MDedge Endocrinology

SAN FRANCISCO — While the physical toll of cancer is well documented, the financial toll can also be severe and lasting.

Overall, patients with cancer tend to face higher rates of debt collection, medical collections, and bankruptcies, as well as lower credit scores, according to two new studies presented at the American College of Surgeons Clinical Congress 2024.

“These are the first studies to provide numerical evidence of financial toxicity among cancer survivors,” Benjamin C. James, MD, with Beth Israel Deaconess Medical Center and Harvard Medical School, both in Boston, Massachusetts, who worked on both studies, said in a statement. “Previous data on this topic largely relies on subjective survey reviews.”

In one study, researchers used the Massachusetts Cancer Registry to identify 99,175 patients diagnosed with cancer between 2010 and 2019 and matched them with 188,875 control individuals without cancer. Researchers then assessed financial toxicity using Experian credit bureau data for participants.

Overall, patients with cancer faced a range of financial challenges that often lasted years following their diagnosis.

Patients were nearly five times more likely to experience bankruptcy and had average credit scores nearly 80 points lower than control individuals without cancer. The drop in credit scores was more pronounced for survivors of bladder, liver, lung, and colorectal cancer (CRC) and persisted for up to 9.5 years.

For certain cancer types, in particular, “we are looking years after a diagnosis, and we see that the credit score goes down and it never comes back up,” James said.

The other study, which used a sample of 7227 patients with CRC from Massachusetts, identified several factors that correlated with lower credit scores.

Compared with patients who only had surgery, peers who underwent radiation only experienced a 62-point drop in their credit score after their diagnosis, while those who had chemotherapy alone had just over a 14-point drop in their credit score. Among patients who had combination treatments, those who underwent both surgery and radiation experienced a nearly 16-point drop in their credit score and those who had surgery and chemoradiation actually experienced a 2.59 bump, compared with those who had surgery alone.

Financial toxicity was worse for patients younger than 62 years, those identifying as Black or Hispanic individuals, unmarried individuals, those with an annual income below $52,000, and those living in deprived areas.

The studies add to findings from the 2015 North American Thyroid Cancer Survivorship Study, which reported that 50% of thyroid cancer survivors encountered financial toxicity because of their diagnosis.

James said the persistent financial strain of cancer care, even in a state like Massachusetts, which mandates universal healthcare, underscores the need for “broader policy changes and reforms, including reconsidering debt collection practices.”

“Financial security should be a priority in cancer care,” he added.

The studies had no specific funding. The authors have disclosed no relevant conflict of interest.

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

SAN FRANCISCO — While the physical toll of cancer is well documented, the financial toll can also be severe and lasting.

Overall, patients with cancer tend to face higher rates of debt collection, medical collections, and bankruptcies, as well as lower credit scores, according to two new studies presented at the American College of Surgeons Clinical Congress 2024.

“These are the first studies to provide numerical evidence of financial toxicity among cancer survivors,” Benjamin C. James, MD, with Beth Israel Deaconess Medical Center and Harvard Medical School, both in Boston, Massachusetts, who worked on both studies, said in a statement. “Previous data on this topic largely relies on subjective survey reviews.”

In one study, researchers used the Massachusetts Cancer Registry to identify 99,175 patients diagnosed with cancer between 2010 and 2019 and matched them with 188,875 control individuals without cancer. Researchers then assessed financial toxicity using Experian credit bureau data for participants.

Overall, patients with cancer faced a range of financial challenges that often lasted years following their diagnosis.

Patients were nearly five times more likely to experience bankruptcy and had average credit scores nearly 80 points lower than control individuals without cancer. The drop in credit scores was more pronounced for survivors of bladder, liver, lung, and colorectal cancer (CRC) and persisted for up to 9.5 years.

For certain cancer types, in particular, “we are looking years after a diagnosis, and we see that the credit score goes down and it never comes back up,” James said.

The other study, which used a sample of 7227 patients with CRC from Massachusetts, identified several factors that correlated with lower credit scores.

Compared with patients who only had surgery, peers who underwent radiation only experienced a 62-point drop in their credit score after their diagnosis, while those who had chemotherapy alone had just over a 14-point drop in their credit score. Among patients who had combination treatments, those who underwent both surgery and radiation experienced a nearly 16-point drop in their credit score and those who had surgery and chemoradiation actually experienced a 2.59 bump, compared with those who had surgery alone.

Financial toxicity was worse for patients younger than 62 years, those identifying as Black or Hispanic individuals, unmarried individuals, those with an annual income below $52,000, and those living in deprived areas.

The studies add to findings from the 2015 North American Thyroid Cancer Survivorship Study, which reported that 50% of thyroid cancer survivors encountered financial toxicity because of their diagnosis.

James said the persistent financial strain of cancer care, even in a state like Massachusetts, which mandates universal healthcare, underscores the need for “broader policy changes and reforms, including reconsidering debt collection practices.”

“Financial security should be a priority in cancer care,” he added.

The studies had no specific funding. The authors have disclosed no relevant conflict of interest.

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

SAN FRANCISCO — While the physical toll of cancer is well documented, the financial toll can also be severe and lasting.

Overall, patients with cancer tend to face higher rates of debt collection, medical collections, and bankruptcies, as well as lower credit scores, according to two new studies presented at the American College of Surgeons Clinical Congress 2024.

“These are the first studies to provide numerical evidence of financial toxicity among cancer survivors,” Benjamin C. James, MD, with Beth Israel Deaconess Medical Center and Harvard Medical School, both in Boston, Massachusetts, who worked on both studies, said in a statement. “Previous data on this topic largely relies on subjective survey reviews.”

In one study, researchers used the Massachusetts Cancer Registry to identify 99,175 patients diagnosed with cancer between 2010 and 2019 and matched them with 188,875 control individuals without cancer. Researchers then assessed financial toxicity using Experian credit bureau data for participants.

Overall, patients with cancer faced a range of financial challenges that often lasted years following their diagnosis.

Patients were nearly five times more likely to experience bankruptcy and had average credit scores nearly 80 points lower than control individuals without cancer. The drop in credit scores was more pronounced for survivors of bladder, liver, lung, and colorectal cancer (CRC) and persisted for up to 9.5 years.

For certain cancer types, in particular, “we are looking years after a diagnosis, and we see that the credit score goes down and it never comes back up,” James said.

The other study, which used a sample of 7227 patients with CRC from Massachusetts, identified several factors that correlated with lower credit scores.

Compared with patients who only had surgery, peers who underwent radiation only experienced a 62-point drop in their credit score after their diagnosis, while those who had chemotherapy alone had just over a 14-point drop in their credit score. Among patients who had combination treatments, those who underwent both surgery and radiation experienced a nearly 16-point drop in their credit score and those who had surgery and chemoradiation actually experienced a 2.59 bump, compared with those who had surgery alone.

Financial toxicity was worse for patients younger than 62 years, those identifying as Black or Hispanic individuals, unmarried individuals, those with an annual income below $52,000, and those living in deprived areas.

The studies add to findings from the 2015 North American Thyroid Cancer Survivorship Study, which reported that 50% of thyroid cancer survivors encountered financial toxicity because of their diagnosis.

James said the persistent financial strain of cancer care, even in a state like Massachusetts, which mandates universal healthcare, underscores the need for “broader policy changes and reforms, including reconsidering debt collection practices.”

“Financial security should be a priority in cancer care,” he added.

The studies had no specific funding. The authors have disclosed no relevant conflict of interest.

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

TOPLINE: 

High-intensity exercise suppresses ghrelin levels more than moderate-intensity exercise, leading to a greater reduction in hunger. This effect may be more pronounced in women than in men.

METHODOLOGY:

• Ghrelin circulates in acylated and deacylated forms and is associated with hunger perceptions. Previous studies have indicated that acute exercise can modulate ghrelin levels, but data on the effect of exercise intensity on ghrelin levels and appetite remain limited.
• To close this gap, researchers examined 14 adults, including eight men (mean age, 43.1 years; body mass index [BMI], 22.2) and six women (mean age, 32.2 years; BMI, 22.7) who fasted overnight and then completed exercises of varying intensity.
• Participants completed a maximal graded cycle ergometer lactate threshold (LT) and peak oxygen consumption (VO2_peak) test to determine the exercise intensity.
• Three calorically matched cycle exercise bouts were conducted: Control (no exercise), moderate-intensity (power output at LT), and high-intensity (power output associated with 75% of the difference between LT and VO2_peak).
• Total ghrelin, acylated ghrelin, deacylated ghrelin, and lactate levels were measured at baseline and at multiple intervals post-exercise; appetite ratings were assessed using a visual analog scale at baseline and every 30 minutes thereafter.

TAKEAWAY:

• Total ghrelin levels were significantly lower during high-intensity exercise than during moderate-intensity and no exercise (P < .0001 for both).
• Both men and women had significantly lower deacylated ghrelin levels during high-intensity exercise than during moderate-intensity (P < .0001) and no exercise (P = .002), whereas only women had significantly lower acylated ghrelin levels during high-intensity exercise (P < .0001).
• Hunger scores were higher in the moderate-intensity exercise group than in the no exercise group (P < .01), with no differences found between high-intensity exercise and moderate-intensity or no exercise.
• Lactate levels were significantly higher during high-intensity exercise than during moderate-intensity and no exercise (P < .0001 for both).

IN PRACTICE:

“Exercise should be thought of as a ‘drug,’ where the ‘dose’ should be customized based on an individual’s personal goals,” the lead author said in a news release. “Our research suggests that high-intensity exercise may be important for appetite suppression, which can be particularly useful as part of a weight loss program.”

SOURCE:

This study was led by Kara C. Anderson, PhD, Department of Kinesiology, University of Virginia, Charlottesville, Virginia, and was published online on October 24, 2024, in the Journal of the Endocrine Society.

LIMITATIONS: 

The real-world application of the study was limited as participants were tested under fasting conditions, which may not have reflected typical exercise scenarios. The differences in fitness levels and exercise caloric expenditure between men and women may have affected the findings. The study only included lean individuals, limiting the applicability of the findings to individuals with overweight or obesity.

DISCLOSURES:

The study was supported by funds from the School of Education and Human Development, University of Virginia, and the National Institute of Diabetes and Digestive and Kidney Diseases. One author reported serving as an editor for the Journal of the Endocrine Society, which played no role in the evaluation of the manuscript.
 

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 appeared on Medscape.com.

TOPLINE: 

High-intensity exercise suppresses ghrelin levels more than moderate-intensity exercise, leading to a greater reduction in hunger. This effect may be more pronounced in women than in men.

METHODOLOGY:

• Ghrelin circulates in acylated and deacylated forms and is associated with hunger perceptions. Previous studies have indicated that acute exercise can modulate ghrelin levels, but data on the effect of exercise intensity on ghrelin levels and appetite remain limited.
• To close this gap, researchers examined 14 adults, including eight men (mean age, 43.1 years; body mass index [BMI], 22.2) and six women (mean age, 32.2 years; BMI, 22.7) who fasted overnight and then completed exercises of varying intensity.
• Participants completed a maximal graded cycle ergometer lactate threshold (LT) and peak oxygen consumption (VO2_peak) test to determine the exercise intensity.
• Three calorically matched cycle exercise bouts were conducted: Control (no exercise), moderate-intensity (power output at LT), and high-intensity (power output associated with 75% of the difference between LT and VO2_peak).
• Total ghrelin, acylated ghrelin, deacylated ghrelin, and lactate levels were measured at baseline and at multiple intervals post-exercise; appetite ratings were assessed using a visual analog scale at baseline and every 30 minutes thereafter.

TAKEAWAY:

• Total ghrelin levels were significantly lower during high-intensity exercise than during moderate-intensity and no exercise (P < .0001 for both).
• Both men and women had significantly lower deacylated ghrelin levels during high-intensity exercise than during moderate-intensity (P < .0001) and no exercise (P = .002), whereas only women had significantly lower acylated ghrelin levels during high-intensity exercise (P < .0001).
• Hunger scores were higher in the moderate-intensity exercise group than in the no exercise group (P < .01), with no differences found between high-intensity exercise and moderate-intensity or no exercise.
• Lactate levels were significantly higher during high-intensity exercise than during moderate-intensity and no exercise (P < .0001 for both).

IN PRACTICE:

“Exercise should be thought of as a ‘drug,’ where the ‘dose’ should be customized based on an individual’s personal goals,” the lead author said in a news release. “Our research suggests that high-intensity exercise may be important for appetite suppression, which can be particularly useful as part of a weight loss program.”

SOURCE:

This study was led by Kara C. Anderson, PhD, Department of Kinesiology, University of Virginia, Charlottesville, Virginia, and was published online on October 24, 2024, in the Journal of the Endocrine Society.

LIMITATIONS: 

The real-world application of the study was limited as participants were tested under fasting conditions, which may not have reflected typical exercise scenarios. The differences in fitness levels and exercise caloric expenditure between men and women may have affected the findings. The study only included lean individuals, limiting the applicability of the findings to individuals with overweight or obesity.

DISCLOSURES:

The study was supported by funds from the School of Education and Human Development, University of Virginia, and the National Institute of Diabetes and Digestive and Kidney Diseases. One author reported serving as an editor for the Journal of the Endocrine Society, which played no role in the evaluation of the manuscript.
 

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 appeared on Medscape.com.

TOPLINE: 

High-intensity exercise suppresses ghrelin levels more than moderate-intensity exercise, leading to a greater reduction in hunger. This effect may be more pronounced in women than in men.

METHODOLOGY:

• Ghrelin circulates in acylated and deacylated forms and is associated with hunger perceptions. Previous studies have indicated that acute exercise can modulate ghrelin levels, but data on the effect of exercise intensity on ghrelin levels and appetite remain limited.
• To close this gap, researchers examined 14 adults, including eight men (mean age, 43.1 years; body mass index [BMI], 22.2) and six women (mean age, 32.2 years; BMI, 22.7) who fasted overnight and then completed exercises of varying intensity.
• Participants completed a maximal graded cycle ergometer lactate threshold (LT) and peak oxygen consumption (VO2_peak) test to determine the exercise intensity.
• Three calorically matched cycle exercise bouts were conducted: Control (no exercise), moderate-intensity (power output at LT), and high-intensity (power output associated with 75% of the difference between LT and VO2_peak).
• Total ghrelin, acylated ghrelin, deacylated ghrelin, and lactate levels were measured at baseline and at multiple intervals post-exercise; appetite ratings were assessed using a visual analog scale at baseline and every 30 minutes thereafter.

TAKEAWAY:

• Total ghrelin levels were significantly lower during high-intensity exercise than during moderate-intensity and no exercise (P < .0001 for both).
• Both men and women had significantly lower deacylated ghrelin levels during high-intensity exercise than during moderate-intensity (P < .0001) and no exercise (P = .002), whereas only women had significantly lower acylated ghrelin levels during high-intensity exercise (P < .0001).
• Hunger scores were higher in the moderate-intensity exercise group than in the no exercise group (P < .01), with no differences found between high-intensity exercise and moderate-intensity or no exercise.
• Lactate levels were significantly higher during high-intensity exercise than during moderate-intensity and no exercise (P < .0001 for both).

IN PRACTICE:

“Exercise should be thought of as a ‘drug,’ where the ‘dose’ should be customized based on an individual’s personal goals,” the lead author said in a news release. “Our research suggests that high-intensity exercise may be important for appetite suppression, which can be particularly useful as part of a weight loss program.”

SOURCE:

This study was led by Kara C. Anderson, PhD, Department of Kinesiology, University of Virginia, Charlottesville, Virginia, and was published online on October 24, 2024, in the Journal of the Endocrine Society.

LIMITATIONS: 

The real-world application of the study was limited as participants were tested under fasting conditions, which may not have reflected typical exercise scenarios. The differences in fitness levels and exercise caloric expenditure between men and women may have affected the findings. The study only included lean individuals, limiting the applicability of the findings to individuals with overweight or obesity.

DISCLOSURES:

The study was supported by funds from the School of Education and Human Development, University of Virginia, and the National Institute of Diabetes and Digestive and Kidney Diseases. One author reported serving as an editor for the Journal of the Endocrine Society, which played no role in the evaluation of the manuscript.
 

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 appeared on Medscape.com.

Primary adrenal insufficiency (Addison’s disease) results from a dysfunction of the adrenal glands, which may be secondary to autoimmune diseases, genetic conditions, infections, and vasculopathies,or may be drug-induced (e.g. checkpoint inhibitors), among others . In contrast, secondary adrenal insufficiency results from pituitary dysfunction of low adrenocorticotropic hormone (ACTH). The most common cause of primary adrenal insufficiency in developed countries is autoimmune adrenalitis, which accounts for upwards of 90% of cases. Typically, 21-hydroxylase autoantibodies are identified and account for destruction of the adrenal cortex through cell-mediated and humoral immune responses.

