Diabetes

TOPLINE:

Compared with dipeptidyl peptidase 4 (DPP-4) inhibitors, glucagon-like peptide 1 receptor agonists (GLP-1 RAs) are associated with a lower risk for all-cause mortality and major adverse cardiovascular events (MACE) in patients with immune-mediated inflammatory diseases (IMIDs) and type 2 diabetes (T2D).

METHODOLOGY:

• GLP-1 RAs reduce the risk for all-cause mortality, cardiovascular mortality, and stroke in patients with diabetes. However, previous trials have excluded those with IMIDs, leaving a gap in understanding the cardioprotective effects of GLP-1 RAs in this population.
• Researchers conducted a population-based cohort study to assess if patients with an IMID derive greater benefits from GLP-1 RAs than DPP-4 inhibitors.
• They used administrative health data from British Columbia, Canada, to include 10,855 patients with IMIDs (rheumatoid arthritis, psoriatic disease, ankylosing spondylitis, inflammatory bowel disease, or systemic autoimmune rheumatic disease) and T2D who initiated either GLP-1 RA (n = 3570) or DPP-4 inhibitor (n = 7285).
• The mean follow-up was 1.46 and 1.88 years in the GLP-1 RA and DPP-4 inhibitor cohorts, respectively.
• The primary outcome was all-cause mortality, and the secondary outcome was MACE, including cardiovascular death, myocardial infarction, and ischemic stroke.

TAKEAWAY:

• The risk for all-cause mortality was 52% lower in patients who initiated GLP-1 RAs than in those who initiated DPP-4 inhibitors (weighted hazard ratio [HR], 0.48; 95% CI, 0.31-0.75).
• Additionally, patients initiating DPP-4 inhibitors.
• In the subgroup of patients with GLP-1 RAs had a significantly lower risk for MACE (weighted HR, 0.66; 95% CI, 0.50-0.88), particularly myocardial infarction (weighted HR, 0.62; 95% CI, 0.40-0.96), than those initiating rheumatoid arthritis and T2D, those who initiated GLP-1 RAs had a 55% lower risk for all-cause mortality and 61% lower risk for MACE than those who initiated DPP-4 inhibitors.

IN PRACTICE:

“This corresponds to nine fewer deaths and 11 fewer MACE per 1000 person-years, respectively, supporting the hypothesis that these agents have a cardioprotective effect in this high-risk population,” the authors wrote.

SOURCE:

This study was led by Derin Karacabeyli, MD, Division of Rheumatology, Department of Medicine, University of British Columbia, Vancouver, Canada, and was published online on August 8, 2024, in PLOS ONE.

LIMITATIONS:

The study’s dependence on administrative health data might have resulted in incomplete capture of comorbidities, particularly obesity. The mean follow-up period was relatively short, which might have limited the long-term applicability of these findings. The accuracy of the case definitions for IMIDs and T2D, according to International Classification of Diseases codes, could not be fully ascertained.

DISCLOSURES:

The study was supported by grants from the Canadian Institutes of Health Research. Two authors declared receiving research support, consulting fees, or participating in advisory boards outside the submitted work.

This article was created using several editorial tools, including AI, as part of the process. Human editors reviewed this content before publication. A version of this article first appeared on Medscape.com.

TOPLINE:

Compared with dipeptidyl peptidase 4 (DPP-4) inhibitors, glucagon-like peptide 1 receptor agonists (GLP-1 RAs) are associated with a lower risk for all-cause mortality and major adverse cardiovascular events (MACE) in patients with immune-mediated inflammatory diseases (IMIDs) and type 2 diabetes (T2D).

METHODOLOGY:

• GLP-1 RAs reduce the risk for all-cause mortality, cardiovascular mortality, and stroke in patients with diabetes. However, previous trials have excluded those with IMIDs, leaving a gap in understanding the cardioprotective effects of GLP-1 RAs in this population.
• Researchers conducted a population-based cohort study to assess if patients with an IMID derive greater benefits from GLP-1 RAs than DPP-4 inhibitors.
• They used administrative health data from British Columbia, Canada, to include 10,855 patients with IMIDs (rheumatoid arthritis, psoriatic disease, ankylosing spondylitis, inflammatory bowel disease, or systemic autoimmune rheumatic disease) and T2D who initiated either GLP-1 RA (n = 3570) or DPP-4 inhibitor (n = 7285).
• The mean follow-up was 1.46 and 1.88 years in the GLP-1 RA and DPP-4 inhibitor cohorts, respectively.
• The primary outcome was all-cause mortality, and the secondary outcome was MACE, including cardiovascular death, myocardial infarction, and ischemic stroke.

TAKEAWAY:

• The risk for all-cause mortality was 52% lower in patients who initiated GLP-1 RAs than in those who initiated DPP-4 inhibitors (weighted hazard ratio [HR], 0.48; 95% CI, 0.31-0.75).
• Additionally, patients initiating DPP-4 inhibitors.
• In the subgroup of patients with GLP-1 RAs had a significantly lower risk for MACE (weighted HR, 0.66; 95% CI, 0.50-0.88), particularly myocardial infarction (weighted HR, 0.62; 95% CI, 0.40-0.96), than those initiating rheumatoid arthritis and T2D, those who initiated GLP-1 RAs had a 55% lower risk for all-cause mortality and 61% lower risk for MACE than those who initiated DPP-4 inhibitors.

IN PRACTICE:

“This corresponds to nine fewer deaths and 11 fewer MACE per 1000 person-years, respectively, supporting the hypothesis that these agents have a cardioprotective effect in this high-risk population,” the authors wrote.

SOURCE:

This study was led by Derin Karacabeyli, MD, Division of Rheumatology, Department of Medicine, University of British Columbia, Vancouver, Canada, and was published online on August 8, 2024, in PLOS ONE.

LIMITATIONS:

The study’s dependence on administrative health data might have resulted in incomplete capture of comorbidities, particularly obesity. The mean follow-up period was relatively short, which might have limited the long-term applicability of these findings. The accuracy of the case definitions for IMIDs and T2D, according to International Classification of Diseases codes, could not be fully ascertained.

DISCLOSURES:

The study was supported by grants from the Canadian Institutes of Health Research. Two authors declared receiving research support, consulting fees, or participating in advisory boards outside the submitted work.

This article was created using several editorial tools, including AI, as part of the process. Human editors reviewed this content before publication. A version of this article first appeared on Medscape.com.

TOPLINE:

Compared with dipeptidyl peptidase 4 (DPP-4) inhibitors, glucagon-like peptide 1 receptor agonists (GLP-1 RAs) are associated with a lower risk for all-cause mortality and major adverse cardiovascular events (MACE) in patients with immune-mediated inflammatory diseases (IMIDs) and type 2 diabetes (T2D).

METHODOLOGY:

• GLP-1 RAs reduce the risk for all-cause mortality, cardiovascular mortality, and stroke in patients with diabetes. However, previous trials have excluded those with IMIDs, leaving a gap in understanding the cardioprotective effects of GLP-1 RAs in this population.
• Researchers conducted a population-based cohort study to assess if patients with an IMID derive greater benefits from GLP-1 RAs than DPP-4 inhibitors.
• They used administrative health data from British Columbia, Canada, to include 10,855 patients with IMIDs (rheumatoid arthritis, psoriatic disease, ankylosing spondylitis, inflammatory bowel disease, or systemic autoimmune rheumatic disease) and T2D who initiated either GLP-1 RA (n = 3570) or DPP-4 inhibitor (n = 7285).
• The mean follow-up was 1.46 and 1.88 years in the GLP-1 RA and DPP-4 inhibitor cohorts, respectively.
• The primary outcome was all-cause mortality, and the secondary outcome was MACE, including cardiovascular death, myocardial infarction, and ischemic stroke.

TAKEAWAY:

• The risk for all-cause mortality was 52% lower in patients who initiated GLP-1 RAs than in those who initiated DPP-4 inhibitors (weighted hazard ratio [HR], 0.48; 95% CI, 0.31-0.75).
• Additionally, patients initiating DPP-4 inhibitors.
• In the subgroup of patients with GLP-1 RAs had a significantly lower risk for MACE (weighted HR, 0.66; 95% CI, 0.50-0.88), particularly myocardial infarction (weighted HR, 0.62; 95% CI, 0.40-0.96), than those initiating rheumatoid arthritis and T2D, those who initiated GLP-1 RAs had a 55% lower risk for all-cause mortality and 61% lower risk for MACE than those who initiated DPP-4 inhibitors.

IN PRACTICE:

“This corresponds to nine fewer deaths and 11 fewer MACE per 1000 person-years, respectively, supporting the hypothesis that these agents have a cardioprotective effect in this high-risk population,” the authors wrote.

SOURCE:

This study was led by Derin Karacabeyli, MD, Division of Rheumatology, Department of Medicine, University of British Columbia, Vancouver, Canada, and was published online on August 8, 2024, in PLOS ONE.

LIMITATIONS:

The study’s dependence on administrative health data might have resulted in incomplete capture of comorbidities, particularly obesity. The mean follow-up period was relatively short, which might have limited the long-term applicability of these findings. The accuracy of the case definitions for IMIDs and T2D, according to International Classification of Diseases codes, could not be fully ascertained.

DISCLOSURES:

The study was supported by grants from the Canadian Institutes of Health Research. Two authors declared receiving research support, consulting fees, or participating in advisory boards outside the submitted work.

This article was created using several editorial tools, including AI, as part of the process. Human editors reviewed this content before publication. A version of this article first appeared on Medscape.com.

Edema in the feet and legs is a common complaint in our practices. It can cause pain, weakness, heaviness, discomfort, limited movement, and a negative body image. Medications can contribute to edema, either alone or in combination with other health issues.

Edema is also associated with advanced age, female sex, obesity, diabetes, hypertension, pain, lack of physical activity, and mobility limitations. These factors often necessitate medication prescriptions, which can aggravate the problem. Therefore, it is important to know how to treat or prevent medication-induced edema.

There are four main causes of edema, and all can facilitate medication-induced edema.

• Increased capillary pressure. Conditions such as heart failure, renal dysfunction, venous insufficiency, deep vein thrombosis, and cirrhosis can increase capillary pressure, leading to edema.
• Decreased oncotic pressure. Hypoalbuminemia, a primary cause of reduced colloid oncotic pressure, can result from nephrotic syndrome, diabetic nephropathy, lupus nephropathy, amyloidosis, nephropathies, cirrhosis, chronic liver disease, and malabsorption or malnutrition.
• Increased capillary permeability. Vascular injury, often associated with diabetes, can increase capillary permeability and contribute to edema.
• Impaired lymphatic drainage. Lymphatic obstruction is common in patients with lymphedema, tumors, inflammation, fibrosis, certain infections, surgery, and congenital anomalies. Conditions such as thyroid disorders can also cause an increase in interstitial albumin and other proteins without a corresponding increase in lymphatic flow, leading to lymphedema.

Medications That Can Cause Edema

• Calcium channel blockers (CCBs). Drugs such as nifedipine and amlodipine can increase hydrostatic pressure by causing selective vasodilation of precapillary vessels, leading to increased intracapillary pressures. Newer lipophilic CCBs (eg, levamlodipine) exhibit lower rates of edema. Reducing the dose is often effective. Diuretics are not very effective for vasodilation-induced edema. Combining CCBs with angiotensin-converting enzyme (ACE) inhibitors or angiotensin receptor blockers (ARBs), which induce postcapillary dilation and normalize intracapillary pressure, may reduce fluid leakage into the interstitial space. This combination may be more beneficial than high-dose CCB monotherapy.
• Thiazolidinedione (eg, pioglitazone). These increase vascular permeability and hydrostatic pressure. They work by stimulating the peroxisome proliferator–activated gamma receptor, increasing vascular endothelial permeability, vascular endothelial growth factor secretion, and renal retention of sodium and fluids. Because of other adverse effects, their use is now limited.
• Agents for neuropathic pain (gabapentin and pregabalin). These drugs can induce selective vasodilation of arterioles through a mechanism similar to that of CCBs, causing increased intracapillary pressures. Edema usually begins within the first month of treatment or dose increase and often regresses after dose reduction or drug discontinuation.
• Antiparkinsonian dopamine agonists. These increase hydrostatic pressure by reducing sympathetic tone and dilating arterioles through alpha-2 adrenergic receptor activity.
• New antipsychotics. Drugs like clozapine, iloperidone, lurasidone, olanzapine, quetiapine, risperidone, and ziprasidone can increase hydrostatic pressure through antagonistic effects on alpha-1 adrenergic receptors, causing vasodilation.
• Nitrates. These drugs increase hydrostatic pressure by causing preferential venous dilation, leading to increased venous pooling.
• Nonsteroidal anti-inflammatory drugs (NSAIDs). These drugs can increase hydrostatic pressure by inhibiting vasodilation of afferent renal arterioles, decreasing the glomerular filtration rate, and stimulating the renin-angiotensin-aldosterone system, which leads to sodium and water retention. These adverse effects warrant cautious use of these agents.
• ACE inhibitors. Drugs such as enalapril and ramipril can increase vascular permeability. They reduce the metabolism and accumulation of bradykinin, which increases vascular permeability and fluid leakage. These effects are rare and are usually related to allergic responses.
• Insulin. Insulin decreases capillary oncotic pressure and increases vascular permeability. Rapid correction of hyperglycemia can cause a loss of oncotic pressure, while chronic hyperglycemia can damage vascular membranes, increasing permeability. These effects are generally benign and can be managed with careful dose titration, sodium restriction, or diuretics.
• Steroids. Steroids with mineralocorticoid activity can increase renal sodium and water retention, leading to increased blood volume. Fludrocortisone has the highest mineralocorticoid activity, while dexamethasone and methylprednisolone have negligible activity.

Implications

Understanding how these medications cause edema is important for effective management. For example, in the case of those causing edema due to reduced oncotic pressure, like insulin, slow dose titrations can help adapt to osmolarity changes. For drugs causing edema due to increased hydrostatic pressure, diuretics are more effective in acute management.

The key takeaways from this review are:

• Awareness of drug-induced edema. Many drugs besides CCBs can cause edema.
• Combination therapy. Combining ACE inhibitors or ARBs with CCBs can prevent or reduce CCB-induced edema.
• Edema management strategies. Strategies to manage or prevent edema should include dose reductions or replacement of the problematic medication, especially in severe or refractory cases.

Dr. Wajngarten, professor of cardiology, University of São Paulo, Brazil, has disclosed no relevant financial relationships.

This story was translated from the Medscape Portuguese edition using several editorial tools, including AI, as part of the process. Human editors reviewed this content before publication. A version of this article appeared on Medscape.com.

Edema in the feet and legs is a common complaint in our practices. It can cause pain, weakness, heaviness, discomfort, limited movement, and a negative body image. Medications can contribute to edema, either alone or in combination with other health issues.

Edema is also associated with advanced age, female sex, obesity, diabetes, hypertension, pain, lack of physical activity, and mobility limitations. These factors often necessitate medication prescriptions, which can aggravate the problem. Therefore, it is important to know how to treat or prevent medication-induced edema.

There are four main causes of edema, and all can facilitate medication-induced edema.

• Increased capillary pressure. Conditions such as heart failure, renal dysfunction, venous insufficiency, deep vein thrombosis, and cirrhosis can increase capillary pressure, leading to edema.
• Decreased oncotic pressure. Hypoalbuminemia, a primary cause of reduced colloid oncotic pressure, can result from nephrotic syndrome, diabetic nephropathy, lupus nephropathy, amyloidosis, nephropathies, cirrhosis, chronic liver disease, and malabsorption or malnutrition.
• Increased capillary permeability. Vascular injury, often associated with diabetes, can increase capillary permeability and contribute to edema.
• Impaired lymphatic drainage. Lymphatic obstruction is common in patients with lymphedema, tumors, inflammation, fibrosis, certain infections, surgery, and congenital anomalies. Conditions such as thyroid disorders can also cause an increase in interstitial albumin and other proteins without a corresponding increase in lymphatic flow, leading to lymphedema.

Medications That Can Cause Edema

• Calcium channel blockers (CCBs). Drugs such as nifedipine and amlodipine can increase hydrostatic pressure by causing selective vasodilation of precapillary vessels, leading to increased intracapillary pressures. Newer lipophilic CCBs (eg, levamlodipine) exhibit lower rates of edema. Reducing the dose is often effective. Diuretics are not very effective for vasodilation-induced edema. Combining CCBs with angiotensin-converting enzyme (ACE) inhibitors or angiotensin receptor blockers (ARBs), which induce postcapillary dilation and normalize intracapillary pressure, may reduce fluid leakage into the interstitial space. This combination may be more beneficial than high-dose CCB monotherapy.
• Thiazolidinedione (eg, pioglitazone). These increase vascular permeability and hydrostatic pressure. They work by stimulating the peroxisome proliferator–activated gamma receptor, increasing vascular endothelial permeability, vascular endothelial growth factor secretion, and renal retention of sodium and fluids. Because of other adverse effects, their use is now limited.
• Agents for neuropathic pain (gabapentin and pregabalin). These drugs can induce selective vasodilation of arterioles through a mechanism similar to that of CCBs, causing increased intracapillary pressures. Edema usually begins within the first month of treatment or dose increase and often regresses after dose reduction or drug discontinuation.
• Antiparkinsonian dopamine agonists. These increase hydrostatic pressure by reducing sympathetic tone and dilating arterioles through alpha-2 adrenergic receptor activity.
• New antipsychotics. Drugs like clozapine, iloperidone, lurasidone, olanzapine, quetiapine, risperidone, and ziprasidone can increase hydrostatic pressure through antagonistic effects on alpha-1 adrenergic receptors, causing vasodilation.
• Nitrates. These drugs increase hydrostatic pressure by causing preferential venous dilation, leading to increased venous pooling.
• Nonsteroidal anti-inflammatory drugs (NSAIDs). These drugs can increase hydrostatic pressure by inhibiting vasodilation of afferent renal arterioles, decreasing the glomerular filtration rate, and stimulating the renin-angiotensin-aldosterone system, which leads to sodium and water retention. These adverse effects warrant cautious use of these agents.
• ACE inhibitors. Drugs such as enalapril and ramipril can increase vascular permeability. They reduce the metabolism and accumulation of bradykinin, which increases vascular permeability and fluid leakage. These effects are rare and are usually related to allergic responses.
• Insulin. Insulin decreases capillary oncotic pressure and increases vascular permeability. Rapid correction of hyperglycemia can cause a loss of oncotic pressure, while chronic hyperglycemia can damage vascular membranes, increasing permeability. These effects are generally benign and can be managed with careful dose titration, sodium restriction, or diuretics.
• Steroids. Steroids with mineralocorticoid activity can increase renal sodium and water retention, leading to increased blood volume. Fludrocortisone has the highest mineralocorticoid activity, while dexamethasone and methylprednisolone have negligible activity.

Implications

Understanding how these medications cause edema is important for effective management. For example, in the case of those causing edema due to reduced oncotic pressure, like insulin, slow dose titrations can help adapt to osmolarity changes. For drugs causing edema due to increased hydrostatic pressure, diuretics are more effective in acute management.

The key takeaways from this review are:

• Awareness of drug-induced edema. Many drugs besides CCBs can cause edema.
• Combination therapy. Combining ACE inhibitors or ARBs with CCBs can prevent or reduce CCB-induced edema.
• Edema management strategies. Strategies to manage or prevent edema should include dose reductions or replacement of the problematic medication, especially in severe or refractory cases.

Dr. Wajngarten, professor of cardiology, University of São Paulo, Brazil, has disclosed no relevant financial relationships.

This story was translated from the Medscape Portuguese edition using several editorial tools, including AI, as part of the process. Human editors reviewed this content before publication. A version of this article appeared on Medscape.com.

Edema in the feet and legs is a common complaint in our practices. It can cause pain, weakness, heaviness, discomfort, limited movement, and a negative body image. Medications can contribute to edema, either alone or in combination with other health issues.

Edema is also associated with advanced age, female sex, obesity, diabetes, hypertension, pain, lack of physical activity, and mobility limitations. These factors often necessitate medication prescriptions, which can aggravate the problem. Therefore, it is important to know how to treat or prevent medication-induced edema.

There are four main causes of edema, and all can facilitate medication-induced edema.

