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Genitourinary Symptoms in Men: Canaries in the Coal Mine for Underlying Chronic Disease

Article Type
Changed
Wed, 09/18/2024 - 10:24

 

At age 57, a senior scientific researcher in Santa Barbara, California, complained of chronic erectile dysfunction (ED) in what had been a sexually active marriage. “I just couldn’t get an erection, let alone sustain one. Apart from that, I maybe felt a bit tired but generally okay,” he said. Though seemingly well otherwise, 18 months later he was dead of a hereditary right-sided colon cancer.

While not all cases of ED are associated with a dire outcome, the genitourinary signals of ED and lower urinary tract symptoms (LUTS), especially nocturia, serve as sentinel indicators of the presence of, or risk factors for, serious chronic conditions. These commonly include cardiovascular disease (CVD), diabetes, and metabolic syndrome and are associated with obesity, depression, and obstructive sleep apnea.

Sometimes these serious conditions may stay under the radar until men seek help for ED or LUTS.

“We know that among men who had a heart attack, 50% had some degree of ED within 3 years of their cardiac event,” Sam Tafari, MBBS, of the Endocrine and Metabolic Unit at Royal Adelaide Hospital in Adelaide, South Australia, said in an interview.

That’s the bad news. The good news is that these two problems may specifically incentivize men to seek timely care for serious conditions they might otherwise not get, according to Dr. Tafari. And primary care doctors are ideally positioned to get men early multifaceted care. He recently coauthored a call to action on this issue in a review appearing in the Journal of Men’s Health.

In Dr. Tafari’s experience, most patients seeking urological care are unaware of the multiple conditions linked to ED and LUTS. “Many consider these to be due to issues like low testosterone, which actually make up a very small proportion of cases of ED,” he said. Aging, obesity, inactivity, smoking, alcohol abuse, and prescription and street drugs can also contribute to the development of ED.

In most affected men, ED is of vascular etiology, with endothelial dysfunction of the inner lining of blood vessels and smooth muscle the common denominator.

This dysfunction causes inadequate blood supply to both the coronary and the penile arteries, so ED and CVD are considered different manifestations of the same systemic disorder. Because the tumescence-controlling cavernosal vessels of the penis are considerably smaller, the same level of arteriopathy causes a more severe reduction in blood in the erectile tissue. As a result, ED often precedes CVD and presents an early opportunity to screen men for CVD.

As to the mechanisms behind LUTS, Peter N. Tsambarlis, MD, a urologist at Northwestern Medicine in Chicago, subscribes to the inflammation theory. “Suboptimal health issues such as high [blood] pressure, blood lipids, and blood glucose lead to chronic widespread inflammation, which makes the bladder less flexible as a storage vessel,” he explained. “It’s not able to stretch adequately overnight to hold the urine until morning.”
 

Ask Early, Ask Often

Jeffrey P. Weiss, MD, PhD, chair of the Department of Urology at SUNY Downstate Health Sciences University in Brooklyn, New York, has done research that uncovered a relationship between structural cardiac disease and nocturia. “So if you had to ask a patient a single question that would point to a global health issue, it would be ‘Do you have frequent nighttime urination,’ ” he said.

It’s never too soon to ask men about these symptoms, said Dr. Tsambarlis. The best time to raise issues of ED and LUTS is when a man enters primary care — regardless of age or absence of symptoms. “That way you have a baseline and can watch for changes and do early intervention as needed. Men don’t usually want to bring up sexual dysfunction or urinary health, but asking doesn’t need to dominate the visit,” he said.

Dr. Tafari recommends that primary care physicians adopt a targeted approach using ED and nocturia as entry points for engaging men in their healthcare. While acknowledging that primary care physicians have an ever-growing checklist of questions to ask patients and hardly need one more thing to screen for, he suggests asking two quick, and easy “before you go” genitourinary queries:

  • Are you having trouble with erections or having sex?
  • Are you getting up at night to pass urine more than once?

“The men really appreciate being asked,” he said. “But what worries me is all the men we don’t see who have these symptoms but don’t know they’re important, and no one is asking about them.”

Gideon Richards, MD, a urologist at the Northwell Health Physician Partners Smith Institute for Urology at Garden City, and director of Men’s Health, Central Region, for Northwell Health in New Hyde Park, both in New York, said erectile problems should not wait for specialty care. By the time men with ED are referred to urology, they may already have failed treatment with first-line phosphodiesterase 5 inhibitor therapy, he said. “A significant proportion will have arteriogenic erectile dysfunction, a measurable decrease in the amount of blood flow into the erectile bodies.”

 

 

Addressing the Issue

Addressing genitourinary-signaled issues has the double benefit of easing ED and LUTS and improving men’s health and longevity and may help narrow the worldwide gender gap in life expectancy. As a recent global analysis found, there’s a 5-year longevity disparity favoring women over men. Biology aside, men do not access healthcare as often as women, who consult their general practitioners regularly throughout their lifespan for multiple reasons, including reproductive care, and more screening programs are aimed at women.

Added Dr. Tsambarlis, “Men should know that losing weight and switching to a healthy lifestyle can improve sexual function about half as much as phosphodiesterase 5 inhibitors such as sildenafil [Viagra] or tadalafil [Cialis].”

“Many, however, would prefer just to take drugs rather than change their lifestyle and lose weight. There are certainly effective options available, but these are not uniformly effective,” said Dr. Weiss.

Dr. Tafari’s group is designing a short, simple, culturally acceptable screening tool for use in primary care practice and will monitor its impact on physician prescribing habits and overall men’s health outcomes.

Dr. Tafari received funding from the Hospital Research Foundation and Freemasons Centre for Male Health and Wellbeing in Adelaide, South Australia. Dr. Tafari, Dr. Tsambarlis, Dr. Weiss, and Dr. Richards had no relevant conflicts of interest to declare.
 

A version of this article appeared on Medscape.com.

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At age 57, a senior scientific researcher in Santa Barbara, California, complained of chronic erectile dysfunction (ED) in what had been a sexually active marriage. “I just couldn’t get an erection, let alone sustain one. Apart from that, I maybe felt a bit tired but generally okay,” he said. Though seemingly well otherwise, 18 months later he was dead of a hereditary right-sided colon cancer.

While not all cases of ED are associated with a dire outcome, the genitourinary signals of ED and lower urinary tract symptoms (LUTS), especially nocturia, serve as sentinel indicators of the presence of, or risk factors for, serious chronic conditions. These commonly include cardiovascular disease (CVD), diabetes, and metabolic syndrome and are associated with obesity, depression, and obstructive sleep apnea.

Sometimes these serious conditions may stay under the radar until men seek help for ED or LUTS.

“We know that among men who had a heart attack, 50% had some degree of ED within 3 years of their cardiac event,” Sam Tafari, MBBS, of the Endocrine and Metabolic Unit at Royal Adelaide Hospital in Adelaide, South Australia, said in an interview.

That’s the bad news. The good news is that these two problems may specifically incentivize men to seek timely care for serious conditions they might otherwise not get, according to Dr. Tafari. And primary care doctors are ideally positioned to get men early multifaceted care. He recently coauthored a call to action on this issue in a review appearing in the Journal of Men’s Health.

In Dr. Tafari’s experience, most patients seeking urological care are unaware of the multiple conditions linked to ED and LUTS. “Many consider these to be due to issues like low testosterone, which actually make up a very small proportion of cases of ED,” he said. Aging, obesity, inactivity, smoking, alcohol abuse, and prescription and street drugs can also contribute to the development of ED.

In most affected men, ED is of vascular etiology, with endothelial dysfunction of the inner lining of blood vessels and smooth muscle the common denominator.

This dysfunction causes inadequate blood supply to both the coronary and the penile arteries, so ED and CVD are considered different manifestations of the same systemic disorder. Because the tumescence-controlling cavernosal vessels of the penis are considerably smaller, the same level of arteriopathy causes a more severe reduction in blood in the erectile tissue. As a result, ED often precedes CVD and presents an early opportunity to screen men for CVD.

As to the mechanisms behind LUTS, Peter N. Tsambarlis, MD, a urologist at Northwestern Medicine in Chicago, subscribes to the inflammation theory. “Suboptimal health issues such as high [blood] pressure, blood lipids, and blood glucose lead to chronic widespread inflammation, which makes the bladder less flexible as a storage vessel,” he explained. “It’s not able to stretch adequately overnight to hold the urine until morning.”
 

Ask Early, Ask Often

Jeffrey P. Weiss, MD, PhD, chair of the Department of Urology at SUNY Downstate Health Sciences University in Brooklyn, New York, has done research that uncovered a relationship between structural cardiac disease and nocturia. “So if you had to ask a patient a single question that would point to a global health issue, it would be ‘Do you have frequent nighttime urination,’ ” he said.

It’s never too soon to ask men about these symptoms, said Dr. Tsambarlis. The best time to raise issues of ED and LUTS is when a man enters primary care — regardless of age or absence of symptoms. “That way you have a baseline and can watch for changes and do early intervention as needed. Men don’t usually want to bring up sexual dysfunction or urinary health, but asking doesn’t need to dominate the visit,” he said.

Dr. Tafari recommends that primary care physicians adopt a targeted approach using ED and nocturia as entry points for engaging men in their healthcare. While acknowledging that primary care physicians have an ever-growing checklist of questions to ask patients and hardly need one more thing to screen for, he suggests asking two quick, and easy “before you go” genitourinary queries:

  • Are you having trouble with erections or having sex?
  • Are you getting up at night to pass urine more than once?

“The men really appreciate being asked,” he said. “But what worries me is all the men we don’t see who have these symptoms but don’t know they’re important, and no one is asking about them.”

Gideon Richards, MD, a urologist at the Northwell Health Physician Partners Smith Institute for Urology at Garden City, and director of Men’s Health, Central Region, for Northwell Health in New Hyde Park, both in New York, said erectile problems should not wait for specialty care. By the time men with ED are referred to urology, they may already have failed treatment with first-line phosphodiesterase 5 inhibitor therapy, he said. “A significant proportion will have arteriogenic erectile dysfunction, a measurable decrease in the amount of blood flow into the erectile bodies.”

 

 

Addressing the Issue

Addressing genitourinary-signaled issues has the double benefit of easing ED and LUTS and improving men’s health and longevity and may help narrow the worldwide gender gap in life expectancy. As a recent global analysis found, there’s a 5-year longevity disparity favoring women over men. Biology aside, men do not access healthcare as often as women, who consult their general practitioners regularly throughout their lifespan for multiple reasons, including reproductive care, and more screening programs are aimed at women.

Added Dr. Tsambarlis, “Men should know that losing weight and switching to a healthy lifestyle can improve sexual function about half as much as phosphodiesterase 5 inhibitors such as sildenafil [Viagra] or tadalafil [Cialis].”

“Many, however, would prefer just to take drugs rather than change their lifestyle and lose weight. There are certainly effective options available, but these are not uniformly effective,” said Dr. Weiss.

Dr. Tafari’s group is designing a short, simple, culturally acceptable screening tool for use in primary care practice and will monitor its impact on physician prescribing habits and overall men’s health outcomes.

Dr. Tafari received funding from the Hospital Research Foundation and Freemasons Centre for Male Health and Wellbeing in Adelaide, South Australia. Dr. Tafari, Dr. Tsambarlis, Dr. Weiss, and Dr. Richards had no relevant conflicts of interest to declare.
 

A version of this article appeared on Medscape.com.

 

At age 57, a senior scientific researcher in Santa Barbara, California, complained of chronic erectile dysfunction (ED) in what had been a sexually active marriage. “I just couldn’t get an erection, let alone sustain one. Apart from that, I maybe felt a bit tired but generally okay,” he said. Though seemingly well otherwise, 18 months later he was dead of a hereditary right-sided colon cancer.

While not all cases of ED are associated with a dire outcome, the genitourinary signals of ED and lower urinary tract symptoms (LUTS), especially nocturia, serve as sentinel indicators of the presence of, or risk factors for, serious chronic conditions. These commonly include cardiovascular disease (CVD), diabetes, and metabolic syndrome and are associated with obesity, depression, and obstructive sleep apnea.

Sometimes these serious conditions may stay under the radar until men seek help for ED or LUTS.

“We know that among men who had a heart attack, 50% had some degree of ED within 3 years of their cardiac event,” Sam Tafari, MBBS, of the Endocrine and Metabolic Unit at Royal Adelaide Hospital in Adelaide, South Australia, said in an interview.

That’s the bad news. The good news is that these two problems may specifically incentivize men to seek timely care for serious conditions they might otherwise not get, according to Dr. Tafari. And primary care doctors are ideally positioned to get men early multifaceted care. He recently coauthored a call to action on this issue in a review appearing in the Journal of Men’s Health.

In Dr. Tafari’s experience, most patients seeking urological care are unaware of the multiple conditions linked to ED and LUTS. “Many consider these to be due to issues like low testosterone, which actually make up a very small proportion of cases of ED,” he said. Aging, obesity, inactivity, smoking, alcohol abuse, and prescription and street drugs can also contribute to the development of ED.

In most affected men, ED is of vascular etiology, with endothelial dysfunction of the inner lining of blood vessels and smooth muscle the common denominator.

This dysfunction causes inadequate blood supply to both the coronary and the penile arteries, so ED and CVD are considered different manifestations of the same systemic disorder. Because the tumescence-controlling cavernosal vessels of the penis are considerably smaller, the same level of arteriopathy causes a more severe reduction in blood in the erectile tissue. As a result, ED often precedes CVD and presents an early opportunity to screen men for CVD.

As to the mechanisms behind LUTS, Peter N. Tsambarlis, MD, a urologist at Northwestern Medicine in Chicago, subscribes to the inflammation theory. “Suboptimal health issues such as high [blood] pressure, blood lipids, and blood glucose lead to chronic widespread inflammation, which makes the bladder less flexible as a storage vessel,” he explained. “It’s not able to stretch adequately overnight to hold the urine until morning.”
 

Ask Early, Ask Often

Jeffrey P. Weiss, MD, PhD, chair of the Department of Urology at SUNY Downstate Health Sciences University in Brooklyn, New York, has done research that uncovered a relationship between structural cardiac disease and nocturia. “So if you had to ask a patient a single question that would point to a global health issue, it would be ‘Do you have frequent nighttime urination,’ ” he said.

It’s never too soon to ask men about these symptoms, said Dr. Tsambarlis. The best time to raise issues of ED and LUTS is when a man enters primary care — regardless of age or absence of symptoms. “That way you have a baseline and can watch for changes and do early intervention as needed. Men don’t usually want to bring up sexual dysfunction or urinary health, but asking doesn’t need to dominate the visit,” he said.

Dr. Tafari recommends that primary care physicians adopt a targeted approach using ED and nocturia as entry points for engaging men in their healthcare. While acknowledging that primary care physicians have an ever-growing checklist of questions to ask patients and hardly need one more thing to screen for, he suggests asking two quick, and easy “before you go” genitourinary queries:

  • Are you having trouble with erections or having sex?
  • Are you getting up at night to pass urine more than once?

“The men really appreciate being asked,” he said. “But what worries me is all the men we don’t see who have these symptoms but don’t know they’re important, and no one is asking about them.”

Gideon Richards, MD, a urologist at the Northwell Health Physician Partners Smith Institute for Urology at Garden City, and director of Men’s Health, Central Region, for Northwell Health in New Hyde Park, both in New York, said erectile problems should not wait for specialty care. By the time men with ED are referred to urology, they may already have failed treatment with first-line phosphodiesterase 5 inhibitor therapy, he said. “A significant proportion will have arteriogenic erectile dysfunction, a measurable decrease in the amount of blood flow into the erectile bodies.”