Dr. Sophia M. Akhiyat

Dr. Sophia M. Akhiyat

Dr. Bilu Martin is a board-certified dermatologist in private practice at Premier Dermatology, MD, in Aventura, Florida. More diagnostic cases are available at mdedge.com/dermatology. To submit a case for possible publication, send an email to [email protected].

References

J Am Acad Dermatol. 2014 May;70(5):Supplement 1AB118. doi: 10.1016/j.jaad.2014.01.491.

Michels A, Michels N. Am Fam Physician. 2014 Apr 1;89(7):563-568.

Kauzman A et al. J Can Dent Assoc. 2004 Nov;70(10):682-683.

Primary adrenal insufficiency (Addison’s disease) results from a dysfunction of the adrenal glands, which may be secondary to autoimmune diseases, genetic conditions, infections, and vasculopathies,or may be drug-induced (e.g. checkpoint inhibitors), among others . In contrast, secondary adrenal insufficiency results from pituitary dysfunction of low adrenocorticotropic hormone (ACTH). The most common cause of primary adrenal insufficiency in developed countries is autoimmune adrenalitis, which accounts for upwards of 90% of cases. Typically, 21-hydroxylase autoantibodies are identified and account for destruction of the adrenal cortex through cell-mediated and humoral immune responses.

Dr. Sophia M. Akhiyat

Dr. Sophia M. Akhiyat

Dr. Bilu Martin is a board-certified dermatologist in private practice at Premier Dermatology, MD, in Aventura, Florida. More diagnostic cases are available at mdedge.com/dermatology. To submit a case for possible publication, send an email to [email protected].

References

J Am Acad Dermatol. 2014 May;70(5):Supplement 1AB118. doi: 10.1016/j.jaad.2014.01.491.

Michels A, Michels N. Am Fam Physician. 2014 Apr 1;89(7):563-568.

Kauzman A et al. J Can Dent Assoc. 2004 Nov;70(10):682-683.

Primary adrenal insufficiency (Addison’s disease) results from a dysfunction of the adrenal glands, which may be secondary to autoimmune diseases, genetic conditions, infections, and vasculopathies,or may be drug-induced (e.g. checkpoint inhibitors), among others . In contrast, secondary adrenal insufficiency results from pituitary dysfunction of low adrenocorticotropic hormone (ACTH). The most common cause of primary adrenal insufficiency in developed countries is autoimmune adrenalitis, which accounts for upwards of 90% of cases. Typically, 21-hydroxylase autoantibodies are identified and account for destruction of the adrenal cortex through cell-mediated and humoral immune responses.

Dr. Sophia M. Akhiyat

Dr. Sophia M. Akhiyat

Dr. Bilu Martin is a board-certified dermatologist in private practice at Premier Dermatology, MD, in Aventura, Florida. More diagnostic cases are available at mdedge.com/dermatology. To submit a case for possible publication, send an email to [email protected].

References

J Am Acad Dermatol. 2014 May;70(5):Supplement 1AB118. doi: 10.1016/j.jaad.2014.01.491.

Michels A, Michels N. Am Fam Physician. 2014 Apr 1;89(7):563-568.

Kauzman A et al. J Can Dent Assoc. 2004 Nov;70(10):682-683.

Plant-based diets have become increasingly popular over the last decade as the evidence supporting their health benefits becomes stronger. 

Research pooled from nearly 100 studies has indicated that people who adhere to a vegan diet (ie, completely devoid of animal products) or a vegetarian diet (ie, devoid of meat, but may include dairy and eggs) are able to ward off some chronic diseases, such as cardiovascular disease, optimize glycemic control, and decrease their risk for cancer compared with those who consume omnivorous diets. 

Vegan and vegetarian diets, or flexitarian diets — which are less reliant on animal protein than the standard US diet but do not completely exclude meat, fish, eggs, or dairy — may promote homeostasis and decrease inflammation by providing more fiber, antioxidants, and unsaturated fatty acids than the typical Western diet. 
 

Inflammation and Obesity

Adipose tissue is a major producer of pro-inflammatory cytokines like interleukin (IL)-6, whose presence then triggers a rush of acute-phase reactants such as C-reactive protein (CRP) by the liver. This process develops into chronic low-grade inflammation that can increase a person’s chances of developing diabetes, cardiovascular disease, kidney disease, metabolic syndrome, and related complications.

Adopting a plant-based diet can improve markers of chronic low-grade inflammation that can lead to chronic disease and worsen existent chronic disease. A meta-analysis of 29 studies encompassing nearly 2700 participants found that initiation of a plant-based diet showed significant improvement in CRP, IL-6, and soluble intercellular adhesion molecule 1. 

If we want to prevent these inflammatory disease states and their complications, the obvious response is to counsel patients to avoid excessive weight gain or to lose weight if obesity is their baseline. This can be tough for some patients, but it is nonetheless an important step in chronic disease prevention and management.
 

Plant-Based Diet for Type 2 Diabetes

According to a review of nine studies of patients living with type 2 diabetes who adhered to a plant-based diet, all but one found that this approach led to significantly lower A1c values than those seen in control groups. Six of the included studies reported that participants were able to decrease or discontinue medications for the management of diabetes. Researchers across all included studies also noted a decrease in total cholesterol, low-density lipoprotein cholesterol, and triglycerides, as well as increased weight loss in participants in each intervention group. 

Such improvements are probably the result of the increase in fiber intake that occurs with a plant-based diet. A high-fiber diet is known to promote improved glucose and lipid metabolism as well as weight loss. 

It is also worth noting that participants in the intervention groups also experienced improvements in depression and less chronic pain than did those in the control groups. 
 

Plant-Based Diet for Chronic Kidney Disease (CKD)

Although the use of a plant-based diet in the prevention of CKD is well documented, adopting such diets for the treatment of CKD may intimidate both patients and practitioners owing to the high potassium and phosphorus content of many fruits and vegetables.

However, research indicates that the bioavailability of both potassium and phosphorus is lower in plant-based, whole foods than in preservatives and the highly processed food items that incorporate them. This makes a plant-based diet more viable than previously thought. 

Diets rich in vegetables, whole grains, nuts, and legumes have been shown to decrease dietary acid load, both preventing and treating metabolic acidosis. Such diets have also been shown to decrease blood pressure and the risk for a decline in estimated glomerular filtration rate. This type of diet would also prioritize the unsaturated fatty acids and fiber-rich proteins such as avocados, beans, and nuts shown to improve dyslipidemia, which may occur alongside CKD.
 

Realistic Options for Patients on Medical Diets

There is one question that I always seem to get from when recommending a plant-based diet: “These patients already have so many restrictions. Why would you add more?” And my answer is also always the same: I don’t. 

I rarely, if ever, recommend completely cutting out any food item or food group. Instead, I ask the patient to increase their intake of plant-based foods and only limit highly processed foods and fatty meats. By shifting a patient’s focus to beans; nuts; and low-carbohydrate, high-fiber fruits and vegetables, I am often opening up a whole new world of possibilities. 

Instead of a sandwich with low-sodium turkey and cheese on white bread with a side of unsalted pretzels, I recommend a caprese salad with blueberries and almonds or a Southwest salad with black beans, corn, and avocado. I don’t encourage my patients to skip the foods that they love, but instead to only think about all the delicious plant-based options that will provide them with more than just calories.

Meat, dairy, seafood, and eggs can certainly be a part of a healthy diet, but what if our chronically ill patients, especially those with diabetes, had more options than just grilled chicken and green beans for every meal? What if we focus on decreasing dietary restrictions, incorporating a variety of nourishing foods, and educating our patients, instead of on portion control and moderation? 

This is how I choose to incorporate plant-based diets into my practice to treat and prevent these chronic inflammatory conditions and promote sustainable, realistic change in my clients’ health.

Brandy Winfree Root, a renal dietitian in private practice in Mary Esther, Florida, has disclosed no relevant financial relationships.

A version of this article appeared on Medscape.com.

Plant-based diets have become increasingly popular over the last decade as the evidence supporting their health benefits becomes stronger. 

Research pooled from nearly 100 studies has indicated that people who adhere to a vegan diet (ie, completely devoid of animal products) or a vegetarian diet (ie, devoid of meat, but may include dairy and eggs) are able to ward off some chronic diseases, such as cardiovascular disease, optimize glycemic control, and decrease their risk for cancer compared with those who consume omnivorous diets. 

Vegan and vegetarian diets, or flexitarian diets — which are less reliant on animal protein than the standard US diet but do not completely exclude meat, fish, eggs, or dairy — may promote homeostasis and decrease inflammation by providing more fiber, antioxidants, and unsaturated fatty acids than the typical Western diet. 
 

Inflammation and Obesity

Adipose tissue is a major producer of pro-inflammatory cytokines like interleukin (IL)-6, whose presence then triggers a rush of acute-phase reactants such as C-reactive protein (CRP) by the liver. This process develops into chronic low-grade inflammation that can increase a person’s chances of developing diabetes, cardiovascular disease, kidney disease, metabolic syndrome, and related complications.

Adopting a plant-based diet can improve markers of chronic low-grade inflammation that can lead to chronic disease and worsen existent chronic disease. A meta-analysis of 29 studies encompassing nearly 2700 participants found that initiation of a plant-based diet showed significant improvement in CRP, IL-6, and soluble intercellular adhesion molecule 1. 

If we want to prevent these inflammatory disease states and their complications, the obvious response is to counsel patients to avoid excessive weight gain or to lose weight if obesity is their baseline. This can be tough for some patients, but it is nonetheless an important step in chronic disease prevention and management.
 

Plant-Based Diet for Type 2 Diabetes

According to a review of nine studies of patients living with type 2 diabetes who adhered to a plant-based diet, all but one found that this approach led to significantly lower A1c values than those seen in control groups. Six of the included studies reported that participants were able to decrease or discontinue medications for the management of diabetes. Researchers across all included studies also noted a decrease in total cholesterol, low-density lipoprotein cholesterol, and triglycerides, as well as increased weight loss in participants in each intervention group. 

Such improvements are probably the result of the increase in fiber intake that occurs with a plant-based diet. A high-fiber diet is known to promote improved glucose and lipid metabolism as well as weight loss. 

It is also worth noting that participants in the intervention groups also experienced improvements in depression and less chronic pain than did those in the control groups. 
 

Plant-Based Diet for Chronic Kidney Disease (CKD)

Although the use of a plant-based diet in the prevention of CKD is well documented, adopting such diets for the treatment of CKD may intimidate both patients and practitioners owing to the high potassium and phosphorus content of many fruits and vegetables.

However, research indicates that the bioavailability of both potassium and phosphorus is lower in plant-based, whole foods than in preservatives and the highly processed food items that incorporate them. This makes a plant-based diet more viable than previously thought. 

Diets rich in vegetables, whole grains, nuts, and legumes have been shown to decrease dietary acid load, both preventing and treating metabolic acidosis. Such diets have also been shown to decrease blood pressure and the risk for a decline in estimated glomerular filtration rate. This type of diet would also prioritize the unsaturated fatty acids and fiber-rich proteins such as avocados, beans, and nuts shown to improve dyslipidemia, which may occur alongside CKD.
 

Realistic Options for Patients on Medical Diets

There is one question that I always seem to get from when recommending a plant-based diet: “These patients already have so many restrictions. Why would you add more?” And my answer is also always the same: I don’t. 

I rarely, if ever, recommend completely cutting out any food item or food group. Instead, I ask the patient to increase their intake of plant-based foods and only limit highly processed foods and fatty meats. By shifting a patient’s focus to beans; nuts; and low-carbohydrate, high-fiber fruits and vegetables, I am often opening up a whole new world of possibilities. 

Instead of a sandwich with low-sodium turkey and cheese on white bread with a side of unsalted pretzels, I recommend a caprese salad with blueberries and almonds or a Southwest salad with black beans, corn, and avocado. I don’t encourage my patients to skip the foods that they love, but instead to only think about all the delicious plant-based options that will provide them with more than just calories.

Meat, dairy, seafood, and eggs can certainly be a part of a healthy diet, but what if our chronically ill patients, especially those with diabetes, had more options than just grilled chicken and green beans for every meal? What if we focus on decreasing dietary restrictions, incorporating a variety of nourishing foods, and educating our patients, instead of on portion control and moderation? 

This is how I choose to incorporate plant-based diets into my practice to treat and prevent these chronic inflammatory conditions and promote sustainable, realistic change in my clients’ health.

Brandy Winfree Root, a renal dietitian in private practice in Mary Esther, Florida, has disclosed no relevant financial relationships.

A version of this article appeared on Medscape.com.

Plant-based diets have become increasingly popular over the last decade as the evidence supporting their health benefits becomes stronger. 

Research pooled from nearly 100 studies has indicated that people who adhere to a vegan diet (ie, completely devoid of animal products) or a vegetarian diet (ie, devoid of meat, but may include dairy and eggs) are able to ward off some chronic diseases, such as cardiovascular disease, optimize glycemic control, and decrease their risk for cancer compared with those who consume omnivorous diets. 

Vegan and vegetarian diets, or flexitarian diets — which are less reliant on animal protein than the standard US diet but do not completely exclude meat, fish, eggs, or dairy — may promote homeostasis and decrease inflammation by providing more fiber, antioxidants, and unsaturated fatty acids than the typical Western diet. 
 

Inflammation and Obesity

Adipose tissue is a major producer of pro-inflammatory cytokines like interleukin (IL)-6, whose presence then triggers a rush of acute-phase reactants such as C-reactive protein (CRP) by the liver. This process develops into chronic low-grade inflammation that can increase a person’s chances of developing diabetes, cardiovascular disease, kidney disease, metabolic syndrome, and related complications.

Adopting a plant-based diet can improve markers of chronic low-grade inflammation that can lead to chronic disease and worsen existent chronic disease. A meta-analysis of 29 studies encompassing nearly 2700 participants found that initiation of a plant-based diet showed significant improvement in CRP, IL-6, and soluble intercellular adhesion molecule 1. 

If we want to prevent these inflammatory disease states and their complications, the obvious response is to counsel patients to avoid excessive weight gain or to lose weight if obesity is their baseline. This can be tough for some patients, but it is nonetheless an important step in chronic disease prevention and management.
 

Plant-Based Diet for Type 2 Diabetes

According to a review of nine studies of patients living with type 2 diabetes who adhered to a plant-based diet, all but one found that this approach led to significantly lower A1c values than those seen in control groups. Six of the included studies reported that participants were able to decrease or discontinue medications for the management of diabetes. Researchers across all included studies also noted a decrease in total cholesterol, low-density lipoprotein cholesterol, and triglycerides, as well as increased weight loss in participants in each intervention group. 

Such improvements are probably the result of the increase in fiber intake that occurs with a plant-based diet. A high-fiber diet is known to promote improved glucose and lipid metabolism as well as weight loss. 

It is also worth noting that participants in the intervention groups also experienced improvements in depression and less chronic pain than did those in the control groups. 
 

Plant-Based Diet for Chronic Kidney Disease (CKD)

Although the use of a plant-based diet in the prevention of CKD is well documented, adopting such diets for the treatment of CKD may intimidate both patients and practitioners owing to the high potassium and phosphorus content of many fruits and vegetables.

However, research indicates that the bioavailability of both potassium and phosphorus is lower in plant-based, whole foods than in preservatives and the highly processed food items that incorporate them. This makes a plant-based diet more viable than previously thought. 

Diets rich in vegetables, whole grains, nuts, and legumes have been shown to decrease dietary acid load, both preventing and treating metabolic acidosis. Such diets have also been shown to decrease blood pressure and the risk for a decline in estimated glomerular filtration rate. This type of diet would also prioritize the unsaturated fatty acids and fiber-rich proteins such as avocados, beans, and nuts shown to improve dyslipidemia, which may occur alongside CKD.
 

Realistic Options for Patients on Medical Diets

There is one question that I always seem to get from when recommending a plant-based diet: “These patients already have so many restrictions. Why would you add more?” And my answer is also always the same: I don’t. 

I rarely, if ever, recommend completely cutting out any food item or food group. Instead, I ask the patient to increase their intake of plant-based foods and only limit highly processed foods and fatty meats. By shifting a patient’s focus to beans; nuts; and low-carbohydrate, high-fiber fruits and vegetables, I am often opening up a whole new world of possibilities. 