• Increased capillary pressure. Conditions such as heart failure, renal dysfunction, venous insufficiency, deep vein thrombosis, and cirrhosis can increase capillary pressure, leading to edema.
• Decreased oncotic pressure. Hypoalbuminemia, a primary cause of reduced colloid oncotic pressure, can result from nephrotic syndrome, diabetic nephropathy, lupus nephropathy, amyloidosis, nephropathies, cirrhosis, chronic liver disease, and malabsorption or malnutrition.
• Increased capillary permeability. Vascular injury, often associated with diabetes, can increase capillary permeability and contribute to edema.
• Impaired lymphatic drainage. Lymphatic obstruction is common in patients with lymphedema, tumors, inflammation, fibrosis, certain infections, surgery, and congenital anomalies. Conditions such as thyroid disorders can also cause an increase in interstitial albumin and other proteins without a corresponding increase in lymphatic flow, leading to lymphedema.

Medications That Can Cause Edema

• Calcium channel blockers (CCBs). Drugs such as nifedipine and amlodipine can increase hydrostatic pressure by causing selective vasodilation of precapillary vessels, leading to increased intracapillary pressures. Newer lipophilic CCBs (eg, levamlodipine) exhibit lower rates of edema. Reducing the dose is often effective. Diuretics are not very effective for vasodilation-induced edema. Combining CCBs with angiotensin-converting enzyme (ACE) inhibitors or angiotensin receptor blockers (ARBs), which induce postcapillary dilation and normalize intracapillary pressure, may reduce fluid leakage into the interstitial space. This combination may be more beneficial than high-dose CCB monotherapy.
• Thiazolidinedione (eg, pioglitazone). These increase vascular permeability and hydrostatic pressure. They work by stimulating the peroxisome proliferator–activated gamma receptor, increasing vascular endothelial permeability, vascular endothelial growth factor secretion, and renal retention of sodium and fluids. Because of other adverse effects, their use is now limited.
• Agents for neuropathic pain (gabapentin and pregabalin). These drugs can induce selective vasodilation of arterioles through a mechanism similar to that of CCBs, causing increased intracapillary pressures. Edema usually begins within the first month of treatment or dose increase and often regresses after dose reduction or drug discontinuation.
• Antiparkinsonian dopamine agonists. These increase hydrostatic pressure by reducing sympathetic tone and dilating arterioles through alpha-2 adrenergic receptor activity.
• New antipsychotics. Drugs like clozapine, iloperidone, lurasidone, olanzapine, quetiapine, risperidone, and ziprasidone can increase hydrostatic pressure through antagonistic effects on alpha-1 adrenergic receptors, causing vasodilation.
• Nitrates. These drugs increase hydrostatic pressure by causing preferential venous dilation, leading to increased venous pooling.
• Nonsteroidal anti-inflammatory drugs (NSAIDs). These drugs can increase hydrostatic pressure by inhibiting vasodilation of afferent renal arterioles, decreasing the glomerular filtration rate, and stimulating the renin-angiotensin-aldosterone system, which leads to sodium and water retention. These adverse effects warrant cautious use of these agents.
• ACE inhibitors. Drugs such as enalapril and ramipril can increase vascular permeability. They reduce the metabolism and accumulation of bradykinin, which increases vascular permeability and fluid leakage. These effects are rare and are usually related to allergic responses.
• Insulin. Insulin decreases capillary oncotic pressure and increases vascular permeability. Rapid correction of hyperglycemia can cause a loss of oncotic pressure, while chronic hyperglycemia can damage vascular membranes, increasing permeability. These effects are generally benign and can be managed with careful dose titration, sodium restriction, or diuretics.
• Steroids. Steroids with mineralocorticoid activity can increase renal sodium and water retention, leading to increased blood volume. Fludrocortisone has the highest mineralocorticoid activity, while dexamethasone and methylprednisolone have negligible activity.

Implications

Understanding how these medications cause edema is important for effective management. For example, in the case of those causing edema due to reduced oncotic pressure, like insulin, slow dose titrations can help adapt to osmolarity changes. For drugs causing edema due to increased hydrostatic pressure, diuretics are more effective in acute management.

The key takeaways from this review are:

• Awareness of drug-induced edema. Many drugs besides CCBs can cause edema.
• Combination therapy. Combining ACE inhibitors or ARBs with CCBs can prevent or reduce CCB-induced edema.
• Edema management strategies. Strategies to manage or prevent edema should include dose reductions or replacement of the problematic medication, especially in severe or refractory cases.

Dr. Wajngarten, professor of cardiology, University of São Paulo, Brazil, has disclosed no relevant financial relationships.

This story was translated from the Medscape Portuguese edition using several editorial tools, including AI, as part of the process. Human editors reviewed this content before publication. A version of this article appeared on Medscape.com.

STOCKHOLM — At the American Society of Retina Specialists (ASRS) 2024 Annual Meeting, researchers discussed how insights into potential risk factors and new treatments could improve outcomes for patients with diabetic retinopathy.

Jennifer Lim, MD, an ophthalmologist and director of the Retina Service at the University of Illinois Hospital & Health Sciences System in Chicago, told this news organization that emerging approaches to treating diabetic retinopathy offer hope because they address the root causes of the disease beyond just targeting vascular endothelial growth factor (VEGF). She said innovative methods and add-on treatments could lead to more durable and effective drugs.

Exploration of risk factors and treatment options for diabetic retinopathy could lead to more effective management strategies for the condition, agreed David Boyer, MD, an ophthalmologist at Retina Vitreous Associates Medical Group in Los Angeles, speaking with this news organization.
 

Risk Factors for Diabetic Retinopathy

Sodium-glucose cotransporter 2 (SGLT2) inhibitors and glucagon-like peptide 1 receptor agonists (GLP-1 RAs) have gained popularity because of their benefits beyond glycemic control, including weight loss, and cardiovascular and kidney protection. However, the impact of these medications on vision-threatening retinal complications is not fully understood. “There has always been a question about whether these newer diabetes medications might exacerbate diabetic eye disease,” said Dr. Boyer.

In a retrospective observational study, researchers included adults with type 2 diabetes and moderate cardiovascular disease risk who had no history of advanced diabetic retinal complications. These patients initiated treatment with GLP-1 RA, SGLT2 inhibitors, DPP-4 inhibitors, or sulfonylureas. The study used inverse probability of treatment weighting to mimic randomization and compared the time to the first treatment for diabetic macular edema or proliferative diabetic retinopathy across the treatment groups.

Results, presented by Andrew J. Barkmeier, MD, an associate professor of ophthalmology at the Mayo Clinic, showed that among 371,698 patients, those who initiated therapy with SGLT2 inhibitors had a lower risk of requiring treatment for sight-threatening retinopathy compared with those using other medication classes. GLP-1 RA did not increase retinopathy risk relative to dipeptidyl peptidase 4 inhibitors and sulfonylurea medications.

“[This study] told us that we do have to keep an eye on patients’ retinopathy when they start on these new inhibitors. But the progression is minimal and, overall, I think most people today favor keeping blood sugar levels as good as possible,” said Dr. Boyer, who was not involved in the study.

Another factor that might increase diabetic retinopathy progression is obstructive sleep apnea. This underdiagnosed condition is linked to several health issues, including dementia, stroke, and myocardial infarctions. Although not easily treated, obstructive sleep apnea is manageable, Dr. Boyer explained.

Researchers utilized the TriNetX electronic health records research network to identify patients with nonproliferative diabetic retinopathy, both with and without obstructive sleep apnea. 

The results, presented by Ehsan Rahimy, MD, a retinal specialist at Palo Alto Medical Foundation and a professor at Stanford University, showed that patients with obstructive sleep apnea had a significantly higher risk of progressing to proliferative diabetic retinopathy and developing new-onset diabetic macular edema. These patients were more likely to require ocular interventions, such as intravitreal injections and laser photocoagulation. They also had greater risks for stroke, myocardial infarction, and death compared with those who did not have obstructive sleep apnea.

“It was good to bring this to everybody’s attention,” said Dr. Boyer, who was not involved in the study. “It’s an easy question to ask someone if they snore.”
 

New Treatments on the Horizon

In another presentation, Nathan C. Steinle, MD, of California Retina Consultants, presented a study that assessed the durability of response to sozinibercept in patients with retinal vascular diseases. This novel therapeutic agent is designed to inhibit VEGF-C and VEGF-D in conditions where VEGF-A suppression alone is insufficient. 

Sozinibercept was combined with standard anti–VEGF-A therapies such as ranibizumab or aflibercept. It involved a prospective, post hoc analysis of two phase 1b, open-label, dose-escalation studies, including 40 patients with neovascular age-related macular degeneration (nAMD; 31 patients) or diabetic macular edema (nine patients). These patients, either treatment-naive or previously treated, received three intravitreal injections of ranibizumab or aflibercept in combination with sozinibercept at various doses.

Results indicated that sozinibercept combination therapy was well tolerated, with no dose-limiting toxicities. In treatment-naive nAMD patients, the mean best-corrected visual acuity (BCVA) improved significantly from baseline at months 3 and 6. Previously treated nAMD patients also showed BCVA improvements, although to a lesser extent. For patients with persistent diabetic macular edema, switching to sozinibercept plus aflibercept resulted in notable BCVA gains. The mean time to requiring retreatment was longer in treatment-naive patients than in those previously treated, indicating a durable response. 

“Combination therapy with sozinibercept is going to be really important,” said Dr. Lim, who was not involved in the study, “because it attacks with a dual mechanism of action.”

Oral agents promise a potentially easier alternative for patients compared with frequent injections. CU06-1004 is a novel orally administered endothelial dysfunction blocker that has shown promise in stabilizing damaged capillaries, reducing abnormal angiogenesis, and inhibiting inflammatory activation in preclinical studies. “CU06 is very interesting to me because by preventing endothelial loss, it gets to the pathophysiology of why the blood vessels break down,” Dr. Lim said.

In a proof-of-concept phase 2a, multicenter, open-label, parallel-group trial, investigators randomly assigned 67 patients with diabetic macular edema to receive 100 mg, 200 mg, or 300 mg of CU06-1004 once daily for 12 weeks, followed by a 4-week follow-up. 

Results presented by Victor Gonzalez, MD, of Valley Retina Institute in Texas, indicated that the oral agent improved BCVA, stabilized central subfield thickness, and showed positive anatomical changes in optical coherence tomography images. CU06-1004 was well tolerated, with no drug-related serious adverse events. 

“The number [of patients] was very small, and we will need a much longer, larger trial to see if [CU06-1004] has benefits long term,” said Dr. Boyer, who was not involved in the study. “But I think we’re all very excited if we can find an oral agent for treating diabetic retinopathy. It would be easier for the patient to take a pill than having to come in for injections.” 

The sustained-release axitinib implant, OTX-TKI, is also generating significant interest, particularly for nonproliferative diabetic retinopathy. Axitinib, a tyrosine kinase inhibitor (TKI), targets signaling pathways crucial in cellular processes, providing a novel approach to managing diseases where traditional therapies might fall short. Unlike traditional anti-VEGF treatments that focus solely on cytokine levels, TKIs block the activation of signaling pathways, preventing downstream signaling regardless of cytokine levels. This mechanism is particularly important because it effectively inhibits disease progression even if levels of VEGF are high, Dr. Lim explained.

In the phase 1 HELIOS trial, OTX-TKI was assessed in patients with nonproliferative diabetic retinopathy. This multicenter, double-masked, parallel-group clinical study included 21 patients who had not received anti-VEGF treatment, dexamethasone intravitreal implants in the previous 12 months, or intraocular steroid injections in the prior 4 months. Patients were randomly assigned to receive either OTX-TKI or sham treatment.

Results presented by Dilsher S. Dhoot, MD, of California Retina Consultants, indicated that OTX-TKI was generally well tolerated, with no serious ocular adverse events. At 48 weeks, 46.2% of eyes treated with OTX-TKI showed a 1- or 2-step improvement on the Diabetic Retinopathy Severity Scale (DRSS) compared with none in the sham arm. Additionally, no eyes treated with OTX-TKI experienced a worsening on the DRSS, whereas 25% of eyes in the sham arm did. Vision-threatening complications, such as proliferative diabetic retinopathy or diabetic macular edema, developed in 37.5% of the sham group but in none of the OTX-TKI treated eyes. A single injection of OTX-TKI provided durable DRSS improvement for up to 48 weeks, with no patients in either arm requiring rescue therapy.

“This is a really exciting add-on treatment,” Dr. Lim said, who was not involved in the study. She explained that it is initially necessary to control the disease with standard treatments, because TKIs may take longer to exhibit their effects. Once the disease is stabilized, TKIs can be used alongside other therapies, potentially reducing the reliance on frequent anti-VEGF injections. “These are preliminary results, but that’s the hope going forward.”

Dr. Lim and Dr. Boyer report no relevant financial relationships.

A version of this article first appeared on Medscape.com.

STOCKHOLM — At the American Society of Retina Specialists (ASRS) 2024 Annual Meeting, researchers discussed how insights into potential risk factors and new treatments could improve outcomes for patients with diabetic retinopathy.

Jennifer Lim, MD, an ophthalmologist and director of the Retina Service at the University of Illinois Hospital & Health Sciences System in Chicago, told this news organization that emerging approaches to treating diabetic retinopathy offer hope because they address the root causes of the disease beyond just targeting vascular endothelial growth factor (VEGF). She said innovative methods and add-on treatments could lead to more durable and effective drugs.

Exploration of risk factors and treatment options for diabetic retinopathy could lead to more effective management strategies for the condition, agreed David Boyer, MD, an ophthalmologist at Retina Vitreous Associates Medical Group in Los Angeles, speaking with this news organization.
 

Risk Factors for Diabetic Retinopathy

Sodium-glucose cotransporter 2 (SGLT2) inhibitors and glucagon-like peptide 1 receptor agonists (GLP-1 RAs) have gained popularity because of their benefits beyond glycemic control, including weight loss, and cardiovascular and kidney protection. However, the impact of these medications on vision-threatening retinal complications is not fully understood. “There has always been a question about whether these newer diabetes medications might exacerbate diabetic eye disease,” said Dr. Boyer.

In a retrospective observational study, researchers included adults with type 2 diabetes and moderate cardiovascular disease risk who had no history of advanced diabetic retinal complications. These patients initiated treatment with GLP-1 RA, SGLT2 inhibitors, DPP-4 inhibitors, or sulfonylureas. The study used inverse probability of treatment weighting to mimic randomization and compared the time to the first treatment for diabetic macular edema or proliferative diabetic retinopathy across the treatment groups.

Results, presented by Andrew J. Barkmeier, MD, an associate professor of ophthalmology at the Mayo Clinic, showed that among 371,698 patients, those who initiated therapy with SGLT2 inhibitors had a lower risk of requiring treatment for sight-threatening retinopathy compared with those using other medication classes. GLP-1 RA did not increase retinopathy risk relative to dipeptidyl peptidase 4 inhibitors and sulfonylurea medications.

“[This study] told us that we do have to keep an eye on patients’ retinopathy when they start on these new inhibitors. But the progression is minimal and, overall, I think most people today favor keeping blood sugar levels as good as possible,” said Dr. Boyer, who was not involved in the study.

Another factor that might increase diabetic retinopathy progression is obstructive sleep apnea. This underdiagnosed condition is linked to several health issues, including dementia, stroke, and myocardial infarctions. Although not easily treated, obstructive sleep apnea is manageable, Dr. Boyer explained.

Researchers utilized the TriNetX electronic health records research network to identify patients with nonproliferative diabetic retinopathy, both with and without obstructive sleep apnea. 

The results, presented by Ehsan Rahimy, MD, a retinal specialist at Palo Alto Medical Foundation and a professor at Stanford University, showed that patients with obstructive sleep apnea had a significantly higher risk of progressing to proliferative diabetic retinopathy and developing new-onset diabetic macular edema. These patients were more likely to require ocular interventions, such as intravitreal injections and laser photocoagulation. They also had greater risks for stroke, myocardial infarction, and death compared with those who did not have obstructive sleep apnea.

“It was good to bring this to everybody’s attention,” said Dr. Boyer, who was not involved in the study. “It’s an easy question to ask someone if they snore.”
 

New Treatments on the Horizon

In another presentation, Nathan C. Steinle, MD, of California Retina Consultants, presented a study that assessed the durability of response to sozinibercept in patients with retinal vascular diseases. This novel therapeutic agent is designed to inhibit VEGF-C and VEGF-D in conditions where VEGF-A suppression alone is insufficient. 

Sozinibercept was combined with standard anti–VEGF-A therapies such as ranibizumab or aflibercept. It involved a prospective, post hoc analysis of two phase 1b, open-label, dose-escalation studies, including 40 patients with neovascular age-related macular degeneration (nAMD; 31 patients) or diabetic macular edema (nine patients). These patients, either treatment-naive or previously treated, received three intravitreal injections of ranibizumab or aflibercept in combination with sozinibercept at various doses.

Results indicated that sozinibercept combination therapy was well tolerated, with no dose-limiting toxicities. In treatment-naive nAMD patients, the mean best-corrected visual acuity (BCVA) improved significantly from baseline at months 3 and 6. Previously treated nAMD patients also showed BCVA improvements, although to a lesser extent. For patients with persistent diabetic macular edema, switching to sozinibercept plus aflibercept resulted in notable BCVA gains. The mean time to requiring retreatment was longer in treatment-naive patients than in those previously treated, indicating a durable response. 

“Combination therapy with sozinibercept is going to be really important,” said Dr. Lim, who was not involved in the study, “because it attacks with a dual mechanism of action.”

Oral agents promise a potentially easier alternative for patients compared with frequent injections. CU06-1004 is a novel orally administered endothelial dysfunction blocker that has shown promise in stabilizing damaged capillaries, reducing abnormal angiogenesis, and inhibiting inflammatory activation in preclinical studies. “CU06 is very interesting to me because by preventing endothelial loss, it gets to the pathophysiology of why the blood vessels break down,” Dr. Lim said.

In a proof-of-concept phase 2a, multicenter, open-label, parallel-group trial, investigators randomly assigned 67 patients with diabetic macular edema to receive 100 mg, 200 mg, or 300 mg of CU06-1004 once daily for 12 weeks, followed by a 4-week follow-up. 

Results presented by Victor Gonzalez, MD, of Valley Retina Institute in Texas, indicated that the oral agent improved BCVA, stabilized central subfield thickness, and showed positive anatomical changes in optical coherence tomography images. CU06-1004 was well tolerated, with no drug-related serious adverse events. 

“The number [of patients] was very small, and we will need a much longer, larger trial to see if [CU06-1004] has benefits long term,” said Dr. Boyer, who was not involved in the study. “But I think we’re all very excited if we can find an oral agent for treating diabetic retinopathy. It would be easier for the patient to take a pill than having to come in for injections.” 

The sustained-release axitinib implant, OTX-TKI, is also generating significant interest, particularly for nonproliferative diabetic retinopathy. Axitinib, a tyrosine kinase inhibitor (TKI), targets signaling pathways crucial in cellular processes, providing a novel approach to managing diseases where traditional therapies might fall short. Unlike traditional anti-VEGF treatments that focus solely on cytokine levels, TKIs block the activation of signaling pathways, preventing downstream signaling regardless of cytokine levels. This mechanism is particularly important because it effectively inhibits disease progression even if levels of VEGF are high, Dr. Lim explained.

In the phase 1 HELIOS trial, OTX-TKI was assessed in patients with nonproliferative diabetic retinopathy. This multicenter, double-masked, parallel-group clinical study included 21 patients who had not received anti-VEGF treatment, dexamethasone intravitreal implants in the previous 12 months, or intraocular steroid injections in the prior 4 months. Patients were randomly assigned to receive either OTX-TKI or sham treatment.

Results presented by Dilsher S. Dhoot, MD, of California Retina Consultants, indicated that OTX-TKI was generally well tolerated, with no serious ocular adverse events. At 48 weeks, 46.2% of eyes treated with OTX-TKI showed a 1- or 2-step improvement on the Diabetic Retinopathy Severity Scale (DRSS) compared with none in the sham arm. Additionally, no eyes treated with OTX-TKI experienced a worsening on the DRSS, whereas 25% of eyes in the sham arm did. Vision-threatening complications, such as proliferative diabetic retinopathy or diabetic macular edema, developed in 37.5% of the sham group but in none of the OTX-TKI treated eyes. A single injection of OTX-TKI provided durable DRSS improvement for up to 48 weeks, with no patients in either arm requiring rescue therapy.

