excess collagen with matrix metalloproteinases. Prior experiments have revealed GdCl3-induced macrophage toxicity.27 It is speculated that elemental Gd is turbid above a pH of 6.0 and is engulfed by macrophages. The Gd aggregates may again dissolve in the acidic environment of the endosomes and attach to components of the vesicle membrane. Recycling of endosomes to the plasma membrane may gradually change the cellular membrane causing cell death.27 With the use of GdCl3, Roggin et al26 selectively inhibited Kupffer cells and observed delayed injury repair with increased extracellular matrix, bridging fibrosis and altered collagen metabolism, including increased type I collagen over time in livers of Gd-treated rats compared with the saline-treated controls. In addition, it is believed that fibrocytes undergo several phenotypic changes over the course of wound healing, resulting in modification of their interactions with the surrounding extracellular matrix.28 In 2004, Mori et al25 used a mouse model to show that more than 60% of the circulating bone marrow–derived CD13+/collagen I+/CD45+/CD34+ fibrocytes that migrate to sites of tissue injury become α-smooth muscle actin–positive myofibroblasts by day 7 post–wound healing. They noted down-regulation of expression of CD34 as cells underwent differentiation to myofibroblasts. They concluded that circulating fibrocytes undergo rapid phenotypic change under the influence of local factors once they have migrated to sites of injury.25 Based on these previously reported data, we hypothesize that in the presence of some unclear metabolic alteration, such as acidosis, and renal failure, exposure to high-dose Gd (as in MRA) for prolonged periods of time could result in Gd ion dissociation from its chelator. The Gd ion may precipitate with other anions, such as phosphate, or other metals, such as iron, and deposit in any tissue, resulting in local macrophage recruitment to engulf the elemental Gd. This theory could explain the initial tissue injury and the presence of multinucleated giant cells. The macrophages could recruit proinflammatory cells, such as CD34+ fibrocytes; however, the elemental Gd may cause early macrophage death, as previously demonstrated.27 The loss of macrophages could result in an aberrant tissue injury response with failure to progress to the remodeling stage. The persistent proinflammatory/recruitment stage with loss of functional macrophages could explain the high proportion of CD34+ fibrocytes, as they lack macrophage-derived stimulus to undergo appropriate phenotypic/functional change. Ultimately, we propose that NSF may stem from elemental Gd–induced macrophage death (Table).

 

 

Although there appears to be a strong association between Gd exposure and NSF, potential triggers are still being evaluated. In the past decade, there has been a dramatic shift to the use of MRA with Gd contrast in patients with renal failure due to known contrast-induced nephropathy observed with iodinated contrast. Considering the number of patients with renal failure receiving Gd contrast, Gd exposure alone is unlikely to be the sole cause of NSF and is more likely a component in a multifactorial process; however, the other risk factors remain elusive. MRA technology has been lifesaving for many patients with renal failure and remains a medical necessity in many situations, but the possible link to NSF may result in a need to modify current medical practices. The FDA's public health advisory strongly recommends prompt initiation of dialysis in any patient with advanced kidney disease who undergoes MRA with Gd.16 With the potential association of the dissociation of Gd chelates in an acidic environment, it also may be prudent to consider normalizing the pH of patients with bicarbonate infusion prior to MRA. At this time, further studies evaluating the safety of Gd contrast, its possible link to NSF, and the possible role of macrophage inhibition in the pathophysiology of NSF are needed.

References

  1. Centers for Disease Control and Prevention. Fibrosing skin condition among patients with renal disease—United States and Europe, 1997-2002. MMWR Morb Mortal Wkly Rep. 2002;51:25-26.
  2. Cowper SE, Robin HS, Steinberg SM, et al. Scleromyxedema-like cutaneous diseases in renal-dialysis patients. Lancet. 2000;356:1000-1001.
  3. Cowper SE, Bucala RB, LeBoit PE. Nephrogenic fibrosing dermopathy/nephrogenic systemic fibrosis—setting the record straight [editorial]. Semin Arthritis Rheum. 2006;35:208-210.
  4. Daram SR, Cortese CM, Bastani B. Nephrogenic fibrosing dermopathy/nephrogenic systemic fibrosis: report of a new case with literature review. Am J Kidney Dis. 2005;46:754-759.
  5. Gibson SE, Farver CF, Prayson RA. Multiorgan involvement in nephrogenic fibrosing dermopathy: an autopsy case and review of the literature. Arch Pathol Lab Med. 2006;130:209-212.
  6. LeBoit PE. What nephrogenic fibrosing dermopathy might be. Arch Dermatol. 2003;139:928-930.
  7. Ting WW, Stone MS, Madison KC, et al. Nephrogenic fibrosing dermopathy with systemic involvement. Arch Dermatol. 2003;139:903-906.
  8. Cassis TB, Jackson JM, Sonnier GB, et al. Nephrogenic fibrosing dermopathy in a patient with acute renal failure never requiring dialysis. Int J Dermatol. 2006;45:56-59.
  9. Cowper SE. Nephrogenic systemic fibrosis: the nosological and conceptual evolution of nephrogenic fibrosing dermopathy. Am J Kidney Dis. 2005;46:763-765.
  10. Panda S, Bandyopadhyay D, Tarafder A. Nephrogenic fibrosing dermopathy: a series in a non-Western population. J Am Acad Dermatol. 2006;54:155-159.
  11. Tan AW, Tan SH, Lian TY, et al. A case of nephrogenic fibrosing dermopathy. Ann Acad Med Singapore. 2004;33:527-529.
  12. Grobner T. Gadolinium—a specific trigger for the development of nephrogenic fibrosing dermopathy and nephrogenic systemic fibrosis? Nephrol Dial Transplant. 2006;21:1104-1108.
  13. Marckmann P, Skov L, Rossen K, et al. Nephrogenic systemic fibrosis: suspected causative role of gadodiamide used for contrast-enhanced magnetic resonance imaging. J Am Soc Nephrol. 2006;17:2359-2362.
  14. High WA, Ayers RA, Chandler J, et al. Gadolinium is detectable within the tissue of patients with nephrogenic systemic fibrosis. J Am Acad Dermatol. 2007;56:21-26.
  15. Boyd AS, Zic JA, Abraham JL. Gadolinium deposition in nephrogenic fibrosing dermopathy. J Am Acad Dermatol. 2007;56:27-30.
  16. Public health advisory: gadolinium-containing contrast agents for magnetic resonance imaging (MRI): Omniscan, OptiMARK, Magnevist, ProHance, and MultiHance. US Food and Drug Administration Web site. http://www .fda.gov/cder/drug/advisory/gadolinium_agents.htm. Published June 8, 2006. Updated May 23, 2007. Accessed June 22, 2006.
  17. Spinosa DJ, Kaufmann JA, Hartwell GD. Gadolinium chelates in angiography and interventional radiology: a useful alternative to iodinated contrast media for angiography. Radiology. 2002;223:319-325.
  18. Sadowski EA, Bennett LK, Chan MR, et al. Nephrogenic systemic fibrosis: risk factors and incidence estimation. Radiology. 2007;243:148-157.
  19. Vorobiov M, Basok A, Tovbin D, et al. Iron-mobilizing properties of the gadolinium-DTPA complex: clinical and experimental observations. Nephrol Dial Transplant. 2003;18:884-887.
  20. Okada S, Katagiri K, Kumazaki T, et al. Safety of gadolinium contrast agent in hemodialysis patients. Acta Radiol. 2001;42:339-341.
  21. Mann JS. Stability of gadolinium complexes in vitro and in vivo. J Comput Assist Tomogr. 1993;17:(suppl 1):S19-S23.
  22. Kaufman JA, Geller SC, Waltman AC. Renal insufficiency: gadopentetate dimeglumine as a radiographic contrast a
References