 

 

Addressing the Issue

Addressing genitourinary-signaled issues has the double benefit of easing ED and LUTS and improving men’s health and longevity and may help narrow the worldwide gender gap in life expectancy. As a recent global analysis found, there’s a 5-year longevity disparity favoring women over men. Biology aside, men do not access healthcare as often as women, who consult their general practitioners regularly throughout their lifespan for multiple reasons, including reproductive care, and more screening programs are aimed at women.

Added Dr. Tsambarlis, “Men should know that losing weight and switching to a healthy lifestyle can improve sexual function about half as much as phosphodiesterase 5 inhibitors such as sildenafil [Viagra] or tadalafil [Cialis].”

“Many, however, would prefer just to take drugs rather than change their lifestyle and lose weight. There are certainly effective options available, but these are not uniformly effective,” said Dr. Weiss.

Dr. Tafari’s group is designing a short, simple, culturally acceptable screening tool for use in primary care practice and will monitor its impact on physician prescribing habits and overall men’s health outcomes.

Dr. Tafari received funding from the Hospital Research Foundation and Freemasons Centre for Male Health and Wellbeing in Adelaide, South Australia. Dr. Tafari, Dr. Tsambarlis, Dr. Weiss, and Dr. Richards had no relevant conflicts of interest to declare.
 

A version of this article appeared on Medscape.com.

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Early vs Late Fast Window: Is One More Effective?

Article Type
Changed
Fri, 09/13/2024 - 11:29

 

A daily 8-hour eating window controls blood glucose whether followed early or late in the day by people at risk for type 2 diabetes, showed a time-restricted eating (TRE) study presented at the European Association for the Study of Diabetes (EASD) 2024 Annual Meeting.

The study, examining shifting the time of day for the 8-hour eating window along with a tightly controlled diet, found that 8 hours of TRE — whether early or late in the day — led to a significant improvement in the time spent within a normal daily blood glucose range and in glycemic variability.

“We didn’t show a benefit in terms of early versus late TRE, but we did show a benefit of time-restricted eating within a window of 8 h/d,” said study lead Kelly Bowden Davies, MSc, PhD, from Manchester Metropolitan University, Manchester, England, when presenting the work. “It doesn’t matter when you restrict eating, but if you restrict it to 8 hours then, according to our study, it benefits glycemic control in people at risk of type 2 diabetes.”

The researcher added that the effect was seen after only 3 days, and “demonstrates its therapeutic role in adults at risk of type 2 diabetes, which warrants investigation in the longer term.”

The current study examined the effect of shifting the time of day for the TRE window from early (8 AM-4 PM) to late (12 PM-8 PM) in people at risk of developing type 2 diabetes due to a lifestyle characterized as sedentary and poor diet.

Previous studies indicate that TRE, which limits when, but not what, individuals eat, can improve insulin sensitivity and A1c in people at risk for type 2 diabetes.

But Dr. Bowden Davies pointed out that the effect of TRE on glycemic variability remained unclear. While prior work had attributed the positive effects of TRE to reduced energy intake, this study provided a diet where energy consumption matched energy expenditure — taking into account sex, age, weight, height, and activity level, termed a “eucaloric” diet.

“Some research groups recognize that if we manipulate the time at which we eat, then we can better align with circadian metabolic rhythms to improve whole body insulin sensitivity and glycemic variability,” explained Dr. Bowden Davies. “It may be that eating in the morning may be better aligned [with circadian rhythms] and cause greater improvement in glucose control.”
 

Three-Day TRE Plan Led to Blood Glucose Control

In a cross-over study design, all 15 participants were randomized to follow the early and late TRE regimens with a 7-day washout period in the middle. Participants had a mean body mass index (BMI) of 27.7 kg/m2, had a mean waist circumference of 73 cm, were sedentary, and followed a poor diet.

“Participants were normoglycemic so had good glucose control, but due to having overweight and obesity, they are considered as having risk factors for the development of type 2 diabetes,” noted Dr. Bowden Davies.

Before the TRE period, participants provided researchers with a dietary record. If they started on the early TRE, they crossed over to the late TRE after the washout period, and vice versa, she explained.

Continuous glucose monitoring (FreeStyle Libre 2, Abbott Laboratories) was carried out across the study to assess the daily time spent in euglycemia (3.9-7.8 mmol/L) and provide markers of glycemic variability, including mean absolute glucose, coefficient of variation, and mean amplitude of glucose excursions. Blood draws both pre- and post-TRE period provided biochemical measurements, and anthropometric readings were also taken.

There were nine female participants, with a mean age of 52 years, a BMI of 28 kg/m2, and an A1c level of 37.9 mmol/mol (5.6%). They tended to snack across an eating period of 14 h/d or more (habitual eating). They were assigned to two different investigational eating patterns for 3-day durations: Early or late, and these findings were compared with those from participants who continued their habitual eating.

Participants were provided with a eucaloric, standardized diet [50% carbohydrates, 30% fat, and 20% protein] to be eaten during the TRE period, whereas they ate as usual (ie, as and what they wanted) when not on the TRE regimen.

No changes were seen in the biochemistry markers assessed. “Given they only followed the TRE for 3 days, this is unsurprising,” remarked Dr. Bowden Davies. “We did see weight loss after only 3 days of TRE of around 1.1 kg across the two interventions,” she reported.

Referring to the early vs late TRE regimen, she added that “we didn’t see a benefit [no significant differences in glycemic control] of early compared with late TRE, but we did see a benefit of restricting the eating window to 8 h/d, so both conditions [early and late TRE regimens] had a benefit on glucose control.”

Variables of blood glucose control were also reduced while on the TRE regimen compared with habitual eating (more than 14 h/d), with significantly increased time spent within the normal blood glucose range on average by 3.3%, and also reduced mean absolute glucose by 0.6 mmol/L, coefficient of variation by 2.6%, and mean amplitude of glucose excursions by 0.4 mmol/L.

“Within 3 days, this is quite striking,” Dr. Bowden Davies pointed out.

She added that these data were interim analyses, but “these are positive in terms of participants seeing a benefit in glucose control and glycemic variability, which is a risk factor for developing type 2 diabetes but also for microvascular complications. We also saw improved time in range in terms of tight glucose control.

“Even in 3 days, there were small, subtle differences which are subclinical — but this is not a clinical cohort. The results are statistically significant and a promising piece of data to suggest a feasible intervention that could be translated across different populations,” she said, adding that over a longer time period, changes between TRE timing might show changes in people at risk for type 2 diabetes who don’t have compromised circadian rhythms.

Moderating the session was Lutgarda Bozzetto, MD, from the University of Naples Federico II, Naples, Italy. She told this news organization, “It’s a hot topic right now, and the finding that there’s no difference in the time of day when the restricted eating is done suggests that in people at risk of diabetes, the hormonal flux and cycle involved in blood glucose control is not so strong or sensitive.”

Using a continuous glucose monitor, they can look at their blood glucose levels after eating, and this might “be powerful in guiding behavioral change,” said Dr. Bozzetto.

Abbott Laboratories funded the continuous glucose monitoring. Neither Dr. Bowden Davies nor Dr. Bozzetto had any other relevant financial disclosures.

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

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A daily 8-hour eating window controls blood glucose whether followed early or late in the day by people at risk for type 2 diabetes, showed a time-restricted eating (TRE) study presented at the European Association for the Study of Diabetes (EASD) 2024 Annual Meeting.

The study, examining shifting the time of day for the 8-hour eating window along with a tightly controlled diet, found that 8 hours of TRE — whether early or late in the day — led to a significant improvement in the time spent within a normal daily blood glucose range and in glycemic variability.

“We didn’t show a benefit in terms of early versus late TRE, but we did show a benefit of time-restricted eating within a window of 8 h/d,” said study lead Kelly Bowden Davies, MSc, PhD, from Manchester Metropolitan University, Manchester, England, when presenting the work. “It doesn’t matter when you restrict eating, but if you restrict it to 8 hours then, according to our study, it benefits glycemic control in people at risk of type 2 diabetes.”

The researcher added that the effect was seen after only 3 days, and “demonstrates its therapeutic role in adults at risk of type 2 diabetes, which warrants investigation in the longer term.”

The current study examined the effect of shifting the time of day for the TRE window from early (8 AM-4 PM) to late (12 PM-8 PM) in people at risk of developing type 2 diabetes due to a lifestyle characterized as sedentary and poor diet.

Previous studies indicate that TRE, which limits when, but not what, individuals eat, can improve insulin sensitivity and A1c in people at risk for type 2 diabetes.

But Dr. Bowden Davies pointed out that the effect of TRE on glycemic variability remained unclear. While prior work had attributed the positive effects of TRE to reduced energy intake, this study provided a diet where energy consumption matched energy expenditure — taking into account sex, age, weight, height, and activity level, termed a “eucaloric” diet.

“Some research groups recognize that if we manipulate the time at which we eat, then we can better align with circadian metabolic rhythms to improve whole body insulin sensitivity and glycemic variability,” explained Dr. Bowden Davies. “It may be that eating in the morning may be better aligned [with circadian rhythms] and cause greater improvement in glucose control.”
 

Three-Day TRE Plan Led to Blood Glucose Control

In a cross-over study design, all 15 participants were randomized to follow the early and late TRE regimens with a 7-day washout period in the middle. Participants had a mean body mass index (BMI) of 27.7 kg/m2, had a mean waist circumference of 73 cm, were sedentary, and followed a poor diet.

“Participants were normoglycemic so had good glucose control, but due to having overweight and obesity, they are considered as having risk factors for the development of type 2 diabetes,” noted Dr. Bowden Davies.

Before the TRE period, participants provided researchers with a dietary record. If they started on the early TRE, they crossed over to the late TRE after the washout period, and vice versa, she explained.

Continuous glucose monitoring (FreeStyle Libre 2, Abbott Laboratories) was carried out across the study to assess the daily time spent in euglycemia (3.9-7.8 mmol/L) and provide markers of glycemic variability, including mean absolute glucose, coefficient of variation, and mean amplitude of glucose excursions. Blood draws both pre- and post-TRE period provided biochemical measurements, and anthropometric readings were also taken.

There were nine female participants, with a mean age of 52 years, a BMI of 28 kg/m2, and an A1c level of 37.9 mmol/mol (5.6%). They tended to snack across an eating period of 14 h/d or more (habitual eating). They were assigned to two different investigational eating patterns for 3-day durations: Early or late, and these findings were compared with those from participants who continued their habitual eating.

Participants were provided with a eucaloric, standardized diet [50% carbohydrates, 30% fat, and 20% protein] to be eaten during the TRE period, whereas they ate as usual (ie, as and what they wanted) when not on the TRE regimen.

No changes were seen in the biochemistry markers assessed. “Given they only followed the TRE for 3 days, this is unsurprising,” remarked Dr. Bowden Davies. “We did see weight loss after only 3 days of TRE of around 1.1 kg across the two interventions,” she reported.

Referring to the early vs late TRE regimen, she added that “we didn’t see a benefit [no significant differences in glycemic control] of early compared with late TRE, but we did see a benefit of restricting the eating window to 8 h/d, so both conditions [early and late TRE regimens] had a benefit on glucose control.”

Variables of blood glucose control were also reduced while on the TRE regimen compared with habitual eating (more than 14 h/d), with significantly increased time spent within the normal blood glucose range on average by 3.3%, and also reduced mean absolute glucose by 0.6 mmol/L, coefficient of variation by 2.6%, and mean amplitude of glucose excursions by 0.4 mmol/L.

“Within 3 days, this is quite striking,” Dr. Bowden Davies pointed out.

She added that these data were interim analyses, but “these are positive in terms of participants seeing a benefit in glucose control and glycemic variability, which is a risk factor for developing type 2 diabetes but also for microvascular complications. We also saw improved time in range in terms of tight glucose control.

“Even in 3 days, there were small, subtle differences which are subclinical — but this is not a clinical cohort. The results are statistically significant and a promising piece of data to suggest a feasible intervention that could be translated across different populations,” she said, adding that over a longer time period, changes between TRE timing might show changes in people at risk for type 2 diabetes who don’t have compromised circadian rhythms.

Moderating the session was Lutgarda Bozzetto, MD, from the University of Naples Federico II, Naples, Italy. She told this news organization, “It’s a hot topic right now, and the finding that there’s no difference in the time of day when the restricted eating is done suggests that in people at risk of diabetes, the hormonal flux and cycle involved in blood glucose control is not so strong or sensitive.”

Using a continuous glucose monitor, they can look at their blood glucose levels after eating, and this might “be powerful in guiding behavioral change,” said Dr. Bozzetto.

Abbott Laboratories funded the continuous glucose monitoring. Neither Dr. Bowden Davies nor Dr. Bozzetto had any other relevant financial disclosures.

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

 

A daily 8-hour eating window controls blood glucose whether followed early or late in the day by people at risk for type 2 diabetes, showed a time-restricted eating (TRE) study presented at the European Association for the Study of Diabetes (EASD) 2024 Annual Meeting.

The study, examining shifting the time of day for the 8-hour eating window along with a tightly controlled diet, found that 8 hours of TRE — whether early or late in the day — led to a significant improvement in the time spent within a normal daily blood glucose range and in glycemic variability.

“We didn’t show a benefit in terms of early versus late TRE, but we did show a benefit of time-restricted eating within a window of 8 h/d,” said study lead Kelly Bowden Davies, MSc, PhD, from Manchester Metropolitan University, Manchester, England, when presenting the work. “It doesn’t matter when you restrict eating, but if you restrict it to 8 hours then, according to our study, it benefits glycemic control in people at risk of type 2 diabetes.”

The researcher added that the effect was seen after only 3 days, and “demonstrates its therapeutic role in adults at risk of type 2 diabetes, which warrants investigation in the longer term.”

The current study examined the effect of shifting the time of day for the TRE window from early (8 AM-4 PM) to late (12 PM-8 PM) in people at risk of developing type 2 diabetes due to a lifestyle characterized as sedentary and poor diet.

Previous studies indicate that TRE, which limits when, but not what, individuals eat, can improve insulin sensitivity and A1c in people at risk for type 2 diabetes.

But Dr. Bowden Davies pointed out that the effect of TRE on glycemic variability remained unclear. While prior work had attributed the positive effects of TRE to reduced energy intake, this study provided a diet where energy consumption matched energy expenditure — taking into account sex, age, weight, height, and activity level, termed a “eucaloric” diet.

“Some research groups recognize that if we manipulate the time at which we eat, then we can better align with circadian metabolic rhythms to improve whole body insulin sensitivity and glycemic variability,” explained Dr. Bowden Davies. “It may be that eating in the morning may be better aligned [with circadian rhythms] and cause greater improvement in glucose control.”
 

Three-Day TRE Plan Led to Blood Glucose Control

In a cross-over study design, all 15 participants were randomized to follow the early and late TRE regimens with a 7-day washout period in the middle. Participants had a mean body mass index (BMI) of 27.7 kg/m2, had a mean waist circumference of 73 cm, were sedentary, and followed a poor diet.

“Participants were normoglycemic so had good glucose control, but due to having overweight and obesity, they are considered as having risk factors for the development of type 2 diabetes,” noted Dr. Bowden Davies.

Before the TRE period, participants provided researchers with a dietary record. If they started on the early TRE, they crossed over to the late TRE after the washout period, and vice versa, she explained.

Continuous glucose monitoring (FreeStyle Libre 2, Abbott Laboratories) was carried out across the study to assess the daily time spent in euglycemia (3.9-7.8 mmol/L) and provide markers of glycemic variability, including mean absolute glucose, coefficient of variation, and mean amplitude of glucose excursions. Blood draws both pre- and post-TRE period provided biochemical measurements, and anthropometric readings were also taken.

There were nine female participants, with a mean age of 52 years, a BMI of 28 kg/m2, and an A1c level of 37.9 mmol/mol (5.6%). They tended to snack across an eating period of 14 h/d or more (habitual eating). They were assigned to two different investigational eating patterns for 3-day durations: Early or late, and these findings were compared with those from participants who continued their habitual eating.