“This is a really exciting add-on treatment,” Dr. Lim said, who was not involved in the study. She explained that it is initially necessary to control the disease with standard treatments, because TKIs may take longer to exhibit their effects. Once the disease is stabilized, TKIs can be used alongside other therapies, potentially reducing the reliance on frequent anti-VEGF injections. “These are preliminary results, but that’s the hope going forward.”

Dr. Lim and Dr. Boyer report no relevant financial relationships.

A version of this article first appeared on Medscape.com.

STOCKHOLM — At the American Society of Retina Specialists (ASRS) 2024 Annual Meeting, researchers discussed how insights into potential risk factors and new treatments could improve outcomes for patients with diabetic retinopathy.

Jennifer Lim, MD, an ophthalmologist and director of the Retina Service at the University of Illinois Hospital & Health Sciences System in Chicago, told this news organization that emerging approaches to treating diabetic retinopathy offer hope because they address the root causes of the disease beyond just targeting vascular endothelial growth factor (VEGF). She said innovative methods and add-on treatments could lead to more durable and effective drugs.

Exploration of risk factors and treatment options for diabetic retinopathy could lead to more effective management strategies for the condition, agreed David Boyer, MD, an ophthalmologist at Retina Vitreous Associates Medical Group in Los Angeles, speaking with this news organization.
 

Risk Factors for Diabetic Retinopathy

Sodium-glucose cotransporter 2 (SGLT2) inhibitors and glucagon-like peptide 1 receptor agonists (GLP-1 RAs) have gained popularity because of their benefits beyond glycemic control, including weight loss, and cardiovascular and kidney protection. However, the impact of these medications on vision-threatening retinal complications is not fully understood. “There has always been a question about whether these newer diabetes medications might exacerbate diabetic eye disease,” said Dr. Boyer.

In a retrospective observational study, researchers included adults with type 2 diabetes and moderate cardiovascular disease risk who had no history of advanced diabetic retinal complications. These patients initiated treatment with GLP-1 RA, SGLT2 inhibitors, DPP-4 inhibitors, or sulfonylureas. The study used inverse probability of treatment weighting to mimic randomization and compared the time to the first treatment for diabetic macular edema or proliferative diabetic retinopathy across the treatment groups.

Results, presented by Andrew J. Barkmeier, MD, an associate professor of ophthalmology at the Mayo Clinic, showed that among 371,698 patients, those who initiated therapy with SGLT2 inhibitors had a lower risk of requiring treatment for sight-threatening retinopathy compared with those using other medication classes. GLP-1 RA did not increase retinopathy risk relative to dipeptidyl peptidase 4 inhibitors and sulfonylurea medications.

“[This study] told us that we do have to keep an eye on patients’ retinopathy when they start on these new inhibitors. But the progression is minimal and, overall, I think most people today favor keeping blood sugar levels as good as possible,” said Dr. Boyer, who was not involved in the study.

Another factor that might increase diabetic retinopathy progression is obstructive sleep apnea. This underdiagnosed condition is linked to several health issues, including dementia, stroke, and myocardial infarctions. Although not easily treated, obstructive sleep apnea is manageable, Dr. Boyer explained.

Researchers utilized the TriNetX electronic health records research network to identify patients with nonproliferative diabetic retinopathy, both with and without obstructive sleep apnea. 

The results, presented by Ehsan Rahimy, MD, a retinal specialist at Palo Alto Medical Foundation and a professor at Stanford University, showed that patients with obstructive sleep apnea had a significantly higher risk of progressing to proliferative diabetic retinopathy and developing new-onset diabetic macular edema. These patients were more likely to require ocular interventions, such as intravitreal injections and laser photocoagulation. They also had greater risks for stroke, myocardial infarction, and death compared with those who did not have obstructive sleep apnea.

“It was good to bring this to everybody’s attention,” said Dr. Boyer, who was not involved in the study. “It’s an easy question to ask someone if they snore.”
 

New Treatments on the Horizon

In another presentation, Nathan C. Steinle, MD, of California Retina Consultants, presented a study that assessed the durability of response to sozinibercept in patients with retinal vascular diseases. This novel therapeutic agent is designed to inhibit VEGF-C and VEGF-D in conditions where VEGF-A suppression alone is insufficient. 

Sozinibercept was combined with standard anti–VEGF-A therapies such as ranibizumab or aflibercept. It involved a prospective, post hoc analysis of two phase 1b, open-label, dose-escalation studies, including 40 patients with neovascular age-related macular degeneration (nAMD; 31 patients) or diabetic macular edema (nine patients). These patients, either treatment-naive or previously treated, received three intravitreal injections of ranibizumab or aflibercept in combination with sozinibercept at various doses.

Results indicated that sozinibercept combination therapy was well tolerated, with no dose-limiting toxicities. In treatment-naive nAMD patients, the mean best-corrected visual acuity (BCVA) improved significantly from baseline at months 3 and 6. Previously treated nAMD patients also showed BCVA improvements, although to a lesser extent. For patients with persistent diabetic macular edema, switching to sozinibercept plus aflibercept resulted in notable BCVA gains. The mean time to requiring retreatment was longer in treatment-naive patients than in those previously treated, indicating a durable response. 

“Combination therapy with sozinibercept is going to be really important,” said Dr. Lim, who was not involved in the study, “because it attacks with a dual mechanism of action.”

Oral agents promise a potentially easier alternative for patients compared with frequent injections. CU06-1004 is a novel orally administered endothelial dysfunction blocker that has shown promise in stabilizing damaged capillaries, reducing abnormal angiogenesis, and inhibiting inflammatory activation in preclinical studies. “CU06 is very interesting to me because by preventing endothelial loss, it gets to the pathophysiology of why the blood vessels break down,” Dr. Lim said.

In a proof-of-concept phase 2a, multicenter, open-label, parallel-group trial, investigators randomly assigned 67 patients with diabetic macular edema to receive 100 mg, 200 mg, or 300 mg of CU06-1004 once daily for 12 weeks, followed by a 4-week follow-up. 

Results presented by Victor Gonzalez, MD, of Valley Retina Institute in Texas, indicated that the oral agent improved BCVA, stabilized central subfield thickness, and showed positive anatomical changes in optical coherence tomography images. CU06-1004 was well tolerated, with no drug-related serious adverse events. 

“The number [of patients] was very small, and we will need a much longer, larger trial to see if [CU06-1004] has benefits long term,” said Dr. Boyer, who was not involved in the study. “But I think we’re all very excited if we can find an oral agent for treating diabetic retinopathy. It would be easier for the patient to take a pill than having to come in for injections.” 

The sustained-release axitinib implant, OTX-TKI, is also generating significant interest, particularly for nonproliferative diabetic retinopathy. Axitinib, a tyrosine kinase inhibitor (TKI), targets signaling pathways crucial in cellular processes, providing a novel approach to managing diseases where traditional therapies might fall short. Unlike traditional anti-VEGF treatments that focus solely on cytokine levels, TKIs block the activation of signaling pathways, preventing downstream signaling regardless of cytokine levels. This mechanism is particularly important because it effectively inhibits disease progression even if levels of VEGF are high, Dr. Lim explained.

In the phase 1 HELIOS trial, OTX-TKI was assessed in patients with nonproliferative diabetic retinopathy. This multicenter, double-masked, parallel-group clinical study included 21 patients who had not received anti-VEGF treatment, dexamethasone intravitreal implants in the previous 12 months, or intraocular steroid injections in the prior 4 months. Patients were randomly assigned to receive either OTX-TKI or sham treatment.

Results presented by Dilsher S. Dhoot, MD, of California Retina Consultants, indicated that OTX-TKI was generally well tolerated, with no serious ocular adverse events. At 48 weeks, 46.2% of eyes treated with OTX-TKI showed a 1- or 2-step improvement on the Diabetic Retinopathy Severity Scale (DRSS) compared with none in the sham arm. Additionally, no eyes treated with OTX-TKI experienced a worsening on the DRSS, whereas 25% of eyes in the sham arm did. Vision-threatening complications, such as proliferative diabetic retinopathy or diabetic macular edema, developed in 37.5% of the sham group but in none of the OTX-TKI treated eyes. A single injection of OTX-TKI provided durable DRSS improvement for up to 48 weeks, with no patients in either arm requiring rescue therapy.

“This is a really exciting add-on treatment,” Dr. Lim said, who was not involved in the study. She explained that it is initially necessary to control the disease with standard treatments, because TKIs may take longer to exhibit their effects. Once the disease is stabilized, TKIs can be used alongside other therapies, potentially reducing the reliance on frequent anti-VEGF injections. “These are preliminary results, but that’s the hope going forward.”

Dr. Lim and Dr. Boyer report no relevant financial relationships.

A version of this article first appeared on Medscape.com.

Take a look at any of the evidence-based US obesity treatment guidelines. The key criteria for diagnosing overweight and obesity is based on the body mass index (BMI). 

The guidelines also use BMI to stratify care options to decrease cardiovascular risk. For example, persons with BMI ≥30 are classified as having obesity, and antiobesity medications are recommended. Those with BMI ≥ 40 are classified as having severe obesity, and metabolic bariatric surgery may be appropriate. 

But where did these cutoff points for more and less aggressive treatments come from? These BMI cutoffs are based primarily on mortality data collected from large non-Hispanic White populations, without data on potential differences by gender and ethnicity. In fact, by itself, BMI is an incomplete measure of cardiometabolic risk, especially in a multiethnic clinic with all genders represented.

For example, it is certainly true that those with BMI ≥ 30 have more cardiovascular risk factors than those with BMI < 30. But Asian American individuals have more risk factors at lower BMIs than do White or African American individuals likely because of more visceral fat accumulation at lower BMIs.

Besides the variation in gender and ethnicity, BMI does not take the type and location of body fat into consideration. Adipose tissue in visceral or ectopic areas have much higher risks for disease than subcutaneous adipose tissue because of the associated inflammation. Measures such as waist circumference, waist-to-hip ratio, and skinfold measurements aim to capture this aspect but often fall short because of variation in techniques.

BMI does not account for muscle mass either, so fit athletes and bodybuilders can be classified as having obesity by BMI alone. More accurate body fat percent measures, such as dual-energy X-ray absorptiometry or MRI specifically for ectopic fat, are labor intensive, expensive, and not feasible to perform in a busy primary care or endocrinology clinic.
 

Assessing Risks From Obesity Beyond BMI

Clearly, better risk measures than BMI are needed, but until they are available, supplemental clinical tools can aid diagnosis and treatment decisions at obesity medicine specialty centers, endocrinology and diabetes centers, and those centers that focus on the treatment of obesity.

For example, a seca scale can measure percent body fat by bioelectric impedance analysis. This technique also has its limitations, but for persons who are well hydrated, it can be used as a baseline to determine efficacy of behavioral interventions, such as resistance-exercise training and a high-protein diet to protect muscle mass as the patient loses weight.

A lot also can be gleaned from diet and exercise history, social history, family history, and physical exam as well as laboratory analyses. For example, an Asian American patient with a BMI of 26 who has been gaining weight mostly in the abdominal region after age 35 years is likely to have cardiometabolic risk, and a family history can solidify that. An exam can show signs of acanthosis nigricans or an enlarged liver and generous abdominal adipose tissue. This would be the patient in whom you would want to obtain a hemoglobin A1c measurement in the chance that it is elevated at > 5.7 mg/dL, suggesting high risk for type 2 diabetes. 

A Fibrosis-4 score can assess the risk for liver disease from aspartate transaminase and alanine aminotransferase and platelet count and age, providing clues to cardiometabolic disease risk.

In the next 10, years there may be a better measure for cardiometabolic risk that is more accurate than BMI is. It could be the sagittal abdominal diameter, which has been purported to more accurately measure visceral abdominal fat. But this has not made it to be one of the vital signs in a busy primary care clinic, however. 
 

Will New Body Fat Tools Change Practice?

In the next 10 years, there may be an affordable gadget to scan the body to determine visceral vs subcutaneous deposition of fat — like radiography for tissue. Now, three-dimensional (3D) total-body scanners can obtain body composition, but they are extremely expensive. The more important clinical question is: How will the use of these imaging modalities change your practice protocol for a particular patient? 

Think about the FibroScan, a type of ultrasound used to determine fatty liver disease and fibrosis. We order the test for those patients in whom we already have a strong suspicion for liver disease and, in obesity practices, for fatty liver and metabolic-associated fatty liver disease or metabolic associated steatohepatitis.

The test results do much to educate the patient and help the patient understand the need for aggressive treatment for their obesity. But it doesn’t necessarily change the clinician’s practice protocols and decisions. We would still recommend weight management and medications or surgery to patients regardless of the findings. 

A FibroScan is an expense, and not all primary care or endocrine practitioners may feel it necessary to purchase one for the added benefit of patient education. And I would argue that a 3D body scanner is a great tool but more for educational purposes than to really determine practice decision-making or outcomes. 

In the meantime, an old-fashioned physical examination, along with a thorough medical, social, and family history should give even the busiest primary care provider enough information to decide whether their patient is a candidate for preventive measures to reduce body fat with diet, exercise, and medication as well as whether the patient is a candidate for metabolic bariatric surgery. Higher suspicion of cardiovascular risk at lower BMI ranges for various ethnicities can help primary care providers pick up on the patients with low BMI but who are at higher risk for type 2 diabetes or prediabetes and cardiovascular disease. 

So the answer to whether we need a better measure than the BMI: Yes, we do. We need a physical examination on all patients.

Dr. Apovian, professor of medicine, Harvard Medical School, and codirector, Center for Weight Management and Wellness, Brigham and Women’s Hospital, both in Boston, Massachusetts, disclosed ties with Altimmune, CinFina Pharma, Cowen and Company, EPG Communication Holdings, Form Health, Gelesis, L-Nutra, NeuroBo Pharm, Novo, OptumRx, Pain Script, Palatin, Pursuit by You, Roman Health, Xeno, and Riverview School.

A version of this article appeared on Medscape.com.

Take a look at any of the evidence-based US obesity treatment guidelines. The key criteria for diagnosing overweight and obesity is based on the body mass index (BMI). 

The guidelines also use BMI to stratify care options to decrease cardiovascular risk. For example, persons with BMI ≥30 are classified as having obesity, and antiobesity medications are recommended. Those with BMI ≥ 40 are classified as having severe obesity, and metabolic bariatric surgery may be appropriate. 

But where did these cutoff points for more and less aggressive treatments come from? These BMI cutoffs are based primarily on mortality data collected from large non-Hispanic White populations, without data on potential differences by gender and ethnicity. In fact, by itself, BMI is an incomplete measure of cardiometabolic risk, especially in a multiethnic clinic with all genders represented.

For example, it is certainly true that those with BMI ≥ 30 have more cardiovascular risk factors than those with BMI < 30. But Asian American individuals have more risk factors at lower BMIs than do White or African American individuals likely because of more visceral fat accumulation at lower BMIs.

Besides the variation in gender and ethnicity, BMI does not take the type and location of body fat into consideration. Adipose tissue in visceral or ectopic areas have much higher risks for disease than subcutaneous adipose tissue because of the associated inflammation. Measures such as waist circumference, waist-to-hip ratio, and skinfold measurements aim to capture this aspect but often fall short because of variation in techniques.

BMI does not account for muscle mass either, so fit athletes and bodybuilders can be classified as having obesity by BMI alone. More accurate body fat percent measures, such as dual-energy X-ray absorptiometry or MRI specifically for ectopic fat, are labor intensive, expensive, and not feasible to perform in a busy primary care or endocrinology clinic.
 

Assessing Risks From Obesity Beyond BMI

Clearly, better risk measures than BMI are needed, but until they are available, supplemental clinical tools can aid diagnosis and treatment decisions at obesity medicine specialty centers, endocrinology and diabetes centers, and those centers that focus on the treatment of obesity.

For example, a seca scale can measure percent body fat by bioelectric impedance analysis. This technique also has its limitations, but for persons who are well hydrated, it can be used as a baseline to determine efficacy of behavioral interventions, such as resistance-exercise training and a high-protein diet to protect muscle mass as the patient loses weight.

A lot also can be gleaned from diet and exercise history, social history, family history, and physical exam as well as laboratory analyses. For example, an Asian American patient with a BMI of 26 who has been gaining weight mostly in the abdominal region after age 35 years is likely to have cardiometabolic risk, and a family history can solidify that. An exam can show signs of acanthosis nigricans or an enlarged liver and generous abdominal adipose tissue. This would be the patient in whom you would want to obtain a hemoglobin A1c measurement in the chance that it is elevated at > 5.7 mg/dL, suggesting high risk for type 2 diabetes. 

A Fibrosis-4 score can assess the risk for liver disease from aspartate transaminase and alanine aminotransferase and platelet count and age, providing clues to cardiometabolic disease risk.

In the next 10, years there may be a better measure for cardiometabolic risk that is more accurate than BMI is. It could be the sagittal abdominal diameter, which has been purported to more accurately measure visceral abdominal fat. But this has not made it to be one of the vital signs in a busy primary care clinic, however. 
 

Will New Body Fat Tools Change Practice?

In the next 10 years, there may be an affordable gadget to scan the body to determine visceral vs subcutaneous deposition of fat — like radiography for tissue. Now, three-dimensional (3D) total-body scanners can obtain body composition, but they are extremely expensive. The more important clinical question is: How will the use of these imaging modalities change your practice protocol for a particular patient? 

Think about the FibroScan, a type of ultrasound used to determine fatty liver disease and fibrosis. We order the test for those patients in whom we already have a strong suspicion for liver disease and, in obesity practices, for fatty liver and metabolic-associated fatty liver disease or metabolic associated steatohepatitis.

The test results do much to educate the patient and help the patient understand the need for aggressive treatment for their obesity. But it doesn’t necessarily change the clinician’s practice protocols and decisions. We would still recommend weight management and medications or surgery to patients regardless of the findings. 

A FibroScan is an expense, and not all primary care or endocrine practitioners may feel it necessary to purchase one for the added benefit of patient education. And I would argue that a 3D body scanner is a great tool but more for educational purposes than to really determine practice decision-making or outcomes. 

In the meantime, an old-fashioned physical examination, along with a thorough medical, social, and family history should give even the busiest primary care provider enough information to decide whether their patient is a candidate for preventive measures to reduce body fat with diet, exercise, and medication as well as whether the patient is a candidate for metabolic bariatric surgery. Higher suspicion of cardiovascular risk at lower BMI ranges for various ethnicities can help primary care providers pick up on the patients with low BMI but who are at higher risk for type 2 diabetes or prediabetes and cardiovascular disease. 

So the answer to whether we need a better measure than the BMI: Yes, we do. We need a physical examination on all patients.

Dr. Apovian, professor of medicine, Harvard Medical School, and codirector, Center for Weight Management and Wellness, Brigham and Women’s Hospital, both in Boston, Massachusetts, disclosed ties with Altimmune, CinFina Pharma, Cowen and Company, EPG Communication Holdings, Form Health, Gelesis, L-Nutra, NeuroBo Pharm, Novo, OptumRx, Pain Script, Palatin, Pursuit by You, Roman Health, Xeno, and Riverview School.

A version of this article appeared on Medscape.com.

Take a look at any of the evidence-based US obesity treatment guidelines. The key criteria for diagnosing overweight and obesity is based on the body mass index (BMI). 

The guidelines also use BMI to stratify care options to decrease cardiovascular risk. For example, persons with BMI ≥30 are classified as having obesity, and antiobesity medications are recommended. Those with BMI ≥ 40 are classified as having severe obesity, and metabolic bariatric surgery may be appropriate. 

But where did these cutoff points for more and less aggressive treatments come from? These BMI cutoffs are based primarily on mortality data collected from large non-Hispanic White populations, without data on potential differences by gender and ethnicity. In fact, by itself, BMI is an incomplete measure of cardiometabolic risk, especially in a multiethnic clinic with all genders represented.

For example, it is certainly true that those with BMI ≥ 30 have more cardiovascular risk factors than those with BMI < 30. But Asian American individuals have more risk factors at lower BMIs than do White or African American individuals likely because of more visceral fat accumulation at lower BMIs.

Besides the variation in gender and ethnicity, BMI does not take the type and location of body fat into consideration. Adipose tissue in visceral or ectopic areas have much higher risks for disease than subcutaneous adipose tissue because of the associated inflammation. Measures such as waist circumference, waist-to-hip ratio, and skinfold measurements aim to capture this aspect but often fall short because of variation in techniques.

BMI does not account for muscle mass either, so fit athletes and bodybuilders can be classified as having obesity by BMI alone. More accurate body fat percent measures, such as dual-energy X-ray absorptiometry or MRI specifically for ectopic fat, are labor intensive, expensive, and not feasible to perform in a busy primary care or endocrinology clinic.
 