  1. Centers for Disease Control and Prevention. Fibrosing skin condition among patients with renal disease—United States and Europe, 1997-2002. MMWR Morb Mortal Wkly Rep. 2002;51:25-26.
  2. Cowper SE, Robin HS, Steinberg SM, et al. Scleromyxedema-like cutaneous diseases in renal-dialysis patients. Lancet. 2000;356:1000-1001.
  3. Cowper SE, Bucala RB, LeBoit PE. Nephrogenic fibrosing dermopathy/nephrogenic systemic fibrosis—setting the record straight [editorial]. Semin Arthritis Rheum. 2006;35:208-210.
  4. Daram SR, Cortese CM, Bastani B. Nephrogenic fibrosing dermopathy/nephrogenic systemic fibrosis: report of a new case with literature review. Am J Kidney Dis. 2005;46:754-759.
  5. Gibson SE, Farver CF, Prayson RA. Multiorgan involvement in nephrogenic fibrosing dermopathy: an autopsy case and review of the literature. Arch Pathol Lab Med. 2006;130:209-212.
  6. LeBoit PE. What nephrogenic fibrosing dermopathy might be. Arch Dermatol. 2003;139:928-930.
  7. Ting WW, Stone MS, Madison KC, et al. Nephrogenic fibrosing dermopathy with systemic involvement. Arch Dermatol. 2003;139:903-906.
  8. Cassis TB, Jackson JM, Sonnier GB, et al. Nephrogenic fibrosing dermopathy in a patient with acute renal failure never requiring dialysis. Int J Dermatol. 2006;45:56-59.
  9. Cowper SE. Nephrogenic systemic fibrosis: the nosological and conceptual evolution of nephrogenic fibrosing dermopathy. Am J Kidney Dis. 2005;46:763-765.
  10. Panda S, Bandyopadhyay D, Tarafder A. Nephrogenic fibrosing dermopathy: a series in a non-Western population. J Am Acad Dermatol. 2006;54:155-159.
  11. Tan AW, Tan SH, Lian TY, et al. A case of nephrogenic fibrosing dermopathy. Ann Acad Med Singapore. 2004;33:527-529.
  12. Grobner T. Gadolinium—a specific trigger for the development of nephrogenic fibrosing dermopathy and nephrogenic systemic fibrosis? Nephrol Dial Transplant. 2006;21:1104-1108.
  13. Marckmann P, Skov L, Rossen K, et al. Nephrogenic systemic fibrosis: suspected causative role of gadodiamide used for contrast-enhanced magnetic resonance imaging. J Am Soc Nephrol. 2006;17:2359-2362.
  14. High WA, Ayers RA, Chandler J, et al. Gadolinium is detectable within the tissue of patients with nephrogenic systemic fibrosis. J Am Acad Dermatol. 2007;56:21-26.
  15. Boyd AS, Zic JA, Abraham JL. Gadolinium deposition in nephrogenic fibrosing dermopathy. J Am Acad Dermatol. 2007;56:27-30.
  16. Public health advisory: gadolinium-containing contrast agents for magnetic resonance imaging (MRI): Omniscan, OptiMARK, Magnevist, ProHance, and MultiHance. US Food and Drug Administration Web site. http://www .fda.gov/cder/drug/advisory/gadolinium_agents.htm. Published June 8, 2006. Updated May 23, 2007. Accessed June 22, 2006.
  17. Spinosa DJ, Kaufmann JA, Hartwell GD. Gadolinium chelates in angiography and interventional radiology: a useful alternative to iodinated contrast media for angiography. Radiology. 2002;223:319-325.
  18. Sadowski EA, Bennett LK, Chan MR, et al. Nephrogenic systemic fibrosis: risk factors and incidence estimation. Radiology. 2007;243:148-157.
  19. Vorobiov M, Basok A, Tovbin D, et al. Iron-mobilizing properties of the gadolinium-DTPA complex: clinical and experimental observations. Nephrol Dial Transplant. 2003;18:884-887.
  20. Okada S, Katagiri K, Kumazaki T, et al. Safety of gadolinium contrast agent in hemodialysis patients. Acta Radiol. 2001;42:339-341.
  21. Mann JS. Stability of gadolinium complexes in vitro and in vivo. J Comput Assist Tomogr. 1993;17:(suppl 1):S19-S23.
  22. Kaufman JA, Geller SC, Waltman AC. Renal insufficiency: gadopentetate dimeglumine as a radiographic contrast a
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Larva Currens in a Patient Scheduled for Renal Transplant

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Case Report

A 54-year-old woman with polycystic disease of kidneys was scheduled for renal transplant and presented with a 2-week history of an extremely pruritic rash that primarily affected her torso, buttocks, shoulders, and thighs. She described the lesions as red, raised, and linear, typically lasting less than 24 hours at a time. She had been previously treated with a 5-day course of prednisone by another physician, without improvement. Her only new medication was glucosamine and chondroitin sulfate, which she had started one week prior to the eruption. Raloxifene hydrochloride and cetirizine hydrochloride were long-term medications.