Participants were provided with a eucaloric, standardized diet [50% carbohydrates, 30% fat, and 20% protein] to be eaten during the TRE period, whereas they ate as usual (ie, as and what they wanted) when not on the TRE regimen.

No changes were seen in the biochemistry markers assessed. “Given they only followed the TRE for 3 days, this is unsurprising,” remarked Dr. Bowden Davies. “We did see weight loss after only 3 days of TRE of around 1.1 kg across the two interventions,” she reported.

Referring to the early vs late TRE regimen, she added that “we didn’t see a benefit [no significant differences in glycemic control] of early compared with late TRE, but we did see a benefit of restricting the eating window to 8 h/d, so both conditions [early and late TRE regimens] had a benefit on glucose control.”

Variables of blood glucose control were also reduced while on the TRE regimen compared with habitual eating (more than 14 h/d), with significantly increased time spent within the normal blood glucose range on average by 3.3%, and also reduced mean absolute glucose by 0.6 mmol/L, coefficient of variation by 2.6%, and mean amplitude of glucose excursions by 0.4 mmol/L.

“Within 3 days, this is quite striking,” Dr. Bowden Davies pointed out.

She added that these data were interim analyses, but “these are positive in terms of participants seeing a benefit in glucose control and glycemic variability, which is a risk factor for developing type 2 diabetes but also for microvascular complications. We also saw improved time in range in terms of tight glucose control.

“Even in 3 days, there were small, subtle differences which are subclinical — but this is not a clinical cohort. The results are statistically significant and a promising piece of data to suggest a feasible intervention that could be translated across different populations,” she said, adding that over a longer time period, changes between TRE timing might show changes in people at risk for type 2 diabetes who don’t have compromised circadian rhythms.

Moderating the session was Lutgarda Bozzetto, MD, from the University of Naples Federico II, Naples, Italy. She told this news organization, “It’s a hot topic right now, and the finding that there’s no difference in the time of day when the restricted eating is done suggests that in people at risk of diabetes, the hormonal flux and cycle involved in blood glucose control is not so strong or sensitive.”

Using a continuous glucose monitor, they can look at their blood glucose levels after eating, and this might “be powerful in guiding behavioral change,” said Dr. Bozzetto.

Abbott Laboratories funded the continuous glucose monitoring. Neither Dr. Bowden Davies nor Dr. Bozzetto had any other relevant financial disclosures.

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

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Are Pharmacy Deserts Worsening Health Disparities?

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Fri, 09/13/2024 - 11:14

 

TOPLINE:

Pharmacy closures in the United States are creating “pharmacy deserts,” disproportionately affecting socially vulnerable communities. High social vulnerability and low primary care practitioner (PCP) density are linked to increased pharmacy desert density.

METHODOLOGY:

  • Data through 2020 on communities located 10 or more miles from the nearest retail pharmacy were sourced from TelePharm Map.
  • Counties were stratified as having a high pharmacy desert density if the number of pharmacy deserts per 1000 inhabitants was in the 80th percentile or higher.
  • Social vulnerability index and healthcare practitioner data were obtained from the Agency for Toxic Substances and Disease Registry and the Area Health Resources Files.
  • PCP density was calculated as the number of PCPs per 10,000 inhabitants.
  • A total of 3143 counties were analyzed, with 1447 (46%) having at least one pharmacy desert.

TAKEAWAY:

  • Counties with a high pharmacy desert density had a higher social vulnerability index than those with a low pharmacy desert density (P = .006).
  • Areas with a high pharmacy desert density had lower median PCP density than those with low or no pharmacy desert density (P < .001).
  • High social vulnerability index (odds ratio [OR], 1.35; 95% CI, 1.07-1.70; P = .01) and low PCP density (OR, 2.27; 95% CI, 1.80-2.86; P < .001) were associated with a higher likelihood for a county to have a high pharmacy desert density.
  • Pharmacy closures are leaving more individuals without easy access to medications, with disproportionate consequences for certain communities.

IN PRACTICE:

“As high pharmacy desert density counties also have a lower PCP density, patients residing in these regions face increased barriers to accessing primary healthcare needs,” wrote the authors of the study.

SOURCE:

The study was led by Giovanni Catalano, MD, Muhammad Muntazir Mehdi Khan, MBBS, and Timothy M. Pawlik, MD, PhD, MPH, MTS, MBA, Department of Surgery, The Ohio State University Wexner Medical Center in Columbus, Ohio. It was published online in JAMA Network Open.

LIMITATIONS:

The cross-sectional design of the study limited the ability to draw causal inferences. The study relied on public county-level data, which may not have captured all relevant variables. The use of the social vulnerability index and PCP density as proxies did not fully represent the complexity of pharmacy access issues. The study’s findings were not generalizable to regions outside the United States.

DISCLOSURES:

No relevant conflicts of interest were disclosed by the authors. Additional disclosures are noted in the original article.

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

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TOPLINE:

Pharmacy closures in the United States are creating “pharmacy deserts,” disproportionately affecting socially vulnerable communities. High social vulnerability and low primary care practitioner (PCP) density are linked to increased pharmacy desert density.

METHODOLOGY:

  • Data through 2020 on communities located 10 or more miles from the nearest retail pharmacy were sourced from TelePharm Map.
  • Counties were stratified as having a high pharmacy desert density if the number of pharmacy deserts per 1000 inhabitants was in the 80th percentile or higher.
  • Social vulnerability index and healthcare practitioner data were obtained from the Agency for Toxic Substances and Disease Registry and the Area Health Resources Files.
  • PCP density was calculated as the number of PCPs per 10,000 inhabitants.
  • A total of 3143 counties were analyzed, with 1447 (46%) having at least one pharmacy desert.

TAKEAWAY:

  • Counties with a high pharmacy desert density had a higher social vulnerability index than those with a low pharmacy desert density (P = .006).
  • Areas with a high pharmacy desert density had lower median PCP density than those with low or no pharmacy desert density (P < .001).
  • High social vulnerability index (odds ratio [OR], 1.35; 95% CI, 1.07-1.70; P = .01) and low PCP density (OR, 2.27; 95% CI, 1.80-2.86; P < .001) were associated with a higher likelihood for a county to have a high pharmacy desert density.
  • Pharmacy closures are leaving more individuals without easy access to medications, with disproportionate consequences for certain communities.

IN PRACTICE:

“As high pharmacy desert density counties also have a lower PCP density, patients residing in these regions face increased barriers to accessing primary healthcare needs,” wrote the authors of the study.

SOURCE:

The study was led by Giovanni Catalano, MD, Muhammad Muntazir Mehdi Khan, MBBS, and Timothy M. Pawlik, MD, PhD, MPH, MTS, MBA, Department of Surgery, The Ohio State University Wexner Medical Center in Columbus, Ohio. It was published online in JAMA Network Open.

LIMITATIONS:

The cross-sectional design of the study limited the ability to draw causal inferences. The study relied on public county-level data, which may not have captured all relevant variables. The use of the social vulnerability index and PCP density as proxies did not fully represent the complexity of pharmacy access issues. The study’s findings were not generalizable to regions outside the United States.

DISCLOSURES:

No relevant conflicts of interest were disclosed by the authors. Additional disclosures are noted in the original article.

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

 

TOPLINE:

Pharmacy closures in the United States are creating “pharmacy deserts,” disproportionately affecting socially vulnerable communities. High social vulnerability and low primary care practitioner (PCP) density are linked to increased pharmacy desert density.

METHODOLOGY:

  • Data through 2020 on communities located 10 or more miles from the nearest retail pharmacy were sourced from TelePharm Map.
  • Counties were stratified as having a high pharmacy desert density if the number of pharmacy deserts per 1000 inhabitants was in the 80th percentile or higher.
  • Social vulnerability index and healthcare practitioner data were obtained from the Agency for Toxic Substances and Disease Registry and the Area Health Resources Files.
  • PCP density was calculated as the number of PCPs per 10,000 inhabitants.
  • A total of 3143 counties were analyzed, with 1447 (46%) having at least one pharmacy desert.

TAKEAWAY:

  • Counties with a high pharmacy desert density had a higher social vulnerability index than those with a low pharmacy desert density (P = .006).
  • Areas with a high pharmacy desert density had lower median PCP density than those with low or no pharmacy desert density (P < .001).
  • High social vulnerability index (odds ratio [OR], 1.35; 95% CI, 1.07-1.70; P = .01) and low PCP density (OR, 2.27; 95% CI, 1.80-2.86; P < .001) were associated with a higher likelihood for a county to have a high pharmacy desert density.
  • Pharmacy closures are leaving more individuals without easy access to medications, with disproportionate consequences for certain communities.

IN PRACTICE:

“As high pharmacy desert density counties also have a lower PCP density, patients residing in these regions face increased barriers to accessing primary healthcare needs,” wrote the authors of the study.

SOURCE:

The study was led by Giovanni Catalano, MD, Muhammad Muntazir Mehdi Khan, MBBS, and Timothy M. Pawlik, MD, PhD, MPH, MTS, MBA, Department of Surgery, The Ohio State University Wexner Medical Center in Columbus, Ohio. It was published online in JAMA Network Open.

LIMITATIONS:

The cross-sectional design of the study limited the ability to draw causal inferences. The study relied on public county-level data, which may not have captured all relevant variables. The use of the social vulnerability index and PCP density as proxies did not fully represent the complexity of pharmacy access issues. The study’s findings were not generalizable to regions outside the United States.

DISCLOSURES:

No relevant conflicts of interest were disclosed by the authors. Additional disclosures are noted in the original article.

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

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UVA Defends Medical School Dean, Hospital CEO After Docs Call for Their Removal

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Changed
Thu, 09/12/2024 - 14:18

 

The University of Virginia (UVA) is defending the CEO of its health system and its medical school dean in the wake of a very public call for their removal.

At least 128 members of the University of Virginia faculty who are employed by both the medical school and the UVA Physicians Group wrote to the UVA Board of Visitors and its peer-elected faculty leaders, expressing no confidence in K. Craig Kent, MD, CEO of UVA Health and executive vice president for health affairs, and Melina Kibbe, MD, dean of the medical school and chief health affairs officer.

Dr. Kibbe, a vascular surgeon and researcher, is also the editor in chief of JAMA Surgery.

“We call for the immediate removal of Craig Kent and Melina Kibbe,” wrote the physicians.

The letter alleged that patient safety was compromised because doctors, nurses, and other staff were pressured to abstain from reporting safety concerns and that physicians had been hired “despite concerns regarding integrity and quality.” Those who raised safety concerns faced “explicit and implicit threats and retaliation,” including delays and denials of promotion and tenure, said the letter.

The September 5 letter did not include signatures. The authors said that names were being protected, but that they would share the names with a limited audience.

UVA President Jim Ryan took issue with the notion that the signees were anonymous. He said in his own letter to medical school faculty that some of the accusations were about matters that had already been addressed or that were being worked on. As far as allegations that he was not previously aware of, “we will do our best to investigate,” he said.

The faculty who signed the letter “have besmirched the reputations of not just Melina and Craig,” wrote Mr. Ryan. “They have unfairly — and I trust unwittingly — cast a shadow over the great work of the entire health system and medical school.”

The authors claimed that reports about bullying and harassment of trainees had been “suppressed, minimized, and subsequently altered.”

And they said that spending on leadership was prioritized over addressing clinical and technical staff shortages. Whistleblowers who reported fraud were not protected, and clinicians were pressured to modify patient records to “obfuscate adverse outcomes and boost productivity metrics,” they wrote.

The 128 members of the UVA Physicians Group who signed the letter represent about 10% of the 1400 medical school faculty members.

It is not the first time that Dr. Kent has been given a vote of no confidence. In 2017, when he was the dean of the College of Medicine at the Ohio State University, Dr. Kent was accused in a “no confidence” letter from 25 physicians and faculty of helping to undermine the school’s mission and taking actions that led to resignations and early retirements of many staff, the Columbus Dispatch reported.

William G. Crutchfield Jr., a member of the UVA Health System Board, defended Dr. Kent and Dr. Kibbe in a lengthy statement shared with this news organization. He said that UVA Health’s four hospitals had received “A” ratings for safety, and that the system has a 5.1% turnover rate compared with a national average of 8.3%.

Dr. Kent and Dr. Kibbe have recruited faculty from top academic medical centers, Mr. Crutchfield wrote.

“If our work environment were so toxic, these people would not have joined our faculty,” he wrote.

Mr. Crutchfield credited Dr. Kent and Dr. Kibbe with crafting a new 10-year strategic plan and for hiring a chief strategy officer to lead the plan — a move that replaced “expensive outside consultants.”

Mr. Ryan said in his letter that his inbox “is overflowing with testimonials from some of the 1200-plus faculty who did not sign the letter, who attest that the health system today — under Melina and Craig’s leadership — is in the best shape it has ever been in, and that they have addressed changes that have needed to be made for more than two decades.”

A request to see some of these positive testimonials was not answered by press time.

Mr. Crutchfield, like Mr. Ryan, said that the letter writers were doing more harm than good.

“If a small cabal of people hiding behind anonymity can force outstanding leaders out of UVA, it will make it extremely difficult to recruit outstanding new physicians, nurses, technicians, and administrators,” he wrote.

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

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The University of Virginia (UVA) is defending the CEO of its health system and its medical school dean in the wake of a very public call for their removal.

At least 128 members of the University of Virginia faculty who are employed by both the medical school and the UVA Physicians Group wrote to the UVA Board of Visitors and its peer-elected faculty leaders, expressing no confidence in K. Craig Kent, MD, CEO of UVA Health and executive vice president for health affairs, and Melina Kibbe, MD, dean of the medical school and chief health affairs officer.

Dr. Kibbe, a vascular surgeon and researcher, is also the editor in chief of JAMA Surgery.

“We call for the immediate removal of Craig Kent and Melina Kibbe,” wrote the physicians.

The letter alleged that patient safety was compromised because doctors, nurses, and other staff were pressured to abstain from reporting safety concerns and that physicians had been hired “despite concerns regarding integrity and quality.” Those who raised safety concerns faced “explicit and implicit threats and retaliation,” including delays and denials of promotion and tenure, said the letter.

The September 5 letter did not include signatures. The authors said that names were being protected, but that they would share the names with a limited audience.

UVA President Jim Ryan took issue with the notion that the signees were anonymous. He said in his own letter to medical school faculty that some of the accusations were about matters that had already been addressed or that were being worked on. As far as allegations that he was not previously aware of, “we will do our best to investigate,” he said.

The faculty who signed the letter “have besmirched the reputations of not just Melina and Craig,” wrote Mr. Ryan. “They have unfairly — and I trust unwittingly — cast a shadow over the great work of the entire health system and medical school.”

The authors claimed that reports about bullying and harassment of trainees had been “suppressed, minimized, and subsequently altered.”

And they said that spending on leadership was prioritized over addressing clinical and technical staff shortages. Whistleblowers who reported fraud were not protected, and clinicians were pressured to modify patient records to “obfuscate adverse outcomes and boost productivity metrics,” they wrote.

The 128 members of the UVA Physicians Group who signed the letter represent about 10% of the 1400 medical school faculty members.

It is not the first time that Dr. Kent has been given a vote of no confidence. In 2017, when he was the dean of the College of Medicine at the Ohio State University, Dr. Kent was accused in a “no confidence” letter from 25 physicians and faculty of helping to undermine the school’s mission and taking actions that led to resignations and early retirements of many staff, the Columbus Dispatch reported.

William G. Crutchfield Jr., a member of the UVA Health System Board, defended Dr. Kent and Dr. Kibbe in a lengthy statement shared with this news organization. He said that UVA Health’s four hospitals had received “A” ratings for safety, and that the system has a 5.1% turnover rate compared with a national average of 8.3%.

Dr. Kent and Dr. Kibbe have recruited faculty from top academic medical centers, Mr. Crutchfield wrote.