Assessing Risks From Obesity Beyond BMI

Clearly, better risk measures than BMI are needed, but until they are available, supplemental clinical tools can aid diagnosis and treatment decisions at obesity medicine specialty centers, endocrinology and diabetes centers, and those centers that focus on the treatment of obesity.

For example, a seca scale can measure percent body fat by bioelectric impedance analysis. This technique also has its limitations, but for persons who are well hydrated, it can be used as a baseline to determine efficacy of behavioral interventions, such as resistance-exercise training and a high-protein diet to protect muscle mass as the patient loses weight.

A lot also can be gleaned from diet and exercise history, social history, family history, and physical exam as well as laboratory analyses. For example, an Asian American patient with a BMI of 26 who has been gaining weight mostly in the abdominal region after age 35 years is likely to have cardiometabolic risk, and a family history can solidify that. An exam can show signs of acanthosis nigricans or an enlarged liver and generous abdominal adipose tissue. This would be the patient in whom you would want to obtain a hemoglobin A1c measurement in the chance that it is elevated at > 5.7 mg/dL, suggesting high risk for type 2 diabetes. 

A Fibrosis-4 score can assess the risk for liver disease from aspartate transaminase and alanine aminotransferase and platelet count and age, providing clues to cardiometabolic disease risk.

In the next 10, years there may be a better measure for cardiometabolic risk that is more accurate than BMI is. It could be the sagittal abdominal diameter, which has been purported to more accurately measure visceral abdominal fat. But this has not made it to be one of the vital signs in a busy primary care clinic, however. 
 

Will New Body Fat Tools Change Practice?

In the next 10 years, there may be an affordable gadget to scan the body to determine visceral vs subcutaneous deposition of fat — like radiography for tissue. Now, three-dimensional (3D) total-body scanners can obtain body composition, but they are extremely expensive. The more important clinical question is: How will the use of these imaging modalities change your practice protocol for a particular patient? 

Think about the FibroScan, a type of ultrasound used to determine fatty liver disease and fibrosis. We order the test for those patients in whom we already have a strong suspicion for liver disease and, in obesity practices, for fatty liver and metabolic-associated fatty liver disease or metabolic associated steatohepatitis.

The test results do much to educate the patient and help the patient understand the need for aggressive treatment for their obesity. But it doesn’t necessarily change the clinician’s practice protocols and decisions. We would still recommend weight management and medications or surgery to patients regardless of the findings. 

A FibroScan is an expense, and not all primary care or endocrine practitioners may feel it necessary to purchase one for the added benefit of patient education. And I would argue that a 3D body scanner is a great tool but more for educational purposes than to really determine practice decision-making or outcomes. 

In the meantime, an old-fashioned physical examination, along with a thorough medical, social, and family history should give even the busiest primary care provider enough information to decide whether their patient is a candidate for preventive measures to reduce body fat with diet, exercise, and medication as well as whether the patient is a candidate for metabolic bariatric surgery. Higher suspicion of cardiovascular risk at lower BMI ranges for various ethnicities can help primary care providers pick up on the patients with low BMI but who are at higher risk for type 2 diabetes or prediabetes and cardiovascular disease. 

So the answer to whether we need a better measure than the BMI: Yes, we do. We need a physical examination on all patients.

Dr. Apovian, professor of medicine, Harvard Medical School, and codirector, Center for Weight Management and Wellness, Brigham and Women’s Hospital, both in Boston, Massachusetts, disclosed ties with Altimmune, CinFina Pharma, Cowen and Company, EPG Communication Holdings, Form Health, Gelesis, L-Nutra, NeuroBo Pharm, Novo, OptumRx, Pain Script, Palatin, Pursuit by You, Roman Health, Xeno, and Riverview School.

A version of this article appeared on Medscape.com.

A multi-institutional partnership has funded six new research projects aimed at developing novel insulin analogs that more closely mimic the action of a healthy pancreas. 

The Type 1 Diabetes Grand Challenge comprises Diabetes UK, JDRF (now called “Breakthrough T1D” in the United States), and the Steve Morgan Foundation. It will provide a total of £50 million (about $64 million in US dollars) for type 1 diabetes research, including £15 million (~$19 million) for six separate projects on novel insulins to be conducted at universities in the United States, Australia, and China. Four will aim to develop glucose-responsive “smart” insulins, another one ultrafast-acting insulin, and the sixth a product combining insulin and glucagon. 

“Even with the currently available modern insulins, people living with type 1 diabetes put lots of effort into managing their diabetes every day to find a good balance between acceptable glycemic control on the one hand and avoiding hypoglycemia on the other. The funded six new research projects address major shortcomings in insulin therapy,” Tim Heise, MD, vice-chair of the project’s Novel Insulins Scientific Advisory Panel, said in a statement from the Steve Morgan Foundation. 

All six projects are currently in the preclinical stage, Dr. Heise said, noting that “the idea behind the funding program is to help the most promising research initiatives to reach the clinical stage.”

Glucose-responsive, or so-called “smart,” insulins are considered the holy grail because they would become active only to prevent hyperglycemia and remain dormant otherwise, thereby not causing hypoglycemia as current insulin analogs can. The idea isn’t new. In 2010, there was excitement in the type 1 diabetes community when the pharmaceutical company Merck acquired a smaller company called SmartCells that had been working on a “smart insulin” for several years. But nothing came of that. 

“The challenges then and today are pretty similar. In particular, it is quite difficult to find a glucose-sensing moiety that is safe, reacts sufficiently to relatively small changes in the human body in both falling and increasing glucose, and can be produced in large quantities,” Dr. Heise, lead scientist and co-founder of the diabetes contract research organization Profil, based in Neuss, Germany, told this news organization.

Several papers since have reported proof-of-concept in rodents, but there are no published data thus far in humans. However, in recent years the major insulin manufacturers Novo Nordisk and Eli Lilly have acquired smaller companies with the aim of smart insulin development. 

It will still take some time, Dr. Heise said. “The challenges are well understood, although difficult to overcome. There has been quite some progress in the development of glucose-sensing moieties including, but not limited to, nanotechnological approaches.”

Applications for the newly funded projects “were thoroughly reviewed by a large panel of scientists with different areas of expertise. At the end, there was agreement in the review panel that these projects deserved further investigation, although considering their early stage, there still is a substantial risk of failure for all these projects,” he said. 

The development path might be a bit more straightforward for the other two projects. Ultra–fast-acting insulin is needed because the action of the current ones, Novo Nordisk’s Fiasp and Eli Lilly and Company’s Lyumjev, is still delayed, potentially leading to postmeal hyperglycemia if administered after or immediately prior to eating. “A truly rapid short-acting insulin might make it finally possible to progress from hybrid to fully closed loop systems, allowing a technological ‘cure’ for people with diabetes,” Dr. Heise said in the statement. 

And a protein combining insulin with glucagon could help minimize the risk for hypoglycemia, which still exists for current insulin analogs and remains “one of the major concerns associated with insulin therapy today,” he noted. 

Dr. Heise told this news organization that compared with “smart” insulin, development of the other two products “might be a bit faster if they succeed. But none of these approaches will make it to market in the next 5 years, and if one entered clinic within the next 2 years, that would be a huge success.” Nonetheless, “these research projects, if successful, might do no less than heralding a new era in insulin therapy.”

Dr. Heise is an employee of Profil, which has worked with a large number of the major diabetes industry manufacturers.

A version of this article first appeared on Medscape.com.

A multi-institutional partnership has funded six new research projects aimed at developing novel insulin analogs that more closely mimic the action of a healthy pancreas. 

The Type 1 Diabetes Grand Challenge comprises Diabetes UK, JDRF (now called “Breakthrough T1D” in the United States), and the Steve Morgan Foundation. It will provide a total of £50 million (about $64 million in US dollars) for type 1 diabetes research, including £15 million (~$19 million) for six separate projects on novel insulins to be conducted at universities in the United States, Australia, and China. Four will aim to develop glucose-responsive “smart” insulins, another one ultrafast-acting insulin, and the sixth a product combining insulin and glucagon. 

“Even with the currently available modern insulins, people living with type 1 diabetes put lots of effort into managing their diabetes every day to find a good balance between acceptable glycemic control on the one hand and avoiding hypoglycemia on the other. The funded six new research projects address major shortcomings in insulin therapy,” Tim Heise, MD, vice-chair of the project’s Novel Insulins Scientific Advisory Panel, said in a statement from the Steve Morgan Foundation. 

All six projects are currently in the preclinical stage, Dr. Heise said, noting that “the idea behind the funding program is to help the most promising research initiatives to reach the clinical stage.”

Glucose-responsive, or so-called “smart,” insulins are considered the holy grail because they would become active only to prevent hyperglycemia and remain dormant otherwise, thereby not causing hypoglycemia as current insulin analogs can. The idea isn’t new. In 2010, there was excitement in the type 1 diabetes community when the pharmaceutical company Merck acquired a smaller company called SmartCells that had been working on a “smart insulin” for several years. But nothing came of that. 

“The challenges then and today are pretty similar. In particular, it is quite difficult to find a glucose-sensing moiety that is safe, reacts sufficiently to relatively small changes in the human body in both falling and increasing glucose, and can be produced in large quantities,” Dr. Heise, lead scientist and co-founder of the diabetes contract research organization Profil, based in Neuss, Germany, told this news organization.

Several papers since have reported proof-of-concept in rodents, but there are no published data thus far in humans. However, in recent years the major insulin manufacturers Novo Nordisk and Eli Lilly have acquired smaller companies with the aim of smart insulin development. 

It will still take some time, Dr. Heise said. “The challenges are well understood, although difficult to overcome. There has been quite some progress in the development of glucose-sensing moieties including, but not limited to, nanotechnological approaches.”

Applications for the newly funded projects “were thoroughly reviewed by a large panel of scientists with different areas of expertise. At the end, there was agreement in the review panel that these projects deserved further investigation, although considering their early stage, there still is a substantial risk of failure for all these projects,” he said. 

The development path might be a bit more straightforward for the other two projects. Ultra–fast-acting insulin is needed because the action of the current ones, Novo Nordisk’s Fiasp and Eli Lilly and Company’s Lyumjev, is still delayed, potentially leading to postmeal hyperglycemia if administered after or immediately prior to eating. “A truly rapid short-acting insulin might make it finally possible to progress from hybrid to fully closed loop systems, allowing a technological ‘cure’ for people with diabetes,” Dr. Heise said in the statement. 

And a protein combining insulin with glucagon could help minimize the risk for hypoglycemia, which still exists for current insulin analogs and remains “one of the major concerns associated with insulin therapy today,” he noted. 

Dr. Heise told this news organization that compared with “smart” insulin, development of the other two products “might be a bit faster if they succeed. But none of these approaches will make it to market in the next 5 years, and if one entered clinic within the next 2 years, that would be a huge success.” Nonetheless, “these research projects, if successful, might do no less than heralding a new era in insulin therapy.”

Dr. Heise is an employee of Profil, which has worked with a large number of the major diabetes industry manufacturers.

A version of this article first appeared on Medscape.com.

A multi-institutional partnership has funded six new research projects aimed at developing novel insulin analogs that more closely mimic the action of a healthy pancreas. 

The Type 1 Diabetes Grand Challenge comprises Diabetes UK, JDRF (now called “Breakthrough T1D” in the United States), and the Steve Morgan Foundation. It will provide a total of £50 million (about $64 million in US dollars) for type 1 diabetes research, including £15 million (~$19 million) for six separate projects on novel insulins to be conducted at universities in the United States, Australia, and China. Four will aim to develop glucose-responsive “smart” insulins, another one ultrafast-acting insulin, and the sixth a product combining insulin and glucagon. 

“Even with the currently available modern insulins, people living with type 1 diabetes put lots of effort into managing their diabetes every day to find a good balance between acceptable glycemic control on the one hand and avoiding hypoglycemia on the other. The funded six new research projects address major shortcomings in insulin therapy,” Tim Heise, MD, vice-chair of the project’s Novel Insulins Scientific Advisory Panel, said in a statement from the Steve Morgan Foundation. 

All six projects are currently in the preclinical stage, Dr. Heise said, noting that “the idea behind the funding program is to help the most promising research initiatives to reach the clinical stage.”

Glucose-responsive, or so-called “smart,” insulins are considered the holy grail because they would become active only to prevent hyperglycemia and remain dormant otherwise, thereby not causing hypoglycemia as current insulin analogs can. The idea isn’t new. In 2010, there was excitement in the type 1 diabetes community when the pharmaceutical company Merck acquired a smaller company called SmartCells that had been working on a “smart insulin” for several years. But nothing came of that. 

“The challenges then and today are pretty similar. In particular, it is quite difficult to find a glucose-sensing moiety that is safe, reacts sufficiently to relatively small changes in the human body in both falling and increasing glucose, and can be produced in large quantities,” Dr. Heise, lead scientist and co-founder of the diabetes contract research organization Profil, based in Neuss, Germany, told this news organization.

Several papers since have reported proof-of-concept in rodents, but there are no published data thus far in humans. However, in recent years the major insulin manufacturers Novo Nordisk and Eli Lilly have acquired smaller companies with the aim of smart insulin development. 

It will still take some time, Dr. Heise said. “The challenges are well understood, although difficult to overcome. There has been quite some progress in the development of glucose-sensing moieties including, but not limited to, nanotechnological approaches.”

Applications for the newly funded projects “were thoroughly reviewed by a large panel of scientists with different areas of expertise. At the end, there was agreement in the review panel that these projects deserved further investigation, although considering their early stage, there still is a substantial risk of failure for all these projects,” he said. 

The development path might be a bit more straightforward for the other two projects. Ultra–fast-acting insulin is needed because the action of the current ones, Novo Nordisk’s Fiasp and Eli Lilly and Company’s Lyumjev, is still delayed, potentially leading to postmeal hyperglycemia if administered after or immediately prior to eating. “A truly rapid short-acting insulin might make it finally possible to progress from hybrid to fully closed loop systems, allowing a technological ‘cure’ for people with diabetes,” Dr. Heise said in the statement. 

And a protein combining insulin with glucagon could help minimize the risk for hypoglycemia, which still exists for current insulin analogs and remains “one of the major concerns associated with insulin therapy today,” he noted. 

Dr. Heise told this news organization that compared with “smart” insulin, development of the other two products “might be a bit faster if they succeed. But none of these approaches will make it to market in the next 5 years, and if one entered clinic within the next 2 years, that would be a huge success.” Nonetheless, “these research projects, if successful, might do no less than heralding a new era in insulin therapy.”

Dr. Heise is an employee of Profil, which has worked with a large number of the major diabetes industry manufacturers.

A version of this article first appeared on Medscape.com.

In July 2024, a 33-year-old woman with type 1 diabetes was boating on a hot day when her insulin delivery device slipped off. By the time she was able to exit the river, she was clearly ill, and an ambulance was called. The hospital was at capacity. Lying in the hallway, she was treated with fluids but not insulin, despite her boyfriend repeatedly telling the staff she had diabetes. She was released while still vomiting. The next morning, her boyfriend found her dead.

This story was shared by a friend of the woman in a Facebook group for people with type 1 diabetes and later confirmed by the boyfriend in a separate heartbreaking post. While it may be an extreme case, encounters with a lack of knowledge about type 1 diabetes in healthcare settings are quite common, sometimes resulting in serious adverse consequences.

In my 50+ years of living with the condition, I’ve lost track of the number of times I’ve had to speak up for myself, correct errors, raise issues that haven’t been considered, and educate nonspecialist healthcare professionals about even some of the basics.

Type 1 diabetes is an autoimmune condition in which the insulin-producing cells in the pancreas are destroyed, necessitating lifelong insulin treatment. Type 2, in contrast, arises from a combination of insulin resistance and decreased insulin production. Type 1 accounts for just 5% of all people with diabetes, but at a prevalence of about 1 in 200, it’s not rare. And that’s not even counting the adults who have been misdiagnosed as having type 2 but who actually have type 1.

As a general rule, people with type 1 diabetes are more insulin sensitive than those with type 2 and more prone to both hyper- and hypoglycemia. Blood sugar levels tend to be more labile and less predictable, even under normal circumstances. Recent advances in hybrid closed-loop technology have been extremely helpful in reducing the swings, but the systems aren’t foolproof yet. They still require user input (ie, guesswork), so there’s still room for error.

Managing type 1 diabetes is challenging even for endocrinologists. But here are some very important basics that every healthcare provider should know.
 

We Need Insulin 24/7

Never, ever withhold insulin from a person with type 1 diabetes, for any reason. Even when not eating — or when vomiting — we still need basal (background) insulin, either via long-acting analog or a pump infusion. The dose may need to be lowered to avoid hypoglycemia, but if insulin is stopped, diabetic ketoacidosis will result. And if that continues, death will follow.

This should be basic knowledge, but I’ve read and heard far too many stories of insulin being withheld from people with type 1 in various settings, including emergency departments, psychiatric facilities, and jails. On Facebook, people with type 1 diabetes often report being told not to take their insulin the morning before a procedure, while more than one has described “sneaking” their own insulin while hospitalized because they weren’t receiving any or not receiving enough.

On the flip side, although insulin needs are very individual, the amount needed for someone with type 1 is typically considerably less than for a person with type 2. Too much can result in severe hypoglycemia. There are lots of stories from people with type 1 diabetes who had to battle with hospital staff who tried to give them much higher doses than they knew they needed.

The American Diabetes Association recommends that people with type 1 diabetes who are hospitalized be allowed to wear their devices and self-manage to the degree possible. And please, listen to us when we tell you what we know about our own condition.
 

Fasting Is Fraught

I cringe every time I’m told to fast for a test or procedure. Fasting poses a risk for hypoglycemia in people with type 1 diabetes, even when using state-of-the-art technology. Fasting should not be required unless absolutely necessary, especially for routine lab tests.

Saleh Aldasouqi, MD, chief of endocrinology at Michigan State University, East Lansing, Michigan, has published several papers on a phenomenon he calls “Fasting-Evoked En Route Hypoglycemia in Diabetes,” in which patients who fast overnight and skip breakfast experience hypoglycemia on the way to the lab.

“Patients continue taking their diabetes medication but don’t eat anything, resulting in low blood sugar levels that cause them to have a hypoglycemic event while driving to or from the lab, putting themselves and others at risk,” Dr. Aldasouqi explained, adding that fasting often isn’t necessary for routine lipid panels.

If fasting is necessary, as for a surgical procedure that involves anesthesia, the need for insulin adjustment — NOT withholding — should be discussed with the patient to determine whether they can do it themselves or whether their diabetes provider should be consulted.

But again, this is tricky even for endocrinologists. True story: When I had my second carpal tunnel surgery in July 2019, my hand surgeon wisely scheduled me for his first procedure in the morning to minimize the length of time I’d have to fast. (He has type 1 diabetes himself, which helped.) My endocrinologist had advised me, per guidelines, to cut back my basal insulin infusion on my pump by 20% before going to bed.

But at bedtime, my continuous glucose monitor (CGM) showed that I was in the 170 mg/dL’s and rising, not entirely surprising since I’d cut back on my predinner insulin dose knowing I wouldn’t be able to eat if I dropped low later. I didn’t cut back the basal.

When I woke up, my glucose level was over 300 mg/dL. This time, stress was the likely cause. (That’s happened before.) Despite giving myself several small insulin boluses that morning without eating, my blood sugar was still about 345 mg/dL when I arrived at the hospital. The nurse told me that if it had been over 375 mg/dL, they would have had to cancel the surgery, but it wasn’t, so they went ahead. I have no idea how they came up with that cutoff.

Anyway, thankfully, everything went fine; I brought my blood sugar back in target range afterward and healed normally. Point being, type 1 diabetes management is a crazy balancing act, and guidelines only go so far.
 

We Don’t React Well to Steroids

If it’s absolutely necessary to give steroids to a person with type 1 diabetes for any reason, plans must be made in advance for the inevitable glucose spike. If the person doesn’t know how to adjust their insulin for it, please have them consult their diabetes provider. In my experience with locally injected corticosteroids, the spike is always higher and longer than I expected. Thankfully, I haven’t had to deal with systemic steroids, but my guess is they’re probably worse.

Procedures Can Be Pesky

People who wear insulin pumps and/or CGMs must remove them for MRI and certain other imaging procedures. In some cases — as with CGMs and the Omnipod insulin delivery device that can’t be put back on after removal — this necessitates advance planning to bring along replacement equipment for immediately after the procedure.