Instead of a sandwich with low-sodium turkey and cheese on white bread with a side of unsalted pretzels, I recommend a caprese salad with blueberries and almonds or a Southwest salad with black beans, corn, and avocado. I don’t encourage my patients to skip the foods that they love, but instead to only think about all the delicious plant-based options that will provide them with more than just calories.

Meat, dairy, seafood, and eggs can certainly be a part of a healthy diet, but what if our chronically ill patients, especially those with diabetes, had more options than just grilled chicken and green beans for every meal? What if we focus on decreasing dietary restrictions, incorporating a variety of nourishing foods, and educating our patients, instead of on portion control and moderation? 

This is how I choose to incorporate plant-based diets into my practice to treat and prevent these chronic inflammatory conditions and promote sustainable, realistic change in my clients’ health.

Brandy Winfree Root, a renal dietitian in private practice in Mary Esther, Florida, has disclosed no relevant financial relationships.

A version of this article appeared on Medscape.com.

This October, millions of Americans missed out on two of the most spectacular shows in the universe: the northern lights and a rare comet. Even if you were aware of them, light pollution made them difficult to see, unless you went to a dark area and let your eyes adjust.

It’s not getting any easier — the night sky over North America has been growing brighter by about 10% per year since 2011. More and more research is linking all that light pollution to a surprising range of health consequences: cancer, heart disease, diabetes, Alzheimer’s disease, and even low sperm quality, though the reasons for these troubling associations are not always clear. 

“We’ve lost the contrast between light and dark, and we are confusing our physiology on a regular basis,” said John Hanifin, PhD, associate director of Thomas Jefferson University’s Light Research Program. 

Our own galaxy is invisible to nearly 80% of people in North America. In 1994, an earthquake-triggered blackout in Los Angeles led to calls to the Griffith Observatory from people wondering about that hazy blob of light in the night sky. It was the Milky Way.

Glaring headlights, illuminated buildings, blazing billboards, and streetlights fill our urban skies with a glow that even affects rural residents. Inside, since the invention of the lightbulb, we’ve kept our homes bright at night. Now, we’ve also added blue light-emitting devices — smartphones, television screens, tablets — which have been linked to sleep problems.

But outdoor light may matter for our health, too. “Every photon counts,” Hanifin said. 
 

Bright Lights, Big Problems

For one 2024 study researchers used satellite data to measure light pollution at residential addresses of over 13,000 people. They found that those who lived in places with the brightest skies at night had a 31% higher risk of high blood pressure. Another study out of Hong Kong showed a 29% higher risk of death from coronary heart disease. And yet another found a 17%higher risk of cerebrovascular disease, such as strokes or brain aneurysms. 

Of course, urban areas also have air pollution, noise, and a lack of greenery. So, for some studies, scientists controlled for these factors, and the correlation remained strong (although air pollution with fine particulate matter appeared to be worse for heart health than outdoor light). 

Research has found links between the nighttime glow outside and other diseases:

Breast cancer. “It’s a very strong correlation,” said Randy Nelson, PhD, a neuroscientist at West Virginia University. A study of over 100,000 teachers in California revealed that women living in areas with the most light pollution had a 12%higher risk. That effect is comparable to increasing your intake of ultra-processed foods by 10%. 

Alzheimer’s disease. In a study published this fall, outdoor light at night was more strongly linked to the disease than even alcohol misuse or obesity.

Diabetes. In one recent study, people living in the most illuminated areas had a 28% higher risk of diabetes than those residing in much darker places. In a country like China, scientists concluded that 9 million cases of diabetes could be linked to light pollution. 
 

What Happens in Your Body When You’re Exposed to Light at Night

Research has revealed that light at night (indoors or out) disrupts circadian clocks, increases inflammation, affects cell division, and suppresses melatonin, the “hormone of darkness.” “Darkness is very important,” Hanifin said. When he and his colleagues decades ago started studying the effects of light on human physiology, “people thought we were borderline crazy,” he said.

Nighttime illumination affects the health and behavior of species as diverse as Siberian hamsters, zebra finches, mice, crickets, and mosquitoes. Like most creatures on Earth, humans have internal clocks that are synced to the 24-hour cycle of day and night. The master clock is in your hypothalamus, a diamond-shaped part of the brain, but every cell in your body has its own clock, too. Many physiological processes run on circadian rhythms (a term derived from a Latin phrase meaning “about a day”), from sleep-wake cycle to hormone secretion, as well as processes involved in cancer progression, such as cell division.

“There are special photoreceptors in the eye that don’t deal with visual information. They just send light information,” Nelson said. “If you get light at the wrong time, you’re resetting the clocks.” 

This internal clock “prepares the body for various recurrent challenges, such as eating,” said Christian Benedict, PhD, a sleep researcher at Uppsala University, Sweden. “Light exposure [at night] can mess up this very important system.” This could mean, for instance, that your insulin is released at the wrong time, Benedict said, causing “a jet lag-ish condition that will then impair the ability to handle blood sugar.” Animal studies confirm that exposure to light at night can reduce glucose tolerance and alter insulin secretion – potential pathways to diabetes.

The hormone melatonin, produced when it’s dark by the pineal gland in the brain, is a key player in this modern struggle. Melatonin helps you sleep, synchronizes the body’s circadian rhythms, protects neurons from damage, regulates the immune system, and fights inflammation. But even a sliver of light at night can suppress its secretion. Less than 30 lux of light, about the level of a pedestrian street at night, can slash melatonin by half. 

When lab animals are exposed to nighttime light, they “show enormous neuroinflammation” — that is, inflammation of nervous tissue, Nelson said. In one experiment on humans, those who slept immersed in weak light had higher levels of C-reactive protein in their blood, a marker of inflammation.

Low melatonin has also been linked to cancer. It “allows the metabolic machinery of the cancer cells to be active,” Hanifin said. One of melatonin’s effects is stimulation of natural killer cells, which can recognize and destroy cancer cells. What’s more, when melatonin plunges, estrogen may go up, which could explain the link between light at night and breast cancer (estrogen fuels tumor growth in breast cancers). 

Researchers concede that satellite data might be too coarse to estimate how much light people are actually exposed to while they sleep. Plus, many of us are staring at bright screens. “But the studies keep coming,” Nelson said, suggesting that outdoor light pollution does have an impact. 

When researchers put wrist-worn light sensors on over 80,000 British people, they found that the more light the device registered between half-past midnight and 6 a.m., the more its wearer was at risk of having diabetes several years down the road — no matter how long they’ve actually slept. This, according to the study’s authors, supports the findings of satellite data.

A similar study that used actigraphy with built-in light sensors, measuring whether people had been sleeping in complete darkness for at least five hours, found that light pollution upped the risk of heart disease by 74%.
 

What Can You Do About This?

Not everyone’s melatonin is affected by nighttime light to the same degree. “Some people are very much sensitive to very dim light, whereas others are not as sensitive and need far, far more light stimulation [to impact melatonin],” Benedict said. In one study, some volunteers needed 350 lux to lower their melatonin by half. For such people, flipping on the light in the bathroom at night wouldn’t matter; for others, though, a mere 6 lux was already as harmful – which is darker than twilight. 

You can protect yourself by keeping your bedroom lights off and your screens stashed away, but avoiding outdoor light pollution may be harder. You can invest in high-quality blackout curtains, of course, although some light may still seep inside. You can plant trees in front of your windows, reorient any motion-detector lights, and even petition your local government to reduce over-illumination of buildings and to choose better streetlights. You can support organizations, such as the International Dark-Sky Association, that work to preserve darkness.

Last but not least, you might want to change your habits. If you live in a particularly light-polluted area, such as the District of Columbia, America’s top place for urban blaze, you might reconsider late-night walks or drives around the neighborhood. Instead, Hanifin said, read a book in bed, while keeping the light “as dim as you can.” It’s “a much better idea versus being outside in midtown Manhattan,” he said. According to recent recommendations published by Hanifin and his colleagues, when you sleep, there should be no more than 1 lux of illumination at the level of your eyes — about as much as you’d get from having a lit candle 1 meter away. 

And if we manage to preserve outdoor darkness, and the stars reappear (including the breathtaking Milky Way), we could reap more benefits — some research suggests that stargazing can elicit positive emotions, a sense of personal growth, and “a variety of transcendent thoughts and experiences.” 
 

A version of this article appeared on WebMD.com.

This October, millions of Americans missed out on two of the most spectacular shows in the universe: the northern lights and a rare comet. Even if you were aware of them, light pollution made them difficult to see, unless you went to a dark area and let your eyes adjust.

It’s not getting any easier — the night sky over North America has been growing brighter by about 10% per year since 2011. More and more research is linking all that light pollution to a surprising range of health consequences: cancer, heart disease, diabetes, Alzheimer’s disease, and even low sperm quality, though the reasons for these troubling associations are not always clear. 

“We’ve lost the contrast between light and dark, and we are confusing our physiology on a regular basis,” said John Hanifin, PhD, associate director of Thomas Jefferson University’s Light Research Program. 

Our own galaxy is invisible to nearly 80% of people in North America. In 1994, an earthquake-triggered blackout in Los Angeles led to calls to the Griffith Observatory from people wondering about that hazy blob of light in the night sky. It was the Milky Way.

Glaring headlights, illuminated buildings, blazing billboards, and streetlights fill our urban skies with a glow that even affects rural residents. Inside, since the invention of the lightbulb, we’ve kept our homes bright at night. Now, we’ve also added blue light-emitting devices — smartphones, television screens, tablets — which have been linked to sleep problems.

But outdoor light may matter for our health, too. “Every photon counts,” Hanifin said. 
 

Bright Lights, Big Problems

For one 2024 study researchers used satellite data to measure light pollution at residential addresses of over 13,000 people. They found that those who lived in places with the brightest skies at night had a 31% higher risk of high blood pressure. Another study out of Hong Kong showed a 29% higher risk of death from coronary heart disease. And yet another found a 17%higher risk of cerebrovascular disease, such as strokes or brain aneurysms. 

Of course, urban areas also have air pollution, noise, and a lack of greenery. So, for some studies, scientists controlled for these factors, and the correlation remained strong (although air pollution with fine particulate matter appeared to be worse for heart health than outdoor light). 

Research has found links between the nighttime glow outside and other diseases:

Breast cancer. “It’s a very strong correlation,” said Randy Nelson, PhD, a neuroscientist at West Virginia University. A study of over 100,000 teachers in California revealed that women living in areas with the most light pollution had a 12%higher risk. That effect is comparable to increasing your intake of ultra-processed foods by 10%. 

Alzheimer’s disease. In a study published this fall, outdoor light at night was more strongly linked to the disease than even alcohol misuse or obesity.

Diabetes. In one recent study, people living in the most illuminated areas had a 28% higher risk of diabetes than those residing in much darker places. In a country like China, scientists concluded that 9 million cases of diabetes could be linked to light pollution. 
 

What Happens in Your Body When You’re Exposed to Light at Night

Research has revealed that light at night (indoors or out) disrupts circadian clocks, increases inflammation, affects cell division, and suppresses melatonin, the “hormone of darkness.” “Darkness is very important,” Hanifin said. When he and his colleagues decades ago started studying the effects of light on human physiology, “people thought we were borderline crazy,” he said.

Nighttime illumination affects the health and behavior of species as diverse as Siberian hamsters, zebra finches, mice, crickets, and mosquitoes. Like most creatures on Earth, humans have internal clocks that are synced to the 24-hour cycle of day and night. The master clock is in your hypothalamus, a diamond-shaped part of the brain, but every cell in your body has its own clock, too. Many physiological processes run on circadian rhythms (a term derived from a Latin phrase meaning “about a day”), from sleep-wake cycle to hormone secretion, as well as processes involved in cancer progression, such as cell division.

“There are special photoreceptors in the eye that don’t deal with visual information. They just send light information,” Nelson said. “If you get light at the wrong time, you’re resetting the clocks.” 

This internal clock “prepares the body for various recurrent challenges, such as eating,” said Christian Benedict, PhD, a sleep researcher at Uppsala University, Sweden. “Light exposure [at night] can mess up this very important system.” This could mean, for instance, that your insulin is released at the wrong time, Benedict said, causing “a jet lag-ish condition that will then impair the ability to handle blood sugar.” Animal studies confirm that exposure to light at night can reduce glucose tolerance and alter insulin secretion – potential pathways to diabetes.

The hormone melatonin, produced when it’s dark by the pineal gland in the brain, is a key player in this modern struggle. Melatonin helps you sleep, synchronizes the body’s circadian rhythms, protects neurons from damage, regulates the immune system, and fights inflammation. But even a sliver of light at night can suppress its secretion. Less than 30 lux of light, about the level of a pedestrian street at night, can slash melatonin by half. 

When lab animals are exposed to nighttime light, they “show enormous neuroinflammation” — that is, inflammation of nervous tissue, Nelson said. In one experiment on humans, those who slept immersed in weak light had higher levels of C-reactive protein in their blood, a marker of inflammation.

Low melatonin has also been linked to cancer. It “allows the metabolic machinery of the cancer cells to be active,” Hanifin said. One of melatonin’s effects is stimulation of natural killer cells, which can recognize and destroy cancer cells. What’s more, when melatonin plunges, estrogen may go up, which could explain the link between light at night and breast cancer (estrogen fuels tumor growth in breast cancers). 

Researchers concede that satellite data might be too coarse to estimate how much light people are actually exposed to while they sleep. Plus, many of us are staring at bright screens. “But the studies keep coming,” Nelson said, suggesting that outdoor light pollution does have an impact. 

When researchers put wrist-worn light sensors on over 80,000 British people, they found that the more light the device registered between half-past midnight and 6 a.m., the more its wearer was at risk of having diabetes several years down the road — no matter how long they’ve actually slept. This, according to the study’s authors, supports the findings of satellite data.

A similar study that used actigraphy with built-in light sensors, measuring whether people had been sleeping in complete darkness for at least five hours, found that light pollution upped the risk of heart disease by 74%.
 

What Can You Do About This?

Not everyone’s melatonin is affected by nighttime light to the same degree. “Some people are very much sensitive to very dim light, whereas others are not as sensitive and need far, far more light stimulation [to impact melatonin],” Benedict said. In one study, some volunteers needed 350 lux to lower their melatonin by half. For such people, flipping on the light in the bathroom at night wouldn’t matter; for others, though, a mere 6 lux was already as harmful – which is darker than twilight. 

You can protect yourself by keeping your bedroom lights off and your screens stashed away, but avoiding outdoor light pollution may be harder. You can invest in high-quality blackout curtains, of course, although some light may still seep inside. You can plant trees in front of your windows, reorient any motion-detector lights, and even petition your local government to reduce over-illumination of buildings and to choose better streetlights. You can support organizations, such as the International Dark-Sky Association, that work to preserve darkness.

Last but not least, you might want to change your habits. If you live in a particularly light-polluted area, such as the District of Columbia, America’s top place for urban blaze, you might reconsider late-night walks or drives around the neighborhood. Instead, Hanifin said, read a book in bed, while keeping the light “as dim as you can.” It’s “a much better idea versus being outside in midtown Manhattan,” he said. According to recent recommendations published by Hanifin and his colleagues, when you sleep, there should be no more than 1 lux of illumination at the level of your eyes — about as much as you’d get from having a lit candle 1 meter away. 

And if we manage to preserve outdoor darkness, and the stars reappear (including the breathtaking Milky Way), we could reap more benefits — some research suggests that stargazing can elicit positive emotions, a sense of personal growth, and “a variety of transcendent thoughts and experiences.” 
 

A version of this article appeared on WebMD.com.

This October, millions of Americans missed out on two of the most spectacular shows in the universe: the northern lights and a rare comet. Even if you were aware of them, light pollution made them difficult to see, unless you went to a dark area and let your eyes adjust.

It’s not getting any easier — the night sky over North America has been growing brighter by about 10% per year since 2011. More and more research is linking all that light pollution to a surprising range of health consequences: cancer, heart disease, diabetes, Alzheimer’s disease, and even low sperm quality, though the reasons for these troubling associations are not always clear. 

“We’ve lost the contrast between light and dark, and we are confusing our physiology on a regular basis,” said John Hanifin, PhD, associate director of Thomas Jefferson University’s Light Research Program. 

Our own galaxy is invisible to nearly 80% of people in North America. In 1994, an earthquake-triggered blackout in Los Angeles led to calls to the Griffith Observatory from people wondering about that hazy blob of light in the night sky. It was the Milky Way.

Glaring headlights, illuminated buildings, blazing billboards, and streetlights fill our urban skies with a glow that even affects rural residents. Inside, since the invention of the lightbulb, we’ve kept our homes bright at night. Now, we’ve also added blue light-emitting devices — smartphones, television screens, tablets — which have been linked to sleep problems.