The patient reported one similar episode many years ago. She denied any recent changes in her health and reported no gastrointestinal tract or pulmonary symptoms. She was raised in Panama and had visited there in the past year. She specifically denied walking without shoes.

On physical examination, the patient had a pink, serpiginous, urticarial plaque on the right side of the trunk that was surrounded by a few red serpiginous patches (Figure). Her white blood cell count was 6.5X103/µL (reference range, 3.5–10.5X103/µL), with 19.2% eosinophils (reference, 2.7%). Her absolute eosinophil count was elevated at 1200/µL (reference range, 0–450/µL). A review of prior laboratory test results indicated that her absolute eosinophil count also had been elevated 6 months prior to presentation. Serologic evaluation by enzyme-linked immunosorbent assay was positive for Strongyloides. Results of stool studies did not reveal ova and parasites.

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The patient was treated with oral thiabendazole 1500 mg twice daily for 2 days and her transplant was postponed. Her rash resolved, but 2 weeks later, her white blood cell count was 5.6X103/µL, with 11.6% eosinophils. She was subsequently treated with a single dose of 200 µg/kg of ivermectin. Results of a complete blood count obtained 2 weeks later demonstrated that her eosinophil count was within reference range and she was able to proceed with the transplant. The patient's sister (the donor) also was born in Panama and had negative serologic evaluation results for Strongyloides. The patient did well following the transplant and the results of repeat serologic evaluations performed 4 months after the transplant were negative for Strongyloides.

Comment

Strongyloides stercoralis is an intestinal nematode primarily found in tropical or subtropical countries. Humans are infected by filariform larvae that dwell in the soil. Larvae penetrate intact skin, gain access to the venous system, pass through the heart to the lungs, enter the pulmonary alveoli, migrate up the tracheobronchial tree, and are swallowed, thereby entering the gastrointestinal tract.1 The larvae mature into adult females that penetrate the mucosa of the small intestine and deposit eggs. The eggs hatch into rhabditiform larvae that are passed in the stool to the soil where transformation into the infective form (filariform) occurs. Autoinfection may take place when this transformation to the infective-stage larvae occurs within the gastrointestinal tract, enabling the infective larvae to invade the lower large bowel or perianal skin and begin the migratory pathway. Autoinfection can allow the persistence of infection for long periods of time and also can allow chronic infections to persist in climates where free-living larvae cannot survive.2

Uncomplicated infection with S stercoralis can cause cutaneous, gastrointestinal tract, and pulmonary symptoms corresponding to the involvement of organs during the parasite's life cycle. Rash is uncommon in acute infection, though it is common in chronic disease. Maculopapular eruptions and chronic urticaria have been reported in up to two-thirds of patients.3 Larva currens is a migratory, rapidly extending, serpiginous, urticarial lesion that is pathognomonic for chronic strongyloidiasis. The rash typically lasts from several hours to several days. It most commonly affects the buttocks, perineum, and thighs, and is secondary to invasion of perianal skin by filariform larvae from the patient's intestine. Arthur and Shelley4 proposed the term larva currens (running larva) because the larvae and subsequent rash can move up to 10 cm per hour.

In a healthy host, the cellular immune system seems to limit parasite invasion of mucosal tissues.5 If immunosuppression occurs, individuals with strongyloidiasis can develop a hyperinfective syndrome and massive numbers of larvae can invade any organ of the body, with a mortality rate of 70% to 90%.6,7 The cutaneous manifestation of disseminated strongyloidiasis is the rapid onset of a petechial and purpuric eruption that typically involves the proximal extremities and trunk and results from massive invasion of the skin by filariform larvae. The "thumbprint sign" refers to a pattern of periumbilical ecchymoses resembling multiple thumbprints that can occur in hyperinfection.8

Gastrointestinal tract symptoms predominate in acute infection. Diarrhea and midepigastric pain that may mimic peptic ulcer disease are common. Diarrhea also can alternate with constipation. Other gastrointestinal tract symptoms include nausea, vomiting, anorexia, pruritus ani, and bloating.1 Some severe cases can have malabsorption and evidence of a protein-losing enteropathy.9,10

 

 

Pulmonary symptoms in acute infection can occur and include wheezing, coughing, and shortness of breath.1 Larval migration through the lungs also can lead to transient pulmonary infiltrates. Some patients have presented with asthma.11 Patients with chronic disease may have gastrointestinal tract and pulmonary symptoms, though chronic infection tends to be indolent and patients may be asymptomatic.

Diagnosis can be difficult, as results from stool samples often are negative and multiple samples may be required. Results of biopsies performed on larva currens specimens usually do not reveal larvae, though biopsy results of the petechial and purpuric eruptions of disseminated disease will reveal larvae. Serologic testing with enzyme-linked immunosorbent assay has a sensitivity of approximately 90%.12,13

Traditionally, thiabendazole has been used to treat this infection, though in approximately 30% of cases, the parasite is not eradicated from the feces. Ivermectin has been found to be more effective for treating uncomplicated chronic disease.14

In most cases of disseminated disease, patients were receiving corticosteroids or other immunosuppressive drugs or had an underlying illness, such as malignancy or AIDS.1,2,15,16 Our patient was scheduled to undergo a renal transplant and fatal disseminated strongyloidiasis has been reported in patients undergoing renal transplant.2,16 Morgan et al2 reviewed 29 cases of strongyloidiasis complicating renal transplants; 15 patients died.