Diabetes devices can stay in place for other imaging studies, such as x-rays, most CT scans, ECGs, and ultrasounds. For heaven’s sake, don’t ask us to remove our devices if it isn’t totally necessary.

In general, surprises that affect blood sugar are a bad idea. I recently underwent a gastric emptying study. I knew the test would involve eating radioactive eggs, but I didn’t find out there’s also a jelly sandwich with two slices of white bread until the technician handed it to me and told me to eat it. I had to quickly give myself insulin, and of course my blood sugar spiked later. Had I been forewarned, I could have at least “pre-bolused” 15-20 minutes in advance to give the insulin more time to start working.

Another anecdote: Prior to a dental appointment that involved numbing my gums for an in-depth cleaning, my longtime dental hygienist told me “be sure to eat before you come.” I do appreciate her thinking of my diabetes. However, while that advice would have made sense long ago when treatment involved two daily insulin injections without dose adjustments, now it’s more complicated.

Today, when we eat foods containing carbohydrates, we typically take short-acting insulin, which can lead to hypoglycemia if the dose given exceeds the amount needed for the carbs, regardless of how much is eaten. Better to not eat at all (assuming the basal insulin dose is correct) or just eat protein. And for the provider, best to just tell the patient about the eating limitations and make sure they know how to handle them.
 

Duh, We Already Have Diabetes

I’ve heard of at least four instances in which pregnant women with type 1 diabetes have been ordered to undergo an oral glucose tolerance test to screen for gestational diabetes. In two cases, it was a “can you believe it?!” post on Facebook, with the women rightly refusing to take the test.

But in May 2024, a pregnant woman reported she actually drank the liquid, her blood sugar skyrocketed, she was vomiting, and she was in the midst of trying to bring her glucose level down with insulin on her own at home. She hadn’t objected to taking the test because “my ob.gyn. knows I have diabetes,” so she figured it was appropriate.

I don’t work in a healthcare setting, but here’s my guess: The ob.gyn. hadn’t actually ordered the test but had neglected to UN-order a routine test for a pregnant patient who already had diabetes and obviously should NOT be forced to drink a high-sugar liquid for no reason. If this is happening in pregnancies with type 1 diabetes, it most certainly could be as well for those with pre-existing type 2 diabetes. Clearly, something should be done to prevent this unnecessary and potentially harmful scenario.

In summary, I think I speak for everyone living with type 1 diabetes in saying that we would like to have confidence that healthcare providers in all settings can provide care for whatever brought us to them without adding to the daily burden we already carry. Let’s work together.

Reviewed by Saleh Aldasouqi, MD, chief of endocrinology at Michigan State University. A version of this article first appeared on Medscape.com.

In July 2024, a 33-year-old woman with type 1 diabetes was boating on a hot day when her insulin delivery device slipped off. By the time she was able to exit the river, she was clearly ill, and an ambulance was called. The hospital was at capacity. Lying in the hallway, she was treated with fluids but not insulin, despite her boyfriend repeatedly telling the staff she had diabetes. She was released while still vomiting. The next morning, her boyfriend found her dead.

This story was shared by a friend of the woman in a Facebook group for people with type 1 diabetes and later confirmed by the boyfriend in a separate heartbreaking post. While it may be an extreme case, encounters with a lack of knowledge about type 1 diabetes in healthcare settings are quite common, sometimes resulting in serious adverse consequences.

In my 50+ years of living with the condition, I’ve lost track of the number of times I’ve had to speak up for myself, correct errors, raise issues that haven’t been considered, and educate nonspecialist healthcare professionals about even some of the basics.

Type 1 diabetes is an autoimmune condition in which the insulin-producing cells in the pancreas are destroyed, necessitating lifelong insulin treatment. Type 2, in contrast, arises from a combination of insulin resistance and decreased insulin production. Type 1 accounts for just 5% of all people with diabetes, but at a prevalence of about 1 in 200, it’s not rare. And that’s not even counting the adults who have been misdiagnosed as having type 2 but who actually have type 1.

As a general rule, people with type 1 diabetes are more insulin sensitive than those with type 2 and more prone to both hyper- and hypoglycemia. Blood sugar levels tend to be more labile and less predictable, even under normal circumstances. Recent advances in hybrid closed-loop technology have been extremely helpful in reducing the swings, but the systems aren’t foolproof yet. They still require user input (ie, guesswork), so there’s still room for error.

Managing type 1 diabetes is challenging even for endocrinologists. But here are some very important basics that every healthcare provider should know.
 

We Need Insulin 24/7

Never, ever withhold insulin from a person with type 1 diabetes, for any reason. Even when not eating — or when vomiting — we still need basal (background) insulin, either via long-acting analog or a pump infusion. The dose may need to be lowered to avoid hypoglycemia, but if insulin is stopped, diabetic ketoacidosis will result. And if that continues, death will follow.

This should be basic knowledge, but I’ve read and heard far too many stories of insulin being withheld from people with type 1 in various settings, including emergency departments, psychiatric facilities, and jails. On Facebook, people with type 1 diabetes often report being told not to take their insulin the morning before a procedure, while more than one has described “sneaking” their own insulin while hospitalized because they weren’t receiving any or not receiving enough.

On the flip side, although insulin needs are very individual, the amount needed for someone with type 1 is typically considerably less than for a person with type 2. Too much can result in severe hypoglycemia. There are lots of stories from people with type 1 diabetes who had to battle with hospital staff who tried to give them much higher doses than they knew they needed.

The American Diabetes Association recommends that people with type 1 diabetes who are hospitalized be allowed to wear their devices and self-manage to the degree possible. And please, listen to us when we tell you what we know about our own condition.
 

Fasting Is Fraught

I cringe every time I’m told to fast for a test or procedure. Fasting poses a risk for hypoglycemia in people with type 1 diabetes, even when using state-of-the-art technology. Fasting should not be required unless absolutely necessary, especially for routine lab tests.

Saleh Aldasouqi, MD, chief of endocrinology at Michigan State University, East Lansing, Michigan, has published several papers on a phenomenon he calls “Fasting-Evoked En Route Hypoglycemia in Diabetes,” in which patients who fast overnight and skip breakfast experience hypoglycemia on the way to the lab.

“Patients continue taking their diabetes medication but don’t eat anything, resulting in low blood sugar levels that cause them to have a hypoglycemic event while driving to or from the lab, putting themselves and others at risk,” Dr. Aldasouqi explained, adding that fasting often isn’t necessary for routine lipid panels.

If fasting is necessary, as for a surgical procedure that involves anesthesia, the need for insulin adjustment — NOT withholding — should be discussed with the patient to determine whether they can do it themselves or whether their diabetes provider should be consulted.

But again, this is tricky even for endocrinologists. True story: When I had my second carpal tunnel surgery in July 2019, my hand surgeon wisely scheduled me for his first procedure in the morning to minimize the length of time I’d have to fast. (He has type 1 diabetes himself, which helped.) My endocrinologist had advised me, per guidelines, to cut back my basal insulin infusion on my pump by 20% before going to bed.

But at bedtime, my continuous glucose monitor (CGM) showed that I was in the 170 mg/dL’s and rising, not entirely surprising since I’d cut back on my predinner insulin dose knowing I wouldn’t be able to eat if I dropped low later. I didn’t cut back the basal.

When I woke up, my glucose level was over 300 mg/dL. This time, stress was the likely cause. (That’s happened before.) Despite giving myself several small insulin boluses that morning without eating, my blood sugar was still about 345 mg/dL when I arrived at the hospital. The nurse told me that if it had been over 375 mg/dL, they would have had to cancel the surgery, but it wasn’t, so they went ahead. I have no idea how they came up with that cutoff.

Anyway, thankfully, everything went fine; I brought my blood sugar back in target range afterward and healed normally. Point being, type 1 diabetes management is a crazy balancing act, and guidelines only go so far.
 

We Don’t React Well to Steroids

If it’s absolutely necessary to give steroids to a person with type 1 diabetes for any reason, plans must be made in advance for the inevitable glucose spike. If the person doesn’t know how to adjust their insulin for it, please have them consult their diabetes provider. In my experience with locally injected corticosteroids, the spike is always higher and longer than I expected. Thankfully, I haven’t had to deal with systemic steroids, but my guess is they’re probably worse.

Procedures Can Be Pesky

People who wear insulin pumps and/or CGMs must remove them for MRI and certain other imaging procedures. In some cases — as with CGMs and the Omnipod insulin delivery device that can’t be put back on after removal — this necessitates advance planning to bring along replacement equipment for immediately after the procedure.

Diabetes devices can stay in place for other imaging studies, such as x-rays, most CT scans, ECGs, and ultrasounds. For heaven’s sake, don’t ask us to remove our devices if it isn’t totally necessary.

In general, surprises that affect blood sugar are a bad idea. I recently underwent a gastric emptying study. I knew the test would involve eating radioactive eggs, but I didn’t find out there’s also a jelly sandwich with two slices of white bread until the technician handed it to me and told me to eat it. I had to quickly give myself insulin, and of course my blood sugar spiked later. Had I been forewarned, I could have at least “pre-bolused” 15-20 minutes in advance to give the insulin more time to start working.

Another anecdote: Prior to a dental appointment that involved numbing my gums for an in-depth cleaning, my longtime dental hygienist told me “be sure to eat before you come.” I do appreciate her thinking of my diabetes. However, while that advice would have made sense long ago when treatment involved two daily insulin injections without dose adjustments, now it’s more complicated.

Today, when we eat foods containing carbohydrates, we typically take short-acting insulin, which can lead to hypoglycemia if the dose given exceeds the amount needed for the carbs, regardless of how much is eaten. Better to not eat at all (assuming the basal insulin dose is correct) or just eat protein. And for the provider, best to just tell the patient about the eating limitations and make sure they know how to handle them.
 

Duh, We Already Have Diabetes

I’ve heard of at least four instances in which pregnant women with type 1 diabetes have been ordered to undergo an oral glucose tolerance test to screen for gestational diabetes. In two cases, it was a “can you believe it?!” post on Facebook, with the women rightly refusing to take the test.

But in May 2024, a pregnant woman reported she actually drank the liquid, her blood sugar skyrocketed, she was vomiting, and she was in the midst of trying to bring her glucose level down with insulin on her own at home. She hadn’t objected to taking the test because “my ob.gyn. knows I have diabetes,” so she figured it was appropriate.

I don’t work in a healthcare setting, but here’s my guess: The ob.gyn. hadn’t actually ordered the test but had neglected to UN-order a routine test for a pregnant patient who already had diabetes and obviously should NOT be forced to drink a high-sugar liquid for no reason. If this is happening in pregnancies with type 1 diabetes, it most certainly could be as well for those with pre-existing type 2 diabetes. Clearly, something should be done to prevent this unnecessary and potentially harmful scenario.

In summary, I think I speak for everyone living with type 1 diabetes in saying that we would like to have confidence that healthcare providers in all settings can provide care for whatever brought us to them without adding to the daily burden we already carry. Let’s work together.

Reviewed by Saleh Aldasouqi, MD, chief of endocrinology at Michigan State University. A version of this article first appeared on Medscape.com.

In July 2024, a 33-year-old woman with type 1 diabetes was boating on a hot day when her insulin delivery device slipped off. By the time she was able to exit the river, she was clearly ill, and an ambulance was called. The hospital was at capacity. Lying in the hallway, she was treated with fluids but not insulin, despite her boyfriend repeatedly telling the staff she had diabetes. She was released while still vomiting. The next morning, her boyfriend found her dead.

This story was shared by a friend of the woman in a Facebook group for people with type 1 diabetes and later confirmed by the boyfriend in a separate heartbreaking post. While it may be an extreme case, encounters with a lack of knowledge about type 1 diabetes in healthcare settings are quite common, sometimes resulting in serious adverse consequences.

In my 50+ years of living with the condition, I’ve lost track of the number of times I’ve had to speak up for myself, correct errors, raise issues that haven’t been considered, and educate nonspecialist healthcare professionals about even some of the basics.

Type 1 diabetes is an autoimmune condition in which the insulin-producing cells in the pancreas are destroyed, necessitating lifelong insulin treatment. Type 2, in contrast, arises from a combination of insulin resistance and decreased insulin production. Type 1 accounts for just 5% of all people with diabetes, but at a prevalence of about 1 in 200, it’s not rare. And that’s not even counting the adults who have been misdiagnosed as having type 2 but who actually have type 1.

As a general rule, people with type 1 diabetes are more insulin sensitive than those with type 2 and more prone to both hyper- and hypoglycemia. Blood sugar levels tend to be more labile and less predictable, even under normal circumstances. Recent advances in hybrid closed-loop technology have been extremely helpful in reducing the swings, but the systems aren’t foolproof yet. They still require user input (ie, guesswork), so there’s still room for error.

Managing type 1 diabetes is challenging even for endocrinologists. But here are some very important basics that every healthcare provider should know.
 

We Need Insulin 24/7

Never, ever withhold insulin from a person with type 1 diabetes, for any reason. Even when not eating — or when vomiting — we still need basal (background) insulin, either via long-acting analog or a pump infusion. The dose may need to be lowered to avoid hypoglycemia, but if insulin is stopped, diabetic ketoacidosis will result. And if that continues, death will follow.

This should be basic knowledge, but I’ve read and heard far too many stories of insulin being withheld from people with type 1 in various settings, including emergency departments, psychiatric facilities, and jails. On Facebook, people with type 1 diabetes often report being told not to take their insulin the morning before a procedure, while more than one has described “sneaking” their own insulin while hospitalized because they weren’t receiving any or not receiving enough.

On the flip side, although insulin needs are very individual, the amount needed for someone with type 1 is typically considerably less than for a person with type 2. Too much can result in severe hypoglycemia. There are lots of stories from people with type 1 diabetes who had to battle with hospital staff who tried to give them much higher doses than they knew they needed.

The American Diabetes Association recommends that people with type 1 diabetes who are hospitalized be allowed to wear their devices and self-manage to the degree possible. And please, listen to us when we tell you what we know about our own condition.
 

Fasting Is Fraught

I cringe every time I’m told to fast for a test or procedure. Fasting poses a risk for hypoglycemia in people with type 1 diabetes, even when using state-of-the-art technology. Fasting should not be required unless absolutely necessary, especially for routine lab tests.

Saleh Aldasouqi, MD, chief of endocrinology at Michigan State University, East Lansing, Michigan, has published several papers on a phenomenon he calls “Fasting-Evoked En Route Hypoglycemia in Diabetes,” in which patients who fast overnight and skip breakfast experience hypoglycemia on the way to the lab.

“Patients continue taking their diabetes medication but don’t eat anything, resulting in low blood sugar levels that cause them to have a hypoglycemic event while driving to or from the lab, putting themselves and others at risk,” Dr. Aldasouqi explained, adding that fasting often isn’t necessary for routine lipid panels.

If fasting is necessary, as for a surgical procedure that involves anesthesia, the need for insulin adjustment — NOT withholding — should be discussed with the patient to determine whether they can do it themselves or whether their diabetes provider should be consulted.

But again, this is tricky even for endocrinologists. True story: When I had my second carpal tunnel surgery in July 2019, my hand surgeon wisely scheduled me for his first procedure in the morning to minimize the length of time I’d have to fast. (He has type 1 diabetes himself, which helped.) My endocrinologist had advised me, per guidelines, to cut back my basal insulin infusion on my pump by 20% before going to bed.

But at bedtime, my continuous glucose monitor (CGM) showed that I was in the 170 mg/dL’s and rising, not entirely surprising since I’d cut back on my predinner insulin dose knowing I wouldn’t be able to eat if I dropped low later. I didn’t cut back the basal.

When I woke up, my glucose level was over 300 mg/dL. This time, stress was the likely cause. (That’s happened before.) Despite giving myself several small insulin boluses that morning without eating, my blood sugar was still about 345 mg/dL when I arrived at the hospital. The nurse told me that if it had been over 375 mg/dL, they would have had to cancel the surgery, but it wasn’t, so they went ahead. I have no idea how they came up with that cutoff.

Anyway, thankfully, everything went fine; I brought my blood sugar back in target range afterward and healed normally. Point being, type 1 diabetes management is a crazy balancing act, and guidelines only go so far.
 

We Don’t React Well to Steroids

If it’s absolutely necessary to give steroids to a person with type 1 diabetes for any reason, plans must be made in advance for the inevitable glucose spike. If the person doesn’t know how to adjust their insulin for it, please have them consult their diabetes provider. In my experience with locally injected corticosteroids, the spike is always higher and longer than I expected. Thankfully, I haven’t had to deal with systemic steroids, but my guess is they’re probably worse.

Procedures Can Be Pesky

People who wear insulin pumps and/or CGMs must remove them for MRI and certain other imaging procedures. In some cases — as with CGMs and the Omnipod insulin delivery device that can’t be put back on after removal — this necessitates advance planning to bring along replacement equipment for immediately after the procedure.

Diabetes devices can stay in place for other imaging studies, such as x-rays, most CT scans, ECGs, and ultrasounds. For heaven’s sake, don’t ask us to remove our devices if it isn’t totally necessary.

In general, surprises that affect blood sugar are a bad idea. I recently underwent a gastric emptying study. I knew the test would involve eating radioactive eggs, but I didn’t find out there’s also a jelly sandwich with two slices of white bread until the technician handed it to me and told me to eat it. I had to quickly give myself insulin, and of course my blood sugar spiked later. Had I been forewarned, I could have at least “pre-bolused” 15-20 minutes in advance to give the insulin more time to start working.

Another anecdote: Prior to a dental appointment that involved numbing my gums for an in-depth cleaning, my longtime dental hygienist told me “be sure to eat before you come.” I do appreciate her thinking of my diabetes. However, while that advice would have made sense long ago when treatment involved two daily insulin injections without dose adjustments, now it’s more complicated.

Today, when we eat foods containing carbohydrates, we typically take short-acting insulin, which can lead to hypoglycemia if the dose given exceeds the amount needed for the carbs, regardless of how much is eaten. Better to not eat at all (assuming the basal insulin dose is correct) or just eat protein. And for the provider, best to just tell the patient about the eating limitations and make sure they know how to handle them.
 

Duh, We Already Have Diabetes

I’ve heard of at least four instances in which pregnant women with type 1 diabetes have been ordered to undergo an oral glucose tolerance test to screen for gestational diabetes. In two cases, it was a “can you believe it?!” post on Facebook, with the women rightly refusing to take the test.

But in May 2024, a pregnant woman reported she actually drank the liquid, her blood sugar skyrocketed, she was vomiting, and she was in the midst of trying to bring her glucose level down with insulin on her own at home. She hadn’t objected to taking the test because “my ob.gyn. knows I have diabetes,” so she figured it was appropriate.

I don’t work in a healthcare setting, but here’s my guess: The ob.gyn. hadn’t actually ordered the test but had neglected to UN-order a routine test for a pregnant patient who already had diabetes and obviously should NOT be forced to drink a high-sugar liquid for no reason. If this is happening in pregnancies with type 1 diabetes, it most certainly could be as well for those with pre-existing type 2 diabetes. Clearly, something should be done to prevent this unnecessary and potentially harmful scenario.

In summary, I think I speak for everyone living with type 1 diabetes in saying that we would like to have confidence that healthcare providers in all settings can provide care for whatever brought us to them without adding to the daily burden we already carry. Let’s work together.

Reviewed by Saleh Aldasouqi, MD, chief of endocrinology at Michigan State University. A version of this article first appeared on Medscape.com.

A patient who developed atrial fibrillation resulting from the failure to adjust the levothyroxine dose after rapid, significant weight loss while on the antiobesity drug tirzepatide (Zepbound) serves as a key reminder in managing patients experiencing rapid weight loss, either from antiobesity medications or any other means: Patients taking medications with weight-based dosing need to have their doses closely monitored.

“Failing to monitor and adjust dosing of these [and other] medications during a period of rapid weight loss may lead to supratherapeutic — even toxic — levels, as was seen in this [case],” underscore the authors of an editorial regarding the Teachable Moment case, published in JAMA Internal Medicine.

Toxicities from excessive doses can have a range of detrimental effects. In terms of thyroid medicine, the failure to adjust levothyroxine treatment for hypothyroidism in cases of rapid weight loss can lead to thyrotoxicosis, and in older patients in particular, a resulting thyrotropin level < 0.1 mIU/L is associated with as much as a threefold increased risk for atrial fibrillation, as observed in the report. 
 