But outdoor light may matter for our health, too. “Every photon counts,” Hanifin said. 
 

Bright Lights, Big Problems

For one 2024 study researchers used satellite data to measure light pollution at residential addresses of over 13,000 people. They found that those who lived in places with the brightest skies at night had a 31% higher risk of high blood pressure. Another study out of Hong Kong showed a 29% higher risk of death from coronary heart disease. And yet another found a 17%higher risk of cerebrovascular disease, such as strokes or brain aneurysms. 

Of course, urban areas also have air pollution, noise, and a lack of greenery. So, for some studies, scientists controlled for these factors, and the correlation remained strong (although air pollution with fine particulate matter appeared to be worse for heart health than outdoor light). 

Research has found links between the nighttime glow outside and other diseases:

Breast cancer. “It’s a very strong correlation,” said Randy Nelson, PhD, a neuroscientist at West Virginia University. A study of over 100,000 teachers in California revealed that women living in areas with the most light pollution had a 12%higher risk. That effect is comparable to increasing your intake of ultra-processed foods by 10%. 

Alzheimer’s disease. In a study published this fall, outdoor light at night was more strongly linked to the disease than even alcohol misuse or obesity.

Diabetes. In one recent study, people living in the most illuminated areas had a 28% higher risk of diabetes than those residing in much darker places. In a country like China, scientists concluded that 9 million cases of diabetes could be linked to light pollution. 
 

What Happens in Your Body When You’re Exposed to Light at Night

Research has revealed that light at night (indoors or out) disrupts circadian clocks, increases inflammation, affects cell division, and suppresses melatonin, the “hormone of darkness.” “Darkness is very important,” Hanifin said. When he and his colleagues decades ago started studying the effects of light on human physiology, “people thought we were borderline crazy,” he said.

Nighttime illumination affects the health and behavior of species as diverse as Siberian hamsters, zebra finches, mice, crickets, and mosquitoes. Like most creatures on Earth, humans have internal clocks that are synced to the 24-hour cycle of day and night. The master clock is in your hypothalamus, a diamond-shaped part of the brain, but every cell in your body has its own clock, too. Many physiological processes run on circadian rhythms (a term derived from a Latin phrase meaning “about a day”), from sleep-wake cycle to hormone secretion, as well as processes involved in cancer progression, such as cell division.

“There are special photoreceptors in the eye that don’t deal with visual information. They just send light information,” Nelson said. “If you get light at the wrong time, you’re resetting the clocks.” 

This internal clock “prepares the body for various recurrent challenges, such as eating,” said Christian Benedict, PhD, a sleep researcher at Uppsala University, Sweden. “Light exposure [at night] can mess up this very important system.” This could mean, for instance, that your insulin is released at the wrong time, Benedict said, causing “a jet lag-ish condition that will then impair the ability to handle blood sugar.” Animal studies confirm that exposure to light at night can reduce glucose tolerance and alter insulin secretion – potential pathways to diabetes.

The hormone melatonin, produced when it’s dark by the pineal gland in the brain, is a key player in this modern struggle. Melatonin helps you sleep, synchronizes the body’s circadian rhythms, protects neurons from damage, regulates the immune system, and fights inflammation. But even a sliver of light at night can suppress its secretion. Less than 30 lux of light, about the level of a pedestrian street at night, can slash melatonin by half. 

When lab animals are exposed to nighttime light, they “show enormous neuroinflammation” — that is, inflammation of nervous tissue, Nelson said. In one experiment on humans, those who slept immersed in weak light had higher levels of C-reactive protein in their blood, a marker of inflammation.

Low melatonin has also been linked to cancer. It “allows the metabolic machinery of the cancer cells to be active,” Hanifin said. One of melatonin’s effects is stimulation of natural killer cells, which can recognize and destroy cancer cells. What’s more, when melatonin plunges, estrogen may go up, which could explain the link between light at night and breast cancer (estrogen fuels tumor growth in breast cancers). 

Researchers concede that satellite data might be too coarse to estimate how much light people are actually exposed to while they sleep. Plus, many of us are staring at bright screens. “But the studies keep coming,” Nelson said, suggesting that outdoor light pollution does have an impact. 

When researchers put wrist-worn light sensors on over 80,000 British people, they found that the more light the device registered between half-past midnight and 6 a.m., the more its wearer was at risk of having diabetes several years down the road — no matter how long they’ve actually slept. This, according to the study’s authors, supports the findings of satellite data.

A similar study that used actigraphy with built-in light sensors, measuring whether people had been sleeping in complete darkness for at least five hours, found that light pollution upped the risk of heart disease by 74%.
 

What Can You Do About This?

Not everyone’s melatonin is affected by nighttime light to the same degree. “Some people are very much sensitive to very dim light, whereas others are not as sensitive and need far, far more light stimulation [to impact melatonin],” Benedict said. In one study, some volunteers needed 350 lux to lower their melatonin by half. For such people, flipping on the light in the bathroom at night wouldn’t matter; for others, though, a mere 6 lux was already as harmful – which is darker than twilight. 

You can protect yourself by keeping your bedroom lights off and your screens stashed away, but avoiding outdoor light pollution may be harder. You can invest in high-quality blackout curtains, of course, although some light may still seep inside. You can plant trees in front of your windows, reorient any motion-detector lights, and even petition your local government to reduce over-illumination of buildings and to choose better streetlights. You can support organizations, such as the International Dark-Sky Association, that work to preserve darkness.

Last but not least, you might want to change your habits. If you live in a particularly light-polluted area, such as the District of Columbia, America’s top place for urban blaze, you might reconsider late-night walks or drives around the neighborhood. Instead, Hanifin said, read a book in bed, while keeping the light “as dim as you can.” It’s “a much better idea versus being outside in midtown Manhattan,” he said. According to recent recommendations published by Hanifin and his colleagues, when you sleep, there should be no more than 1 lux of illumination at the level of your eyes — about as much as you’d get from having a lit candle 1 meter away. 

And if we manage to preserve outdoor darkness, and the stars reappear (including the breathtaking Milky Way), we could reap more benefits — some research suggests that stargazing can elicit positive emotions, a sense of personal growth, and “a variety of transcendent thoughts and experiences.” 
 

A version of this article appeared on WebMD.com.

TOPLINE: 

More than half of the US peer reviewers for four major medical journals received industry payments between 2020-2022, new research shows. Altogether they received more than $64 million in general, non-research payments, with a median payment per physician of $7614. Research payments — including money paid directly to physicians as well as funds related to research for which a physician was registered as a principal investigator — exceeded $1 billion.

METHODOLOGY:

• Researchers identified peer reviewers in 2022 for The BMJ, JAMA, The Lancet, and The New England Journal of Medicine using each journal’s list of reviewers for that year. They included 1962 US-based physicians in their analysis.
• General and research payments made to the peer reviewers between 2020-2022 were extracted from the Open Payments database.

TAKEAWAY:

• Nearly 59% of the peer reviewers received industry payments between 2020-2022.
• Payments included $34.31 million in consulting fees and $11.8 million for speaking compensation unrelated to continuing medical education programs.
• Male reviewers received a significantly higher median total payment than did female reviewers ($38,959 vs $19,586). General payments were higher for men as well ($8663 vs $4183).
• For comparison, the median general payment to all physicians in 2018 was $216, the researchers noted.

IN PRACTICE:

“Additional research and transparency regarding industry payments in the peer review process are needed,” the authors of the study wrote.

SOURCE:

Christopher J. D. Wallis, MD, PhD, with the division of urology at the University of Toronto, Canada, was the corresponding author for the study. The article was published online October 10 in JAMA.

LIMITATIONS: 

Whether the financial ties were relevant to any of the papers that the peer reviewers critiqued is not known. Some reviewers might have received additional payments from insurance and technology companies that were not captured in this study. The findings might not apply to other journals, the researchers noted. 

DISCLOSURES:

Wallis disclosed personal fees from Janssen Oncology, Nanostics, Precision Point Specialty, Sesen Bio, AbbVie, Astellas, AstraZeneca, Bayer, EMD Serono, Knight Therapeutics, Merck, Science and Medicine Canada, TerSera, and Tolmar. He and some coauthors also disclosed support and grants from foundations and government institutions.

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 appeared on Medscape.com.

TOPLINE: 

More than half of the US peer reviewers for four major medical journals received industry payments between 2020-2022, new research shows. Altogether they received more than $64 million in general, non-research payments, with a median payment per physician of $7614. Research payments — including money paid directly to physicians as well as funds related to research for which a physician was registered as a principal investigator — exceeded $1 billion.

METHODOLOGY:

• Researchers identified peer reviewers in 2022 for The BMJ, JAMA, The Lancet, and The New England Journal of Medicine using each journal’s list of reviewers for that year. They included 1962 US-based physicians in their analysis.
• General and research payments made to the peer reviewers between 2020-2022 were extracted from the Open Payments database.

TAKEAWAY:

• Nearly 59% of the peer reviewers received industry payments between 2020-2022.
• Payments included $34.31 million in consulting fees and $11.8 million for speaking compensation unrelated to continuing medical education programs.
• Male reviewers received a significantly higher median total payment than did female reviewers ($38,959 vs $19,586). General payments were higher for men as well ($8663 vs $4183).
• For comparison, the median general payment to all physicians in 2018 was $216, the researchers noted.

IN PRACTICE:

“Additional research and transparency regarding industry payments in the peer review process are needed,” the authors of the study wrote.

SOURCE:

Christopher J. D. Wallis, MD, PhD, with the division of urology at the University of Toronto, Canada, was the corresponding author for the study. The article was published online October 10 in JAMA.

LIMITATIONS: 

Whether the financial ties were relevant to any of the papers that the peer reviewers critiqued is not known. Some reviewers might have received additional payments from insurance and technology companies that were not captured in this study. The findings might not apply to other journals, the researchers noted. 

DISCLOSURES:

Wallis disclosed personal fees from Janssen Oncology, Nanostics, Precision Point Specialty, Sesen Bio, AbbVie, Astellas, AstraZeneca, Bayer, EMD Serono, Knight Therapeutics, Merck, Science and Medicine Canada, TerSera, and Tolmar. He and some coauthors also disclosed support and grants from foundations and government institutions.

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 appeared on Medscape.com.

TOPLINE: 

More than half of the US peer reviewers for four major medical journals received industry payments between 2020-2022, new research shows. Altogether they received more than $64 million in general, non-research payments, with a median payment per physician of $7614. Research payments — including money paid directly to physicians as well as funds related to research for which a physician was registered as a principal investigator — exceeded $1 billion.

METHODOLOGY:

• Researchers identified peer reviewers in 2022 for The BMJ, JAMA, The Lancet, and The New England Journal of Medicine using each journal’s list of reviewers for that year. They included 1962 US-based physicians in their analysis.
• General and research payments made to the peer reviewers between 2020-2022 were extracted from the Open Payments database.

TAKEAWAY:

• Nearly 59% of the peer reviewers received industry payments between 2020-2022.
• Payments included $34.31 million in consulting fees and $11.8 million for speaking compensation unrelated to continuing medical education programs.
• Male reviewers received a significantly higher median total payment than did female reviewers ($38,959 vs $19,586). General payments were higher for men as well ($8663 vs $4183).
• For comparison, the median general payment to all physicians in 2018 was $216, the researchers noted.

IN PRACTICE:

“Additional research and transparency regarding industry payments in the peer review process are needed,” the authors of the study wrote.

SOURCE:

Christopher J. D. Wallis, MD, PhD, with the division of urology at the University of Toronto, Canada, was the corresponding author for the study. The article was published online October 10 in JAMA.

LIMITATIONS: 

Whether the financial ties were relevant to any of the papers that the peer reviewers critiqued is not known. Some reviewers might have received additional payments from insurance and technology companies that were not captured in this study. The findings might not apply to other journals, the researchers noted. 

DISCLOSURES:

Wallis disclosed personal fees from Janssen Oncology, Nanostics, Precision Point Specialty, Sesen Bio, AbbVie, Astellas, AstraZeneca, Bayer, EMD Serono, Knight Therapeutics, Merck, Science and Medicine Canada, TerSera, and Tolmar. He and some coauthors also disclosed support and grants from foundations and government institutions.

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 appeared on Medscape.com.

Words do have power. Names have power. Words are events, they do things, change things. They transform both speaker and hearer ... They feed understanding or emotion back and forth and amplify it. — Ursula K. Le Guin
 

Every medical student should have a class in linguistics. I’m just unsure what it might replace. Maybe physiology? (When was the last time you used Fick’s or Fourier’s Laws anyway?). Even if we don’t supplant any core curriculum, it’s worth noting that we spend more time in our daily work calculating how to communicate things than calculating cardiac outputs. That we can convey so much so consistently and without specific training is a marvel. Making the diagnosis or a plan is often the easy part. The difficulty comes in trying to communicate what we know to patients such that they understand and can act on it.

Linguistics is a broad field. At its essence, it studies how we communicate. It’s fascinating how we use tone, word choice, gestures, syntax, and grammar to explain, reassure, instruct or implore patients. Medical appointments are sometimes high stakes and occur within a huge variety of circumstances. In a single day of clinic, I had a patient with dementia, and one pursuing a PhD in P-Chem. I had English speakers, second language English speakers, and a Vietnamese patient who knew no English. In just one day, I explained things to toddlers and adults, a Black woman from Oklahoma and a Jewish woman from New York. For a brief few minutes, each of them was my partner in a game of medical charades. For each one, I had to figure out how to get them to know what I’m thinking.

Dr. Benabio

I learned of this game of charades concept from a podcast featuring Morten Christiansen, professor of psychology at Cornell University, and professor in Cognitive Science of Language, at Aarhus University, Denmark. The idea is that language can be thought of as a game where speakers constantly improvise based on the topic, each one’s expertise, and the shared understanding. I found this intriguing. In his explanation, grammar and definitions are less important than the mutual understanding of what is being communicated. It helps explain the wide variations of speech even among those speaking the same language. It also flips the idea that brains are designed for language, a concept proposed by linguistic greats such as Noam Chomsky and Steven Pinker. Rather, what we call language is just the best solution our brains could create to convey information.

I thought about how each of us instinctively varies the complexity of sentences and tone of voice based on the ability of each patient to understand. Gestures, storytelling and analogies are linguistic tools we use without thinking about them. We’ve a unique communications conundrum in that we often need patients to understand a complex idea, but only have minutes to get them there. We don’t want them to panic. We also don’t want them to be so dispassionate as to not act. To speed things up, we often use a technique known as chunking, short phrases that capture an idea in one bite. For example, “soak and smear” to get atopic patients to moisturize or “scrape and burn” to describe a curettage and electrodesiccation of a basal cell carcinoma or “a stick and a burn” before injecting them (I never liked that one). These are pithy, efficient. But they don’t always work.

One afternoon I had a 93-year-old woman with glossodynia. She had dementia and her 96-year-old husband was helping. When I explained how she’d “swish and spit” her magic mouthwash, he looked perplexed. Is she swishing a wand or something? I shook my head, “No” and gestured with my hands palms down, waving back and forth. It is just a mouthwash. She should rinse, then spit it out. I lost that round.

Then a 64-year-old woman whom I had to advise that the pink bump on her arm was a cutaneous neuroendocrine tumor. Do I call it a Merkel cell carcinoma? Do I say, “You know, like the one Jimmy Buffett had?” (Nope, not a good use of storytelling). She wanted to know how she got it. Sun exposure, we think. Or, perhaps a virus. Just how does one explain a virus called MCPyV that is ubiquitous but somehow caused cancer just for you? How do you convey, “This is serious, but you might not die like Jimmy Buffett?” I had to use all my language skills to get this right.

Then there is the Henderson-Hasselbalch problem of linguistics: communicating through a translator. When doing so, I’m cognizant of choosing short, simple sentences. Subject, verb, object. First this, then that. This mitigates what’s lost in translation and reduces waiting for translations (especially when your patient is storytelling in paragraphs). But try doing this with an emotionally wrought condition like alopecia. Finding the fewest words to convey that your FSH and estrogen levels are irrelevant to your telogen effluvium to a Vietnamese speaker is tricky. “Yes, I see your primary care physician ordered these tests. No, the numbers do not matter.” Did that translate as they are normal? Or that they don’t matter because she is 54? Or that they don’t matter to me because I didn’t order them?

When you find yourself exhausted at the day’s end, perhaps you’ll better appreciate how it was not only the graduate level medicine you did today; you’ve practically got a PhD in linguistics as well. You just didn’t realize it.