“If our work environment were so toxic, these people would not have joined our faculty,” he wrote.

Mr. Crutchfield credited Dr. Kent and Dr. Kibbe with crafting a new 10-year strategic plan and for hiring a chief strategy officer to lead the plan — a move that replaced “expensive outside consultants.”

Mr. Ryan said in his letter that his inbox “is overflowing with testimonials from some of the 1200-plus faculty who did not sign the letter, who attest that the health system today — under Melina and Craig’s leadership — is in the best shape it has ever been in, and that they have addressed changes that have needed to be made for more than two decades.”

A request to see some of these positive testimonials was not answered by press time.

Mr. Crutchfield, like Mr. Ryan, said that the letter writers were doing more harm than good.

“If a small cabal of people hiding behind anonymity can force outstanding leaders out of UVA, it will make it extremely difficult to recruit outstanding new physicians, nurses, technicians, and administrators,” he wrote.

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

 

The University of Virginia (UVA) is defending the CEO of its health system and its medical school dean in the wake of a very public call for their removal.

At least 128 members of the University of Virginia faculty who are employed by both the medical school and the UVA Physicians Group wrote to the UVA Board of Visitors and its peer-elected faculty leaders, expressing no confidence in K. Craig Kent, MD, CEO of UVA Health and executive vice president for health affairs, and Melina Kibbe, MD, dean of the medical school and chief health affairs officer.

Dr. Kibbe, a vascular surgeon and researcher, is also the editor in chief of JAMA Surgery.

“We call for the immediate removal of Craig Kent and Melina Kibbe,” wrote the physicians.

The letter alleged that patient safety was compromised because doctors, nurses, and other staff were pressured to abstain from reporting safety concerns and that physicians had been hired “despite concerns regarding integrity and quality.” Those who raised safety concerns faced “explicit and implicit threats and retaliation,” including delays and denials of promotion and tenure, said the letter.

The September 5 letter did not include signatures. The authors said that names were being protected, but that they would share the names with a limited audience.

UVA President Jim Ryan took issue with the notion that the signees were anonymous. He said in his own letter to medical school faculty that some of the accusations were about matters that had already been addressed or that were being worked on. As far as allegations that he was not previously aware of, “we will do our best to investigate,” he said.

The faculty who signed the letter “have besmirched the reputations of not just Melina and Craig,” wrote Mr. Ryan. “They have unfairly — and I trust unwittingly — cast a shadow over the great work of the entire health system and medical school.”

The authors claimed that reports about bullying and harassment of trainees had been “suppressed, minimized, and subsequently altered.”

And they said that spending on leadership was prioritized over addressing clinical and technical staff shortages. Whistleblowers who reported fraud were not protected, and clinicians were pressured to modify patient records to “obfuscate adverse outcomes and boost productivity metrics,” they wrote.

The 128 members of the UVA Physicians Group who signed the letter represent about 10% of the 1400 medical school faculty members.

It is not the first time that Dr. Kent has been given a vote of no confidence. In 2017, when he was the dean of the College of Medicine at the Ohio State University, Dr. Kent was accused in a “no confidence” letter from 25 physicians and faculty of helping to undermine the school’s mission and taking actions that led to resignations and early retirements of many staff, the Columbus Dispatch reported.

William G. Crutchfield Jr., a member of the UVA Health System Board, defended Dr. Kent and Dr. Kibbe in a lengthy statement shared with this news organization. He said that UVA Health’s four hospitals had received “A” ratings for safety, and that the system has a 5.1% turnover rate compared with a national average of 8.3%.

Dr. Kent and Dr. Kibbe have recruited faculty from top academic medical centers, Mr. Crutchfield wrote.

“If our work environment were so toxic, these people would not have joined our faculty,” he wrote.

Mr. Crutchfield credited Dr. Kent and Dr. Kibbe with crafting a new 10-year strategic plan and for hiring a chief strategy officer to lead the plan — a move that replaced “expensive outside consultants.”

Mr. Ryan said in his letter that his inbox “is overflowing with testimonials from some of the 1200-plus faculty who did not sign the letter, who attest that the health system today — under Melina and Craig’s leadership — is in the best shape it has ever been in, and that they have addressed changes that have needed to be made for more than two decades.”

A request to see some of these positive testimonials was not answered by press time.

Mr. Crutchfield, like Mr. Ryan, said that the letter writers were doing more harm than good.

“If a small cabal of people hiding behind anonymity can force outstanding leaders out of UVA, it will make it extremely difficult to recruit outstanding new physicians, nurses, technicians, and administrators,” he wrote.

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

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Beyond Weight Loss, Limited Bariatric Surgery Benefits in Older Adults

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Changed
Thu, 09/12/2024 - 12:53

 

TOPLINE:

For older adults with obesity, bariatric surgery does not appear to significantly reduce the risk for obesity-related cancer and cardiovascular disease (CVD), as it does in younger adults.

METHODOLOGY:

  • Bariatric surgery has been shown to decrease the risk for obesity-related cancer and CVD but is typically reserved for patients aged < 60 years. Whether the same holds for patients who undergo surgery at older ages is unclear.
  • Researchers analyzed nationwide data from three countries (Denmark, Finland, and Sweden) to compare patients with no history of cancer or CVD and age ≥ 60 years who underwent bariatric surgery against matched controls who received nonoperative treatment for obesity.
  • The main outcome was obesity-related cancer, defined as a composite outcome of breast, endometrial, esophageal, colorectal, and kidney cancer. The secondary outcome was CVD, defined as a composite of myocardial infarction, ischemic stroke, and cerebral hemorrhage.
  • Analyses were adjusted for diabetes, hypertension, peripheral vascular disease, chronic obstructive pulmonary disease, kidney disease, and frailty.

TAKEAWAY:

  • Of the 15,300 patients (66.4% women) included, 2550 underwent bariatric surgery (including gastric bypass in 1930) and 12,750 matched controls received nonoperative treatment for obesity.
  • During a median 5.8 years of follow-up, 658 (4.3%) people developed obesity-related cancer and 1436 (9.4%) developed CVD.
  • Bariatric surgery in adults aged ≥ 60 years was not associated with a reduced risk for obesity-related cancer (hazard ratio [HR], 0.81) or CVD (HR, 0.86) compared with matched nonoperative controls.
  • Bariatric surgery appeared to be associated with a decreased risk for obesity-related cancer in women (HR, 0.76).
  • There was a decreased risk for both obesity-related cancer (HR, 0.74) and CVD (HR, 0.82) in patients who underwent gastric bypass.

IN PRACTICE:

“The findings from this study suggest a limited role of bariatric surgery in older patients for the prevention of obesity-related cancer or cardiovascular disease,” the authors wrote, noting that this “may be explained by the poorer weight loss and resolution of comorbidities observed in patients who underwent surgery at an older age.”

SOURCE:

The study, with first author Peter Gerber, MD, PhD, Department of Surgery, Capio St Göran’s Hospital, Stockholm, Sweden, was published online in JAMA Network Open.

LIMITATIONS:

Data on smoking status and body mass index were not available. The observational design limited the ability to draw causal inferences. The null association between bariatric surgery and outcomes may be due to limited power.

DISCLOSURES:

The study was funded by the Swedish Society of Medicine. The authors reported no conflicts of interest.

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

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TOPLINE:

For older adults with obesity, bariatric surgery does not appear to significantly reduce the risk for obesity-related cancer and cardiovascular disease (CVD), as it does in younger adults.

METHODOLOGY:

  • Bariatric surgery has been shown to decrease the risk for obesity-related cancer and CVD but is typically reserved for patients aged < 60 years. Whether the same holds for patients who undergo surgery at older ages is unclear.
  • Researchers analyzed nationwide data from three countries (Denmark, Finland, and Sweden) to compare patients with no history of cancer or CVD and age ≥ 60 years who underwent bariatric surgery against matched controls who received nonoperative treatment for obesity.
  • The main outcome was obesity-related cancer, defined as a composite outcome of breast, endometrial, esophageal, colorectal, and kidney cancer. The secondary outcome was CVD, defined as a composite of myocardial infarction, ischemic stroke, and cerebral hemorrhage.
  • Analyses were adjusted for diabetes, hypertension, peripheral vascular disease, chronic obstructive pulmonary disease, kidney disease, and frailty.

TAKEAWAY:

  • Of the 15,300 patients (66.4% women) included, 2550 underwent bariatric surgery (including gastric bypass in 1930) and 12,750 matched controls received nonoperative treatment for obesity.
  • During a median 5.8 years of follow-up, 658 (4.3%) people developed obesity-related cancer and 1436 (9.4%) developed CVD.
  • Bariatric surgery in adults aged ≥ 60 years was not associated with a reduced risk for obesity-related cancer (hazard ratio [HR], 0.81) or CVD (HR, 0.86) compared with matched nonoperative controls.
  • Bariatric surgery appeared to be associated with a decreased risk for obesity-related cancer in women (HR, 0.76).
  • There was a decreased risk for both obesity-related cancer (HR, 0.74) and CVD (HR, 0.82) in patients who underwent gastric bypass.

IN PRACTICE:

“The findings from this study suggest a limited role of bariatric surgery in older patients for the prevention of obesity-related cancer or cardiovascular disease,” the authors wrote, noting that this “may be explained by the poorer weight loss and resolution of comorbidities observed in patients who underwent surgery at an older age.”

SOURCE:

The study, with first author Peter Gerber, MD, PhD, Department of Surgery, Capio St Göran’s Hospital, Stockholm, Sweden, was published online in JAMA Network Open.

LIMITATIONS:

Data on smoking status and body mass index were not available. The observational design limited the ability to draw causal inferences. The null association between bariatric surgery and outcomes may be due to limited power.

DISCLOSURES:

The study was funded by the Swedish Society of Medicine. The authors reported no conflicts of interest.

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

 

TOPLINE:

For older adults with obesity, bariatric surgery does not appear to significantly reduce the risk for obesity-related cancer and cardiovascular disease (CVD), as it does in younger adults.

METHODOLOGY:

  • Bariatric surgery has been shown to decrease the risk for obesity-related cancer and CVD but is typically reserved for patients aged < 60 years. Whether the same holds for patients who undergo surgery at older ages is unclear.
  • Researchers analyzed nationwide data from three countries (Denmark, Finland, and Sweden) to compare patients with no history of cancer or CVD and age ≥ 60 years who underwent bariatric surgery against matched controls who received nonoperative treatment for obesity.
  • The main outcome was obesity-related cancer, defined as a composite outcome of breast, endometrial, esophageal, colorectal, and kidney cancer. The secondary outcome was CVD, defined as a composite of myocardial infarction, ischemic stroke, and cerebral hemorrhage.
  • Analyses were adjusted for diabetes, hypertension, peripheral vascular disease, chronic obstructive pulmonary disease, kidney disease, and frailty.

TAKEAWAY:

  • Of the 15,300 patients (66.4% women) included, 2550 underwent bariatric surgery (including gastric bypass in 1930) and 12,750 matched controls received nonoperative treatment for obesity.
  • During a median 5.8 years of follow-up, 658 (4.3%) people developed obesity-related cancer and 1436 (9.4%) developed CVD.
  • Bariatric surgery in adults aged ≥ 60 years was not associated with a reduced risk for obesity-related cancer (hazard ratio [HR], 0.81) or CVD (HR, 0.86) compared with matched nonoperative controls.
  • Bariatric surgery appeared to be associated with a decreased risk for obesity-related cancer in women (HR, 0.76).
  • There was a decreased risk for both obesity-related cancer (HR, 0.74) and CVD (HR, 0.82) in patients who underwent gastric bypass.

IN PRACTICE:

“The findings from this study suggest a limited role of bariatric surgery in older patients for the prevention of obesity-related cancer or cardiovascular disease,” the authors wrote, noting that this “may be explained by the poorer weight loss and resolution of comorbidities observed in patients who underwent surgery at an older age.”

SOURCE:

The study, with first author Peter Gerber, MD, PhD, Department of Surgery, Capio St Göran’s Hospital, Stockholm, Sweden, was published online in JAMA Network Open.

LIMITATIONS:

Data on smoking status and body mass index were not available. The observational design limited the ability to draw causal inferences. The null association between bariatric surgery and outcomes may be due to limited power.

DISCLOSURES:

The study was funded by the Swedish Society of Medicine. The authors reported no conflicts of interest.

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

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Diabetes Increases Injury Risk: A Troubling Trend

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Changed
Wed, 09/11/2024 - 15:38

 

In 2024, a record number of people are celebrating their 65th birthdays. Increasing age is associated with a higher risk for falls, fractures, and other injuries that may require hospitalization. 

In older adults with type 1 and type 2 diabetes, the risk for falls is double that seen in older people without these conditions. Increased clinician awareness of the many factors that result in this higher risk in people with diabetes, and timely implementation of strategies to prevent falls, are essential.

The annual incidence of falls in people with diabetes older than 65 years is about 39%, compared with 19% among those without diabetes. People with diabetes on insulin face an even greater increased risk for falls compared with those who are not using insulin (94% vs 27% increased risk).

Many well-known aspects of diabetes contribute to this greater risk. These include decreased sensorimotor function, musculoskeletal and neuromuscular deficits, foot and body pain, poor vision, hypoglycemic episodes, pharmacologic complications, and problems with hearing and balance. 

Optimal management of diabetes and its complications is essential, and the American Diabetes Association has developed clear guidelines for clinicians to follow to reduce the risk for diabetes related complications and manage these conditions.

The prevalence of diabetic peripheral neuropathy increases with age and duration of diabetes. People with diabetic peripheral neuropathy and diminished sensation on their feet are at increased risk for loss of postural control. Loss of proprioceptive feedback (the ability to sense movement, action and location) during standing and walking leads increases the risk for falls.

In addition, less physical activity, impaired muscle strength, and suboptimal postural control all influence gait patterns and increase the risk for falling. Adults with diabetes have a two to three times higher risk for sarcopenia (decreased muscle strength and muscle mass). They also have low plantar flexion strength, causing increased displacement of their center of gravity, which in turn reduces their maximum forward stride and may result in falls and injury.

Many people with diabetes experience neuropathic foot and body pain, requiring psychotropic and other medications that may exacerbate the risk, such as amitriptyline and duloxetine. Furthermore, older adults with diabetes are more likely to take more prescription medications and may be more sensitive to effects of multiple medications than are individuals without diabetes.

A hazard of managing diabetes, particularly with insulin, is the increased risk for unexpected low blood glucose levels. These episodes can also occur in patients taking certain kinds of oral diabetes medications, but they are more common in those on insulin. Low blood glucose can cause dizziness, confusion, and postural instability, increasing the risk for falling.

Diabetic eye complications include retinopathy, macular edema, cataracts, and glaucoma. In a study of close to 10,000 middle-aged and older adults with diabetes, those with moderate eye complications had almost double the risk of falls as those without eye complications.

Another concern with diabetes is its effect on nerves and blood vessels in the inner ear, leading to a negative effect on balance and hearing loss, both of which are also associated with a higher risk for falling and injury.

Clinicians can reduce the risk for falls in patients by taking measures to improve diabetes control and reduce the risk for microvascular disease affecting the nerves, eyes, and ears. 

In addition, exercises that optimize muscle mass, bone strength, gait, and balance, and use of specialized footwear in people with neuropathy, may reduce fall risk. Chair yoga and tai chi have also been shown to be helpful. Clinicians can also advise patients on commonsense strategies to implement in their homes, such as ensuring proper lighting, reducing, clutter and minimizing the use of floor rugs.

The risk for falls and the associated risk for fracture and possible hospitalization are of significant concern in older adults — particularly those with diabetes, and even more so in those with diabetes who are on insulin. It is our responsibility as clinicians to implement strategies to optimize diabetes control in our patients and monitor them for microvascular and other complications that may increase this risk, and manage them appropriately if and when these complications occur.