Case Demonstrates Risks

The case involved a 62-year-old man with obesity, hypothyroidism, and type 1 diabetes who presented to the emergency department with palpitations, excessive sweating, confusion, fever, and hand tremors. Upon being diagnosed with atrial fibrillation, the patient was immediately treated. 

His medical history revealed the underlying culprit: Six months earlier, the patient had started treatment with the gastric inhibitory polypeptide (GIP)/glucagon-like peptide (GLP) 1 dual agonist tirzepatide. As is typical with the drug, the patient’s weight quickly plummeted, dropping from a starting body mass index of 44.4 down to 31.2 after 6 months and a decrease in body weight from 132 kg to 93 kg (a loss of 39 kg [approximately 86 lb]).

Despite the substantial change in body weight, his initial dose of 200 µg of levothyroxine, received for hypothyroidism, was not adjusted.

When he was prescribed tirzepatide, 2.5 mg weekly, for obesity, the patient had been recommended to increase the dose every 4 weeks as tolerated and, importantly, to have a follow-up visit in a month. But because he lived in different states seasonally, the follow-up never occurred.

Upon his emergency department visit, the patient’s thyrotropin level had dropped from 1.9 mIU/L at the first visit 6 months earlier to 0.001 mIU/L (well within the atrial fibrillation risk range), and his free thyroxine level (fT4) was 7.26 ng/ dL — substantially outside of the normal range of about 0.9-1.7 ng/dL for adults. 

“The patient had 4-times higher fT4 levels of the upper limit,” first author Kagan E. Karakus, MD, of the Barbara Davis Center for Diabetes, University of Colorado Anschutz Medical Campus, Aurora, told this news organization. “That is why he had experienced the adverse event of atrial fibrillation.”
 

Thyrotoxicosis Symptoms Can Be ‘Insidious,’ Levothyroxine Should Be Monitored

Although tirzepatide has not been approved by the US Food and Drug Administration for the treatment of type 1 diabetes, obesity is on the rise among patients with this disorder and recent research has shown a more than 10% reduction in body weight in 6 months and significant reductions in A1c with various doses. 

Of note, in the current case, although the patient’s levothyroxine dose was not adjusted, his insulin dose was gradually self-decreased during his tirzepatide treatment to prevent hypoglycemia.

“If insulin treatment is excessive in diabetes, it causes hypoglycemia, [and] people with type 1 diabetes will recognize the signs of hypoglycemia related to excessive insulin earlier,” Dr. Karakus said.

If symptoms appear, patients can reduce their insulin doses on their own; however, the symptoms of thyrotoxicosis caused by excessive levothyroxine can be more insidious compared with hypoglycemia, he explained. 

“Although patients can change their insulin doses, they cannot change the levothyroxine doses since it requires a blood test [thyroid-stimulating hormone; TSH] and a new prescription of the new dose.”

The key lesson is that “following levothyroxine treatment initiation or dose adjustment, 4-6 weeks is the optimal duration to recheck [the] thyrotropin level and adjust the dose as needed,” Dr. Karakus said.
 

Key Medications to Monitor

Other common outpatient medications that should be closely monitored in patients experiencing rapid weight loss, by any method, range from anticoagulants, anticonvulsants, and antituberculosis drugs to antibiotics and antifungals, the authors note.

Of note, medications with a narrow therapeutic index include phenytoin, warfarin, lithium carbonate, digoxin theophylline, tacrolimus, valproic acid, carbamazepine, and cyclosporine.

The failure to make necessary dose adjustments “is seen more often since the newer antiobesity drugs reduce a great amount of weight within months, almost as rapidly as bariatric surgery,” Dr. Karakus said.

“It is very important for physicians to be aware of the weight-based medications and narrow therapeutic index medications since their doses should be adjusted carefully, especially during weight loss,” he added.

Furthermore, “the patient should also know that weight reduction medication may cause adverse effects like nausea, vomiting and also may affect metabolism of other medications such that some medication doses should be adjusted regularly.”

In the editorial published with the study, Tyrone A. Johnson, MD, of the Department of Medicine, University of California, San Francisco, and colleagues note that the need for close monitoring is particularly important with older patients, who, in addition to having a higher likelihood of comorbidities, commonly have polypharmacy that could increase the potential for adverse effects.

Another key area concern is the emergence of direct-to-consumer avenues for GLP-1/GIP agonists for the many who either cannot afford or do not have access to the drugs, providing further opportunities for treatment without appropriate clinical oversight, they add.

Overall, the case “highlights the potential dangers underlying under-supervised prescribing of GLP-1/GIP receptor agonists and affirms the need for strong partnerships between patients and their clinicians during their use,” they wrote. 

“These medications are best used in collaboration with continuity care teams, in context of a patient’s entire health, and in comprehensive risk-benefit assessment throughout the entire duration of treatment.”
 

A Caveat: Subclinical Levothyroxine Dosing

Commenting on the study, Matthew Ettleson, MD, a clinical instructor of medicine in the Section of Endocrinology, Diabetes, & Metabolism, University of Chicago, noted the important caveat that patients with hypothyroidism are commonly on subclinical doses, with varying dose adjustment needs.

“The patient in the case was clearly on a replacement level dose. However, many patients are on low doses of levothyroxine (75 µg or lower) for subclinical hypothyroidism, and, in general, I think the risks are lower with patients with subclinical hypothyroidism on lower doses of levothyroxine,” he told this news organization.

Because of that, “frequent TSH monitoring may be excessive in this population,” he said. “I would hesitate to empirically lower the dose with weight loss, unless it was clear that the patient was unlikely to follow up.

“Checking TSH at a more frequent interval and adjusting the dose accordingly should be adequate to prevent situations like this case.”

Dr. Karakus, Dr. Ettleson, and the editorial authors had no relevant disclosures to report.
 

A version of this article appeared on Medscape.com.

A patient who developed atrial fibrillation resulting from the failure to adjust the levothyroxine dose after rapid, significant weight loss while on the antiobesity drug tirzepatide (Zepbound) serves as a key reminder in managing patients experiencing rapid weight loss, either from antiobesity medications or any other means: Patients taking medications with weight-based dosing need to have their doses closely monitored.

“Failing to monitor and adjust dosing of these [and other] medications during a period of rapid weight loss may lead to supratherapeutic — even toxic — levels, as was seen in this [case],” underscore the authors of an editorial regarding the Teachable Moment case, published in JAMA Internal Medicine.

Toxicities from excessive doses can have a range of detrimental effects. In terms of thyroid medicine, the failure to adjust levothyroxine treatment for hypothyroidism in cases of rapid weight loss can lead to thyrotoxicosis, and in older patients in particular, a resulting thyrotropin level < 0.1 mIU/L is associated with as much as a threefold increased risk for atrial fibrillation, as observed in the report. 
 

Case Demonstrates Risks

The case involved a 62-year-old man with obesity, hypothyroidism, and type 1 diabetes who presented to the emergency department with palpitations, excessive sweating, confusion, fever, and hand tremors. Upon being diagnosed with atrial fibrillation, the patient was immediately treated. 

His medical history revealed the underlying culprit: Six months earlier, the patient had started treatment with the gastric inhibitory polypeptide (GIP)/glucagon-like peptide (GLP) 1 dual agonist tirzepatide. As is typical with the drug, the patient’s weight quickly plummeted, dropping from a starting body mass index of 44.4 down to 31.2 after 6 months and a decrease in body weight from 132 kg to 93 kg (a loss of 39 kg [approximately 86 lb]).

Despite the substantial change in body weight, his initial dose of 200 µg of levothyroxine, received for hypothyroidism, was not adjusted.

When he was prescribed tirzepatide, 2.5 mg weekly, for obesity, the patient had been recommended to increase the dose every 4 weeks as tolerated and, importantly, to have a follow-up visit in a month. But because he lived in different states seasonally, the follow-up never occurred.

Upon his emergency department visit, the patient’s thyrotropin level had dropped from 1.9 mIU/L at the first visit 6 months earlier to 0.001 mIU/L (well within the atrial fibrillation risk range), and his free thyroxine level (fT4) was 7.26 ng/ dL — substantially outside of the normal range of about 0.9-1.7 ng/dL for adults. 

“The patient had 4-times higher fT4 levels of the upper limit,” first author Kagan E. Karakus, MD, of the Barbara Davis Center for Diabetes, University of Colorado Anschutz Medical Campus, Aurora, told this news organization. “That is why he had experienced the adverse event of atrial fibrillation.”
 

Thyrotoxicosis Symptoms Can Be ‘Insidious,’ Levothyroxine Should Be Monitored

Although tirzepatide has not been approved by the US Food and Drug Administration for the treatment of type 1 diabetes, obesity is on the rise among patients with this disorder and recent research has shown a more than 10% reduction in body weight in 6 months and significant reductions in A1c with various doses. 

Of note, in the current case, although the patient’s levothyroxine dose was not adjusted, his insulin dose was gradually self-decreased during his tirzepatide treatment to prevent hypoglycemia.

“If insulin treatment is excessive in diabetes, it causes hypoglycemia, [and] people with type 1 diabetes will recognize the signs of hypoglycemia related to excessive insulin earlier,” Dr. Karakus said.

If symptoms appear, patients can reduce their insulin doses on their own; however, the symptoms of thyrotoxicosis caused by excessive levothyroxine can be more insidious compared with hypoglycemia, he explained. 

“Although patients can change their insulin doses, they cannot change the levothyroxine doses since it requires a blood test [thyroid-stimulating hormone; TSH] and a new prescription of the new dose.”

The key lesson is that “following levothyroxine treatment initiation or dose adjustment, 4-6 weeks is the optimal duration to recheck [the] thyrotropin level and adjust the dose as needed,” Dr. Karakus said.
 

Key Medications to Monitor

Other common outpatient medications that should be closely monitored in patients experiencing rapid weight loss, by any method, range from anticoagulants, anticonvulsants, and antituberculosis drugs to antibiotics and antifungals, the authors note.

Of note, medications with a narrow therapeutic index include phenytoin, warfarin, lithium carbonate, digoxin theophylline, tacrolimus, valproic acid, carbamazepine, and cyclosporine.

The failure to make necessary dose adjustments “is seen more often since the newer antiobesity drugs reduce a great amount of weight within months, almost as rapidly as bariatric surgery,” Dr. Karakus said.

“It is very important for physicians to be aware of the weight-based medications and narrow therapeutic index medications since their doses should be adjusted carefully, especially during weight loss,” he added.

Furthermore, “the patient should also know that weight reduction medication may cause adverse effects like nausea, vomiting and also may affect metabolism of other medications such that some medication doses should be adjusted regularly.”

In the editorial published with the study, Tyrone A. Johnson, MD, of the Department of Medicine, University of California, San Francisco, and colleagues note that the need for close monitoring is particularly important with older patients, who, in addition to having a higher likelihood of comorbidities, commonly have polypharmacy that could increase the potential for adverse effects.

Another key area concern is the emergence of direct-to-consumer avenues for GLP-1/GIP agonists for the many who either cannot afford or do not have access to the drugs, providing further opportunities for treatment without appropriate clinical oversight, they add.

Overall, the case “highlights the potential dangers underlying under-supervised prescribing of GLP-1/GIP receptor agonists and affirms the need for strong partnerships between patients and their clinicians during their use,” they wrote. 

“These medications are best used in collaboration with continuity care teams, in context of a patient’s entire health, and in comprehensive risk-benefit assessment throughout the entire duration of treatment.”
 

A Caveat: Subclinical Levothyroxine Dosing

Commenting on the study, Matthew Ettleson, MD, a clinical instructor of medicine in the Section of Endocrinology, Diabetes, & Metabolism, University of Chicago, noted the important caveat that patients with hypothyroidism are commonly on subclinical doses, with varying dose adjustment needs.

“The patient in the case was clearly on a replacement level dose. However, many patients are on low doses of levothyroxine (75 µg or lower) for subclinical hypothyroidism, and, in general, I think the risks are lower with patients with subclinical hypothyroidism on lower doses of levothyroxine,” he told this news organization.

Because of that, “frequent TSH monitoring may be excessive in this population,” he said. “I would hesitate to empirically lower the dose with weight loss, unless it was clear that the patient was unlikely to follow up.

“Checking TSH at a more frequent interval and adjusting the dose accordingly should be adequate to prevent situations like this case.”

Dr. Karakus, Dr. Ettleson, and the editorial authors had no relevant disclosures to report.
 

A version of this article appeared on Medscape.com.

A patient who developed atrial fibrillation resulting from the failure to adjust the levothyroxine dose after rapid, significant weight loss while on the antiobesity drug tirzepatide (Zepbound) serves as a key reminder in managing patients experiencing rapid weight loss, either from antiobesity medications or any other means: Patients taking medications with weight-based dosing need to have their doses closely monitored.

“Failing to monitor and adjust dosing of these [and other] medications during a period of rapid weight loss may lead to supratherapeutic — even toxic — levels, as was seen in this [case],” underscore the authors of an editorial regarding the Teachable Moment case, published in JAMA Internal Medicine.

Toxicities from excessive doses can have a range of detrimental effects. In terms of thyroid medicine, the failure to adjust levothyroxine treatment for hypothyroidism in cases of rapid weight loss can lead to thyrotoxicosis, and in older patients in particular, a resulting thyrotropin level < 0.1 mIU/L is associated with as much as a threefold increased risk for atrial fibrillation, as observed in the report. 
 

Case Demonstrates Risks

The case involved a 62-year-old man with obesity, hypothyroidism, and type 1 diabetes who presented to the emergency department with palpitations, excessive sweating, confusion, fever, and hand tremors. Upon being diagnosed with atrial fibrillation, the patient was immediately treated. 

His medical history revealed the underlying culprit: Six months earlier, the patient had started treatment with the gastric inhibitory polypeptide (GIP)/glucagon-like peptide (GLP) 1 dual agonist tirzepatide. As is typical with the drug, the patient’s weight quickly plummeted, dropping from a starting body mass index of 44.4 down to 31.2 after 6 months and a decrease in body weight from 132 kg to 93 kg (a loss of 39 kg [approximately 86 lb]).

Despite the substantial change in body weight, his initial dose of 200 µg of levothyroxine, received for hypothyroidism, was not adjusted.

When he was prescribed tirzepatide, 2.5 mg weekly, for obesity, the patient had been recommended to increase the dose every 4 weeks as tolerated and, importantly, to have a follow-up visit in a month. But because he lived in different states seasonally, the follow-up never occurred.

Upon his emergency department visit, the patient’s thyrotropin level had dropped from 1.9 mIU/L at the first visit 6 months earlier to 0.001 mIU/L (well within the atrial fibrillation risk range), and his free thyroxine level (fT4) was 7.26 ng/ dL — substantially outside of the normal range of about 0.9-1.7 ng/dL for adults. 

“The patient had 4-times higher fT4 levels of the upper limit,” first author Kagan E. Karakus, MD, of the Barbara Davis Center for Diabetes, University of Colorado Anschutz Medical Campus, Aurora, told this news organization. “That is why he had experienced the adverse event of atrial fibrillation.”
 

Thyrotoxicosis Symptoms Can Be ‘Insidious,’ Levothyroxine Should Be Monitored

Although tirzepatide has not been approved by the US Food and Drug Administration for the treatment of type 1 diabetes, obesity is on the rise among patients with this disorder and recent research has shown a more than 10% reduction in body weight in 6 months and significant reductions in A1c with various doses. 

Of note, in the current case, although the patient’s levothyroxine dose was not adjusted, his insulin dose was gradually self-decreased during his tirzepatide treatment to prevent hypoglycemia.

“If insulin treatment is excessive in diabetes, it causes hypoglycemia, [and] people with type 1 diabetes will recognize the signs of hypoglycemia related to excessive insulin earlier,” Dr. Karakus said.

If symptoms appear, patients can reduce their insulin doses on their own; however, the symptoms of thyrotoxicosis caused by excessive levothyroxine can be more insidious compared with hypoglycemia, he explained. 

“Although patients can change their insulin doses, they cannot change the levothyroxine doses since it requires a blood test [thyroid-stimulating hormone; TSH] and a new prescription of the new dose.”

The key lesson is that “following levothyroxine treatment initiation or dose adjustment, 4-6 weeks is the optimal duration to recheck [the] thyrotropin level and adjust the dose as needed,” Dr. Karakus said.
 

Key Medications to Monitor

Other common outpatient medications that should be closely monitored in patients experiencing rapid weight loss, by any method, range from anticoagulants, anticonvulsants, and antituberculosis drugs to antibiotics and antifungals, the authors note.

Of note, medications with a narrow therapeutic index include phenytoin, warfarin, lithium carbonate, digoxin theophylline, tacrolimus, valproic acid, carbamazepine, and cyclosporine.

The failure to make necessary dose adjustments “is seen more often since the newer antiobesity drugs reduce a great amount of weight within months, almost as rapidly as bariatric surgery,” Dr. Karakus said.

“It is very important for physicians to be aware of the weight-based medications and narrow therapeutic index medications since their doses should be adjusted carefully, especially during weight loss,” he added.

Furthermore, “the patient should also know that weight reduction medication may cause adverse effects like nausea, vomiting and also may affect metabolism of other medications such that some medication doses should be adjusted regularly.”

In the editorial published with the study, Tyrone A. Johnson, MD, of the Department of Medicine, University of California, San Francisco, and colleagues note that the need for close monitoring is particularly important with older patients, who, in addition to having a higher likelihood of comorbidities, commonly have polypharmacy that could increase the potential for adverse effects.

Another key area concern is the emergence of direct-to-consumer avenues for GLP-1/GIP agonists for the many who either cannot afford or do not have access to the drugs, providing further opportunities for treatment without appropriate clinical oversight, they add.

Overall, the case “highlights the potential dangers underlying under-supervised prescribing of GLP-1/GIP receptor agonists and affirms the need for strong partnerships between patients and their clinicians during their use,” they wrote. 

“These medications are best used in collaboration with continuity care teams, in context of a patient’s entire health, and in comprehensive risk-benefit assessment throughout the entire duration of treatment.”
 

A Caveat: Subclinical Levothyroxine Dosing

Commenting on the study, Matthew Ettleson, MD, a clinical instructor of medicine in the Section of Endocrinology, Diabetes, & Metabolism, University of Chicago, noted the important caveat that patients with hypothyroidism are commonly on subclinical doses, with varying dose adjustment needs.

“The patient in the case was clearly on a replacement level dose. However, many patients are on low doses of levothyroxine (75 µg or lower) for subclinical hypothyroidism, and, in general, I think the risks are lower with patients with subclinical hypothyroidism on lower doses of levothyroxine,” he told this news organization.

Because of that, “frequent TSH monitoring may be excessive in this population,” he said. “I would hesitate to empirically lower the dose with weight loss, unless it was clear that the patient was unlikely to follow up.

“Checking TSH at a more frequent interval and adjusting the dose accordingly should be adequate to prevent situations like this case.”

Dr. Karakus, Dr. Ettleson, and the editorial authors had no relevant disclosures to report.
 

A version of this article appeared on Medscape.com.

Dry fasting, the practice of going without food and water, has enthusiastic advocates on TikTok, X, YouTube, and other social media platforms. Devotees claim a wide range of health effects, but medical professionals advise caution to ensure that the practice does more good than harm, especially for individuals with diabetes. 

Purported benefits and risks vary, depending on who is following the regimen and how long they abstain from food and water. Advocates on social media assert that dry fasting makes “intuition skyrocket” and puts autophagy on “overdrive.” Although such statements may rev up followers, there is little evidence to support these and many other dry-fasting claims. In fact, several physicians warned about unintended consequences.

“I had one patient who followed this fasting method often, and over time she developed kidney stones that led to a severe infection,” said Deena Adimoolam, MD, an endocrinologist in private practice in New York City and New Jersey. “Lack of both water and food can fuel hunger and increase the likelihood of overeating or binge eating once the fast is completed, which does not lead to weight loss. Untreated dehydration can lead to loss of consciousness.”

“For individuals with type 2 diabetes, dehydration can exacerbate hyperglycemia and increase the risk of complications such as diabetic ketoacidosis (DKA),” said Abeer Bader, lead clinical nutrition specialist at the Massachusetts General Hospital Weight Center in Boston. “Research also consistently shows that adequate hydration is crucial for maintaining physical and cognitive performance.”