Dr. Benabio is chief of dermatology at Kaiser Permanente San Diego. The opinions expressed in this column are his own and do not represent those of Kaiser Permanente. Dr. Benabio is @Dermdoc on X. Write to him at [email protected].

Words do have power. Names have power. Words are events, they do things, change things. They transform both speaker and hearer ... They feed understanding or emotion back and forth and amplify it. — Ursula K. Le Guin
 

Every medical student should have a class in linguistics. I’m just unsure what it might replace. Maybe physiology? (When was the last time you used Fick’s or Fourier’s Laws anyway?). Even if we don’t supplant any core curriculum, it’s worth noting that we spend more time in our daily work calculating how to communicate things than calculating cardiac outputs. That we can convey so much so consistently and without specific training is a marvel. Making the diagnosis or a plan is often the easy part. The difficulty comes in trying to communicate what we know to patients such that they understand and can act on it.

Linguistics is a broad field. At its essence, it studies how we communicate. It’s fascinating how we use tone, word choice, gestures, syntax, and grammar to explain, reassure, instruct or implore patients. Medical appointments are sometimes high stakes and occur within a huge variety of circumstances. In a single day of clinic, I had a patient with dementia, and one pursuing a PhD in P-Chem. I had English speakers, second language English speakers, and a Vietnamese patient who knew no English. In just one day, I explained things to toddlers and adults, a Black woman from Oklahoma and a Jewish woman from New York. For a brief few minutes, each of them was my partner in a game of medical charades. For each one, I had to figure out how to get them to know what I’m thinking.

Dr. Benabio

I learned of this game of charades concept from a podcast featuring Morten Christiansen, professor of psychology at Cornell University, and professor in Cognitive Science of Language, at Aarhus University, Denmark. The idea is that language can be thought of as a game where speakers constantly improvise based on the topic, each one’s expertise, and the shared understanding. I found this intriguing. In his explanation, grammar and definitions are less important than the mutual understanding of what is being communicated. It helps explain the wide variations of speech even among those speaking the same language. It also flips the idea that brains are designed for language, a concept proposed by linguistic greats such as Noam Chomsky and Steven Pinker. Rather, what we call language is just the best solution our brains could create to convey information.

I thought about how each of us instinctively varies the complexity of sentences and tone of voice based on the ability of each patient to understand. Gestures, storytelling and analogies are linguistic tools we use without thinking about them. We’ve a unique communications conundrum in that we often need patients to understand a complex idea, but only have minutes to get them there. We don’t want them to panic. We also don’t want them to be so dispassionate as to not act. To speed things up, we often use a technique known as chunking, short phrases that capture an idea in one bite. For example, “soak and smear” to get atopic patients to moisturize or “scrape and burn” to describe a curettage and electrodesiccation of a basal cell carcinoma or “a stick and a burn” before injecting them (I never liked that one). These are pithy, efficient. But they don’t always work.

One afternoon I had a 93-year-old woman with glossodynia. She had dementia and her 96-year-old husband was helping. When I explained how she’d “swish and spit” her magic mouthwash, he looked perplexed. Is she swishing a wand or something? I shook my head, “No” and gestured with my hands palms down, waving back and forth. It is just a mouthwash. She should rinse, then spit it out. I lost that round.

Then a 64-year-old woman whom I had to advise that the pink bump on her arm was a cutaneous neuroendocrine tumor. Do I call it a Merkel cell carcinoma? Do I say, “You know, like the one Jimmy Buffett had?” (Nope, not a good use of storytelling). She wanted to know how she got it. Sun exposure, we think. Or, perhaps a virus. Just how does one explain a virus called MCPyV that is ubiquitous but somehow caused cancer just for you? How do you convey, “This is serious, but you might not die like Jimmy Buffett?” I had to use all my language skills to get this right.

Then there is the Henderson-Hasselbalch problem of linguistics: communicating through a translator. When doing so, I’m cognizant of choosing short, simple sentences. Subject, verb, object. First this, then that. This mitigates what’s lost in translation and reduces waiting for translations (especially when your patient is storytelling in paragraphs). But try doing this with an emotionally wrought condition like alopecia. Finding the fewest words to convey that your FSH and estrogen levels are irrelevant to your telogen effluvium to a Vietnamese speaker is tricky. “Yes, I see your primary care physician ordered these tests. No, the numbers do not matter.” Did that translate as they are normal? Or that they don’t matter because she is 54? Or that they don’t matter to me because I didn’t order them?

When you find yourself exhausted at the day’s end, perhaps you’ll better appreciate how it was not only the graduate level medicine you did today; you’ve practically got a PhD in linguistics as well. You just didn’t realize it.

Dr. Benabio is chief of dermatology at Kaiser Permanente San Diego. The opinions expressed in this column are his own and do not represent those of Kaiser Permanente. Dr. Benabio is @Dermdoc on X. Write to him at [email protected].

Words do have power. Names have power. Words are events, they do things, change things. They transform both speaker and hearer ... They feed understanding or emotion back and forth and amplify it. — Ursula K. Le Guin
 

Every medical student should have a class in linguistics. I’m just unsure what it might replace. Maybe physiology? (When was the last time you used Fick’s or Fourier’s Laws anyway?). Even if we don’t supplant any core curriculum, it’s worth noting that we spend more time in our daily work calculating how to communicate things than calculating cardiac outputs. That we can convey so much so consistently and without specific training is a marvel. Making the diagnosis or a plan is often the easy part. The difficulty comes in trying to communicate what we know to patients such that they understand and can act on it.

Linguistics is a broad field. At its essence, it studies how we communicate. It’s fascinating how we use tone, word choice, gestures, syntax, and grammar to explain, reassure, instruct or implore patients. Medical appointments are sometimes high stakes and occur within a huge variety of circumstances. In a single day of clinic, I had a patient with dementia, and one pursuing a PhD in P-Chem. I had English speakers, second language English speakers, and a Vietnamese patient who knew no English. In just one day, I explained things to toddlers and adults, a Black woman from Oklahoma and a Jewish woman from New York. For a brief few minutes, each of them was my partner in a game of medical charades. For each one, I had to figure out how to get them to know what I’m thinking.

Dr. Benabio

I learned of this game of charades concept from a podcast featuring Morten Christiansen, professor of psychology at Cornell University, and professor in Cognitive Science of Language, at Aarhus University, Denmark. The idea is that language can be thought of as a game where speakers constantly improvise based on the topic, each one’s expertise, and the shared understanding. I found this intriguing. In his explanation, grammar and definitions are less important than the mutual understanding of what is being communicated. It helps explain the wide variations of speech even among those speaking the same language. It also flips the idea that brains are designed for language, a concept proposed by linguistic greats such as Noam Chomsky and Steven Pinker. Rather, what we call language is just the best solution our brains could create to convey information.

I thought about how each of us instinctively varies the complexity of sentences and tone of voice based on the ability of each patient to understand. Gestures, storytelling and analogies are linguistic tools we use without thinking about them. We’ve a unique communications conundrum in that we often need patients to understand a complex idea, but only have minutes to get them there. We don’t want them to panic. We also don’t want them to be so dispassionate as to not act. To speed things up, we often use a technique known as chunking, short phrases that capture an idea in one bite. For example, “soak and smear” to get atopic patients to moisturize or “scrape and burn” to describe a curettage and electrodesiccation of a basal cell carcinoma or “a stick and a burn” before injecting them (I never liked that one). These are pithy, efficient. But they don’t always work.

One afternoon I had a 93-year-old woman with glossodynia. She had dementia and her 96-year-old husband was helping. When I explained how she’d “swish and spit” her magic mouthwash, he looked perplexed. Is she swishing a wand or something? I shook my head, “No” and gestured with my hands palms down, waving back and forth. It is just a mouthwash. She should rinse, then spit it out. I lost that round.

Then a 64-year-old woman whom I had to advise that the pink bump on her arm was a cutaneous neuroendocrine tumor. Do I call it a Merkel cell carcinoma? Do I say, “You know, like the one Jimmy Buffett had?” (Nope, not a good use of storytelling). She wanted to know how she got it. Sun exposure, we think. Or, perhaps a virus. Just how does one explain a virus called MCPyV that is ubiquitous but somehow caused cancer just for you? How do you convey, “This is serious, but you might not die like Jimmy Buffett?” I had to use all my language skills to get this right.

Then there is the Henderson-Hasselbalch problem of linguistics: communicating through a translator. When doing so, I’m cognizant of choosing short, simple sentences. Subject, verb, object. First this, then that. This mitigates what’s lost in translation and reduces waiting for translations (especially when your patient is storytelling in paragraphs). But try doing this with an emotionally wrought condition like alopecia. Finding the fewest words to convey that your FSH and estrogen levels are irrelevant to your telogen effluvium to a Vietnamese speaker is tricky. “Yes, I see your primary care physician ordered these tests. No, the numbers do not matter.” Did that translate as they are normal? Or that they don’t matter because she is 54? Or that they don’t matter to me because I didn’t order them?

When you find yourself exhausted at the day’s end, perhaps you’ll better appreciate how it was not only the graduate level medicine you did today; you’ve practically got a PhD in linguistics as well. You just didn’t realize it.

Dr. Benabio is chief of dermatology at Kaiser Permanente San Diego. The opinions expressed in this column are his own and do not represent those of Kaiser Permanente. Dr. Benabio is @Dermdoc on X. Write to him at [email protected].

Emergencies happen anywhere, anytime, and sometimes, medical professionals find themselves in situations where they are the only ones who can help. Is There a Doctor in the House? is a Medscape Medical News series telling these stories.

I sincerely believe that what goes around comes around. Good things come to good people. And sometimes that saves lives.

My 10-year-old son was in the semifinals of the Little League district championship. And we were losing. My son is an excellent pitcher, and he had started the game. But that night, he was struggling. He just couldn’t find where to throw the ball. Needless to say, he was frustrated.

He was changed to shortstop in the second inning, and the home plate umpire walked over to him. This umpire is well known in the area for his kindness and commitment, how he encourages the kids and helps make baseball fun even when it’s stressful.

We didn’t know him well, but he was really supportive of my kid in that moment, talking to him about how baseball is a team sport and we’re here to have fun. Just being really positive.

As the game continued, I saw the umpire suddenly walk to the side of the field. I hadn’t seen it, but he had been hit by a wild pitch on the side of his neck. He was wearing protective gear, but the ball managed to bounce up the side and caught bare neck. I knew something wasn’t right.

I went down to talk to him, and my medical assistant (MA), who was also at the game, came with me. I could tell the umpire was injured, but he didn’t want to leave the game. I suggested going to the hospital, but he wouldn’t consider it. So I sat there with my arms crossed, watching him.

His symptoms got worse. I could see he was in pain, and it was getting harder for him to speak. My concern was that there was a tracheal injury, a carotid injury, or something of that nature that was expanding.

Again, I strongly urged him to go to the hospital, but again, he said no.

In the sixth inning, things got bad enough that the umpire finally agreed to leave the game. As I was figuring out how to get him to the hospital, he disappeared on me. He had walked up to the second floor of the snack shack. My MA and I got him back downstairs and sat him on a bench behind home plate.

We were in the process of calling 911 ... when he arrested.

Luckily, when he lost vital signs, my MA and I were standing right next to him. We were able to activate ACLS protocol and start CPR within seconds.

Many times in these critical situations — especially if people are scared or have never seen an emergency like this — there’s the potential for chaos. Well, that was the polar opposite of what happened.

As soon as I started to run the code, there was this sense of order. People were keeping their composure and following directions. My MA and I would say, “this is what we need,” and the task would immediately be assigned to someone. It was quiet. There was no yelling. Everyone trusted me, even though some of them had never met me before. It was so surprising. I remember thinking, we’re running an arrest, but it’s so calm.

We were an organized team, and it really worked like clockwork, which was remarkable given where we were. It’s one thing to be in the hospital for an event like that. But to be on a baseball field where you have nothing is a completely different scenario.

Meanwhile, the game went on.

I had requested that all the kids be placed in the dugout when they weren’t on the field. So they saw the umpire walk off, but none of them saw him arrest. Some parents were really helpful with making sure the kids were okay.

The president of Oxford Little League ran across the street to a fire station to get an AED. But the fire department personnel were out on a call. He had to break down the door.

By the time he got back, the umpire’s vital signs were returning. And then EMS arrived.

They loaded him in the ambulance, and I called ahead to the trauma team, so they knew exactly what was happening.

I was pretty worried. My hypothesis was that there was probably compression on the vasculature, which had caused him to lose his vital signs. I thought he probably had an impending airway loss. I wasn’t sure if he was going to make it through the night.

What I didn’t know was that while I was giving CPR, my son stole home, and we won the game. As the ambulance was leaving, the celebration was going on in the outfield.

The umpire was in the hospital for several days. Early on, I got permission from his family to visit him. The first time I saw him, I felt this incredible gratitude and peace.

My dad was an ER doctor, and growing up, it seemed like every time we went on a family vacation, there was an emergency. We would be near a car accident or something, and my father would fly in and save the day. I remember being on the Autobahn somewhere in Europe, and there was a devastating accident between a car and a motorcycle. My father stabilized the guy, had him airlifted out, and apparently, he did fine. I grew up watching things like this and thinking, wow, that’s incredible.

Fast forward to 2 years ago, my father was diagnosed with a lung cancer he never should have had. He never smoked. As a cancer surgeon, I know we did everything in our power to save him. But it didn’t happen. He passed away.

I realize this is superstitious, but seeing the umpire alive, I had this feeling that somehow my dad was there. It was bittersweet but also a joyful moment — like I could breathe again.

I met the umpire’s family that first time, and it was like meeting family that you didn’t know you had but now you have forever. Even though the event was traumatic — I’m still trying not to be on high alert every time I go to a game — it felt like a gift to be part of this journey with them.

Little League’s mission is to teach kids about teamwork, leadership, and making good choices so communities are stronger. Our umpire is a guy who does that every day. He’s not a Little League umpire because he makes any money. He shows up at every single game to support these kids and engage them, to model respect, gratitude, and kindness.

I think our obligation as people is to live with intentionality. We all need to make sure we leave the world a better place, even when we are called upon to do uncomfortable things. Our umpire showed our kids what that looks like, and in that moment when he could have died, we were able to do the same for him.

Jennifer LaFemina, MD, is a surgical oncologist at UMass Memorial Medical Center in Massachusetts.
 

Are you a medical professional with a dramatic story outside the clinic? Medscape Medical News would love to consider your story for Is There a Doctor in the House? Please email your contact information and a short summary to [email protected].

A version of this article appeared on Medscape.com.

Emergencies happen anywhere, anytime, and sometimes, medical professionals find themselves in situations where they are the only ones who can help. Is There a Doctor in the House? is a Medscape Medical News series telling these stories.

I sincerely believe that what goes around comes around. Good things come to good people. And sometimes that saves lives.

My 10-year-old son was in the semifinals of the Little League district championship. And we were losing. My son is an excellent pitcher, and he had started the game. But that night, he was struggling. He just couldn’t find where to throw the ball. Needless to say, he was frustrated.

He was changed to shortstop in the second inning, and the home plate umpire walked over to him. This umpire is well known in the area for his kindness and commitment, how he encourages the kids and helps make baseball fun even when it’s stressful.

We didn’t know him well, but he was really supportive of my kid in that moment, talking to him about how baseball is a team sport and we’re here to have fun. Just being really positive.

As the game continued, I saw the umpire suddenly walk to the side of the field. I hadn’t seen it, but he had been hit by a wild pitch on the side of his neck. He was wearing protective gear, but the ball managed to bounce up the side and caught bare neck. I knew something wasn’t right.

I went down to talk to him, and my medical assistant (MA), who was also at the game, came with me. I could tell the umpire was injured, but he didn’t want to leave the game. I suggested going to the hospital, but he wouldn’t consider it. So I sat there with my arms crossed, watching him.

His symptoms got worse. I could see he was in pain, and it was getting harder for him to speak. My concern was that there was a tracheal injury, a carotid injury, or something of that nature that was expanding.

Again, I strongly urged him to go to the hospital, but again, he said no.

In the sixth inning, things got bad enough that the umpire finally agreed to leave the game. As I was figuring out how to get him to the hospital, he disappeared on me. He had walked up to the second floor of the snack shack. My MA and I got him back downstairs and sat him on a bench behind home plate.

We were in the process of calling 911 ... when he arrested.

Luckily, when he lost vital signs, my MA and I were standing right next to him. We were able to activate ACLS protocol and start CPR within seconds.