Madhusmita Misra, Professor, Chair, Physician-in-Chief, Department of Pediatrics, University of Virginia and UVA Health Children’s, Charlottesville, has disclosed being a key opinion leader for Lumos Pharma. Sidhartha Pani, Assistant Professor, Department of Internal Medicine, UVA School of Medicine; Medical Director, Department of General Medicine, Same Day Care Clinic, Charlottesville, disclosed no relevant financial relationships.

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

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In 2024, a record number of people are celebrating their 65th birthdays. Increasing age is associated with a higher risk for falls, fractures, and other injuries that may require hospitalization. 

In older adults with type 1 and type 2 diabetes, the risk for falls is double that seen in older people without these conditions. Increased clinician awareness of the many factors that result in this higher risk in people with diabetes, and timely implementation of strategies to prevent falls, are essential.

The annual incidence of falls in people with diabetes older than 65 years is about 39%, compared with 19% among those without diabetes. People with diabetes on insulin face an even greater increased risk for falls compared with those who are not using insulin (94% vs 27% increased risk).

Many well-known aspects of diabetes contribute to this greater risk. These include decreased sensorimotor function, musculoskeletal and neuromuscular deficits, foot and body pain, poor vision, hypoglycemic episodes, pharmacologic complications, and problems with hearing and balance. 

Optimal management of diabetes and its complications is essential, and the American Diabetes Association has developed clear guidelines for clinicians to follow to reduce the risk for diabetes related complications and manage these conditions.

The prevalence of diabetic peripheral neuropathy increases with age and duration of diabetes. People with diabetic peripheral neuropathy and diminished sensation on their feet are at increased risk for loss of postural control. Loss of proprioceptive feedback (the ability to sense movement, action and location) during standing and walking leads increases the risk for falls.

In addition, less physical activity, impaired muscle strength, and suboptimal postural control all influence gait patterns and increase the risk for falling. Adults with diabetes have a two to three times higher risk for sarcopenia (decreased muscle strength and muscle mass). They also have low plantar flexion strength, causing increased displacement of their center of gravity, which in turn reduces their maximum forward stride and may result in falls and injury.

Many people with diabetes experience neuropathic foot and body pain, requiring psychotropic and other medications that may exacerbate the risk, such as amitriptyline and duloxetine. Furthermore, older adults with diabetes are more likely to take more prescription medications and may be more sensitive to effects of multiple medications than are individuals without diabetes.

A hazard of managing diabetes, particularly with insulin, is the increased risk for unexpected low blood glucose levels. These episodes can also occur in patients taking certain kinds of oral diabetes medications, but they are more common in those on insulin. Low blood glucose can cause dizziness, confusion, and postural instability, increasing the risk for falling.

Diabetic eye complications include retinopathy, macular edema, cataracts, and glaucoma. In a study of close to 10,000 middle-aged and older adults with diabetes, those with moderate eye complications had almost double the risk of falls as those without eye complications.

Another concern with diabetes is its effect on nerves and blood vessels in the inner ear, leading to a negative effect on balance and hearing loss, both of which are also associated with a higher risk for falling and injury.

Clinicians can reduce the risk for falls in patients by taking measures to improve diabetes control and reduce the risk for microvascular disease affecting the nerves, eyes, and ears. 

In addition, exercises that optimize muscle mass, bone strength, gait, and balance, and use of specialized footwear in people with neuropathy, may reduce fall risk. Chair yoga and tai chi have also been shown to be helpful. Clinicians can also advise patients on commonsense strategies to implement in their homes, such as ensuring proper lighting, reducing, clutter and minimizing the use of floor rugs.

The risk for falls and the associated risk for fracture and possible hospitalization are of significant concern in older adults — particularly those with diabetes, and even more so in those with diabetes who are on insulin. It is our responsibility as clinicians to implement strategies to optimize diabetes control in our patients and monitor them for microvascular and other complications that may increase this risk, and manage them appropriately if and when these complications occur.

Madhusmita Misra, Professor, Chair, Physician-in-Chief, Department of Pediatrics, University of Virginia and UVA Health Children’s, Charlottesville, has disclosed being a key opinion leader for Lumos Pharma. Sidhartha Pani, Assistant Professor, Department of Internal Medicine, UVA School of Medicine; Medical Director, Department of General Medicine, Same Day Care Clinic, Charlottesville, disclosed no relevant financial relationships.

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

 

In 2024, a record number of people are celebrating their 65th birthdays. Increasing age is associated with a higher risk for falls, fractures, and other injuries that may require hospitalization. 

In older adults with type 1 and type 2 diabetes, the risk for falls is double that seen in older people without these conditions. Increased clinician awareness of the many factors that result in this higher risk in people with diabetes, and timely implementation of strategies to prevent falls, are essential.

The annual incidence of falls in people with diabetes older than 65 years is about 39%, compared with 19% among those without diabetes. People with diabetes on insulin face an even greater increased risk for falls compared with those who are not using insulin (94% vs 27% increased risk).

Many well-known aspects of diabetes contribute to this greater risk. These include decreased sensorimotor function, musculoskeletal and neuromuscular deficits, foot and body pain, poor vision, hypoglycemic episodes, pharmacologic complications, and problems with hearing and balance. 

Optimal management of diabetes and its complications is essential, and the American Diabetes Association has developed clear guidelines for clinicians to follow to reduce the risk for diabetes related complications and manage these conditions.

The prevalence of diabetic peripheral neuropathy increases with age and duration of diabetes. People with diabetic peripheral neuropathy and diminished sensation on their feet are at increased risk for loss of postural control. Loss of proprioceptive feedback (the ability to sense movement, action and location) during standing and walking leads increases the risk for falls.

In addition, less physical activity, impaired muscle strength, and suboptimal postural control all influence gait patterns and increase the risk for falling. Adults with diabetes have a two to three times higher risk for sarcopenia (decreased muscle strength and muscle mass). They also have low plantar flexion strength, causing increased displacement of their center of gravity, which in turn reduces their maximum forward stride and may result in falls and injury.

Many people with diabetes experience neuropathic foot and body pain, requiring psychotropic and other medications that may exacerbate the risk, such as amitriptyline and duloxetine. Furthermore, older adults with diabetes are more likely to take more prescription medications and may be more sensitive to effects of multiple medications than are individuals without diabetes.

A hazard of managing diabetes, particularly with insulin, is the increased risk for unexpected low blood glucose levels. These episodes can also occur in patients taking certain kinds of oral diabetes medications, but they are more common in those on insulin. Low blood glucose can cause dizziness, confusion, and postural instability, increasing the risk for falling.

Diabetic eye complications include retinopathy, macular edema, cataracts, and glaucoma. In a study of close to 10,000 middle-aged and older adults with diabetes, those with moderate eye complications had almost double the risk of falls as those without eye complications.

Another concern with diabetes is its effect on nerves and blood vessels in the inner ear, leading to a negative effect on balance and hearing loss, both of which are also associated with a higher risk for falling and injury.

Clinicians can reduce the risk for falls in patients by taking measures to improve diabetes control and reduce the risk for microvascular disease affecting the nerves, eyes, and ears. 

In addition, exercises that optimize muscle mass, bone strength, gait, and balance, and use of specialized footwear in people with neuropathy, may reduce fall risk. Chair yoga and tai chi have also been shown to be helpful. Clinicians can also advise patients on commonsense strategies to implement in their homes, such as ensuring proper lighting, reducing, clutter and minimizing the use of floor rugs.

The risk for falls and the associated risk for fracture and possible hospitalization are of significant concern in older adults — particularly those with diabetes, and even more so in those with diabetes who are on insulin. It is our responsibility as clinicians to implement strategies to optimize diabetes control in our patients and monitor them for microvascular and other complications that may increase this risk, and manage them appropriately if and when these complications occur.

Madhusmita Misra, Professor, Chair, Physician-in-Chief, Department of Pediatrics, University of Virginia and UVA Health Children’s, Charlottesville, has disclosed being a key opinion leader for Lumos Pharma. Sidhartha Pani, Assistant Professor, Department of Internal Medicine, UVA School of Medicine; Medical Director, Department of General Medicine, Same Day Care Clinic, Charlottesville, disclosed no relevant financial relationships.

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

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The Silent Exodus: Are Nurse Practitioners and Physician Assistants Quiet Quitting?

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Changed
Wed, 09/11/2024 - 14:47

 

While she cared deeply about her work, Melissa Adams*, a family nurse practitioner (NP) in Madison, Alabama, was being frequently triple-booked, didn’t feel respected by her office manager, and started to worry about becoming burned out. When she sought help, “the administration was tone-deaf,” she said. “When I asked about what I could do to prevent burnout, they sent me an article about it. It was clear to me that asking for respite from triple-booking and asking to be respected by my office manager wasn’t being heard ... so I thought, ‘how do I fly under the radar and get by with what I can?’ ” That meant focusing on patient care and refusing to take on additional responsibilities, like training new hires or working with students.

“You’re overworked and underpaid, and you start giving less and less of yourself,” Ms. Adams said in an interview.

Quiet quitting, defined as performing only the assigned tasks of the job without making any extra effort or going the proverbial extra mile, has gained attention in the press in recent years. A Gallup poll found that about 50% of the workforce were “quiet quitters” or disengaged.

It may be even more prevalent in healthcare, where a recent survey found that 57% of frontline medical staff, including NPs and physician assistants (PAs), report being disengaged at work.
 

The Causes of Quiet Quitting

Potential causes of quiet quitting among PAs and NPs include:

  • Unrealistic care expectations. They ask you to give your all to patients, handle everything, and do it all in under 15 minutes since that’s how much time the appointment allows, Ms. Adams said.
  • Lack of trust or respect. Physicians don’t always respect the role that PAs and NPs play in a practice.
  • Dissatisfaction with leadership or administration. There’s often a feeling that the PA or NP isn’t “heard” or appreciated.
  • Dissatisfaction with pay or working conditions.
  • Moral injury. “There’s no way to escape being morally injured when you work with an at-risk population,” said Ms. Adams. “You may see someone who has 20-24 determinants of health, and you’re expected to schlep them through in 8 minutes — you know you’re not able to do what they need.”

What Quiet Quitting Looks Like

Terri Smith*, an NP at an academic medical center outpatient clinic in rural Vermont, said that, while she feels appreciated by her patients and her team, there’s poor communication from the administration, which has caused her to quietly quit.

“I stopped saying ‘yes’ to all the normal committee work and the extra stuff that used to add a lot to my professional enjoyment,” she said. “The last couple of years, my whole motto is to nod and smile when administration says to do something — to put your head down and take care of your patients.”

While the term “quiet quitting” may be new, the issue is not, said Bridget Roberts, PhD, a healthcare executive who ran a large physician’s group of 100 healthcare providers in Jacksonville, Florida, for a decade. “Quiet quitting is a fancy title for employees who are completely disengaged,” said Dr. Roberts. “When they’re on the way out, they ‘check the box’. That’s not a new thing.”

“Typically, the first thing you see is a lot of frustration in that they aren’t able to complete the tasks they have at hand,” said Rebecca Day, PMNHP, a doctoral-educated NP and director of nursing practice at a Federally Qualified Health Center in Corbin, Kentucky. “Staff may be overworked and not have enough time to do what’s required of them with patient care as well as the paperwork required behind the scenes. It [quiet quitting] is doing just enough to get by, but shortcutting as much as they can to try to save some time.”
 

Addressing Quiet Quitting

Those kinds of shortcuts may affect patients, admits Ms. Smith. “I do think it starts to seep into patient care,” she said. “And that really doesn’t feel good ... at our institution, I’m not just an NP — I’m the nurse, the doctor, the secretary — I’m everybody, and for the last year, almost every single day in clinic, I’m apologizing [to a patient] because we can’t do something.”

Watching for this frustration can help alert administrators to NPs and PAs who may be “checking out” at work. Open lines of communication can help you address the issue. “Ask questions like ‘What could we do differently to make your day easier?’” said Dr. Roberts. Understanding the day-to-day issues NPs and PAs face at work can help in developing a plan to address disengagement.

When Dr. Day sees quiet quitting at her practice, she talks with the advance practice provider about what’s causing the issue. “’Are you overworked? Are you understaffed? Are there problems at home? Do you feel you’re receiving inadequate pay?’ ” she said. “The first thing to do is address that and find mutual ground on the issues…deal with the person as a person and then go back and deal with the person as an employee. If your staff isn’t happy, your clinic isn’t going to be productive.”

Finally, while reasons for quiet quitting may vary, cultivating a collaborative atmosphere where NPs and PAs feel appreciated and valued can help reduce the risk for quiet quitting. “Get to know your advanced practice providers,” said Ms. Adams. “Understand their strengths and what they’re about. It’s not an ‘us vs them’ ... there is a lot more commonality when we approach it that way.” Respect for the integral role that NPs and PAs play in your practice can help reduce the risk for quiet quitting — and help provide better patient care.

*Names have been changed.

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

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While she cared deeply about her work, Melissa Adams*, a family nurse practitioner (NP) in Madison, Alabama, was being frequently triple-booked, didn’t feel respected by her office manager, and started to worry about becoming burned out. When she sought help, “the administration was tone-deaf,” she said. “When I asked about what I could do to prevent burnout, they sent me an article about it. It was clear to me that asking for respite from triple-booking and asking to be respected by my office manager wasn’t being heard ... so I thought, ‘how do I fly under the radar and get by with what I can?’ ” That meant focusing on patient care and refusing to take on additional responsibilities, like training new hires or working with students.

“You’re overworked and underpaid, and you start giving less and less of yourself,” Ms. Adams said in an interview.

Quiet quitting, defined as performing only the assigned tasks of the job without making any extra effort or going the proverbial extra mile, has gained attention in the press in recent years. A Gallup poll found that about 50% of the workforce were “quiet quitters” or disengaged.

It may be even more prevalent in healthcare, where a recent survey found that 57% of frontline medical staff, including NPs and physician assistants (PAs), report being disengaged at work.
 

The Causes of Quiet Quitting

Potential causes of quiet quitting among PAs and NPs include:

  • Unrealistic care expectations. They ask you to give your all to patients, handle everything, and do it all in under 15 minutes since that’s how much time the appointment allows, Ms. Adams said.
  • Lack of trust or respect. Physicians don’t always respect the role that PAs and NPs play in a practice.
  • Dissatisfaction with leadership or administration. There’s often a feeling that the PA or NP isn’t “heard” or appreciated.
  • Dissatisfaction with pay or working conditions.
  • Moral injury. “There’s no way to escape being morally injured when you work with an at-risk population,” said Ms. Adams. “You may see someone who has 20-24 determinants of health, and you’re expected to schlep them through in 8 minutes — you know you’re not able to do what they need.”

What Quiet Quitting Looks Like

Terri Smith*, an NP at an academic medical center outpatient clinic in rural Vermont, said that, while she feels appreciated by her patients and her team, there’s poor communication from the administration, which has caused her to quietly quit.

“I stopped saying ‘yes’ to all the normal committee work and the extra stuff that used to add a lot to my professional enjoyment,” she said. “The last couple of years, my whole motto is to nod and smile when administration says to do something — to put your head down and take care of your patients.”

While the term “quiet quitting” may be new, the issue is not, said Bridget Roberts, PhD, a healthcare executive who ran a large physician’s group of 100 healthcare providers in Jacksonville, Florida, for a decade. “Quiet quitting is a fancy title for employees who are completely disengaged,” said Dr. Roberts. “When they’re on the way out, they ‘check the box’. That’s not a new thing.”

“Typically, the first thing you see is a lot of frustration in that they aren’t able to complete the tasks they have at hand,” said Rebecca Day, PMNHP, a doctoral-educated NP and director of nursing practice at a Federally Qualified Health Center in Corbin, Kentucky. “Staff may be overworked and not have enough time to do what’s required of them with patient care as well as the paperwork required behind the scenes. It [quiet quitting] is doing just enough to get by, but shortcutting as much as they can to try to save some time.”
 