Dry fasting also can lead to electrolyte imbalances, and the risk is higher for those with diabetes due to potential underlying kidney issues, Ms. Bader noted. “Prolonged dry fasting can result in nutrient deficiencies. For individuals with diabetes, maintaining adequate nutrition is crucial to manage blood sugar levels and overall health. The lack of both food and water can exacerbate deficiencies.”

Joanne Bruno, MD, an endocrinologist at NYU Langone Health, added, “Certain medications used for the management of type 2 diabetes, such as SGLT2 inhibitors, can cause dehydration. It is critical that patients stay well hydrated while on these medications to avoid serious side effects such as euglycemic DKA.”
 

What Exactly Is Dry Fasting?

Defining dry fasting, like any kind of fasting, has remained a challenge, according to authors of the first international consensus on fasting terminology, published on July 25 in Cell Metabolism. The clinical terminology “has remained heterogeneous and often confusing, with similar terms being used to define different fasting regimens ... reflecting the manifold contexts in which fasting is practiced.”

Indeed, dry fasting was among the most discussed terms by the consensus panel and went through several rounds before the panelists came to agreement. A few experts were critical of the practice, whereas those familiar with religious fasting traditions, such as during Ramadan, were clear about the importance of including this term in the consensus process.

“The dissent was resolved by the clarification that this form of fasting has historical and geographical extensions and that the present consensus process did not aim at evaluating therapeutic effectiveness or safety for any term defined,” the authors wrote.

The panel concluded that dry fasting is not the same as total or complete fasting because the latter can include water (such as water-only fasting). Their final definition of dry fasting is ‘’a fasting regimen during which a voluntary abstinence from all foods and beverages, including water, is practiced for a certain period of time.’’

Different types of fasting regimens, such as intermittent fasting, may include dry fasting, in which case it is referred to as “intermittent dry fasting.” This is defined in the consensus as intermittent fasting regimens that involve abstaining from food and fluid intake during the fasting interval, which typically lasts 9-20 hours. 

Most dry fasts, including religious ones, are maintained for a specific interval and are followed by a refeeding period. These fasts are not starvation, defined as no food or water intake for days.
 

What the Evidence Says

All that said, dry fasting by any other name remains dry fasting. “Abundant” evidence from animal studies suggests the potential of various types of fasting for disease prevention and treatment in humans, noted the authors of the consensus report, Along with the risks described above, small studies have explored short-term effects in people, all of which have yet to be established by larger and longer-term studies.

In a recent small study, researchers at Baylor College of Medicine, Houston, Texas, reported that dawn-to-dusk dry fasting for 30 days reduced levels of inflammatory cytokines in the 13 participants with a high body mass index. Earlier work by the group showed that dawn-to-dusk dry fasting for 30 days induced “anti-atherosclerotic, anti-inflammatory, and anti-tumorigenic proteome” in peripheral blood mononuclear cells of 14 individuals with metabolic syndrome (The researchers declined to comment for this article.)

Importantly, the health effects can vary among individuals for unknown reasons, found a recent cross-sectional study of fasting blood glucose (FBG) changes in 181 patients with type 2 diabetes during Ramadan intermittent fasting (RIF), which involves dry fasting during daylight hours for 1 month. The researchers classified participants into three groups: reduced average FBG levels (44%), no change in FBG levels (24%), and increased FBG levels (32%). The authors wrote that further studies are needed to identify factors associated with the differences and to identify “those who are great candidates for RIF.”

In contrast to some of the concerns expressed by clinicians, an exploratory study of daytime dry fasting among 34 healthy Baha’i volunteers in Germany concluded that the 19-day regimen “is safe, has no negative effects on hydration, can improve fat metabolism and can cause transient phase shifts of circadian rhythms.” The authors acknowledge that a larger number and more diverse participants are needed to validate the findings and assess the impact on long-term health.
 

What to Advise Patients

For patients who want to fast as part of their weight loss regimen or to help manage diabetes, clinicians can consider suggesting “alternate ways of eating that might achieve similar goals,” Ms. Bader said. One is intermittent fasting without dry fasting: the 16:8 method (16 hours of fasting, 8 hours of eating) or the 5:2 method (normal eating for 5 days, reduced calorie intake for 2 days), which can support improved insulin sensitivity and metabolic health.

Caloric restriction can also work if the patient maintains a balanced diet that includes all essential nutrients, she said. A low-carbohydrate diet that focuses on limiting carbohydrate intake while increasing consumption of lean proteins and healthy fats has been shown to lower blood sugar levels and improve insulin sensitivity.

Other healthy strategies for patients include the Mediterranean diet, which emphasizes whole grains, fruits, vegetables, nuts, seeds, olive oil, and lean proteins such as fish, or a similar plant-based diet with less animal protein. Ms. Bader advises cultivating mindful eating, which involves paying attention to hunger and fullness cues, making thoughtful food choices, and focusing on being present during meals.

“Each of these dietary strategies offers potential benefits for managing type 2 diabetes and improving overall health,” Ms. Bader said. “I have not had any patients who have tried dry fasting specifically. However, I have encountered scenarios where individuals abstained from food and beverages due to religious practices. In those cases, we focused on ensuring that they maintained proper hydration and balanced nutrition during their eating periods to manage their diabetes effectively and prevent complications.”

Overall, Dr. Adimoolam suggests that clinicians help patients find a weight-loss plan that works best for them based on understanding the calories in the foods they like and don’t like. For fasting regimens, patients can be encouraged to choose one with fluids when possible, as well as intervals of time to fast and eat that work best for their lifestyle.

Ms. Bader, Dr. Bruno, and Dr. Adimoolam report no relevant conflicts.
 

A version of this article appeared on Medscape.com.

Dry fasting, the practice of going without food and water, has enthusiastic advocates on TikTok, X, YouTube, and other social media platforms. Devotees claim a wide range of health effects, but medical professionals advise caution to ensure that the practice does more good than harm, especially for individuals with diabetes. 

Purported benefits and risks vary, depending on who is following the regimen and how long they abstain from food and water. Advocates on social media assert that dry fasting makes “intuition skyrocket” and puts autophagy on “overdrive.” Although such statements may rev up followers, there is little evidence to support these and many other dry-fasting claims. In fact, several physicians warned about unintended consequences.

“I had one patient who followed this fasting method often, and over time she developed kidney stones that led to a severe infection,” said Deena Adimoolam, MD, an endocrinologist in private practice in New York City and New Jersey. “Lack of both water and food can fuel hunger and increase the likelihood of overeating or binge eating once the fast is completed, which does not lead to weight loss. Untreated dehydration can lead to loss of consciousness.”

“For individuals with type 2 diabetes, dehydration can exacerbate hyperglycemia and increase the risk of complications such as diabetic ketoacidosis (DKA),” said Abeer Bader, lead clinical nutrition specialist at the Massachusetts General Hospital Weight Center in Boston. “Research also consistently shows that adequate hydration is crucial for maintaining physical and cognitive performance.”

Dry fasting also can lead to electrolyte imbalances, and the risk is higher for those with diabetes due to potential underlying kidney issues, Ms. Bader noted. “Prolonged dry fasting can result in nutrient deficiencies. For individuals with diabetes, maintaining adequate nutrition is crucial to manage blood sugar levels and overall health. The lack of both food and water can exacerbate deficiencies.”

Joanne Bruno, MD, an endocrinologist at NYU Langone Health, added, “Certain medications used for the management of type 2 diabetes, such as SGLT2 inhibitors, can cause dehydration. It is critical that patients stay well hydrated while on these medications to avoid serious side effects such as euglycemic DKA.”
 

What Exactly Is Dry Fasting?

Defining dry fasting, like any kind of fasting, has remained a challenge, according to authors of the first international consensus on fasting terminology, published on July 25 in Cell Metabolism. The clinical terminology “has remained heterogeneous and often confusing, with similar terms being used to define different fasting regimens ... reflecting the manifold contexts in which fasting is practiced.”

Indeed, dry fasting was among the most discussed terms by the consensus panel and went through several rounds before the panelists came to agreement. A few experts were critical of the practice, whereas those familiar with religious fasting traditions, such as during Ramadan, were clear about the importance of including this term in the consensus process.

“The dissent was resolved by the clarification that this form of fasting has historical and geographical extensions and that the present consensus process did not aim at evaluating therapeutic effectiveness or safety for any term defined,” the authors wrote.

The panel concluded that dry fasting is not the same as total or complete fasting because the latter can include water (such as water-only fasting). Their final definition of dry fasting is ‘’a fasting regimen during which a voluntary abstinence from all foods and beverages, including water, is practiced for a certain period of time.’’

Different types of fasting regimens, such as intermittent fasting, may include dry fasting, in which case it is referred to as “intermittent dry fasting.” This is defined in the consensus as intermittent fasting regimens that involve abstaining from food and fluid intake during the fasting interval, which typically lasts 9-20 hours. 

Most dry fasts, including religious ones, are maintained for a specific interval and are followed by a refeeding period. These fasts are not starvation, defined as no food or water intake for days.
 

What the Evidence Says

All that said, dry fasting by any other name remains dry fasting. “Abundant” evidence from animal studies suggests the potential of various types of fasting for disease prevention and treatment in humans, noted the authors of the consensus report, Along with the risks described above, small studies have explored short-term effects in people, all of which have yet to be established by larger and longer-term studies.

In a recent small study, researchers at Baylor College of Medicine, Houston, Texas, reported that dawn-to-dusk dry fasting for 30 days reduced levels of inflammatory cytokines in the 13 participants with a high body mass index. Earlier work by the group showed that dawn-to-dusk dry fasting for 30 days induced “anti-atherosclerotic, anti-inflammatory, and anti-tumorigenic proteome” in peripheral blood mononuclear cells of 14 individuals with metabolic syndrome (The researchers declined to comment for this article.)

Importantly, the health effects can vary among individuals for unknown reasons, found a recent cross-sectional study of fasting blood glucose (FBG) changes in 181 patients with type 2 diabetes during Ramadan intermittent fasting (RIF), which involves dry fasting during daylight hours for 1 month. The researchers classified participants into three groups: reduced average FBG levels (44%), no change in FBG levels (24%), and increased FBG levels (32%). The authors wrote that further studies are needed to identify factors associated with the differences and to identify “those who are great candidates for RIF.”

In contrast to some of the concerns expressed by clinicians, an exploratory study of daytime dry fasting among 34 healthy Baha’i volunteers in Germany concluded that the 19-day regimen “is safe, has no negative effects on hydration, can improve fat metabolism and can cause transient phase shifts of circadian rhythms.” The authors acknowledge that a larger number and more diverse participants are needed to validate the findings and assess the impact on long-term health.
 

What to Advise Patients

For patients who want to fast as part of their weight loss regimen or to help manage diabetes, clinicians can consider suggesting “alternate ways of eating that might achieve similar goals,” Ms. Bader said. One is intermittent fasting without dry fasting: the 16:8 method (16 hours of fasting, 8 hours of eating) or the 5:2 method (normal eating for 5 days, reduced calorie intake for 2 days), which can support improved insulin sensitivity and metabolic health.

Caloric restriction can also work if the patient maintains a balanced diet that includes all essential nutrients, she said. A low-carbohydrate diet that focuses on limiting carbohydrate intake while increasing consumption of lean proteins and healthy fats has been shown to lower blood sugar levels and improve insulin sensitivity.

Other healthy strategies for patients include the Mediterranean diet, which emphasizes whole grains, fruits, vegetables, nuts, seeds, olive oil, and lean proteins such as fish, or a similar plant-based diet with less animal protein. Ms. Bader advises cultivating mindful eating, which involves paying attention to hunger and fullness cues, making thoughtful food choices, and focusing on being present during meals.

“Each of these dietary strategies offers potential benefits for managing type 2 diabetes and improving overall health,” Ms. Bader said. “I have not had any patients who have tried dry fasting specifically. However, I have encountered scenarios where individuals abstained from food and beverages due to religious practices. In those cases, we focused on ensuring that they maintained proper hydration and balanced nutrition during their eating periods to manage their diabetes effectively and prevent complications.”

Overall, Dr. Adimoolam suggests that clinicians help patients find a weight-loss plan that works best for them based on understanding the calories in the foods they like and don’t like. For fasting regimens, patients can be encouraged to choose one with fluids when possible, as well as intervals of time to fast and eat that work best for their lifestyle.

Ms. Bader, Dr. Bruno, and Dr. Adimoolam report no relevant conflicts.
 

A version of this article appeared on Medscape.com.

Dry fasting, the practice of going without food and water, has enthusiastic advocates on TikTok, X, YouTube, and other social media platforms. Devotees claim a wide range of health effects, but medical professionals advise caution to ensure that the practice does more good than harm, especially for individuals with diabetes. 

Purported benefits and risks vary, depending on who is following the regimen and how long they abstain from food and water. Advocates on social media assert that dry fasting makes “intuition skyrocket” and puts autophagy on “overdrive.” Although such statements may rev up followers, there is little evidence to support these and many other dry-fasting claims. In fact, several physicians warned about unintended consequences.

“I had one patient who followed this fasting method often, and over time she developed kidney stones that led to a severe infection,” said Deena Adimoolam, MD, an endocrinologist in private practice in New York City and New Jersey. “Lack of both water and food can fuel hunger and increase the likelihood of overeating or binge eating once the fast is completed, which does not lead to weight loss. Untreated dehydration can lead to loss of consciousness.”

“For individuals with type 2 diabetes, dehydration can exacerbate hyperglycemia and increase the risk of complications such as diabetic ketoacidosis (DKA),” said Abeer Bader, lead clinical nutrition specialist at the Massachusetts General Hospital Weight Center in Boston. “Research also consistently shows that adequate hydration is crucial for maintaining physical and cognitive performance.”

Dry fasting also can lead to electrolyte imbalances, and the risk is higher for those with diabetes due to potential underlying kidney issues, Ms. Bader noted. “Prolonged dry fasting can result in nutrient deficiencies. For individuals with diabetes, maintaining adequate nutrition is crucial to manage blood sugar levels and overall health. The lack of both food and water can exacerbate deficiencies.”

Joanne Bruno, MD, an endocrinologist at NYU Langone Health, added, “Certain medications used for the management of type 2 diabetes, such as SGLT2 inhibitors, can cause dehydration. It is critical that patients stay well hydrated while on these medications to avoid serious side effects such as euglycemic DKA.”
 

What Exactly Is Dry Fasting?

Defining dry fasting, like any kind of fasting, has remained a challenge, according to authors of the first international consensus on fasting terminology, published on July 25 in Cell Metabolism. The clinical terminology “has remained heterogeneous and often confusing, with similar terms being used to define different fasting regimens ... reflecting the manifold contexts in which fasting is practiced.”

Indeed, dry fasting was among the most discussed terms by the consensus panel and went through several rounds before the panelists came to agreement. A few experts were critical of the practice, whereas those familiar with religious fasting traditions, such as during Ramadan, were clear about the importance of including this term in the consensus process.

“The dissent was resolved by the clarification that this form of fasting has historical and geographical extensions and that the present consensus process did not aim at evaluating therapeutic effectiveness or safety for any term defined,” the authors wrote.

The panel concluded that dry fasting is not the same as total or complete fasting because the latter can include water (such as water-only fasting). Their final definition of dry fasting is ‘’a fasting regimen during which a voluntary abstinence from all foods and beverages, including water, is practiced for a certain period of time.’’

Different types of fasting regimens, such as intermittent fasting, may include dry fasting, in which case it is referred to as “intermittent dry fasting.” This is defined in the consensus as intermittent fasting regimens that involve abstaining from food and fluid intake during the fasting interval, which typically lasts 9-20 hours. 

Most dry fasts, including religious ones, are maintained for a specific interval and are followed by a refeeding period. These fasts are not starvation, defined as no food or water intake for days.
 

What the Evidence Says

All that said, dry fasting by any other name remains dry fasting. “Abundant” evidence from animal studies suggests the potential of various types of fasting for disease prevention and treatment in humans, noted the authors of the consensus report, Along with the risks described above, small studies have explored short-term effects in people, all of which have yet to be established by larger and longer-term studies.

In a recent small study, researchers at Baylor College of Medicine, Houston, Texas, reported that dawn-to-dusk dry fasting for 30 days reduced levels of inflammatory cytokines in the 13 participants with a high body mass index. Earlier work by the group showed that dawn-to-dusk dry fasting for 30 days induced “anti-atherosclerotic, anti-inflammatory, and anti-tumorigenic proteome” in peripheral blood mononuclear cells of 14 individuals with metabolic syndrome (The researchers declined to comment for this article.)

Importantly, the health effects can vary among individuals for unknown reasons, found a recent cross-sectional study of fasting blood glucose (FBG) changes in 181 patients with type 2 diabetes during Ramadan intermittent fasting (RIF), which involves dry fasting during daylight hours for 1 month. The researchers classified participants into three groups: reduced average FBG levels (44%), no change in FBG levels (24%), and increased FBG levels (32%). The authors wrote that further studies are needed to identify factors associated with the differences and to identify “those who are great candidates for RIF.”

In contrast to some of the concerns expressed by clinicians, an exploratory study of daytime dry fasting among 34 healthy Baha’i volunteers in Germany concluded that the 19-day regimen “is safe, has no negative effects on hydration, can improve fat metabolism and can cause transient phase shifts of circadian rhythms.” The authors acknowledge that a larger number and more diverse participants are needed to validate the findings and assess the impact on long-term health.
 

What to Advise Patients

For patients who want to fast as part of their weight loss regimen or to help manage diabetes, clinicians can consider suggesting “alternate ways of eating that might achieve similar goals,” Ms. Bader said. One is intermittent fasting without dry fasting: the 16:8 method (16 hours of fasting, 8 hours of eating) or the 5:2 method (normal eating for 5 days, reduced calorie intake for 2 days), which can support improved insulin sensitivity and metabolic health.

Caloric restriction can also work if the patient maintains a balanced diet that includes all essential nutrients, she said. A low-carbohydrate diet that focuses on limiting carbohydrate intake while increasing consumption of lean proteins and healthy fats has been shown to lower blood sugar levels and improve insulin sensitivity.

Other healthy strategies for patients include the Mediterranean diet, which emphasizes whole grains, fruits, vegetables, nuts, seeds, olive oil, and lean proteins such as fish, or a similar plant-based diet with less animal protein. Ms. Bader advises cultivating mindful eating, which involves paying attention to hunger and fullness cues, making thoughtful food choices, and focusing on being present during meals.

“Each of these dietary strategies offers potential benefits for managing type 2 diabetes and improving overall health,” Ms. Bader said. “I have not had any patients who have tried dry fasting specifically. However, I have encountered scenarios where individuals abstained from food and beverages due to religious practices. In those cases, we focused on ensuring that they maintained proper hydration and balanced nutrition during their eating periods to manage their diabetes effectively and prevent complications.”

Overall, Dr. Adimoolam suggests that clinicians help patients find a weight-loss plan that works best for them based on understanding the calories in the foods they like and don’t like. For fasting regimens, patients can be encouraged to choose one with fluids when possible, as well as intervals of time to fast and eat that work best for their lifestyle.

Ms. Bader, Dr. Bruno, and Dr. Adimoolam report no relevant conflicts.
 

A version of this article appeared on Medscape.com.

Consider this: If you’re taking your children to the beach, how do you protect them from drowning? You don’t tell them, “Don’t go into the ocean.” You teach them how to swim; you give them floaties; and you accompany them in the water and go in only when a lifeguard is present. In other words, you give them all the tools to protect themselves because you know they will go into the ocean anyway. 

Patients are diving into the ocean. Patients with obesity, who know that a treatment for their disease exists but is inaccessible, are diving into the ocean. Unfortunately, they are diving in without floaties or a lifeguard, and well-meaning bystanders are simply telling them to not go. 

Compounded peptides are an ocean of alternative therapies. Even though compounding pharmacists need specialized training, facilities and equipment need to be properly certified, and final dosage forms need extensive testing, pharmacies are not equal when it comes to sterile compounding. Regulatory agencies such as the US Food and Drug Administration (FDA) have expressed caution around compounded semaglutide. Professional societies such as the Obesity Medicine Association (OMA) advise against compounded peptides because they lack clinical trials that prove their safety and efficacy. Ask any individual doctor and you are likely to receive a range of opinions. 

As an endocrinologist specializing in obesity, I practice evidence-based medicine as much as possible. However, I also recognize how today’s dysfunctional medical system compels patients to dive into that ocean in search of an alternative solution. 

Doctors can’t be lifeguards, but we can at least empower patients who want to decide for themselves whether the risk of compounded peptides is worth it. 