Many times in these critical situations — especially if people are scared or have never seen an emergency like this — there’s the potential for chaos. Well, that was the polar opposite of what happened.

As soon as I started to run the code, there was this sense of order. People were keeping their composure and following directions. My MA and I would say, “this is what we need,” and the task would immediately be assigned to someone. It was quiet. There was no yelling. Everyone trusted me, even though some of them had never met me before. It was so surprising. I remember thinking, we’re running an arrest, but it’s so calm.

We were an organized team, and it really worked like clockwork, which was remarkable given where we were. It’s one thing to be in the hospital for an event like that. But to be on a baseball field where you have nothing is a completely different scenario.

Meanwhile, the game went on.

I had requested that all the kids be placed in the dugout when they weren’t on the field. So they saw the umpire walk off, but none of them saw him arrest. Some parents were really helpful with making sure the kids were okay.

The president of Oxford Little League ran across the street to a fire station to get an AED. But the fire department personnel were out on a call. He had to break down the door.

By the time he got back, the umpire’s vital signs were returning. And then EMS arrived.

They loaded him in the ambulance, and I called ahead to the trauma team, so they knew exactly what was happening.

I was pretty worried. My hypothesis was that there was probably compression on the vasculature, which had caused him to lose his vital signs. I thought he probably had an impending airway loss. I wasn’t sure if he was going to make it through the night.

What I didn’t know was that while I was giving CPR, my son stole home, and we won the game. As the ambulance was leaving, the celebration was going on in the outfield.

The umpire was in the hospital for several days. Early on, I got permission from his family to visit him. The first time I saw him, I felt this incredible gratitude and peace.

My dad was an ER doctor, and growing up, it seemed like every time we went on a family vacation, there was an emergency. We would be near a car accident or something, and my father would fly in and save the day. I remember being on the Autobahn somewhere in Europe, and there was a devastating accident between a car and a motorcycle. My father stabilized the guy, had him airlifted out, and apparently, he did fine. I grew up watching things like this and thinking, wow, that’s incredible.

Fast forward to 2 years ago, my father was diagnosed with a lung cancer he never should have had. He never smoked. As a cancer surgeon, I know we did everything in our power to save him. But it didn’t happen. He passed away.

I realize this is superstitious, but seeing the umpire alive, I had this feeling that somehow my dad was there. It was bittersweet but also a joyful moment — like I could breathe again.

I met the umpire’s family that first time, and it was like meeting family that you didn’t know you had but now you have forever. Even though the event was traumatic — I’m still trying not to be on high alert every time I go to a game — it felt like a gift to be part of this journey with them.

Little League’s mission is to teach kids about teamwork, leadership, and making good choices so communities are stronger. Our umpire is a guy who does that every day. He’s not a Little League umpire because he makes any money. He shows up at every single game to support these kids and engage them, to model respect, gratitude, and kindness.

I think our obligation as people is to live with intentionality. We all need to make sure we leave the world a better place, even when we are called upon to do uncomfortable things. Our umpire showed our kids what that looks like, and in that moment when he could have died, we were able to do the same for him.

Jennifer LaFemina, MD, is a surgical oncologist at UMass Memorial Medical Center in Massachusetts.
 

Are you a medical professional with a dramatic story outside the clinic? Medscape Medical News would love to consider your story for Is There a Doctor in the House? Please email your contact information and a short summary to [email protected].

A version of this article appeared on Medscape.com.

Emergencies happen anywhere, anytime, and sometimes, medical professionals find themselves in situations where they are the only ones who can help. Is There a Doctor in the House? is a Medscape Medical News series telling these stories.

I sincerely believe that what goes around comes around. Good things come to good people. And sometimes that saves lives.

My 10-year-old son was in the semifinals of the Little League district championship. And we were losing. My son is an excellent pitcher, and he had started the game. But that night, he was struggling. He just couldn’t find where to throw the ball. Needless to say, he was frustrated.

He was changed to shortstop in the second inning, and the home plate umpire walked over to him. This umpire is well known in the area for his kindness and commitment, how he encourages the kids and helps make baseball fun even when it’s stressful.

We didn’t know him well, but he was really supportive of my kid in that moment, talking to him about how baseball is a team sport and we’re here to have fun. Just being really positive.

As the game continued, I saw the umpire suddenly walk to the side of the field. I hadn’t seen it, but he had been hit by a wild pitch on the side of his neck. He was wearing protective gear, but the ball managed to bounce up the side and caught bare neck. I knew something wasn’t right.

I went down to talk to him, and my medical assistant (MA), who was also at the game, came with me. I could tell the umpire was injured, but he didn’t want to leave the game. I suggested going to the hospital, but he wouldn’t consider it. So I sat there with my arms crossed, watching him.

His symptoms got worse. I could see he was in pain, and it was getting harder for him to speak. My concern was that there was a tracheal injury, a carotid injury, or something of that nature that was expanding.

Again, I strongly urged him to go to the hospital, but again, he said no.

In the sixth inning, things got bad enough that the umpire finally agreed to leave the game. As I was figuring out how to get him to the hospital, he disappeared on me. He had walked up to the second floor of the snack shack. My MA and I got him back downstairs and sat him on a bench behind home plate.

We were in the process of calling 911 ... when he arrested.

Luckily, when he lost vital signs, my MA and I were standing right next to him. We were able to activate ACLS protocol and start CPR within seconds.

Many times in these critical situations — especially if people are scared or have never seen an emergency like this — there’s the potential for chaos. Well, that was the polar opposite of what happened.

As soon as I started to run the code, there was this sense of order. People were keeping their composure and following directions. My MA and I would say, “this is what we need,” and the task would immediately be assigned to someone. It was quiet. There was no yelling. Everyone trusted me, even though some of them had never met me before. It was so surprising. I remember thinking, we’re running an arrest, but it’s so calm.

We were an organized team, and it really worked like clockwork, which was remarkable given where we were. It’s one thing to be in the hospital for an event like that. But to be on a baseball field where you have nothing is a completely different scenario.

Meanwhile, the game went on.

I had requested that all the kids be placed in the dugout when they weren’t on the field. So they saw the umpire walk off, but none of them saw him arrest. Some parents were really helpful with making sure the kids were okay.

The president of Oxford Little League ran across the street to a fire station to get an AED. But the fire department personnel were out on a call. He had to break down the door.

By the time he got back, the umpire’s vital signs were returning. And then EMS arrived.

They loaded him in the ambulance, and I called ahead to the trauma team, so they knew exactly what was happening.

I was pretty worried. My hypothesis was that there was probably compression on the vasculature, which had caused him to lose his vital signs. I thought he probably had an impending airway loss. I wasn’t sure if he was going to make it through the night.

What I didn’t know was that while I was giving CPR, my son stole home, and we won the game. As the ambulance was leaving, the celebration was going on in the outfield.

The umpire was in the hospital for several days. Early on, I got permission from his family to visit him. The first time I saw him, I felt this incredible gratitude and peace.

My dad was an ER doctor, and growing up, it seemed like every time we went on a family vacation, there was an emergency. We would be near a car accident or something, and my father would fly in and save the day. I remember being on the Autobahn somewhere in Europe, and there was a devastating accident between a car and a motorcycle. My father stabilized the guy, had him airlifted out, and apparently, he did fine. I grew up watching things like this and thinking, wow, that’s incredible.

Fast forward to 2 years ago, my father was diagnosed with a lung cancer he never should have had. He never smoked. As a cancer surgeon, I know we did everything in our power to save him. But it didn’t happen. He passed away.

I realize this is superstitious, but seeing the umpire alive, I had this feeling that somehow my dad was there. It was bittersweet but also a joyful moment — like I could breathe again.

I met the umpire’s family that first time, and it was like meeting family that you didn’t know you had but now you have forever. Even though the event was traumatic — I’m still trying not to be on high alert every time I go to a game — it felt like a gift to be part of this journey with them.

Little League’s mission is to teach kids about teamwork, leadership, and making good choices so communities are stronger. Our umpire is a guy who does that every day. He’s not a Little League umpire because he makes any money. He shows up at every single game to support these kids and engage them, to model respect, gratitude, and kindness.

I think our obligation as people is to live with intentionality. We all need to make sure we leave the world a better place, even when we are called upon to do uncomfortable things. Our umpire showed our kids what that looks like, and in that moment when he could have died, we were able to do the same for him.

Jennifer LaFemina, MD, is a surgical oncologist at UMass Memorial Medical Center in Massachusetts.
 

Are you a medical professional with a dramatic story outside the clinic? Medscape Medical News would love to consider your story for Is There a Doctor in the House? Please email your contact information and a short summary to [email protected].

A version of this article appeared on Medscape.com.

A low-carbohydrate diet can help preserve beta-cell function in people with mild type 2 diabetes (T2D), potentially allowing some to achieve target glucose levels without medication, new research suggests.

In the 12-week study of 57 people with T2D who were not using insulin, C-peptide levels were significantly higher among those randomized to receive a low-carbohydrate diet (~9% of total calories) vs a higher-carbohydrate diet (~55%). The results were published online on October 22, 2024, in The Journal of Clinical Endocrinology & Metabolism.

“While other studies have demonstrated metabolic health benefits of low-carb diets, our results are the first to show that dietary carbohydrate restriction can improve beta-cell function ... Furthermore, the carbohydrate-restricted diet improved insulin secretion in African American patients to a much greater extent than in Caucasian Americans,” study author Marian L. Yurchishin, MS, Department of Nutrition Sciences, The University of Alabama, Birmingham, Alabama, told Medscape Medical News.

Yurchishin added, “Our data suggests that a carbohydrate-restricted diet provides the opportunity to improve beta-cell function without the need for medication use or weight loss. This approach may be more appealing and effective for some persons with T2D, particularly in patients of African descent.”

At the same time, she clarified, “Our research should not be interpreted to mean that a carbohydrate-restricted diet can replace medical therapy in those who need it, especially patients at risk of cardiovascular disease, heart failure, or chronic kidney disease…or when medications are needed to achieve A1c targets.”

Asked to comment, Alison B. Evert, RDN, CDCES, former (now retired) manager of the Nutrition and Diabetes Education Programs at the University of Washington Medicine Primary Care, Kirkland, Washington, expressed some caveats about the findings, noting “I doubt this approach would be sustainable for the average person.” 

Evert also pointed out that the amount of fat in the carbohydrate-restricted diet — 65% of energy vs just 20% of energy with the higher-carbohydrate diet — was “extremely high ... essentially a keto diet,” and that in the real-world people might not receive education on heart-healthy fat intake. Moreover, she noted that the study’s use of grocery delivery to the participants with instructions for food preparation “is not a real-world situation either.”
 

Low-Carbohydrate Diet Increased C-Peptide Levels

The study participants were all either African American or European American. All had been diagnosed with T2D within the past 10 years, with average 4.9 years in the carbohydrate-restricted group vs 3.0 years in the higher-carbohydrate group. The two diets contained approximately the same number of calories.

All their medications were discontinued 1-2 weeks prior to baseline testing.

A hyperglycemic clamp was used to assess the acute (first-phase) and maximal (arginine-stimulated) C-peptide response to glucose at baseline and after 12 weeks of following the diets. First-phase beta-cell response to glucose was assessed at 30 minutes, insulin sensitivity was evaluated at 2 hours, and maximal beta-cell response to arginine was evaluated after another 30 minutes.

Oral glucose tolerance tests were also conducted at baseline and at 12 weeks to determine the disposition index (DI), a marker of beta-cell function that factors in both C-peptide and insulin sensitivity.

Of 65 participants enrolled, eight discontinued the study, most due to non-adherence. At 12 weeks, the acute C-peptide response from baseline was twice as high with the carbohydrate-restricted diet than with the higher-carbohydrate diet (P < .05). This difference was significant among the 37 African Americans (110% greater; P < .01) but not for the 20 European Americans.

Evert said that because people have typically lost at least 50% of their beta-cell function at the time of T2D diagnosis, “it is helpful to have return of first phase response, but long-term discontinuation of medications that also have cardioprotective function seems short sighted in this patient population.”

The overall maximal C-peptide response was 22% greater with the carbohydrate-restricted diet (P < .05), this time only significant in the European Americans (48%; P < .01) but not the African Americans.

In the combined group, the DI was 32% greater with the carbohydrate-restricted diet (P < .05) but only significantly so in the African American participants (48%; P < .01); however, no DI changes were seen with the higher-carbohydrate diet in the European American participants.

Regarding the racial differences, Yurchishin explained “Research supports the contention that the pathophysiology of T2D differs can differ among races based on genetic factors and environmental interactions that affect beta-cell function. For example, T2D onset in African Americans may be less related to obesity and insulin resistance than it is in European Americans and depend on alterations in beta-cell function to a larger degree. While sociocultural factors do influence T2D risk, other studies have also shown that there are inherent biological differences in the mechanisms that lead to beta-cell failure between races that warrant further investigation.” 

In their paper, Yurchishin and colleagues concluded, “With the caveat that carbohydrate restriction may be difficult for some patients, such a diet may allow patients with mild T2D to discontinue medication and enjoy eating meals and snacks that meet their energy needs while improving beta-cell function, an outcome that cannot be achieved with medication.” 

Evert commented, “I think it is a bit subjective to say that people following a 9% carb intake ‘will enjoy eating their meals and snacks that meet their energy needs.’ Guess they would enjoy as long as they choose very high fat, low carb foods.”

The research was supported by the National Institute of Diabetes and Digestive and Kidney Diseases, the UAB Nutrition Obesity Research Center, and the UAB Diabetes Research Center. Yurchishin was supported by the National Heart, Lung, and Blood Institute. Evert had no disclosures.
 

A version of this article appeared on Medscape.com.

A low-carbohydrate diet can help preserve beta-cell function in people with mild type 2 diabetes (T2D), potentially allowing some to achieve target glucose levels without medication, new research suggests.

In the 12-week study of 57 people with T2D who were not using insulin, C-peptide levels were significantly higher among those randomized to receive a low-carbohydrate diet (~9% of total calories) vs a higher-carbohydrate diet (~55%). The results were published online on October 22, 2024, in The Journal of Clinical Endocrinology & Metabolism.

“While other studies have demonstrated metabolic health benefits of low-carb diets, our results are the first to show that dietary carbohydrate restriction can improve beta-cell function ... Furthermore, the carbohydrate-restricted diet improved insulin secretion in African American patients to a much greater extent than in Caucasian Americans,” study author Marian L. Yurchishin, MS, Department of Nutrition Sciences, The University of Alabama, Birmingham, Alabama, told Medscape Medical News.

Yurchishin added, “Our data suggests that a carbohydrate-restricted diet provides the opportunity to improve beta-cell function without the need for medication use or weight loss. This approach may be more appealing and effective for some persons with T2D, particularly in patients of African descent.”

At the same time, she clarified, “Our research should not be interpreted to mean that a carbohydrate-restricted diet can replace medical therapy in those who need it, especially patients at risk of cardiovascular disease, heart failure, or chronic kidney disease…or when medications are needed to achieve A1c targets.”

Asked to comment, Alison B. Evert, RDN, CDCES, former (now retired) manager of the Nutrition and Diabetes Education Programs at the University of Washington Medicine Primary Care, Kirkland, Washington, expressed some caveats about the findings, noting “I doubt this approach would be sustainable for the average person.” 

Evert also pointed out that the amount of fat in the carbohydrate-restricted diet — 65% of energy vs just 20% of energy with the higher-carbohydrate diet — was “extremely high ... essentially a keto diet,” and that in the real-world people might not receive education on heart-healthy fat intake. Moreover, she noted that the study’s use of grocery delivery to the participants with instructions for food preparation “is not a real-world situation either.”
 

Low-Carbohydrate Diet Increased C-Peptide Levels

The study participants were all either African American or European American. All had been diagnosed with T2D within the past 10 years, with average 4.9 years in the carbohydrate-restricted group vs 3.0 years in the higher-carbohydrate group. The two diets contained approximately the same number of calories.

All their medications were discontinued 1-2 weeks prior to baseline testing.

A hyperglycemic clamp was used to assess the acute (first-phase) and maximal (arginine-stimulated) C-peptide response to glucose at baseline and after 12 weeks of following the diets. First-phase beta-cell response to glucose was assessed at 30 minutes, insulin sensitivity was evaluated at 2 hours, and maximal beta-cell response to arginine was evaluated after another 30 minutes.

Oral glucose tolerance tests were also conducted at baseline and at 12 weeks to determine the disposition index (DI), a marker of beta-cell function that factors in both C-peptide and insulin sensitivity.