Infection in the immunocompromised patient can be complicated by the fact that invasive larvae can transport gram-negative bacilli from the intestine to sites of migration, such as the pulmonary and central nervous systems.5 Gram-negative sepsis, meningitis, or pneumonia can result. Diagnosis can be difficult because eosinophilia often is absent in immunocompromised patients with disseminated disease.5

Although common in tropical and subtropical countries, other geographic regions of endemic Strongyloides are recognized. The climate and soil of the southeastern United States favor the survival of the organism,5 and the parasite was reported in 3% (N=561) of a group of rural Kentucky schoolchildren17; similar findings were reported in another study conducted in Kentucky.18Strongyloides also was the most commonly detected parasite in a review of stool samples examined at the University of Kentucky Medical Center.19 Ex–prisoners of war who served in Southeast Asia during World War II also constitute an at-risk group in the United States.20-22

It is imperative to rule out the presence of this parasite prior to transplant in patients with a geographic history predisposing them to infection, a history of eosinophilia, or symptoms of chronic strongyloidiasis.1 Many transplantation centers routinely screen for this parasite as part of the pretransplant evaluation. Although uncommon in acute infections, cutaneous involvement often is present in chronic strongyloidiasis.1 It also is important to follow patients already treated for larva currens closely posttransplant, as therapeutic failures occur.

References

  1. Longworth DL, Weller PF. Hyperinfection syndrome with strongyloidiasis. In: Remington JS, Swartz MN, eds. Current Clinical Topics in Infectious Diseases. New York, NY: McGraw-Hill; 1986:1-26.
  2. Morgan JS, Schaffner W, Sone WJ. Opportunistic strongyloidiasis in renal transplant recipients. Transplantation. 1986;42:518-524.
  3. Grove DI. Strongyloidiasis in allied ex–prisoners of war in south-east Asia. Br Med J. 1980;280:598-601.
  4. Arthur RP, Shelley WB. Larva currens; a distinctive variant of cutaneous larva migrans due to Strongyloides stercoralis. AMA Arch Derm. 1958;78:186-190.
  5. Zygmunt DJ. Strongyloides stercoralis. Infect Control Hosp Epidemiol. 1990;11:495-497.
  6. Singh S. Human strongyloidiasis in AIDS era: its zoonotic importance. J Assoc Physicians India. 2002;50:415-422.
  7. Rothenberg ME. Eosinophilia. N Engl J Med. 1998;338:1592-1600.
  8. Bank DE, Grossman ME, Kohn SR, et al. The thumbprint sign: rapid diagnosis of disseminated strongyloidiasis. J Am Acad Dermatol. 1990;23(2, pt 1):324-326.
  9. Milner PF, Irvine RA, Barton CJ, et al. Intestinal malabsorption in Strongyloides stercoralis infestation. Gut. 1965;6:574-581.
  10. O'Brien W. Intestinal malabsorption in acute infection with Strongyloides stercoralis. Trans R Soc Trop Med Hyg. 1975;69:69-77.
  11. Nwokolo C, Imohiosen EA. Strongyloidiasis of respiratory tract presenting as "asthma". Br Med J. 1973;2:153-154.
  12. Neva FA, Gam AA, Burke J. Comparison of larval antigens in an enzyme-linked immunosorbent assay for strongyloidiasis in humans. J Infect Dis. 1981;144:427-432.
  13. Genta RM. Strongyloidiasis. In: Walls KW, Schantz PM, eds. Immunodiagnosis of Parasitic Diseases. Vol 1. Orlando, FL: Academic Press Inc; 1986:183-199.
  14. Igual-Adell R, Oltra-Alcaraz C, Soler-Company E, et al. Efficacy and safety of ivermectin and thiabendazole in the treatment of strongyloidiasis. Expert Opin Pharmacother. 2004;5:2615-2619.
  15. Maayan S, Wormser GP, Widerhorn J, et al. Strongyloides stercoralis hyperinfection in a patient with the acquired immune deficiency syndrome. Am J Med. 1987;83:945-948.
  16. Weller IV, Copland P, Gabriel R. Strongyloides stercoralis infection in renal transplant recipients [letter]. Br Med J (Clin Res Ed). 1981;282:524.
  17. Walzer PD, Milder JE, Banwell JG, et al. Epidemiologic features of Strongyloides stercoralis infection in an endemic area of the United States. Am J Trop Med Hyg. 1982;31:313-319.
  18. Fulmer HS, Huempfner HR. Intestinal helminths in eastern Kentucky: a survey in three rural counties. Am J Trop Med Hyg. 1965;14:269-275.
  19. Milder JE, Walzer PD, Kilgore G, et al. Clinical features of Strongyloides stercoralis infection in an endemic area of the United States. Gastroenterology. 1981;80:1481-1488.
  20. Genta RM, Weesner R, Douce RW, et al. Strongyloidiasis in US veterans of the Vietnam and other wars. JAMA. 1987;258:49-52.
  21. Gill GV, Welch E, Bailey JW, et al. Chronic Strongyloides stercoralis infection in former British Far East prisoners of war. QJM. 2004;97:789-795.
  22. Pelletier LL Jr. Chronic strongyloidiasis in World War II Far East ex–prisoners of war. Am J Trop Med Hyg. 1984;33:55-61.
Article PDF
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Virginia C. Hall, MD; Nasimul Ahsan, MD; James H. Keeling, MD

Dr. Hall was and Dr. Keeling is from the Department of Dermatology and Dr. Ahsan is from the Department of Nephrology, all at Mayo Clinic, Jacksonville, Florida. Dr. Hall was Assistant Professor, Dr. Ahsan is Professor, and Dr. Keeling is Associate Professor.