Addressing Quiet Quitting

Those kinds of shortcuts may affect patients, admits Ms. Smith. “I do think it starts to seep into patient care,” she said. “And that really doesn’t feel good ... at our institution, I’m not just an NP — I’m the nurse, the doctor, the secretary — I’m everybody, and for the last year, almost every single day in clinic, I’m apologizing [to a patient] because we can’t do something.”

Watching for this frustration can help alert administrators to NPs and PAs who may be “checking out” at work. Open lines of communication can help you address the issue. “Ask questions like ‘What could we do differently to make your day easier?’” said Dr. Roberts. Understanding the day-to-day issues NPs and PAs face at work can help in developing a plan to address disengagement.

When Dr. Day sees quiet quitting at her practice, she talks with the advance practice provider about what’s causing the issue. “’Are you overworked? Are you understaffed? Are there problems at home? Do you feel you’re receiving inadequate pay?’ ” she said. “The first thing to do is address that and find mutual ground on the issues…deal with the person as a person and then go back and deal with the person as an employee. If your staff isn’t happy, your clinic isn’t going to be productive.”

Finally, while reasons for quiet quitting may vary, cultivating a collaborative atmosphere where NPs and PAs feel appreciated and valued can help reduce the risk for quiet quitting. “Get to know your advanced practice providers,” said Ms. Adams. “Understand their strengths and what they’re about. It’s not an ‘us vs them’ ... there is a lot more commonality when we approach it that way.” Respect for the integral role that NPs and PAs play in your practice can help reduce the risk for quiet quitting — and help provide better patient care.

*Names have been changed.

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

 

While she cared deeply about her work, Melissa Adams*, a family nurse practitioner (NP) in Madison, Alabama, was being frequently triple-booked, didn’t feel respected by her office manager, and started to worry about becoming burned out. When she sought help, “the administration was tone-deaf,” she said. “When I asked about what I could do to prevent burnout, they sent me an article about it. It was clear to me that asking for respite from triple-booking and asking to be respected by my office manager wasn’t being heard ... so I thought, ‘how do I fly under the radar and get by with what I can?’ ” That meant focusing on patient care and refusing to take on additional responsibilities, like training new hires or working with students.

“You’re overworked and underpaid, and you start giving less and less of yourself,” Ms. Adams said in an interview.

Quiet quitting, defined as performing only the assigned tasks of the job without making any extra effort or going the proverbial extra mile, has gained attention in the press in recent years. A Gallup poll found that about 50% of the workforce were “quiet quitters” or disengaged.

It may be even more prevalent in healthcare, where a recent survey found that 57% of frontline medical staff, including NPs and physician assistants (PAs), report being disengaged at work.
 

The Causes of Quiet Quitting

Potential causes of quiet quitting among PAs and NPs include:

  • Unrealistic care expectations. They ask you to give your all to patients, handle everything, and do it all in under 15 minutes since that’s how much time the appointment allows, Ms. Adams said.
  • Lack of trust or respect. Physicians don’t always respect the role that PAs and NPs play in a practice.
  • Dissatisfaction with leadership or administration. There’s often a feeling that the PA or NP isn’t “heard” or appreciated.
  • Dissatisfaction with pay or working conditions.
  • Moral injury. “There’s no way to escape being morally injured when you work with an at-risk population,” said Ms. Adams. “You may see someone who has 20-24 determinants of health, and you’re expected to schlep them through in 8 minutes — you know you’re not able to do what they need.”

What Quiet Quitting Looks Like

Terri Smith*, an NP at an academic medical center outpatient clinic in rural Vermont, said that, while she feels appreciated by her patients and her team, there’s poor communication from the administration, which has caused her to quietly quit.

“I stopped saying ‘yes’ to all the normal committee work and the extra stuff that used to add a lot to my professional enjoyment,” she said. “The last couple of years, my whole motto is to nod and smile when administration says to do something — to put your head down and take care of your patients.”

While the term “quiet quitting” may be new, the issue is not, said Bridget Roberts, PhD, a healthcare executive who ran a large physician’s group of 100 healthcare providers in Jacksonville, Florida, for a decade. “Quiet quitting is a fancy title for employees who are completely disengaged,” said Dr. Roberts. “When they’re on the way out, they ‘check the box’. That’s not a new thing.”

“Typically, the first thing you see is a lot of frustration in that they aren’t able to complete the tasks they have at hand,” said Rebecca Day, PMNHP, a doctoral-educated NP and director of nursing practice at a Federally Qualified Health Center in Corbin, Kentucky. “Staff may be overworked and not have enough time to do what’s required of them with patient care as well as the paperwork required behind the scenes. It [quiet quitting] is doing just enough to get by, but shortcutting as much as they can to try to save some time.”
 

Addressing Quiet Quitting

Those kinds of shortcuts may affect patients, admits Ms. Smith. “I do think it starts to seep into patient care,” she said. “And that really doesn’t feel good ... at our institution, I’m not just an NP — I’m the nurse, the doctor, the secretary — I’m everybody, and for the last year, almost every single day in clinic, I’m apologizing [to a patient] because we can’t do something.”

Watching for this frustration can help alert administrators to NPs and PAs who may be “checking out” at work. Open lines of communication can help you address the issue. “Ask questions like ‘What could we do differently to make your day easier?’” said Dr. Roberts. Understanding the day-to-day issues NPs and PAs face at work can help in developing a plan to address disengagement.

When Dr. Day sees quiet quitting at her practice, she talks with the advance practice provider about what’s causing the issue. “’Are you overworked? Are you understaffed? Are there problems at home? Do you feel you’re receiving inadequate pay?’ ” she said. “The first thing to do is address that and find mutual ground on the issues…deal with the person as a person and then go back and deal with the person as an employee. If your staff isn’t happy, your clinic isn’t going to be productive.”

Finally, while reasons for quiet quitting may vary, cultivating a collaborative atmosphere where NPs and PAs feel appreciated and valued can help reduce the risk for quiet quitting. “Get to know your advanced practice providers,” said Ms. Adams. “Understand their strengths and what they’re about. It’s not an ‘us vs them’ ... there is a lot more commonality when we approach it that way.” Respect for the integral role that NPs and PAs play in your practice can help reduce the risk for quiet quitting — and help provide better patient care.

*Names have been changed.

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

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Eating the Right Fats May Help Patients Live Longer

Article Type
Changed
Wed, 09/11/2024 - 13:58

 

A diet in which the primary source of fat is plant sources is associated with decreased mortality. Animal fat, on the other hand, is associated with an increased risk for death. These are the results of a study published in JAMA Internal Medicine that followed more than 600,000 participants over 2 decades.

Bin Zhao, PhD, of the National Clinical Research Center for Metabolic Diseases at the Key Laboratory of Diabetes Immunology in Changsha, China, and colleagues concluded from these data that consuming plant-based fats instead of animal fats could be beneficial for health and improve survival.

It may not be so simple, however. “We are one step ahead of the publication: We no longer just distinguish between animal and plant fats but mainly consider the composition,” said Stefan Lorkowski, PhD, chair of biochemistry and physiology of nutrition at the Institute of Nutritional Sciences at the University of Jena in Germany, in response to inquiries from this news organization.
 

What’s in a Fat?

Although Dr. Zhao and colleagues studied the effect of different plant and animal fat sources (eg, grains, nuts, legumes, plant oils, red and white meat, dairy, eggs, and fish), they did not consider the composition of the fatty acids that they contained. “It matters which dairy products, which plant oils, and which fish are consumed,” said Dr. Lorkowski.

The data analyzed in the Chinese study come from a prospective cohort study (NIH-AARP Diet and Health Study) conducted in the United States from 1995 to 2019. At the beginning, the 407,531 study participants (average age, 61 years) filled out dietary questionnaires once. They were then followed for up to 24 years for total and cardiovascular mortality.

During this period, 185,111 study participants died, including 58,526 from cardiovascular diseases. Participants who consumed the most plant-based fats, according to the dietary questionnaires filled out in 1995, had a lower risk for death than those who consumed the least plant-based fats. Their overall mortality risk was 9% lower, and their cardiovascular mortality risk was 14% lower. This finding was especially noticeable when it came to plant fats from grains or plant oils.
 

Animal Fat and Mortality

In contrast, a higher intake of animal fat was associated with both a higher overall mortality risk (16%) and a higher cardiovascular mortality risk (14%). This was especially true for fat from dairy products and eggs.

A trend towards a reduced overall and cardiovascular mortality risk was observed for fat from fish. “The fact that only a trend towards fish consumption was observed may be due to the study having many more meat eaters than fish eaters,” said Dr. Lorkowski.

Another imbalance limits the significance of the study, he added. The two groups, those who primarily consumed plant fats and those who primarily consumed animal fats, were already distinct at the beginning of the study. Those who consumed more plant fats were more likely to have diabetes, a higher body mass index (BMI), higher energy intake, and higher alcohol consumption but consumed more fiber, fruits, and vegetables and were more physically active. “They may have been trying to live healthier because they were sicker,” said Dr. Lorkowski.
 

Potential Confounding

Dr. Zhao and his team adjusted the results for various potential confounding factors, including age, gender, BMI, ethnicity, smoking, physical activity, education, marital status, diabetes, health status, vitamin intake, protein, carbohydrates, fiber, trans fats, cholesterol intake, and alcohol consumption. However, according to Dr. Lorkowski, “statistical adjustment is always incomplete, and confounding cannot be completely ruled out.”

Nevertheless, these results provide relevant insights for dietary recommendations that could help improve health and related outcomes, according to the authors. “Replacement of 5% energy from animal fat with 5% energy from plant fat, particularly fat from grains or vegetable oils, was associated with a lower risk for mortality: 4%-24% reduction in overall mortality and 5%-30% reduction in cardiovascular disease mortality.”
 

Fat Composition Matters

Animal fat, however, should not simply be replaced with plant fat, said Dr. Lorkowski. “Cold-water fish, which provides important long-chain omega-3 fatty acids, is also considered animal fat. And palm and coconut fat, while plant-based, contain unhealthy long-chain saturated fats. And the type of plant oils also makes a difference, whether one uses corn germ or sunflower oil rich in omega-6 fatty acids or flaxseed or rapeseed oil rich in omega-3 fatty acids.

“A diet rich in unsaturated fats, with sufficient and balanced intake of omega-3 and omega-6 fatty acids, that is also abundant in fiber-rich carbohydrate sources and plant-based protein, is always better than too much fat from animal sources.”

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

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A diet in which the primary source of fat is plant sources is associated with decreased mortality. Animal fat, on the other hand, is associated with an increased risk for death. These are the results of a study published in JAMA Internal Medicine that followed more than 600,000 participants over 2 decades.

Bin Zhao, PhD, of the National Clinical Research Center for Metabolic Diseases at the Key Laboratory of Diabetes Immunology in Changsha, China, and colleagues concluded from these data that consuming plant-based fats instead of animal fats could be beneficial for health and improve survival.

It may not be so simple, however. “We are one step ahead of the publication: We no longer just distinguish between animal and plant fats but mainly consider the composition,” said Stefan Lorkowski, PhD, chair of biochemistry and physiology of nutrition at the Institute of Nutritional Sciences at the University of Jena in Germany, in response to inquiries from this news organization.
 

What’s in a Fat?

Although Dr. Zhao and colleagues studied the effect of different plant and animal fat sources (eg, grains, nuts, legumes, plant oils, red and white meat, dairy, eggs, and fish), they did not consider the composition of the fatty acids that they contained. “It matters which dairy products, which plant oils, and which fish are consumed,” said Dr. Lorkowski.

The data analyzed in the Chinese study come from a prospective cohort study (NIH-AARP Diet and Health Study) conducted in the United States from 1995 to 2019. At the beginning, the 407,531 study participants (average age, 61 years) filled out dietary questionnaires once. They were then followed for up to 24 years for total and cardiovascular mortality.

During this period, 185,111 study participants died, including 58,526 from cardiovascular diseases. Participants who consumed the most plant-based fats, according to the dietary questionnaires filled out in 1995, had a lower risk for death than those who consumed the least plant-based fats. Their overall mortality risk was 9% lower, and their cardiovascular mortality risk was 14% lower. This finding was especially noticeable when it came to plant fats from grains or plant oils.
 

Animal Fat and Mortality

In contrast, a higher intake of animal fat was associated with both a higher overall mortality risk (16%) and a higher cardiovascular mortality risk (14%). This was especially true for fat from dairy products and eggs.

A trend towards a reduced overall and cardiovascular mortality risk was observed for fat from fish. “The fact that only a trend towards fish consumption was observed may be due to the study having many more meat eaters than fish eaters,” said Dr. Lorkowski.

Another imbalance limits the significance of the study, he added. The two groups, those who primarily consumed plant fats and those who primarily consumed animal fats, were already distinct at the beginning of the study. Those who consumed more plant fats were more likely to have diabetes, a higher body mass index (BMI), higher energy intake, and higher alcohol consumption but consumed more fiber, fruits, and vegetables and were more physically active. “They may have been trying to live healthier because they were sicker,” said Dr. Lorkowski.
 

Potential Confounding

Dr. Zhao and his team adjusted the results for various potential confounding factors, including age, gender, BMI, ethnicity, smoking, physical activity, education, marital status, diabetes, health status, vitamin intake, protein, carbohydrates, fiber, trans fats, cholesterol intake, and alcohol consumption. However, according to Dr. Lorkowski, “statistical adjustment is always incomplete, and confounding cannot be completely ruled out.”

Nevertheless, these results provide relevant insights for dietary recommendations that could help improve health and related outcomes, according to the authors. “Replacement of 5% energy from animal fat with 5% energy from plant fat, particularly fat from grains or vegetable oils, was associated with a lower risk for mortality: 4%-24% reduction in overall mortality and 5%-30% reduction in cardiovascular disease mortality.”
 

Fat Composition Matters

Animal fat, however, should not simply be replaced with plant fat, said Dr. Lorkowski. “Cold-water fish, which provides important long-chain omega-3 fatty acids, is also considered animal fat. And palm and coconut fat, while plant-based, contain unhealthy long-chain saturated fats. And the type of plant oils also makes a difference, whether one uses corn germ or sunflower oil rich in omega-6 fatty acids or flaxseed or rapeseed oil rich in omega-3 fatty acids.

“A diet rich in unsaturated fats, with sufficient and balanced intake of omega-3 and omega-6 fatty acids, that is also abundant in fiber-rich carbohydrate sources and plant-based protein, is always better than too much fat from animal sources.”

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

 

A diet in which the primary source of fat is plant sources is associated with decreased mortality. Animal fat, on the other hand, is associated with an increased risk for death. These are the results of a study published in JAMA Internal Medicine that followed more than 600,000 participants over 2 decades.

Bin Zhao, PhD, of the National Clinical Research Center for Metabolic Diseases at the Key Laboratory of Diabetes Immunology in Changsha, China, and colleagues concluded from these data that consuming plant-based fats instead of animal fats could be beneficial for health and improve survival.

It may not be so simple, however. “We are one step ahead of the publication: We no longer just distinguish between animal and plant fats but mainly consider the composition,” said Stefan Lorkowski, PhD, chair of biochemistry and physiology of nutrition at the Institute of Nutritional Sciences at the University of Jena in Germany, in response to inquiries from this news organization.
 

What’s in a Fat?

Although Dr. Zhao and colleagues studied the effect of different plant and animal fat sources (eg, grains, nuts, legumes, plant oils, red and white meat, dairy, eggs, and fish), they did not consider the composition of the fatty acids that they contained. “It matters which dairy products, which plant oils, and which fish are consumed,” said Dr. Lorkowski.

The data analyzed in the Chinese study come from a prospective cohort study (NIH-AARP Diet and Health Study) conducted in the United States from 1995 to 2019. At the beginning, the 407,531 study participants (average age, 61 years) filled out dietary questionnaires once. They were then followed for up to 24 years for total and cardiovascular mortality.