Of 65 participants enrolled, eight discontinued the study, most due to non-adherence. At 12 weeks, the acute C-peptide response from baseline was twice as high with the carbohydrate-restricted diet than with the higher-carbohydrate diet (P < .05). This difference was significant among the 37 African Americans (110% greater; P < .01) but not for the 20 European Americans.

Evert said that because people have typically lost at least 50% of their beta-cell function at the time of T2D diagnosis, “it is helpful to have return of first phase response, but long-term discontinuation of medications that also have cardioprotective function seems short sighted in this patient population.”

The overall maximal C-peptide response was 22% greater with the carbohydrate-restricted diet (P < .05), this time only significant in the European Americans (48%; P < .01) but not the African Americans.

In the combined group, the DI was 32% greater with the carbohydrate-restricted diet (P < .05) but only significantly so in the African American participants (48%; P < .01); however, no DI changes were seen with the higher-carbohydrate diet in the European American participants.

Regarding the racial differences, Yurchishin explained “Research supports the contention that the pathophysiology of T2D differs can differ among races based on genetic factors and environmental interactions that affect beta-cell function. For example, T2D onset in African Americans may be less related to obesity and insulin resistance than it is in European Americans and depend on alterations in beta-cell function to a larger degree. While sociocultural factors do influence T2D risk, other studies have also shown that there are inherent biological differences in the mechanisms that lead to beta-cell failure between races that warrant further investigation.” 

In their paper, Yurchishin and colleagues concluded, “With the caveat that carbohydrate restriction may be difficult for some patients, such a diet may allow patients with mild T2D to discontinue medication and enjoy eating meals and snacks that meet their energy needs while improving beta-cell function, an outcome that cannot be achieved with medication.” 

Evert commented, “I think it is a bit subjective to say that people following a 9% carb intake ‘will enjoy eating their meals and snacks that meet their energy needs.’ Guess they would enjoy as long as they choose very high fat, low carb foods.”

The research was supported by the National Institute of Diabetes and Digestive and Kidney Diseases, the UAB Nutrition Obesity Research Center, and the UAB Diabetes Research Center. Yurchishin was supported by the National Heart, Lung, and Blood Institute. Evert had no disclosures.
 

A version of this article appeared on Medscape.com.

A low-carbohydrate diet can help preserve beta-cell function in people with mild type 2 diabetes (T2D), potentially allowing some to achieve target glucose levels without medication, new research suggests.

In the 12-week study of 57 people with T2D who were not using insulin, C-peptide levels were significantly higher among those randomized to receive a low-carbohydrate diet (~9% of total calories) vs a higher-carbohydrate diet (~55%). The results were published online on October 22, 2024, in The Journal of Clinical Endocrinology & Metabolism.

“While other studies have demonstrated metabolic health benefits of low-carb diets, our results are the first to show that dietary carbohydrate restriction can improve beta-cell function ... Furthermore, the carbohydrate-restricted diet improved insulin secretion in African American patients to a much greater extent than in Caucasian Americans,” study author Marian L. Yurchishin, MS, Department of Nutrition Sciences, The University of Alabama, Birmingham, Alabama, told Medscape Medical News.

Yurchishin added, “Our data suggests that a carbohydrate-restricted diet provides the opportunity to improve beta-cell function without the need for medication use or weight loss. This approach may be more appealing and effective for some persons with T2D, particularly in patients of African descent.”

At the same time, she clarified, “Our research should not be interpreted to mean that a carbohydrate-restricted diet can replace medical therapy in those who need it, especially patients at risk of cardiovascular disease, heart failure, or chronic kidney disease…or when medications are needed to achieve A1c targets.”

Asked to comment, Alison B. Evert, RDN, CDCES, former (now retired) manager of the Nutrition and Diabetes Education Programs at the University of Washington Medicine Primary Care, Kirkland, Washington, expressed some caveats about the findings, noting “I doubt this approach would be sustainable for the average person.” 

Evert also pointed out that the amount of fat in the carbohydrate-restricted diet — 65% of energy vs just 20% of energy with the higher-carbohydrate diet — was “extremely high ... essentially a keto diet,” and that in the real-world people might not receive education on heart-healthy fat intake. Moreover, she noted that the study’s use of grocery delivery to the participants with instructions for food preparation “is not a real-world situation either.”
 

Low-Carbohydrate Diet Increased C-Peptide Levels

The study participants were all either African American or European American. All had been diagnosed with T2D within the past 10 years, with average 4.9 years in the carbohydrate-restricted group vs 3.0 years in the higher-carbohydrate group. The two diets contained approximately the same number of calories.

All their medications were discontinued 1-2 weeks prior to baseline testing.

A hyperglycemic clamp was used to assess the acute (first-phase) and maximal (arginine-stimulated) C-peptide response to glucose at baseline and after 12 weeks of following the diets. First-phase beta-cell response to glucose was assessed at 30 minutes, insulin sensitivity was evaluated at 2 hours, and maximal beta-cell response to arginine was evaluated after another 30 minutes.

Oral glucose tolerance tests were also conducted at baseline and at 12 weeks to determine the disposition index (DI), a marker of beta-cell function that factors in both C-peptide and insulin sensitivity.

Of 65 participants enrolled, eight discontinued the study, most due to non-adherence. At 12 weeks, the acute C-peptide response from baseline was twice as high with the carbohydrate-restricted diet than with the higher-carbohydrate diet (P < .05). This difference was significant among the 37 African Americans (110% greater; P < .01) but not for the 20 European Americans.

Evert said that because people have typically lost at least 50% of their beta-cell function at the time of T2D diagnosis, “it is helpful to have return of first phase response, but long-term discontinuation of medications that also have cardioprotective function seems short sighted in this patient population.”

The overall maximal C-peptide response was 22% greater with the carbohydrate-restricted diet (P < .05), this time only significant in the European Americans (48%; P < .01) but not the African Americans.

In the combined group, the DI was 32% greater with the carbohydrate-restricted diet (P < .05) but only significantly so in the African American participants (48%; P < .01); however, no DI changes were seen with the higher-carbohydrate diet in the European American participants.

Regarding the racial differences, Yurchishin explained “Research supports the contention that the pathophysiology of T2D differs can differ among races based on genetic factors and environmental interactions that affect beta-cell function. For example, T2D onset in African Americans may be less related to obesity and insulin resistance than it is in European Americans and depend on alterations in beta-cell function to a larger degree. While sociocultural factors do influence T2D risk, other studies have also shown that there are inherent biological differences in the mechanisms that lead to beta-cell failure between races that warrant further investigation.” 

In their paper, Yurchishin and colleagues concluded, “With the caveat that carbohydrate restriction may be difficult for some patients, such a diet may allow patients with mild T2D to discontinue medication and enjoy eating meals and snacks that meet their energy needs while improving beta-cell function, an outcome that cannot be achieved with medication.” 

Evert commented, “I think it is a bit subjective to say that people following a 9% carb intake ‘will enjoy eating their meals and snacks that meet their energy needs.’ Guess they would enjoy as long as they choose very high fat, low carb foods.”

The research was supported by the National Institute of Diabetes and Digestive and Kidney Diseases, the UAB Nutrition Obesity Research Center, and the UAB Diabetes Research Center. Yurchishin was supported by the National Heart, Lung, and Blood Institute. Evert had no disclosures.
 

A version of this article appeared on Medscape.com.

Recent reports suggest diabetic retinopathy is more common in younger people than previously thought, leading to a call for more frequent screening for this condition and more attention to follow-up after diagnosis.

The increased incidence of diabetic retinopathy is “a potentially unappreciated public health catastrophe,” Julie Rosenthal, MD, MS, of the University of Michigan, Ann Arbor, Michigan, and her coauthors wrote in a recent viewpoint in JAMA Ophthalmology.

Rosenthal, an ophthalmologist, said she has been treating each year several young people with diabetes with symptoms of retinopathy that might have been prevented through earlier detection and treatment.

Some patients with retinopathy seek out eye specialists for issues such as seeing floaters, vision loss, or feeling of having cobwebs in their vision, which can be symptoms of bleeding. Other patients may have no symptoms with their retinopathy discovered only in screening.

“It would be wonderful to never need to treat any 20-year-olds with proliferative diabetic retinopathy who are losing vision,” Rosenthal said.

Diabetic retinopathy once was considered rare in young people, with earlier research suggesting an age-adjusted prevalence of 4%-13% in youths with type 2 diabetes, roughly in line with that for type 1 diabetes.

But an analysis of more recent data drawn from two major federally funded studies of diabetes in young people shows what Rosenthal and her colleagues called “alarming rates” of retinopathy. Data from these studies suggest more than half (52%) of youths with type 1 diabetes may have some retinopathy, and as many as 55% of those with youth-onset type 2 diabetes.

Other research suggests young people with type 2 diabetes may have almost twice the risk of developing retinopathy, develop it sooner after diabetes diagnosis, and are more likely to have vision-threatening retinopathy, Rosenthal and coauthors wrote.

Elizabeth Jensen, PhD, of Wake Forest University, Winston-Salem, North Carolina, the lead author of a 2023 study cited by Rosenthal and coauthors in their JAMA Ophthalmology viewpoint, told Medscape Medical News she also supports a call for more screening of young people.

“What many people don’t realize is that there is evidence of retinal changes consistent with development of diabetic retinopathy early in disease,” Jensen said.

The proportion of people with diabetic retinopathy varied according to a range of modifiable factors, including A1c levels and blood pressure, she added.

This fact underscores the need to not only screen for diabetic retinopathy early but also consider addressing those modifiable factors that may mitigate risk for the development and progression of diabetic retinopathy, Jensen said.

Rosenthal said some patients have the false impression of sight loss being inevitable with diabetes. Their primary care physicians can help make them aware that there are treatments for retinopathy in cases where it can’t be avoided.

These interventions include laser treatments and injecting medicines into the eye. “It sounds a lot scarier than it is,” Rosenthal said.

“We do know that keeping good control over not only glucose but also blood pressure, cholesterol, and lipids is all important for decreasing the risk. But even if those are under control, sometimes people can still get diabetes in their eyes,” Rosenthal said. “The longer you have diabetes, the higher your risk of having problems in your eye.”
 

‘Stagnant Guidelines’

Guidelines from major medical groups have “remained largely stagnant in the face of new evidence of increasing diabetes prevalence,” making it difficult to know when to screen younger people, according to Rosenthal and her colleagues.

Medical associations, including the American Diabetes Association (ADA) and the American Academy of Ophthalmology, now recommend ocular screening for youths with type 1 diabetes 3-5 years after diagnosis in those who are at least 11 years old or are experiencing puberty, and for youths with type 2 diabetes from the time of diagnosis.

Follow-up diabetic eye examinations can be performed every 2 years, with some groups advocating for even more infrequent follow-up examinations.

“These guidelines are rooted in evidence from prior studies showing that it is rare to have advanced retinopathy prior to this age,” Rosenthal and coauthors wrote. “However, these guidelines have remained largely stagnant in the face of new evidence of increasing diabetes prevalence.”

The American Academy of Ophthalmology told Medscape Medical News it has no immediate plans to update its recommendations. These include directing people with type 1 diabetes without known diabetic retinopathy to have annual dilated eye examinations beginning 5 years after the onset of diabetes. Individuals with type 2 diabetes without diabetic retinopathy should have annual dilated eye examinations to detect the onset of diabetic retinopathy.

The group also said clinicians should make sure patients understand that even if they may have good vision and no ocular symptoms, they may still have significant disease that needs treatment.
 

More Opportunities for Screening Tools

The current standards of care for retinopathy from the ADA note new products on the market are increasing the options for screening.

“Retinal photography with remote reading by experts has great potential to provide screening services in areas where qualified eye care professionals are not readily available,” according to standards.

“However, the benefits and optimal utilization of this type of screening have yet to be fully determined,” the group stated. “Results of all screening eye examinations should be documented and transmitted to the referring healthcare professionals.”

The approach has promise, despite some significant challenges, according to Rithwick Rajagopal, MD, PhD, an associate professor of ophthalmology and visual sciences at Washington University in St. Louis, St. Louis, Missouri.

Rajagopal and colleagues in 2022 published results of a test of retinopathy screening during appointments at the primary care medicine clinic of Barnes-Jewish Hospital in St. Louis, Missouri. They found the system used worked well in ruling out retinopathy and appeared to help more patients receive care for the condition. Among patients referred for follow-up eye exams, the adherence rate was 55.4% at 1-year compared with the historical adherence rate of 18.7%, Rajagopal and his colleagues reported.

In an email exchange with Medscape Medical News, Rajagopal highlighted several barriers to wider adoption of retinopathy screenings in primary care.

“First is unfamiliarity with eye anatomy and physiology, which is associated with low level of comfort in capturing the photographs and interpreting the results (even though the cameras are increasingly easy to use and that the AI software generates the diagnosis),” Rajagopal said.

In addition, questions about reimbursement and liability remain unresolved.

But Rajagopal said he still expects more use of products such as the EyeArt 2.0 automated DR screening software (Eyenuk, Inc.).

“Despite the above concerns, point-of-care screening offers a powerful solution to a long-standing problem: People with diabetes in this country are generally not adherent to recommended retinal screening guidelines,” Rajagopal told Medscape Medical News. “There are multiple causes of such poor adherence, but point-of-care screening solves several of them: No need to take time off for an additional medical visit, no additional co-pay for eye doctor visits, and no need for dilation in many cases.”

Aiding in the adoption of this service is likely the special Current Procedural Terminology (billing) code — 92229 — the American Medical Association introduced in 2021 for diabetic eye exams when ordered by a physician who is not an ophthalmologist. Many commercial health plans and many state Medicaid programs now cover this service, which is still off-label, Michael Abramoff, MD, PhD, of the University of Iowa, Iowa City, Iowa, and founder of Digital Diagnostics, maker of the AI-assisted LumineticsCore diagnostic system, told Medscape Medical News. A representative for Eyenuk also told Medscape Medical News many insurers now cover the screening service.

LumineticsCore has been used in a study done in conjunction with appointments for regular care at the Johns Hopkins Pediatric Diabetes Center in Baltimore.

Abramoff and coauthors, including Risa Wolf, MD, a pediatric endocrinologist at Johns Hopkins University School of Medicine in Baltimore, reported this year in Nature Communications that 100% of patients in the group offered the autonomous AI screening completed their eye exam that day, while only 22% of a comparison group followed through within 6 months to complete an eye exam with an optometrist or ophthalmologist.

Wolf, who is also a coauthor with Rosenthal of the commentary in JAMA Ophthalmology, said she agrees these tools have the potential to expand the pool of clinicians who can screen patients for retinopathy.
 

Make Screening Easier

The critical issue is to make it easier for young adults with diabetes to get checked for retinopathy, Wolf said. People in their late teens and early 20s face many challenges in getting needed medical screenings. They often are shifting away from living with parents, who likely managed their care for them in their childhood.

These young adults tend to be busy with college and the demands of starting out in careers while living on their own. And they may not want to address the potential consequences of diabetes, which can seem remote to people not feeling effects of the illness.

“It’s just not always a priority, especially when you’re in this time of life where you’re generally feeling very healthy,” Wolf said. “But we want to make sure that they are getting screened.”

Rosenthal reported receiving research grant support from MediBeacon, outside the submitted work. Other coauthors reported receiving grants from Breakthrough T1D, Physical Sciences, Novartis, Genentech/Roche, Novo Nordisk, and Boehringer Ingelheim, and receiving nonfinancial support from Optovue, Boston Micromachines, Novo Nordisk, Adaptive Sensory Technology, Genentech/Roche, Novartis, and Alcon outside the submitted work. Jensen reported no relevant financial disclosures.

Eyenuk Inc. provided the camera and automated screening software used in the study reported by Rajagopal and coauthors and was involved in the data collection and management, but otherwise had no role in the design or conduct of this research. Rajagopal had no personal financial disclosures.
 

A version of this article appeared on Medscape.com.

Recent reports suggest diabetic retinopathy is more common in younger people than previously thought, leading to a call for more frequent screening for this condition and more attention to follow-up after diagnosis.

The increased incidence of diabetic retinopathy is “a potentially unappreciated public health catastrophe,” Julie Rosenthal, MD, MS, of the University of Michigan, Ann Arbor, Michigan, and her coauthors wrote in a recent viewpoint in JAMA Ophthalmology.

Rosenthal, an ophthalmologist, said she has been treating each year several young people with diabetes with symptoms of retinopathy that might have been prevented through earlier detection and treatment.

Some patients with retinopathy seek out eye specialists for issues such as seeing floaters, vision loss, or feeling of having cobwebs in their vision, which can be symptoms of bleeding. Other patients may have no symptoms with their retinopathy discovered only in screening.