With the help of pharmacists, compounding pharmacists, researchers, and clinicians, here is a checklist for patients who seek compounded semaglutide or tirzepatide: 

• Check the state licensing board website to see if there have been any complaints or disciplinary actions made against the pharmacy facility. These government-maintained websites vary in searchability and user-friendliness, but you are specifically looking for whether the FDA ever issued a 483 form.
• Ask for the pharmacy’s state board inspection report. There should be at least one of these reports, issued at the pharmacy’s founding, and there may be more depending on individual state regulations on frequencies of inspections.
• Ask if the compounding pharmacy is accredited by the Pharmacy Compounding Accreditation Board (PCAB). Accreditation is an extra optional step that some compounding pharmacies take to be legitimized by a third party.
• Ask if the pharmacy follows Current Good Manufacturing Practice (CGMP). CGMP is not required of 503a pharmacies, which are pharmacies that provide semaglutide or tirzepatide directly to patients, but following CGMP means an extra level of quality assurance. The bare minimum for anyone doing sterile compounding in the United States is to meet the standards found in the US Pharmacopeia, chapter <797>, Sterile Compounding.
• Ask your compounding pharmacy where they source the medication’s active pharmaceutical ingredient (API).
• Find out if this supplier is registered with the FDA by searching here or here.
• Confirm that semaglutide base, not semaglutide salt, is used in the compounding process.
• Request a certificate of analysis (COA) of the active pharmaceutical ingredient, which should be semaglutide base. This shows you whether the medication has impurities or byproducts due to its manufacturing process.
• Ask if they have third-party confirmation of potency, stability, and sterility testing of the final product.

In generating this guidance, I’m not endorsing compounded peptides, and in fact, I recognize that there is nothing keeping small-time compounding pharmacies from skirting some of these quality measures, falsifying records, and flying under the radar. However, I hope this checklist serves as a starting point for education and risk mitigation. If a compounder is unwilling or unable to answer these questions, consider it a red flag and look elsewhere. 

In an ideal world, the state regulators or the FDA would proactively supervise instead of reactively monitor; trusted compounding pharmacies would be systematically activated to ease medication shortages; and patients with obesity would have access to safe and efficacious treatments for their disease. Until then, we as providers can acknowledge the disappointments of our healthcare system while still developing realistic and individualized solutions that prioritize patient care and safety. 
 

Dr. Tchang is assistant professor, Clinical Medicine, Division of Endocrinology, Diabetes, and Metabolism, Weill Cornell Medicine, and a physician, Department of Medicine, Iris Cantor Women’s Health Center, Comprehensive Weight Control Center, New York. She is an adviser for Novo Nordisk, which manufactures Wegovy, and an adviser for Ro, a telehealth company that offers compounded semaglutide, and serves or has served as a director, officer, partner, employee, advisor, consultant, or trustee for Gelesis and Novo Nordisk.

A version of this article first appeared on Medscape.com.

Consider this: If you’re taking your children to the beach, how do you protect them from drowning? You don’t tell them, “Don’t go into the ocean.” You teach them how to swim; you give them floaties; and you accompany them in the water and go in only when a lifeguard is present. In other words, you give them all the tools to protect themselves because you know they will go into the ocean anyway. 

Patients are diving into the ocean. Patients with obesity, who know that a treatment for their disease exists but is inaccessible, are diving into the ocean. Unfortunately, they are diving in without floaties or a lifeguard, and well-meaning bystanders are simply telling them to not go. 

Compounded peptides are an ocean of alternative therapies. Even though compounding pharmacists need specialized training, facilities and equipment need to be properly certified, and final dosage forms need extensive testing, pharmacies are not equal when it comes to sterile compounding. Regulatory agencies such as the US Food and Drug Administration (FDA) have expressed caution around compounded semaglutide. Professional societies such as the Obesity Medicine Association (OMA) advise against compounded peptides because they lack clinical trials that prove their safety and efficacy. Ask any individual doctor and you are likely to receive a range of opinions. 

As an endocrinologist specializing in obesity, I practice evidence-based medicine as much as possible. However, I also recognize how today’s dysfunctional medical system compels patients to dive into that ocean in search of an alternative solution. 

Doctors can’t be lifeguards, but we can at least empower patients who want to decide for themselves whether the risk of compounded peptides is worth it. 

With the help of pharmacists, compounding pharmacists, researchers, and clinicians, here is a checklist for patients who seek compounded semaglutide or tirzepatide: 

• Check the state licensing board website to see if there have been any complaints or disciplinary actions made against the pharmacy facility. These government-maintained websites vary in searchability and user-friendliness, but you are specifically looking for whether the FDA ever issued a 483 form.
• Ask for the pharmacy’s state board inspection report. There should be at least one of these reports, issued at the pharmacy’s founding, and there may be more depending on individual state regulations on frequencies of inspections.
• Ask if the compounding pharmacy is accredited by the Pharmacy Compounding Accreditation Board (PCAB). Accreditation is an extra optional step that some compounding pharmacies take to be legitimized by a third party.
• Ask if the pharmacy follows Current Good Manufacturing Practice (CGMP). CGMP is not required of 503a pharmacies, which are pharmacies that provide semaglutide or tirzepatide directly to patients, but following CGMP means an extra level of quality assurance. The bare minimum for anyone doing sterile compounding in the United States is to meet the standards found in the US Pharmacopeia, chapter <797>, Sterile Compounding.
• Ask your compounding pharmacy where they source the medication’s active pharmaceutical ingredient (API).
• Find out if this supplier is registered with the FDA by searching here or here.
• Confirm that semaglutide base, not semaglutide salt, is used in the compounding process.
• Request a certificate of analysis (COA) of the active pharmaceutical ingredient, which should be semaglutide base. This shows you whether the medication has impurities or byproducts due to its manufacturing process.
• Ask if they have third-party confirmation of potency, stability, and sterility testing of the final product.

In generating this guidance, I’m not endorsing compounded peptides, and in fact, I recognize that there is nothing keeping small-time compounding pharmacies from skirting some of these quality measures, falsifying records, and flying under the radar. However, I hope this checklist serves as a starting point for education and risk mitigation. If a compounder is unwilling or unable to answer these questions, consider it a red flag and look elsewhere. 

In an ideal world, the state regulators or the FDA would proactively supervise instead of reactively monitor; trusted compounding pharmacies would be systematically activated to ease medication shortages; and patients with obesity would have access to safe and efficacious treatments for their disease. Until then, we as providers can acknowledge the disappointments of our healthcare system while still developing realistic and individualized solutions that prioritize patient care and safety. 
 

Dr. Tchang is assistant professor, Clinical Medicine, Division of Endocrinology, Diabetes, and Metabolism, Weill Cornell Medicine, and a physician, Department of Medicine, Iris Cantor Women’s Health Center, Comprehensive Weight Control Center, New York. She is an adviser for Novo Nordisk, which manufactures Wegovy, and an adviser for Ro, a telehealth company that offers compounded semaglutide, and serves or has served as a director, officer, partner, employee, advisor, consultant, or trustee for Gelesis and Novo Nordisk.

A version of this article first appeared on Medscape.com.

Consider this: If you’re taking your children to the beach, how do you protect them from drowning? You don’t tell them, “Don’t go into the ocean.” You teach them how to swim; you give them floaties; and you accompany them in the water and go in only when a lifeguard is present. In other words, you give them all the tools to protect themselves because you know they will go into the ocean anyway. 

Patients are diving into the ocean. Patients with obesity, who know that a treatment for their disease exists but is inaccessible, are diving into the ocean. Unfortunately, they are diving in without floaties or a lifeguard, and well-meaning bystanders are simply telling them to not go. 

Compounded peptides are an ocean of alternative therapies. Even though compounding pharmacists need specialized training, facilities and equipment need to be properly certified, and final dosage forms need extensive testing, pharmacies are not equal when it comes to sterile compounding. Regulatory agencies such as the US Food and Drug Administration (FDA) have expressed caution around compounded semaglutide. Professional societies such as the Obesity Medicine Association (OMA) advise against compounded peptides because they lack clinical trials that prove their safety and efficacy. Ask any individual doctor and you are likely to receive a range of opinions. 

As an endocrinologist specializing in obesity, I practice evidence-based medicine as much as possible. However, I also recognize how today’s dysfunctional medical system compels patients to dive into that ocean in search of an alternative solution. 

Doctors can’t be lifeguards, but we can at least empower patients who want to decide for themselves whether the risk of compounded peptides is worth it. 

With the help of pharmacists, compounding pharmacists, researchers, and clinicians, here is a checklist for patients who seek compounded semaglutide or tirzepatide: 

• Check the state licensing board website to see if there have been any complaints or disciplinary actions made against the pharmacy facility. These government-maintained websites vary in searchability and user-friendliness, but you are specifically looking for whether the FDA ever issued a 483 form.
• Ask for the pharmacy’s state board inspection report. There should be at least one of these reports, issued at the pharmacy’s founding, and there may be more depending on individual state regulations on frequencies of inspections.
• Ask if the compounding pharmacy is accredited by the Pharmacy Compounding Accreditation Board (PCAB). Accreditation is an extra optional step that some compounding pharmacies take to be legitimized by a third party.
• Ask if the pharmacy follows Current Good Manufacturing Practice (CGMP). CGMP is not required of 503a pharmacies, which are pharmacies that provide semaglutide or tirzepatide directly to patients, but following CGMP means an extra level of quality assurance. The bare minimum for anyone doing sterile compounding in the United States is to meet the standards found in the US Pharmacopeia, chapter <797>, Sterile Compounding.
• Ask your compounding pharmacy where they source the medication’s active pharmaceutical ingredient (API).
• Find out if this supplier is registered with the FDA by searching here or here.
• Confirm that semaglutide base, not semaglutide salt, is used in the compounding process.
• Request a certificate of analysis (COA) of the active pharmaceutical ingredient, which should be semaglutide base. This shows you whether the medication has impurities or byproducts due to its manufacturing process.
• Ask if they have third-party confirmation of potency, stability, and sterility testing of the final product.

In generating this guidance, I’m not endorsing compounded peptides, and in fact, I recognize that there is nothing keeping small-time compounding pharmacies from skirting some of these quality measures, falsifying records, and flying under the radar. However, I hope this checklist serves as a starting point for education and risk mitigation. If a compounder is unwilling or unable to answer these questions, consider it a red flag and look elsewhere. 

In an ideal world, the state regulators or the FDA would proactively supervise instead of reactively monitor; trusted compounding pharmacies would be systematically activated to ease medication shortages; and patients with obesity would have access to safe and efficacious treatments for their disease. Until then, we as providers can acknowledge the disappointments of our healthcare system while still developing realistic and individualized solutions that prioritize patient care and safety. 
 

Dr. Tchang is assistant professor, Clinical Medicine, Division of Endocrinology, Diabetes, and Metabolism, Weill Cornell Medicine, and a physician, Department of Medicine, Iris Cantor Women’s Health Center, Comprehensive Weight Control Center, New York. She is an adviser for Novo Nordisk, which manufactures Wegovy, and an adviser for Ro, a telehealth company that offers compounded semaglutide, and serves or has served as a director, officer, partner, employee, advisor, consultant, or trustee for Gelesis and Novo Nordisk.

A version of this article first appeared on Medscape.com.

Poorer physical function, not poorer bone mineral density (BMD), could be the principal reason for the increased fracture risk in older women with type 2 diabetes (T2D), according to a Swedish prospective observational study in JAMA Network Open.

The study was conducted in more than 3000 Swedish women by Mattias Lorentzon, MD, a professor of geriatric medicine at Gothenburg University, and chief physician at the Osteoporosis Clinic at Sahlgrenska University Hospital in Mölndal, and colleagues.

Study Details

A fractures study was performed in the Gothenburg area from March 2013 to May 2016 with follow-up of incident fracture data completed in March 2023. Data were collected from questionnaires and through examination of anthropometrics, physical function, and bone measurements using dual-energy x-ray absorptiometry and high-resolution peripheral computed tomography. A subsample underwent bone microindentation to assess BMSi.

Among the cohort’s 3008 women, ages 75-80 (mean, 77.8), 294 patients with T2D were compared with 2714 same-age unaffected women.

During a median follow-up of 7.3 years, 1071 incident fractures, 853 major osteoporotic fractures, and 232 hip fractures occurred. In models adjusted for age, BMI, clinical risk factors, and femoral neck BMD, T2D was associated with an increased risk of any fracture: hazard ratio (HR), 1.26; (95% CI, 1.04-1.54), and major osteoporotic fracture (HR, 1.25; 95% CI, 1.00-1.56).

Most fractures were due to falls, with the most common affected sites being the forearm, upper arm, spine, and hip, Dr. Lorentzon said.

Among the findings:

• In bone microarchitecture, women with T2D had higher BMD at all sites: total hip, 4.4% higher; femoral neck, 4.9% higher; and lumbar spine, 5.2% higher.
• At the tibia, the T2D group had 7.4% greater cortical area and 1.3% greater density, as well as 8.7% higher trabecular bone volume fraction.

“Our findings regarding BMD are consistent with previous publications showing higher BMD in individuals with T2D compared with those without diabetes,” Dr. Lorentzon said. A 2012 meta-analysis, for example, showed higher BMD levels in T2D patients. “Some smaller studies, however, have found worse bone microstructure and lower bone material strength in contrast to the results from our study,” Dr. Lorentzon said.

• There was no difference in BMSi, with a mean of 78 in both groups.
• The T2D group had lower performance on all physical function tests: a 9.7% lower grip strength, 9.9% slower gait speed, and 13.9% slower timed up-and-go time than women without diabetes.

“We found all parameters regarding physical function, such as muscle strength, balance, and performance, were much worse in women with diabetes than in those without,” Dr. Lorentzon said. “Dizziness could also be a contributor to the increased risk of falls, but this factor was not investigated in our study.”

Commenting on the study but not involved in it, Anthony J. Pick, MD, an endocrinologist at Northwestern Medicine Lake Forest Hospital in Lake Forest, Illinois, said sarcopenia is a common and often under-recognized problem in older adults and is especially prevalent in T2D, obesity, and heart failure. “I believe that ‘exercise is medicine’ is a key concept for metabolic and osteoporosis patients — and wellness and longevity in general — and I certainly hope studies like this drive awareness of the importance of engaging in strengthening exercises.”

Poorer physical function, not poorer bone mineral density (BMD), could be the principal reason for the increased fracture risk in older women with type 2 diabetes (T2D), according to a Swedish prospective observational study in JAMA Network Open.

The study was conducted in more than 3000 Swedish women by Mattias Lorentzon, MD, a professor of geriatric medicine at Gothenburg University, and chief physician at the Osteoporosis Clinic at Sahlgrenska University Hospital in Mölndal, and colleagues.

Study Details

A fractures study was performed in the Gothenburg area from March 2013 to May 2016 with follow-up of incident fracture data completed in March 2023. Data were collected from questionnaires and through examination of anthropometrics, physical function, and bone measurements using dual-energy x-ray absorptiometry and high-resolution peripheral computed tomography. A subsample underwent bone microindentation to assess BMSi.

Among the cohort’s 3008 women, ages 75-80 (mean, 77.8), 294 patients with T2D were compared with 2714 same-age unaffected women.

During a median follow-up of 7.3 years, 1071 incident fractures, 853 major osteoporotic fractures, and 232 hip fractures occurred. In models adjusted for age, BMI, clinical risk factors, and femoral neck BMD, T2D was associated with an increased risk of any fracture: hazard ratio (HR), 1.26; (95% CI, 1.04-1.54), and major osteoporotic fracture (HR, 1.25; 95% CI, 1.00-1.56).

Most fractures were due to falls, with the most common affected sites being the forearm, upper arm, spine, and hip, Dr. Lorentzon said.

Among the findings:

• In bone microarchitecture, women with T2D had higher BMD at all sites: total hip, 4.4% higher; femoral neck, 4.9% higher; and lumbar spine, 5.2% higher.
• At the tibia, the T2D group had 7.4% greater cortical area and 1.3% greater density, as well as 8.7% higher trabecular bone volume fraction.

“Our findings regarding BMD are consistent with previous publications showing higher BMD in individuals with T2D compared with those without diabetes,” Dr. Lorentzon said. A 2012 meta-analysis, for example, showed higher BMD levels in T2D patients. “Some smaller studies, however, have found worse bone microstructure and lower bone material strength in contrast to the results from our study,” Dr. Lorentzon said.

• There was no difference in BMSi, with a mean of 78 in both groups.
• The T2D group had lower performance on all physical function tests: a 9.7% lower grip strength, 9.9% slower gait speed, and 13.9% slower timed up-and-go time than women without diabetes.

“We found all parameters regarding physical function, such as muscle strength, balance, and performance, were much worse in women with diabetes than in those without,” Dr. Lorentzon said. “Dizziness could also be a contributor to the increased risk of falls, but this factor was not investigated in our study.”

Commenting on the study but not involved in it, Anthony J. Pick, MD, an endocrinologist at Northwestern Medicine Lake Forest Hospital in Lake Forest, Illinois, said sarcopenia is a common and often under-recognized problem in older adults and is especially prevalent in T2D, obesity, and heart failure. “I believe that ‘exercise is medicine’ is a key concept for metabolic and osteoporosis patients — and wellness and longevity in general — and I certainly hope studies like this drive awareness of the importance of engaging in strengthening exercises.”

Poorer physical function, not poorer bone mineral density (BMD), could be the principal reason for the increased fracture risk in older women with type 2 diabetes (T2D), according to a Swedish prospective observational study in JAMA Network Open.

The study was conducted in more than 3000 Swedish women by Mattias Lorentzon, MD, a professor of geriatric medicine at Gothenburg University, and chief physician at the Osteoporosis Clinic at Sahlgrenska University Hospital in Mölndal, and colleagues.

Study Details

A fractures study was performed in the Gothenburg area from March 2013 to May 2016 with follow-up of incident fracture data completed in March 2023. Data were collected from questionnaires and through examination of anthropometrics, physical function, and bone measurements using dual-energy x-ray absorptiometry and high-resolution peripheral computed tomography. A subsample underwent bone microindentation to assess BMSi.

Among the cohort’s 3008 women, ages 75-80 (mean, 77.8), 294 patients with T2D were compared with 2714 same-age unaffected women.

During a median follow-up of 7.3 years, 1071 incident fractures, 853 major osteoporotic fractures, and 232 hip fractures occurred. In models adjusted for age, BMI, clinical risk factors, and femoral neck BMD, T2D was associated with an increased risk of any fracture: hazard ratio (HR), 1.26; (95% CI, 1.04-1.54), and major osteoporotic fracture (HR, 1.25; 95% CI, 1.00-1.56).

Most fractures were due to falls, with the most common affected sites being the forearm, upper arm, spine, and hip, Dr. Lorentzon said.

Among the findings:

• In bone microarchitecture, women with T2D had higher BMD at all sites: total hip, 4.4% higher; femoral neck, 4.9% higher; and lumbar spine, 5.2% higher.
• At the tibia, the T2D group had 7.4% greater cortical area and 1.3% greater density, as well as 8.7% higher trabecular bone volume fraction.

“Our findings regarding BMD are consistent with previous publications showing higher BMD in individuals with T2D compared with those without diabetes,” Dr. Lorentzon said. A 2012 meta-analysis, for example, showed higher BMD levels in T2D patients. “Some smaller studies, however, have found worse bone microstructure and lower bone material strength in contrast to the results from our study,” Dr. Lorentzon said.

• There was no difference in BMSi, with a mean of 78 in both groups.
• The T2D group had lower performance on all physical function tests: a 9.7% lower grip strength, 9.9% slower gait speed, and 13.9% slower timed up-and-go time than women without diabetes.

“We found all parameters regarding physical function, such as muscle strength, balance, and performance, were much worse in women with diabetes than in those without,” Dr. Lorentzon said. “Dizziness could also be a contributor to the increased risk of falls, but this factor was not investigated in our study.”

Commenting on the study but not involved in it, Anthony J. Pick, MD, an endocrinologist at Northwestern Medicine Lake Forest Hospital in Lake Forest, Illinois, said sarcopenia is a common and often under-recognized problem in older adults and is especially prevalent in T2D, obesity, and heart failure. “I believe that ‘exercise is medicine’ is a key concept for metabolic and osteoporosis patients — and wellness and longevity in general — and I certainly hope studies like this drive awareness of the importance of engaging in strengthening exercises.”