Drs. Hall, Ahsan, and Keeling report no conflict of interest.

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Aesthetic Dermatology
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Hall VC
Ahsan N
Keeling JH
Author(s)
Hall VC
Ahsan N
Keeling JH
Author and Disclosure Information

Virginia C. Hall, MD; Nasimul Ahsan, MD; James H. Keeling, MD

Dr. Hall was and Dr. Keeling is from the Department of Dermatology and Dr. Ahsan is from the Department of Nephrology, all at Mayo Clinic, Jacksonville, Florida. Dr. Hall was Assistant Professor, Dr. Ahsan is Professor, and Dr. Keeling is Associate Professor.

Drs. Hall, Ahsan, and Keeling report no conflict of interest.

Author and Disclosure Information

Virginia C. Hall, MD; Nasimul Ahsan, MD; James H. Keeling, MD

Dr. Hall was and Dr. Keeling is from the Department of Dermatology and Dr. Ahsan is from the Department of Nephrology, all at Mayo Clinic, Jacksonville, Florida. Dr. Hall was Assistant Professor, Dr. Ahsan is Professor, and Dr. Keeling is Associate Professor.

Drs. Hall, Ahsan, and Keeling report no conflict of interest.

Article PDF
081050409.pdf
Article PDF
081050409.pdf

Case Report

A 54-year-old woman with polycystic disease of kidneys was scheduled for renal transplant and presented with a 2-week history of an extremely pruritic rash that primarily affected her torso, buttocks, shoulders, and thighs. She described the lesions as red, raised, and linear, typically lasting less than 24 hours at a time. She had been previously treated with a 5-day course of prednisone by another physician, without improvement. Her only new medication was glucosamine and chondroitin sulfate, which she had started one week prior to the eruption. Raloxifene hydrochloride and cetirizine hydrochloride were long-term medications.

The patient reported one similar episode many years ago. She denied any recent changes in her health and reported no gastrointestinal tract or pulmonary symptoms. She was raised in Panama and had visited there in the past year. She specifically denied walking without shoes.

On physical examination, the patient had a pink, serpiginous, urticarial plaque on the right side of the trunk that was surrounded by a few red serpiginous patches (Figure). Her white blood cell count was 6.5X103/µL (reference range, 3.5–10.5X103/µL), with 19.2% eosinophils (reference, 2.7%). Her absolute eosinophil count was elevated at 1200/µL (reference range, 0–450/µL). A review of prior laboratory test results indicated that her absolute eosinophil count also had been elevated 6 months prior to presentation. Serologic evaluation by enzyme-linked immunosorbent assay was positive for Strongyloides. Results of stool studies did not reveal ova and parasites.

PLEASE REFER TO THE PDF TO VIEW THE FIGURE

The patient was treated with oral thiabendazole 1500 mg twice daily for 2 days and her transplant was postponed. Her rash resolved, but 2 weeks later, her white blood cell count was 5.6X103/µL, with 11.6% eosinophils. She was subsequently treated with a single dose of 200 µg/kg of ivermectin. Results of a complete blood count obtained 2 weeks later demonstrated that her eosinophil count was within reference range and she was able to proceed with the transplant. The patient's sister (the donor) also was born in Panama and had negative serologic evaluation results for Strongyloides. The patient did well following the transplant and the results of repeat serologic evaluations performed 4 months after the transplant were negative for Strongyloides.

Comment

Strongyloides stercoralis is an intestinal nematode primarily found in tropical or subtropical countries. Humans are infected by filariform larvae that dwell in the soil. Larvae penetrate intact skin, gain access to the venous system, pass through the heart to the lungs, enter the pulmonary alveoli, migrate up the tracheobronchial tree, and are swallowed, thereby entering the gastrointestinal tract.1 The larvae mature into adult females that penetrate the mucosa of the small intestine and deposit eggs. The eggs hatch into rhabditiform larvae that are passed in the stool to the soil where transformation into the infective form (filariform) occurs. Autoinfection may take place when this transformation to the infective-stage larvae occurs within the gastrointestinal tract, enabling the infective larvae to invade the lower large bowel or perianal skin and begin the migratory pathway. Autoinfection can allow the persistence of infection for long periods of time and also can allow chronic infections to persist in climates where free-living larvae cannot survive.2

Uncomplicated infection with S stercoralis can cause cutaneous, gastrointestinal tract, and pulmonary symptoms corresponding to the involvement of organs during the parasite's life cycle. Rash is uncommon in acute infection, though it is common in chronic disease. Maculopapular eruptions and chronic urticaria have been reported in up to two-thirds of patients.3 Larva currens is a migratory, rapidly extending, serpiginous, urticarial lesion that is pathognomonic for chronic strongyloidiasis. The rash typically lasts from several hours to several days. It most commonly affects the buttocks, perineum, and thighs, and is secondary to invasion of perianal skin by filariform larvae from the patient's intestine. Arthur and Shelley4 proposed the term larva currens (running larva) because the larvae and subsequent rash can move up to 10 cm per hour.

In a healthy host, the cellular immune system seems to limit parasite invasion of mucosal tissues.5 If immunosuppression occurs, individuals with strongyloidiasis can develop a hyperinfective syndrome and massive numbers of larvae can invade any organ of the body, with a mortality rate of 70% to 90%.6,7 The cutaneous manifestation of disseminated strongyloidiasis is the rapid onset of a petechial and purpuric eruption that typically involves the proximal extremities and trunk and results from massive invasion of the skin by filariform larvae. The "thumbprint sign" refers to a pattern of periumbilical ecchymoses resembling multiple thumbprints that can occur in hyperinfection.8

Gastrointestinal tract symptoms predominate in acute infection. Diarrhea and midepigastric pain that may mimic peptic ulcer disease are common. Diarrhea also can alternate with constipation. Other gastrointestinal tract symptoms include nausea, vomiting, anorexia, pruritus ani, and bloating.1 Some severe cases can have malabsorption and evidence of a protein-losing enteropathy.9,10

 

 

Pulmonary symptoms in acute infection can occur and include wheezing, coughing, and shortness of breath.1 Larval migration through the lungs also can lead to transient pulmonary infiltrates. Some patients have presented with asthma.11 Patients with chronic disease may have gastrointestinal tract and pulmonary symptoms, though chronic infection tends to be indolent and patients may be asymptomatic.