“It would be wonderful to never need to treat any 20-year-olds with proliferative diabetic retinopathy who are losing vision,” Rosenthal said.

Diabetic retinopathy once was considered rare in young people, with earlier research suggesting an age-adjusted prevalence of 4%-13% in youths with type 2 diabetes, roughly in line with that for type 1 diabetes.

But an analysis of more recent data drawn from two major federally funded studies of diabetes in young people shows what Rosenthal and her colleagues called “alarming rates” of retinopathy. Data from these studies suggest more than half (52%) of youths with type 1 diabetes may have some retinopathy, and as many as 55% of those with youth-onset type 2 diabetes.

Other research suggests young people with type 2 diabetes may have almost twice the risk of developing retinopathy, develop it sooner after diabetes diagnosis, and are more likely to have vision-threatening retinopathy, Rosenthal and coauthors wrote.

Elizabeth Jensen, PhD, of Wake Forest University, Winston-Salem, North Carolina, the lead author of a 2023 study cited by Rosenthal and coauthors in their JAMA Ophthalmology viewpoint, told Medscape Medical News she also supports a call for more screening of young people.

“What many people don’t realize is that there is evidence of retinal changes consistent with development of diabetic retinopathy early in disease,” Jensen said.

The proportion of people with diabetic retinopathy varied according to a range of modifiable factors, including A1c levels and blood pressure, she added.

This fact underscores the need to not only screen for diabetic retinopathy early but also consider addressing those modifiable factors that may mitigate risk for the development and progression of diabetic retinopathy, Jensen said.

Rosenthal said some patients have the false impression of sight loss being inevitable with diabetes. Their primary care physicians can help make them aware that there are treatments for retinopathy in cases where it can’t be avoided.

These interventions include laser treatments and injecting medicines into the eye. “It sounds a lot scarier than it is,” Rosenthal said.

“We do know that keeping good control over not only glucose but also blood pressure, cholesterol, and lipids is all important for decreasing the risk. But even if those are under control, sometimes people can still get diabetes in their eyes,” Rosenthal said. “The longer you have diabetes, the higher your risk of having problems in your eye.”
 

‘Stagnant Guidelines’

Guidelines from major medical groups have “remained largely stagnant in the face of new evidence of increasing diabetes prevalence,” making it difficult to know when to screen younger people, according to Rosenthal and her colleagues.

Medical associations, including the American Diabetes Association (ADA) and the American Academy of Ophthalmology, now recommend ocular screening for youths with type 1 diabetes 3-5 years after diagnosis in those who are at least 11 years old or are experiencing puberty, and for youths with type 2 diabetes from the time of diagnosis.

Follow-up diabetic eye examinations can be performed every 2 years, with some groups advocating for even more infrequent follow-up examinations.

“These guidelines are rooted in evidence from prior studies showing that it is rare to have advanced retinopathy prior to this age,” Rosenthal and coauthors wrote. “However, these guidelines have remained largely stagnant in the face of new evidence of increasing diabetes prevalence.”

The American Academy of Ophthalmology told Medscape Medical News it has no immediate plans to update its recommendations. These include directing people with type 1 diabetes without known diabetic retinopathy to have annual dilated eye examinations beginning 5 years after the onset of diabetes. Individuals with type 2 diabetes without diabetic retinopathy should have annual dilated eye examinations to detect the onset of diabetic retinopathy.

The group also said clinicians should make sure patients understand that even if they may have good vision and no ocular symptoms, they may still have significant disease that needs treatment.
 

More Opportunities for Screening Tools

The current standards of care for retinopathy from the ADA note new products on the market are increasing the options for screening.

“Retinal photography with remote reading by experts has great potential to provide screening services in areas where qualified eye care professionals are not readily available,” according to standards.

“However, the benefits and optimal utilization of this type of screening have yet to be fully determined,” the group stated. “Results of all screening eye examinations should be documented and transmitted to the referring healthcare professionals.”

The approach has promise, despite some significant challenges, according to Rithwick Rajagopal, MD, PhD, an associate professor of ophthalmology and visual sciences at Washington University in St. Louis, St. Louis, Missouri.

Rajagopal and colleagues in 2022 published results of a test of retinopathy screening during appointments at the primary care medicine clinic of Barnes-Jewish Hospital in St. Louis, Missouri. They found the system used worked well in ruling out retinopathy and appeared to help more patients receive care for the condition. Among patients referred for follow-up eye exams, the adherence rate was 55.4% at 1-year compared with the historical adherence rate of 18.7%, Rajagopal and his colleagues reported.

In an email exchange with Medscape Medical News, Rajagopal highlighted several barriers to wider adoption of retinopathy screenings in primary care.

“First is unfamiliarity with eye anatomy and physiology, which is associated with low level of comfort in capturing the photographs and interpreting the results (even though the cameras are increasingly easy to use and that the AI software generates the diagnosis),” Rajagopal said.

In addition, questions about reimbursement and liability remain unresolved.

But Rajagopal said he still expects more use of products such as the EyeArt 2.0 automated DR screening software (Eyenuk, Inc.).

“Despite the above concerns, point-of-care screening offers a powerful solution to a long-standing problem: People with diabetes in this country are generally not adherent to recommended retinal screening guidelines,” Rajagopal told Medscape Medical News. “There are multiple causes of such poor adherence, but point-of-care screening solves several of them: No need to take time off for an additional medical visit, no additional co-pay for eye doctor visits, and no need for dilation in many cases.”

Aiding in the adoption of this service is likely the special Current Procedural Terminology (billing) code — 92229 — the American Medical Association introduced in 2021 for diabetic eye exams when ordered by a physician who is not an ophthalmologist. Many commercial health plans and many state Medicaid programs now cover this service, which is still off-label, Michael Abramoff, MD, PhD, of the University of Iowa, Iowa City, Iowa, and founder of Digital Diagnostics, maker of the AI-assisted LumineticsCore diagnostic system, told Medscape Medical News. A representative for Eyenuk also told Medscape Medical News many insurers now cover the screening service.

LumineticsCore has been used in a study done in conjunction with appointments for regular care at the Johns Hopkins Pediatric Diabetes Center in Baltimore.

Abramoff and coauthors, including Risa Wolf, MD, a pediatric endocrinologist at Johns Hopkins University School of Medicine in Baltimore, reported this year in Nature Communications that 100% of patients in the group offered the autonomous AI screening completed their eye exam that day, while only 22% of a comparison group followed through within 6 months to complete an eye exam with an optometrist or ophthalmologist.

Wolf, who is also a coauthor with Rosenthal of the commentary in JAMA Ophthalmology, said she agrees these tools have the potential to expand the pool of clinicians who can screen patients for retinopathy.
 

Make Screening Easier

The critical issue is to make it easier for young adults with diabetes to get checked for retinopathy, Wolf said. People in their late teens and early 20s face many challenges in getting needed medical screenings. They often are shifting away from living with parents, who likely managed their care for them in their childhood.

These young adults tend to be busy with college and the demands of starting out in careers while living on their own. And they may not want to address the potential consequences of diabetes, which can seem remote to people not feeling effects of the illness.

“It’s just not always a priority, especially when you’re in this time of life where you’re generally feeling very healthy,” Wolf said. “But we want to make sure that they are getting screened.”

Rosenthal reported receiving research grant support from MediBeacon, outside the submitted work. Other coauthors reported receiving grants from Breakthrough T1D, Physical Sciences, Novartis, Genentech/Roche, Novo Nordisk, and Boehringer Ingelheim, and receiving nonfinancial support from Optovue, Boston Micromachines, Novo Nordisk, Adaptive Sensory Technology, Genentech/Roche, Novartis, and Alcon outside the submitted work. Jensen reported no relevant financial disclosures.

Eyenuk Inc. provided the camera and automated screening software used in the study reported by Rajagopal and coauthors and was involved in the data collection and management, but otherwise had no role in the design or conduct of this research. Rajagopal had no personal financial disclosures.
 

A version of this article appeared on Medscape.com.

Recent reports suggest diabetic retinopathy is more common in younger people than previously thought, leading to a call for more frequent screening for this condition and more attention to follow-up after diagnosis.

The increased incidence of diabetic retinopathy is “a potentially unappreciated public health catastrophe,” Julie Rosenthal, MD, MS, of the University of Michigan, Ann Arbor, Michigan, and her coauthors wrote in a recent viewpoint in JAMA Ophthalmology.

Rosenthal, an ophthalmologist, said she has been treating each year several young people with diabetes with symptoms of retinopathy that might have been prevented through earlier detection and treatment.

Some patients with retinopathy seek out eye specialists for issues such as seeing floaters, vision loss, or feeling of having cobwebs in their vision, which can be symptoms of bleeding. Other patients may have no symptoms with their retinopathy discovered only in screening.

“It would be wonderful to never need to treat any 20-year-olds with proliferative diabetic retinopathy who are losing vision,” Rosenthal said.

Diabetic retinopathy once was considered rare in young people, with earlier research suggesting an age-adjusted prevalence of 4%-13% in youths with type 2 diabetes, roughly in line with that for type 1 diabetes.

But an analysis of more recent data drawn from two major federally funded studies of diabetes in young people shows what Rosenthal and her colleagues called “alarming rates” of retinopathy. Data from these studies suggest more than half (52%) of youths with type 1 diabetes may have some retinopathy, and as many as 55% of those with youth-onset type 2 diabetes.

Other research suggests young people with type 2 diabetes may have almost twice the risk of developing retinopathy, develop it sooner after diabetes diagnosis, and are more likely to have vision-threatening retinopathy, Rosenthal and coauthors wrote.

Elizabeth Jensen, PhD, of Wake Forest University, Winston-Salem, North Carolina, the lead author of a 2023 study cited by Rosenthal and coauthors in their JAMA Ophthalmology viewpoint, told Medscape Medical News she also supports a call for more screening of young people.

“What many people don’t realize is that there is evidence of retinal changes consistent with development of diabetic retinopathy early in disease,” Jensen said.

The proportion of people with diabetic retinopathy varied according to a range of modifiable factors, including A1c levels and blood pressure, she added.

This fact underscores the need to not only screen for diabetic retinopathy early but also consider addressing those modifiable factors that may mitigate risk for the development and progression of diabetic retinopathy, Jensen said.

Rosenthal said some patients have the false impression of sight loss being inevitable with diabetes. Their primary care physicians can help make them aware that there are treatments for retinopathy in cases where it can’t be avoided.

These interventions include laser treatments and injecting medicines into the eye. “It sounds a lot scarier than it is,” Rosenthal said.

“We do know that keeping good control over not only glucose but also blood pressure, cholesterol, and lipids is all important for decreasing the risk. But even if those are under control, sometimes people can still get diabetes in their eyes,” Rosenthal said. “The longer you have diabetes, the higher your risk of having problems in your eye.”
 

‘Stagnant Guidelines’

Guidelines from major medical groups have “remained largely stagnant in the face of new evidence of increasing diabetes prevalence,” making it difficult to know when to screen younger people, according to Rosenthal and her colleagues.

Medical associations, including the American Diabetes Association (ADA) and the American Academy of Ophthalmology, now recommend ocular screening for youths with type 1 diabetes 3-5 years after diagnosis in those who are at least 11 years old or are experiencing puberty, and for youths with type 2 diabetes from the time of diagnosis.

Follow-up diabetic eye examinations can be performed every 2 years, with some groups advocating for even more infrequent follow-up examinations.

“These guidelines are rooted in evidence from prior studies showing that it is rare to have advanced retinopathy prior to this age,” Rosenthal and coauthors wrote. “However, these guidelines have remained largely stagnant in the face of new evidence of increasing diabetes prevalence.”

The American Academy of Ophthalmology told Medscape Medical News it has no immediate plans to update its recommendations. These include directing people with type 1 diabetes without known diabetic retinopathy to have annual dilated eye examinations beginning 5 years after the onset of diabetes. Individuals with type 2 diabetes without diabetic retinopathy should have annual dilated eye examinations to detect the onset of diabetic retinopathy.

The group also said clinicians should make sure patients understand that even if they may have good vision and no ocular symptoms, they may still have significant disease that needs treatment.
 

More Opportunities for Screening Tools

The current standards of care for retinopathy from the ADA note new products on the market are increasing the options for screening.

“Retinal photography with remote reading by experts has great potential to provide screening services in areas where qualified eye care professionals are not readily available,” according to standards.

“However, the benefits and optimal utilization of this type of screening have yet to be fully determined,” the group stated. “Results of all screening eye examinations should be documented and transmitted to the referring healthcare professionals.”

The approach has promise, despite some significant challenges, according to Rithwick Rajagopal, MD, PhD, an associate professor of ophthalmology and visual sciences at Washington University in St. Louis, St. Louis, Missouri.

Rajagopal and colleagues in 2022 published results of a test of retinopathy screening during appointments at the primary care medicine clinic of Barnes-Jewish Hospital in St. Louis, Missouri. They found the system used worked well in ruling out retinopathy and appeared to help more patients receive care for the condition. Among patients referred for follow-up eye exams, the adherence rate was 55.4% at 1-year compared with the historical adherence rate of 18.7%, Rajagopal and his colleagues reported.

In an email exchange with Medscape Medical News, Rajagopal highlighted several barriers to wider adoption of retinopathy screenings in primary care.

“First is unfamiliarity with eye anatomy and physiology, which is associated with low level of comfort in capturing the photographs and interpreting the results (even though the cameras are increasingly easy to use and that the AI software generates the diagnosis),” Rajagopal said.

In addition, questions about reimbursement and liability remain unresolved.

But Rajagopal said he still expects more use of products such as the EyeArt 2.0 automated DR screening software (Eyenuk, Inc.).

“Despite the above concerns, point-of-care screening offers a powerful solution to a long-standing problem: People with diabetes in this country are generally not adherent to recommended retinal screening guidelines,” Rajagopal told Medscape Medical News. “There are multiple causes of such poor adherence, but point-of-care screening solves several of them: No need to take time off for an additional medical visit, no additional co-pay for eye doctor visits, and no need for dilation in many cases.”

Aiding in the adoption of this service is likely the special Current Procedural Terminology (billing) code — 92229 — the American Medical Association introduced in 2021 for diabetic eye exams when ordered by a physician who is not an ophthalmologist. Many commercial health plans and many state Medicaid programs now cover this service, which is still off-label, Michael Abramoff, MD, PhD, of the University of Iowa, Iowa City, Iowa, and founder of Digital Diagnostics, maker of the AI-assisted LumineticsCore diagnostic system, told Medscape Medical News. A representative for Eyenuk also told Medscape Medical News many insurers now cover the screening service.

LumineticsCore has been used in a study done in conjunction with appointments for regular care at the Johns Hopkins Pediatric Diabetes Center in Baltimore.

Abramoff and coauthors, including Risa Wolf, MD, a pediatric endocrinologist at Johns Hopkins University School of Medicine in Baltimore, reported this year in Nature Communications that 100% of patients in the group offered the autonomous AI screening completed their eye exam that day, while only 22% of a comparison group followed through within 6 months to complete an eye exam with an optometrist or ophthalmologist.

Wolf, who is also a coauthor with Rosenthal of the commentary in JAMA Ophthalmology, said she agrees these tools have the potential to expand the pool of clinicians who can screen patients for retinopathy.
 

Make Screening Easier

The critical issue is to make it easier for young adults with diabetes to get checked for retinopathy, Wolf said. People in their late teens and early 20s face many challenges in getting needed medical screenings. They often are shifting away from living with parents, who likely managed their care for them in their childhood.

These young adults tend to be busy with college and the demands of starting out in careers while living on their own. And they may not want to address the potential consequences of diabetes, which can seem remote to people not feeling effects of the illness.

“It’s just not always a priority, especially when you’re in this time of life where you’re generally feeling very healthy,” Wolf said. “But we want to make sure that they are getting screened.”

Rosenthal reported receiving research grant support from MediBeacon, outside the submitted work. Other coauthors reported receiving grants from Breakthrough T1D, Physical Sciences, Novartis, Genentech/Roche, Novo Nordisk, and Boehringer Ingelheim, and receiving nonfinancial support from Optovue, Boston Micromachines, Novo Nordisk, Adaptive Sensory Technology, Genentech/Roche, Novartis, and Alcon outside the submitted work. Jensen reported no relevant financial disclosures.

Eyenuk Inc. provided the camera and automated screening software used in the study reported by Rajagopal and coauthors and was involved in the data collection and management, but otherwise had no role in the design or conduct of this research. Rajagopal had no personal financial disclosures.
 

A version of this article appeared on Medscape.com.