During this period, 185,111 study participants died, including 58,526 from cardiovascular diseases. Participants who consumed the most plant-based fats, according to the dietary questionnaires filled out in 1995, had a lower risk for death than those who consumed the least plant-based fats. Their overall mortality risk was 9% lower, and their cardiovascular mortality risk was 14% lower. This finding was especially noticeable when it came to plant fats from grains or plant oils.
 

Animal Fat and Mortality

In contrast, a higher intake of animal fat was associated with both a higher overall mortality risk (16%) and a higher cardiovascular mortality risk (14%). This was especially true for fat from dairy products and eggs.

A trend towards a reduced overall and cardiovascular mortality risk was observed for fat from fish. “The fact that only a trend towards fish consumption was observed may be due to the study having many more meat eaters than fish eaters,” said Dr. Lorkowski.

Another imbalance limits the significance of the study, he added. The two groups, those who primarily consumed plant fats and those who primarily consumed animal fats, were already distinct at the beginning of the study. Those who consumed more plant fats were more likely to have diabetes, a higher body mass index (BMI), higher energy intake, and higher alcohol consumption but consumed more fiber, fruits, and vegetables and were more physically active. “They may have been trying to live healthier because they were sicker,” said Dr. Lorkowski.
 

Potential Confounding

Dr. Zhao and his team adjusted the results for various potential confounding factors, including age, gender, BMI, ethnicity, smoking, physical activity, education, marital status, diabetes, health status, vitamin intake, protein, carbohydrates, fiber, trans fats, cholesterol intake, and alcohol consumption. However, according to Dr. Lorkowski, “statistical adjustment is always incomplete, and confounding cannot be completely ruled out.”

Nevertheless, these results provide relevant insights for dietary recommendations that could help improve health and related outcomes, according to the authors. “Replacement of 5% energy from animal fat with 5% energy from plant fat, particularly fat from grains or vegetable oils, was associated with a lower risk for mortality: 4%-24% reduction in overall mortality and 5%-30% reduction in cardiovascular disease mortality.”
 

Fat Composition Matters

Animal fat, however, should not simply be replaced with plant fat, said Dr. Lorkowski. “Cold-water fish, which provides important long-chain omega-3 fatty acids, is also considered animal fat. And palm and coconut fat, while plant-based, contain unhealthy long-chain saturated fats. And the type of plant oils also makes a difference, whether one uses corn germ or sunflower oil rich in omega-6 fatty acids or flaxseed or rapeseed oil rich in omega-3 fatty acids.

“A diet rich in unsaturated fats, with sufficient and balanced intake of omega-3 and omega-6 fatty acids, that is also abundant in fiber-rich carbohydrate sources and plant-based protein, is always better than too much fat from animal sources.”

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

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A Simple Blood Test May Predict Cancer Risk in T2D

Article Type
Changed
Wed, 09/11/2024 - 13:30

 

TOPLINE:

— Elevated interleukin (IL) 6 levels are associated with an increased risk for obesity-related cancers in patients newly diagnosed with type 2 diabetes (T2D), potentially enabling the identification of higher-risk individuals through a simple blood test.

METHODOLOGY:

  • T2D is associated with an increased risk for obesity-related cancers, including breast, renal, uterine, thyroid, ovarian, and gastrointestinal cancers, as well as multiple myeloma, possibly because of chronic low-grade inflammation.
  • Researchers explored whether the markers of inflammation IL-6, tumor necrosis factor alpha (TNF-alpha), and high-sensitivity C-reactive protein (hsCRP) can serve as predictive biomarkers for obesity-related cancers in patients recently diagnosed with T2D.
  • They identified patients with recent-onset T2D and no prior history of cancer participating in the ongoing Danish Centre for Strategic Research in Type 2 Diabetes cohort study.
  • At study initiation, plasma levels of IL-6 and TNF-alpha were measured using Meso Scale Discovery assays, and serum levels of hsCRP were measured using immunofluorometric assays.

TAKEAWAY:

  • Among 6,466 eligible patients (40.5% women; median age, 60.9 years), 327 developed obesity-related cancers over a median follow-up of 8.8 years.
  • Each SD increase in log-transformed IL-6 levels increased the risk for obesity-related cancers by 19%.
  • The researchers did not find a strong association between TNF-alpha or hsCRP and obesity-related cancers.
  • The addition of baseline IL-6 levels to other well-known risk factors for obesity-related cancers improved the performance of a cancer prediction model from 0.685 to 0.693, translating to a small but important increase in the ability to predict whether an individual would develop one of these cancers.

IN PRACTICE:

“In future, a simple blood test could identify those at higher risk of the cancers,” said the study’s lead author in an accompanying press release.

SOURCE:

The study was led by Mathilde D. Bennetsen, Steno Diabetes Center Odense, Odense University Hospital, Odense, Denmark, and published online on August 27 as an early release from the European Association for the Study of Diabetes (EASD) 2024 Annual Meeting.

LIMITATIONS:

No limitations were discussed in this abstract. However, the reliance on registry data may have introduced potential biases related to data accuracy and completeness.

DISCLOSURES:

The Danish Centre for Strategic Research in Type 2 Diabetes was supported by grants from the Danish Agency for Science and the Novo Nordisk Foundation. The authors declared no conflicts of interest.

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

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TOPLINE:

— Elevated interleukin (IL) 6 levels are associated with an increased risk for obesity-related cancers in patients newly diagnosed with type 2 diabetes (T2D), potentially enabling the identification of higher-risk individuals through a simple blood test.

METHODOLOGY:

  • T2D is associated with an increased risk for obesity-related cancers, including breast, renal, uterine, thyroid, ovarian, and gastrointestinal cancers, as well as multiple myeloma, possibly because of chronic low-grade inflammation.
  • Researchers explored whether the markers of inflammation IL-6, tumor necrosis factor alpha (TNF-alpha), and high-sensitivity C-reactive protein (hsCRP) can serve as predictive biomarkers for obesity-related cancers in patients recently diagnosed with T2D.
  • They identified patients with recent-onset T2D and no prior history of cancer participating in the ongoing Danish Centre for Strategic Research in Type 2 Diabetes cohort study.
  • At study initiation, plasma levels of IL-6 and TNF-alpha were measured using Meso Scale Discovery assays, and serum levels of hsCRP were measured using immunofluorometric assays.

TAKEAWAY:

  • Among 6,466 eligible patients (40.5% women; median age, 60.9 years), 327 developed obesity-related cancers over a median follow-up of 8.8 years.
  • Each SD increase in log-transformed IL-6 levels increased the risk for obesity-related cancers by 19%.
  • The researchers did not find a strong association between TNF-alpha or hsCRP and obesity-related cancers.
  • The addition of baseline IL-6 levels to other well-known risk factors for obesity-related cancers improved the performance of a cancer prediction model from 0.685 to 0.693, translating to a small but important increase in the ability to predict whether an individual would develop one of these cancers.

IN PRACTICE:

“In future, a simple blood test could identify those at higher risk of the cancers,” said the study’s lead author in an accompanying press release.

SOURCE:

The study was led by Mathilde D. Bennetsen, Steno Diabetes Center Odense, Odense University Hospital, Odense, Denmark, and published online on August 27 as an early release from the European Association for the Study of Diabetes (EASD) 2024 Annual Meeting.

LIMITATIONS:

No limitations were discussed in this abstract. However, the reliance on registry data may have introduced potential biases related to data accuracy and completeness.

DISCLOSURES:

The Danish Centre for Strategic Research in Type 2 Diabetes was supported by grants from the Danish Agency for Science and the Novo Nordisk Foundation. The authors declared no conflicts of interest.

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

 

TOPLINE:

— Elevated interleukin (IL) 6 levels are associated with an increased risk for obesity-related cancers in patients newly diagnosed with type 2 diabetes (T2D), potentially enabling the identification of higher-risk individuals through a simple blood test.

METHODOLOGY:

  • T2D is associated with an increased risk for obesity-related cancers, including breast, renal, uterine, thyroid, ovarian, and gastrointestinal cancers, as well as multiple myeloma, possibly because of chronic low-grade inflammation.
  • Researchers explored whether the markers of inflammation IL-6, tumor necrosis factor alpha (TNF-alpha), and high-sensitivity C-reactive protein (hsCRP) can serve as predictive biomarkers for obesity-related cancers in patients recently diagnosed with T2D.
  • They identified patients with recent-onset T2D and no prior history of cancer participating in the ongoing Danish Centre for Strategic Research in Type 2 Diabetes cohort study.
  • At study initiation, plasma levels of IL-6 and TNF-alpha were measured using Meso Scale Discovery assays, and serum levels of hsCRP were measured using immunofluorometric assays.

TAKEAWAY:

  • Among 6,466 eligible patients (40.5% women; median age, 60.9 years), 327 developed obesity-related cancers over a median follow-up of 8.8 years.
  • Each SD increase in log-transformed IL-6 levels increased the risk for obesity-related cancers by 19%.
  • The researchers did not find a strong association between TNF-alpha or hsCRP and obesity-related cancers.
  • The addition of baseline IL-6 levels to other well-known risk factors for obesity-related cancers improved the performance of a cancer prediction model from 0.685 to 0.693, translating to a small but important increase in the ability to predict whether an individual would develop one of these cancers.

IN PRACTICE:

“In future, a simple blood test could identify those at higher risk of the cancers,” said the study’s lead author in an accompanying press release.

SOURCE:

The study was led by Mathilde D. Bennetsen, Steno Diabetes Center Odense, Odense University Hospital, Odense, Denmark, and published online on August 27 as an early release from the European Association for the Study of Diabetes (EASD) 2024 Annual Meeting.

LIMITATIONS:

No limitations were discussed in this abstract. However, the reliance on registry data may have introduced potential biases related to data accuracy and completeness.

DISCLOSURES:

The Danish Centre for Strategic Research in Type 2 Diabetes was supported by grants from the Danish Agency for Science and the Novo Nordisk Foundation. The authors declared no conflicts of interest.

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

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GLP-1 RA Therapy for Alcohol Use Disorder?

Article Type
Changed
Tue, 09/17/2024 - 19:46

 

This transcript has been edited for clarity. 

Akshay B. Jain, MD: Today we are very excited to have Dr. Leggio join us all the way from the National Institutes of Health (NIH). He is an addiction physician scientist in the intramural research program at NIH. Welcome, Dr. Leggio. Thanks for joining us. 

Lorenzo Leggio, MD, PhD: Thank you so much. 

Dr. Jain: We’ll get right into this. Your session was, in my mind, extremely informative. The session looked at glucagon-like peptide 1 receptor agonist (GLP-1 RA) therapy and its potential effects on mitigating alcohol misuse syndrome, so, reduction of alcohol addiction potentially. 

We’ve seen in some previous clinical trials, including many from your group, that alcohol use is known to be reduced — the overall risk of incidence, as well as recurrence of alcohol use — in individuals who are on GLP-1 RA therapy.

Can you share more insights about the data already out there? 

Dr. Leggio: At the preclinical level, we have a very robust line of studies, experiments, and publications looking at the effect of GLP-1 RAs, starting from exenatide up to, more recently, semaglutide. They show that these GLP-1 RAs do reduce alcohol drinking. They used different animal models of excessive alcohol drinking, using different species — for example, mice, rats, nonhuman primates — models that reflect the excessive alcohol drinking behavior that we see in patients, like physical alcohol dependence or binge-like alcohol drinking, and other behaviors in animal models that reflect the human condition.

In addition to that, we recently have seen an increase in human evidence that GLP-1 RAs may reduce alcohol drinking. For example, there is some anecdotal evidence and some analyses using social media showing that people on GLP-1 RAs report drinking less alcohol. 

There are also some pharmacoepidemiology studies which are very intriguing and quite promising. In this case, people have been looking at electronic medical records; they have used the pharmacoepidemiology approaches to match patients on GLP-1 RAs because of diabetes or obesity, and have compared and matched to patients on different drugs as the controls.

A study was recently published Nature Communications by a group in Cleveland in collaboration with Dr. Nora Volkow from the National Institute on Drug Abuse. This study shows the association between being on a GLP-1 RA and the lower incidence of alcohol use disorder and lower drinking.

There is also some promise from prospective randomized clinical trials. In particular, there was one clinical trial from Denmark, a well-known and -conducted clinical trial where they looked at exenatide, and they didn’t see an effect of exenatide compared with placebo in the main analysis. But in a subanalysis, they did see that exenatide reduced alcohol drinking, but only in patients with alcohol use disorder and obesity.

This suggests that these medications may work for some patients and not for other patients. That’s fine, because just like in any other field in medicine, including diabetes, obesity, hypertension, Parkinson’s, and depression, not all medications work for everybody. If these medications will work for alcohol addiction, we do not expect that they will work for everybody.

One ongoing question in the field is to try to identify the phenotypes or the subgroup of people who may be more responsive to these medications. 

Dr. Jain: This is such a fascinating field, and all these studies are coming out. In your review of all the literature so far, do you think this is dose dependent? Also, we see that, for instance, with certain individuals, when they take GLP-1 RA therapy, they might have a lot of gastrointestinal (GI) side effects. Recent studies have shown that the rate of these GI side effects does not necessarily correlate with the amount of weight loss. In the alcohol addiction field, do you think that the GI side effects, things like nausea, could also have a potential role in mitigating the alcohol addiction?

Dr. Leggio: This is a great question. They may play a role; they may contribute, too, but we don’t think that they are the driving mechanism of why people drink less, for at least a couple of reasons. 

One is that, similar to the obesity field, the data we have so far don’t necessarily show a relationship between the GI side effects and the reduction in drinking. Plus, the reduction in drinking is likely to happen later when many GI side effects are gone or attenuated. 

The second reason is from the neuroscience field. We are starting to better understand the mechanism at the brain level as to how these medications work. We don’t see that the nausea or, more generally, not feeling well — malaise, etc. — are driving mechanisms for how these medications work.

Again, it’s not to discount completely that the GI side effects may play a role, but I would say that, if anything, they may be more contributing to. And if they do, that will not be unique to this class of medication. For example, we have three medications approved by the US Food and Drug Administration (FDA) for alcohol use disorder.

One challenge we have in the addiction field is that many people don’t know that these medications exist — many primary care providers don’t know — and they are completely underutilized. Everybody here who is listening to us knows that roughly 85% of people with diabetes receive a medication for diabetes. For alcohol use disorder, the number is 2%. These are medications approved by the FDA. 

One of them is naltrexone, which does give GI symptoms — in particular, nausea and vomiting. The other medication is acamprosate, which does give diarrhea.

You have medications approved for alcohol disorder where you do have some GI symptoms, but they are not the mechanism either for how these medications help people to curb craving and reduce alcohol drinking.

Dr. Jain: What about the dose-dependent action? Do you think that GLP-1 RAs, at a lower dose, may not have an effect on alcohol use disorder vs at a higher dose, or is everyone a little different? 

Dr. Leggio: That’s a wonderful question. The short answer is, we don’t know, to be honest. Now, in some of the animal studies — my team has been in collaboration with other scientists in the NIH intramural research program, and also with scientists in academia, for example, at Scripps, UCLA — we see a dose response where the higher the dose, the higher the effect of the drug. In this case, semaglutide reduced binge drinking in a rat model of a physical alcohol dependence.

That said, I would be very cautious about claiming, based on the rodent data, that humans will have a dose response. It’s an open question. We really don’t know. Some of the pharmacoepidemiology data suggested that even lower doses — for example, using semaglutide for diabetes without going up to the obesity dose — may be just as effective as a higher dose in reducing the incidence of alcohol use disorder. 

It’s important also to keep in mind that the pharmacoepidemiology data are always an association. Reduction in alcohol disorder is associated with the prescription GLP-1 RA, but they don’t really replace the more gold-standard, double-blind, placebo-controlled randomized clinical trial. Nonetheless, with the pharmacoepidemiology data, I think there is an argument to at least hypothesize that people may respond well, even to lower doses. 