Diagnosis can be difficult, as results from stool samples often are negative and multiple samples may be required. Results of biopsies performed on larva currens specimens usually do not reveal larvae, though biopsy results of the petechial and purpuric eruptions of disseminated disease will reveal larvae. Serologic testing with enzyme-linked immunosorbent assay has a sensitivity of approximately 90%.12,13

Traditionally, thiabendazole has been used to treat this infection, though in approximately 30% of cases, the parasite is not eradicated from the feces. Ivermectin has been found to be more effective for treating uncomplicated chronic disease.14

In most cases of disseminated disease, patients were receiving corticosteroids or other immunosuppressive drugs or had an underlying illness, such as malignancy or AIDS.1,2,15,16 Our patient was scheduled to undergo a renal transplant and fatal disseminated strongyloidiasis has been reported in patients undergoing renal transplant.2,16 Morgan et al2 reviewed 29 cases of strongyloidiasis complicating renal transplants; 15 patients died.

Infection in the immunocompromised patient can be complicated by the fact that invasive larvae can transport gram-negative bacilli from the intestine to sites of migration, such as the pulmonary and central nervous systems.5 Gram-negative sepsis, meningitis, or pneumonia can result. Diagnosis can be difficult because eosinophilia often is absent in immunocompromised patients with disseminated disease.5

Although common in tropical and subtropical countries, other geographic regions of endemic Strongyloides are recognized. The climate and soil of the southeastern United States favor the survival of the organism,5 and the parasite was reported in 3% (N=561) of a group of rural Kentucky schoolchildren17; similar findings were reported in another study conducted in Kentucky.18Strongyloides also was the most commonly detected parasite in a review of stool samples examined at the University of Kentucky Medical Center.19 Ex–prisoners of war who served in Southeast Asia during World War II also constitute an at-risk group in the United States.20-22

It is imperative to rule out the presence of this parasite prior to transplant in patients with a geographic history predisposing them to infection, a history of eosinophilia, or symptoms of chronic strongyloidiasis.1 Many transplantation centers routinely screen for this parasite as part of the pretransplant evaluation. Although uncommon in acute infections, cutaneous involvement often is present in chronic strongyloidiasis.1 It also is important to follow patients already treated for larva currens closely posttransplant, as therapeutic failures occur.

Case Report

A 54-year-old woman with polycystic disease of kidneys was scheduled for renal transplant and presented with a 2-week history of an extremely pruritic rash that primarily affected her torso, buttocks, shoulders, and thighs. She described the lesions as red, raised, and linear, typically lasting less than 24 hours at a time. She had been previously treated with a 5-day course of prednisone by another physician, without improvement. Her only new medication was glucosamine and chondroitin sulfate, which she had started one week prior to the eruption. Raloxifene hydrochloride and cetirizine hydrochloride were long-term medications.

The patient reported one similar episode many years ago. She denied any recent changes in her health and reported no gastrointestinal tract or pulmonary symptoms. She was raised in Panama and had visited there in the past year. She specifically denied walking without shoes.

On physical examination, the patient had a pink, serpiginous, urticarial plaque on the right side of the trunk that was surrounded by a few red serpiginous patches (Figure). Her white blood cell count was 6.5X103/µL (reference range, 3.5–10.5X103/µL), with 19.2% eosinophils (reference, 2.7%). Her absolute eosinophil count was elevated at 1200/µL (reference range, 0–450/µL). A review of prior laboratory test results indicated that her absolute eosinophil count also had been elevated 6 months prior to presentation. Serologic evaluation by enzyme-linked immunosorbent assay was positive for Strongyloides. Results of stool studies did not reveal ova and parasites.

PLEASE REFER TO THE PDF TO VIEW THE FIGURE

The patient was treated with oral thiabendazole 1500 mg twice daily for 2 days and her transplant was postponed. Her rash resolved, but 2 weeks later, her white blood cell count was 5.6X103/µL, with 11.6% eosinophils. She was subsequently treated with a single dose of 200 µg/kg of ivermectin. Results of a complete blood count obtained 2 weeks later demonstrated that her eosinophil count was within reference range and she was able to proceed with the transplant. The patient's sister (the donor) also was born in Panama and had negative serologic evaluation results for Strongyloides. The patient did well following the transplant and the results of repeat serologic evaluations performed 4 months after the transplant were negative for Strongyloides.

Comment

Strongyloides stercoralis is an intestinal nematode primarily found in tropical or subtropical countries. Humans are infected by filariform larvae that dwell in the soil. Larvae penetrate intact skin, gain access to the venous system, pass through the heart to the lungs, enter the pulmonary alveoli, migrate up the tracheobronchial tree, and are swallowed, thereby entering the gastrointestinal tract.1 The larvae mature into adult females that penetrate the mucosa of the small intestine and deposit eggs. The eggs hatch into rhabditiform larvae that are passed in the stool to the soil where transformation into the infective form (filariform) occurs. Autoinfection may take place when this transformation to the infective-stage larvae occurs within the gastrointestinal tract, enabling the infective larvae to invade the lower large bowel or perianal skin and begin the migratory pathway. Autoinfection can allow the persistence of infection for long periods of time and also can allow chronic infections to persist in climates where free-living larvae cannot survive.2

Uncomplicated infection with S stercoralis can cause cutaneous, gastrointestinal tract, and pulmonary symptoms corresponding to the involvement of organs during the parasite's life cycle. Rash is uncommon in acute infection, though it is common in chronic disease. Maculopapular eruptions and chronic urticaria have been reported in up to two-thirds of patients.3 Larva currens is a migratory, rapidly extending, serpiginous, urticarial lesion that is pathognomonic for chronic strongyloidiasis. The rash typically lasts from several hours to several days. It most commonly affects the buttocks, perineum, and thighs, and is secondary to invasion of perianal skin by filariform larvae from the patient's intestine. Arthur and Shelley4 proposed the term larva currens (running larva) because the larvae and subsequent rash can move up to 10 cm per hour.

In a healthy host, the cellular immune system seems to limit parasite invasion of mucosal tissues.5 If immunosuppression occurs, individuals with strongyloidiasis can develop a hyperinfective syndrome and massive numbers of larvae can invade any organ of the body, with a mortality rate of 70% to 90%.6,7 The cutaneous manifestation of disseminated strongyloidiasis is the rapid onset of a petechial and purpuric eruption that typically involves the proximal extremities and trunk and results from massive invasion of the skin by filariform larvae. The "thumbprint sign" refers to a pattern of periumbilical ecchymoses resembling multiple thumbprints that can occur in hyperinfection.8

Gastrointestinal tract symptoms predominate in acute infection. Diarrhea and midepigastric pain that may mimic peptic ulcer disease are common. Diarrhea also can alternate with constipation. Other gastrointestinal tract symptoms include nausea, vomiting, anorexia, pruritus ani, and bloating.1 Some severe cases can have malabsorption and evidence of a protein-losing enteropathy.9,10

 

 

Pulmonary symptoms in acute infection can occur and include wheezing, coughing, and shortness of breath.1 Larval migration through the lungs also can lead to transient pulmonary infiltrates. Some patients have presented with asthma.11 Patients with chronic disease may have gastrointestinal tract and pulmonary symptoms, though chronic infection tends to be indolent and patients may be asymptomatic.

Diagnosis can be difficult, as results from stool samples often are negative and multiple samples may be required. Results of biopsies performed on larva currens specimens usually do not reveal larvae, though biopsy results of the petechial and purpuric eruptions of disseminated disease will reveal larvae. Serologic testing with enzyme-linked immunosorbent assay has a sensitivity of approximately 90%.12,13

Traditionally, thiabendazole has been used to treat this infection, though in approximately 30% of cases, the parasite is not eradicated from the feces. Ivermectin has been found to be more effective for treating uncomplicated chronic disease.14

In most cases of disseminated disease, patients were receiving corticosteroids or other immunosuppressive drugs or had an underlying illness, such as malignancy or AIDS.1,2,15,16 Our patient was scheduled to undergo a renal transplant and fatal disseminated strongyloidiasis has been reported in patients undergoing renal transplant.2,16 Morgan et al2 reviewed 29 cases of strongyloidiasis complicating renal transplants; 15 patients died.

Infection in the immunocompromised patient can be complicated by the fact that invasive larvae can transport gram-negative bacilli from the intestine to sites of migration, such as the pulmonary and central nervous systems.5 Gram-negative sepsis, meningitis, or pneumonia can result. Diagnosis can be difficult because eosinophilia often is absent in immunocompromised patients with disseminated disease.5

Although common in tropical and subtropical countries, other geographic regions of endemic Strongyloides are recognized. The climate and soil of the southeastern United States favor the survival of the organism,5 and the parasite was reported in 3% (N=561) of a group of rural Kentucky schoolchildren17; similar findings were reported in another study conducted in Kentucky.18Strongyloides also was the most commonly detected parasite in a review of stool samples examined at the University of Kentucky Medical Center.19 Ex–prisoners of war who served in Southeast Asia during World War II also constitute an at-risk group in the United States.20-22

It is imperative to rule out the presence of this parasite prior to transplant in patients with a geographic history predisposing them to infection, a history of eosinophilia, or symptoms of chronic strongyloidiasis.1 Many transplantation centers routinely screen for this parasite as part of the pretransplant evaluation. Although uncommon in acute infections, cutaneous involvement often is present in chronic strongyloidiasis.1 It also is important to follow patients already treated for larva currens closely posttransplant, as therapeutic failures occur.

References

  1. Longworth DL, Weller PF. Hyperinfection syndrome with strongyloidiasis. In: Remington JS, Swartz MN, eds. Current Clinical Topics in Infectious Diseases. New York, NY: McGraw-Hill; 1986:1-26.
  2. Morgan JS, Schaffner W, Sone WJ. Opportunistic strongyloidiasis in renal transplant recipients. Transplantation. 1986;42:518-524.
  3. Grove DI. Strongyloidiasis in allied ex–prisoners of war in south-east Asia. Br Med J. 1980;280:598-601.
  4. Arthur RP, Shelley WB. Larva currens; a distinctive variant of cutaneous larva migrans due to Strongyloides stercoralis. AMA Arch Derm. 1958;78:186-190.
  5. Zygmunt DJ. Strongyloides stercoralis. Infect Control Hosp Epidemiol. 1990;11:495-497.
  6. Singh S. Human strongyloidiasis in AIDS era: its zoonotic importance. J Assoc Physicians India. 2002;50:415-422.
  7. Rothenberg ME. Eosinophilia. N Engl J Med. 1998;338:1592-1600.
  8. Bank DE, Grossman ME, Kohn SR, et al. The thumbprint sign: rapid diagnosis of disseminated strongyloidiasis. J Am Acad Dermatol. 1990;23(2, pt 1):324-326.
  9. Milner PF, Irvine RA, Barton CJ, et al. Intestinal malabsorption in Strongyloides stercoralis infestation. Gut. 1965;6:574-581.
  10. O'Brien W. Intestinal malabsorption in acute infection with Strongyloides stercoralis. Trans R Soc Trop Med Hyg. 1975;69:69-77.
  11. Nwokolo C, Imohiosen EA. Strongyloidiasis of respiratory tract presenting as "asthma". Br Med J. 1973;2:153-154.
  12. Neva FA, Gam AA, Burke J. Comparison of larval antigens in an enzyme-linked immunosorbent assay for strongyloidiasis in humans. J Infect Dis. 1981;144:427-432.
  13. Genta RM. Strongyloidiasis. In: Walls KW, Schantz PM, eds. Immunodiagnosis of Parasitic Diseases. Vol 1. Orlando, FL: Academic Press Inc; 1986:183-199.
  14. Igual-Adell R, Oltra-Alcaraz C, Soler-Company E, et al. Efficacy and safety of ivermectin and thiabendazole in the treatment of strongyloidiasis. Expert Opin Pharmacother. 2004;5:2615-2619.
  15. Maayan S, Wormser GP, Widerhorn J, et al. Strongyloides stercoralis hyperinfection in a patient with the acquired immune deficiency syndrome. Am J Med. 1987;83:945-948.
  16. Weller IV, Copland P, Gabriel R. Strongyloides stercoralis infection in renal transplant recipients [letter]. Br Med J (Clin Res Ed). 1981;282:524.
  17. Walzer PD, Milder JE, Banwell JG, et al. Epidemiologic features of Strongyloides stercoralis infection in an endemic area of the United States. Am J Trop Med Hyg. 1982;31:313-319.
  18. Fulmer HS, Huempfner HR. Intestinal helminths in eastern Kentucky: a survey in three rural counties. Am J Trop Med Hyg. 1965;14:269-275.
  19. Milder JE, Walzer PD, Kilgore G, et al. Clinical features of Strongyloides stercoralis infection in an endemic area of the United States. Gastroenterology. 1981;80:1481-1488.
  20. Genta RM, Weesner R, Douce RW, et al. Strongyloidiasis in US veterans of the Vietnam and other wars. JAMA. 1987;258:49-52.
  21. Gill GV, Welch E, Bailey JW, et al. Chronic Strongyloides stercoralis infection in former British Far East prisoners of war. QJM. 2004;97:789-795.
  22. Pelletier LL Jr. Chronic strongyloidiasis in World War II Far East ex–prisoners of war. Am J Trop Med Hyg. 1984;33:55-61.
References

  1. Longworth DL, Weller PF. Hyperinfection syndrome with strongyloidiasis. In: Remington JS, Swartz MN, eds. Current Clinical Topics in Infectious Diseases. New York, NY: McGraw-Hill; 1986:1-26.
  2. Morgan JS, Schaffner W, Sone WJ. Opportunistic strongyloidiasis in renal transplant recipients. Transplantation. 1986;42:518-524.
  3. Grove DI. Strongyloidiasis in allied ex–prisoners of war in south-east Asia. Br Med J. 1980;280:598-601.
  4. Arthur RP, Shelley WB. Larva currens; a distinctive variant of cutaneous larva migrans due to Strongyloides stercoralis. AMA Arch Derm. 1958;78:186-190.
  5. Zygmunt DJ. Strongyloides stercoralis. Infect Control Hosp Epidemiol. 1990;11:495-497.
  6. Singh S. Human strongyloidiasis in AIDS era: its zoonotic importance. J Assoc Physicians India. 2002;50:415-422.
  7. Rothenberg ME. Eosinophilia. N Engl J Med. 1998;338:1592-1600.
  8. Bank DE, Grossman ME, Kohn SR, et al. The thumbprint sign: rapid diagnosis of disseminated strongyloidiasis. J Am Acad Dermatol. 1990;23(2, pt 1):324-326.
  9. Milner PF, Irvine RA, Barton CJ, et al. Intestinal malabsorption in Strongyloides stercoralis infestation. Gut. 1965;6:574-581.
  10. O'Brien W. Intestinal malabsorption in acute infection with Strongyloides stercoralis. Trans R Soc Trop Med Hyg. 1975;69:69-77.
  11. Nwokolo C, Imohiosen EA. Strongyloidiasis of respiratory tract presenting as "asthma". Br Med J. 1973;2:153-154.
  12. Neva FA, Gam AA, Burke J. Comparison of larval antigens in an enzyme-linked immunosorbent assay for strongyloidiasis in humans. J Infect Dis. 1981;144:427-432.
  13. Genta RM. Strongyloidiasis. In: Walls KW, Schantz PM, eds. Immunodiagnosis of Parasitic Diseases. Vol 1. Orlando, FL: Academic Press Inc; 1986:183-199.
  14. Igual-Adell R, Oltra-Alcaraz C, Soler-Company E, et al. Efficacy and safety of ivermectin and thiabendazole in the treatment of strongyloidiasis. Expert Opin Pharmacother. 2004;5:2615-2619.
  15. Maayan S, Wormser GP, Widerhorn J, et al. Strongyloides stercoralis hyperinfection in a patient with the acquired immune deficiency syndrome. Am J Med. 1987;83:945-948.
  16. Weller IV, Copland P, Gabriel R. Strongyloides stercoralis infection in renal transplant recipients [letter]. Br Med J (Clin Res Ed). 1981;282:524.
  17. Walzer PD, Milder JE, Banwell JG, et al. Epidemiologic features of Strongyloides stercoralis infection in an endemic area of the United States. Am J Trop Med Hyg. 1982;31:313-319.
  18. Fulmer HS, Huempfner HR. Intestinal helminths in eastern Kentucky: a survey in three rural counties. Am J Trop Med Hyg. 1965;14:269-275.
  19. Milder JE, Walzer PD, Kilgore G, et al. Clinical features of Strongyloides stercoralis infection in an endemic area of the United States. Gastroenterology. 1981;80:1481-1488.
  20. Genta RM, Weesner R, Douce RW, et al. Strongyloidiasis in US veterans of the Vietnam and other wars. JAMA. 1987;258:49-52.
  21. Gill GV, Welch E, Bailey JW, et al. Chronic Strongyloides stercoralis infection in former British Far East prisoners of war. QJM. 2004;97:789-795.
  22. Pelletier LL Jr. Chronic strongyloidiasis in World War II Far East ex–prisoners of war. Am J Trop Med Hyg. 1984;33:55-61.
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Clindamycin Phosphate 1.2%–Tretinoin 0.025% Gel: Vehicle Characteristics, Stability, and Tolerability

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