This also may be important from a safety standpoint. 

Basically, we need to wait for results in the next years to come from randomized clinical trials to better unfold the question about doses. For example, just anecdotally, I will tell you that in the clinical trial we are conducting right now at the NIH Intramural Research Program, for which I’m the principal investigator (PI), we are going up to 2.4 mg — the highest dose of semaglutide.

We are collaborating with Kyle Simmons, PhD, from Oklahoma State University. Our two studies are not like a two-site clinical trial, but they are harmonized. In Dr. Simmons’ clinical trial, they’re going up to 1.0 mg. We are excited about this team approach because the trials are slightly different, but they’re harmonized to the point that, once the studies are done, we’ll be able to combine and compare data to better answer the question about dosing, and many other questions.

Dr. Jain: From a clinical perspective, we see that many people who are battling alcohol use disorder may not have obesity. They might actually be on the leaner side, and hence, we may not want to use a high dose of GLP-1 RA therapy. It’ll be very exciting to see when these results come out.

This brings me to the next question. I think everyone would love to know why this happens. Why is GLP-1 RA having this effect on alcohol use disorder? I know that your group has done many animal studies, as you pointed out, and one of the postulated theories was the effect on the GABA neurotransmission pathway.

Can you tell us more about what you feel is the underlying mechanism of action here?

Dr. Leggio: I will start by saying that we don’t fully know. There are many open questions. If I can sidetrack for one second: We come up with the idea that, first of all, alcohol use disorder and substance use disorder are addictive behaviors, addictive disorders. We define addiction as a brain disease. 

Granted that addiction is a brain disease, it doesn’t mean that addiction works just in the brain in isolation. As we all know, the brain works in concert with the rest of the body. One specific approach my team has been taking is working on the analogy and the similarities between obesity and addiction to try to understand how the body-brain connection, such as the gut-brain-neuroendocrine pathway, may play a role in patients with addiction.

 

 

With that in mind, a large amount of work in my lab in the past 20 years — since I’ve been a PI — has been focused on studying this neuroendocrine pathways related to the gut-brain axis. For example, we have done work on insulin and leptin, primarily; we had done work on ghrelin, and since 2015 on the GLP-1 RAs.

With that in mind, the framework we are working on, which is also substantiated by many studies done by our team and other teams in the neuroscience field, kind of supports the idea that, similar to what we see in obesity, these medications may work by affecting what we call reward processing, or the seeking for addictive drugs, such as alcohol, and also the drugs such as the stimulants, opioids, nicotine, and so on.

The idea is that the mechanism is driven by the ability of the medication — semaglutide and all the GLP-1 RAs — to reduce the rewarding properties of alcohol and drugs. To maybe make the example more pragmatic, what does that mean? It means, for example, that a patient who typically has 10 drinks per day in the afternoon and night, while they are on the medication they may feel the lack of need to drink up to 10 to feel the same reward. 

They may be able to stop after two or three drinks, which means a significant harm reduction and a beneficial outcome. This also brings us to another mechanism, which may be related to society. We don’t fully understand how much the society mechanism, including society mechanism related to GI motility, may also play a role.

With that said, we don’t think that the effect of the GLP-1 RAs is merely due to alcohol being a calorie-based nutrient because, in fact, we see alcohol as an addictive drug, not as a nutrient. Also, the GLP-1 RAs, at least in animal models, seem to work on other addictive drugs that don’t have calories, such as nicotine, and possibly with cannabis, opioids, and stimulants.

Then on the molecular level, our team recently showed, in collaboration with Dr. Marisa Roberto from Scripps in La Jolla, California, that semaglutide may in fact change the GABA transmission at the level of some brain regions, such as the amygdala and the prefrontal cortex. These are brain regions that are well-established hubs that play a role in the mechanism underlying addiction. 

There are also some very exciting recent data showing how these medications may work not just on GABA or just on dopamine, which is the canonical way we conceive of reward processing, but by working on both by modulating GABA transmission — for example, at the ventral tegmental area and dopamine transmission at the nucleus accumbens.

Bottom line, if I summarize all of this, is that the mechanism is not fully understood, but there is definitely a contribution of this medication to effect and reward processing, possibly by altering the balance between GABA and dopamine. There are still some unknown questions, such as, are these mechanisms all brain driven or are they signaling from the periphery to the brain, or maybe both?

Also, as we all know, there are many differences across all these GLP-1 analogs in brain penetrance. Whether the drug needs to go to the brain to have an effect on alcohol drinking, cocaine seeking, or smoking is really an open question.

Dr. Jain: This is so thought-provoking. I guess the more we uncover, the more mesmerized we get with all the potential crosstalk. There is a large amount of overlap in the brain with each of these different things and how it all interplays with each other. 

Speaking of interplay, I’m thinking about how many people prone to having alcohol use disorder can potentially develop complications, one of these being chronic pancreatitis. This is a well-known complication that can occur in people having alcohol addiction. Along that same line, we know that previous history of pancreatitis is considered a use-with-caution, or we don’t want to use GLP-1 RA therapy in people who have had pancreatitis. 

Now it becomes this quagmire where people may have chronic pancreatitis, but we may want to consider GLP-1 RA therapy for management of alcohol use disorder. What are your thoughts about this, and the safety, potentially, in using it in these patients? 

Dr. Leggio: This is another wonderful question. That’s definitely a top priority in our mind, to address these kinds of questions. For example, our RCT does have, as core primary outcomes, not only the efficacy defined as a reduction in alcohol drinking, but also safety.

The reason is exactly what you just explained. There are many unanswered questions, including whether giving a GLP-1 RA and alcohol together may have synergistic effects and increase the likelihood of having pancreatitis. 

The good news is that, so far, based on the published literature, including the RCT done with exenatide in Denmark and published in 2022 and also the ongoing clinical trials — including my own clinical trial, but of course we are blind — pancreatitis has not been coming out as an adverse event.

However, it’s also true that it often happens in clinical medication development. Of course, we screen and select our population well. For example, we do exclude people who have a history of pancreatitis. We exclude people with high lipase or with any of the clinical symptomatology that makes us concerned about these people having pancreatitis. 

As often happens when you move a medication from clinical trials to clinical practice, we still need to understand whether this medication works in patients. I’m just speculating, but even if the clinical trials do not raise red flags in terms of increased risk for some side effects such as pancreatitis, I think it will be very important for practitioners to keep a close eye on the death risk regardless. 

It’s very interesting that it’s similar to alcohol liver disease. With pancreatitis, not every single patient with alcohol addiction has pancreatitis. We don’t really fully understand why some people develop pancreatitis and some people do not. The point being that there are many patients with alcohol addiction who don’t have pancreatitis and may benefit from these medications if they work. Again, we have to prove that in patients.

On the other side, as we all know, pancreatitis is a potentially life-threatening condition for those people who either have it or are at risk for it. I think we have to be very careful before we consider giving them a GLP-1 RA.

One could argue that alcohol is the leading cause of mortality and morbidity in the world. For example, right now, alcohol is the leading cause of liver disease. It’s the main reason for liver transplantation in our country. Alcohol is affecting thousands of people in terms of death and emergency room visits.

You could argue that the downside is not treating these people and they die because of alcohol addiction. A GLP-1 RA is not going to be for everybody. I will remind everybody that (1) we do have FDA-approved medications for alcohol addiction; and (2) there are also other medications not approved by the FDA, but with a proven efficacy in some clinical trials — for example, topiramate and gabapentin — and they’ve been endorsed by the American Psychiatric Association. 

There is also some evidence for another medication, baclofen, which has been endorsed by the American College of Gastroenterology for patients with alcohol addiction and liver disease.

The point I’m making is that it’s not that either we use the GLP-1 RAs or we have no other tools. We have other tools. I think we have to personalize the treatment based on the patient’s profile from a safety standpoint and from a phenotypic standpoint. 

Dr. Jain: I love that thought. I think individualization is the key here.

We know that people with diabetes have a higher risk for pancreatitis by virtue of having diabetes. People with obesity also have a higher risk for pancreatitis by virtue of having obesity. These are the two conditions where we are using a large amount of GLP-1 RA therapy. Again, the idea is looking at the person in front of us and then deciding, based on their past medical history and their current risk, whether or not a medication is a right fit for them.

I think more individualization here will come as we start using these medications that might be having potential effects on different organ systems. You mentioned a little bit about the liver, so a thought came in my mind. We know that people with diabetes who have alcohol use disorder are at a higher risk for potential hypoglycemia. If they have events when they have increased consumption of alcohol, there can be more hypoglycemia.

We now could potentially be using semaglutide or other GLP-1 RA therapy for management of alcohol use disorder. In your own experience in the studies that you’ve done or the literature that’s out there, has that been associated with an even higher risk for hypoglycemia? 

Dr. Leggio: It’s a wonderful question. I’m not aware of any formal and published report of that association. That said, your thinking from a physiopathologist standpoint makes total sense. I could not agree more. The fact that nothing has been published, at least to my knowledge, doesn’t mean that the death risk doesn’t exist. In fact, I agree with you that it does exist. 

Alcohol use disorder is interesting and tricky clinically because chronically, alcohol addiction or alcohol use disorder is associated with an increased risk for diabetes. Acutely, as you point out; and this could be with or without alcohol use disorder. An episode of a high volume of binge drinking may lead to hypoglycemia.

This is one of the reasons why people may show up to the emergency room with intoxication, and one of the symptoms detected at the emergency room is that they also have hypoglycemia in addition to vomiting, nausea, and everything else that we see in patients with acute intoxication.

Similar to the discussion about pancreatitis, as we work on understanding the possible role of GLP-1 RA in patients with alcohol use disorder, we do have to keep a close eye on the risk for hypoglycemia. The short answer is that this is not well established, but based on the simple concept of “first, do no harm,” I think we need to track that very carefully. 

In the ongoing clinical trial we’re doing in Maryland in my program at the NIH, we do just that. We are tracking glucose levels. Of course, patients come to clinic weekly, so unless they have symptoms, typically we don’t see anything at the time.

 

 

More important, we educate our patients when they go through the consent process. We tell them that this medication per se does not give hypoglycemia. In fact, we’re including people with diabetes, so for people on other medications like metformin, we explain to them that technically such a risk should not exist, but because you’re drinking alcohol in excessive amounts, you do have a potential higher risk. We just don’t know how significant that risk could be. 

We do a large amount of education at baseline when they enroll in our study. We also educate our patients on how to recognize early on the potential risk for hypoglycemia, exactly for the reasons you said. We explain to them the unknown potential that the GLP-1 RAs and alcohol together may synergize and give hypoglycemia.

Dr. Jain: I don’t know if you got this feeling at the ADA conference, but I felt, when attending all these sessions, that it seems like GLP-1 RA is the gift that keeps giving. We see the effect on diabetes, obesity, metabolic-associated steatotic liver disease, possibly with Alzheimer’s, chronic obstructive pulmonary disease, and so many things.

Now, of course, there’s potential use in alcohol use disorder. Do you think that using GLP-1 RA therapy is ready for prime time? Do you think we are now ready to prescribe this in people with alcohol use disorder?

Dr. Leggio: I would say we’re not there yet. As I mentioned at the beginning, the evidence keeps on growing. It’s getting stronger and stronger because the positive data keep on coming up. We have data from animal models, including the different species, ranging from rodents to nonhuman primates. We have anecdotal evidence and machine-learning approaches using, for example, big data and social media data. Now we have pharmacoepidemiology data and some small, initial, but still good randomized clinical trials.

What we are missing is the final step of having a substantial number of prospective, double-blind, placebo-controlled clinical trials to really prove or disprove whether these medications work, and to also better understand which patients may respond to these medications.

The good news is that there are many ongoing clinical trials. We are conducting a clinical trial in Maryland at the NIH. Dr. Simmons is doing a clinical trial at Oklahoma State University. Dr. Christian Hendershot at UNC is conducting a study at Chapel Hill. Dr. Josh Gowin is doing a study in Colorado. Dr. Anders Fink-Jensen is doing a study in Denmark. The momentum is very high. 

I’m only mentioning those people who are doing alcohol-semaglutide clinical trials. There are also people doing clinical trials on smoking, stimulants, and opioids. There are actually some very fresh, still unpublished data from Penn State that were presented publicly at conferences, showing how these drugs may reduce opioid craving, which is, of course, critically important, given that we’re in the middle of a fentanyl pandemic that is killing one person every 7 minutes, for example, in Baltimore. It’s very alarming and we need more treatments.

The bottom line is that it’s very promising, but we need to wait for these clinical trials to have a definitive answer. I would say that if you have a patient with diabetes, obesity, and also alcohol addiction, and they are on semaglutide or any other GLP-1 RA, and in addition to using the medication for diabetes and obesity, they also have a beneficial effect on their alcohol drinking, then that’s fantastic. At the end of the day, that’s the mission we all share: helping people. 

If it’s someone without obesity and diabetes, personally, at this stage, I will go with other medications that either have FDA approval or at least very solid evidence of efficacy from RCTs rather than going with the GLP-1 RA, at least until I see more definitive data from randomized clinical trials. 

There is a large amount of hope. We are hoping that these clinical trials will be positive. We are very enthusiastic and we’re also very thrilled to see that Novo Nordisk recently launched a gigantic multisite clinical trial with — I forgot how many sites, but it’s very large across Europe, America, and maybe other continents as well.

Their primary outcome is improvement in alcohol-related liver disease, but they’re also looking at alcohol drinking as a secondary outcome. That’s very important because, unlike in the diabetes field, in the addiction field, we do struggle to build partnership with the private sector because sometimes the addiction field is not seen as an appetitive field from pharma. 

We all know that the best success in any medication development story is when you put academia, the government, and pharma together. Think about the COVID-19 vaccine development. That’s unfortunately the exception rather than rule in the addiction field. 

With the company doing a large clinical trial in the alcohol field, although they focus more on the liver but they also looked at drinking, I really hope we’ll see more and more companies in the private sector take more and more interest in addiction. Also, I hope to see more and more partnership between the private sector, the government, and academia. 

Dr. Jain: Such exciting times, indeed. We can’t wait enough for the results of these and many other trials to come out. Dr. Leggio, it was an absolute delight chatting with you today. Thank you so much for joining us from ADA 2024.

Akshay B. Jain, MD, Clinical Instructor, Department of Endocrinology, University of British Columbia; Endocrinologist, TLC Diabetes and Endocrinology, Vancouver, British Columbia, Canada, has disclosed the following relevant financial relationships: Serve(d) as a speaker or a member of a speakers bureau for: Abbott; Acerus; AstraZeneca; Amgen; Bausch Healthcare; Bayer; Boehringer Ingelheim; Care to Know; CCRN; Connected in Motion; CPD Network; Dexcom; Diabetes Canada; Eli Lilly; GSK; HLS Therapeutics; Janssen; Master Clinician Alliance; MDBriefcase; Merck; Medtronic; Moderna; Novartis; Novo Nordisk; Partners in Progressive Medical Education; Pfizer; Sanofi Aventis; Timed Right; WebMD. Received research grants/research support from: Abbott; Amgen; Novo Nordisk. Received consulting fees from: Abbott; Acerus; AstraZeneca; Amgen; Bausch Healthcare; Bayer; Boehringer Ingelheim; Dexcom; Eli Lilly; Gilead Sciences; GSK; HLS Therapeutics; Insulet; Janssen; Medtronic; Novo Nordisk; Partners in Progressive Medical Education; PocketPills; Roche; Sanofi Aventis; Takeda. Lorenzo Leggio, MD, PhD, Clinical Director, Deputy Scientific Director, National Institute on Drug Abuse Intramural Research Program, National Institutes of Health, Baltimore, Maryland, has disclosed the following relevant financial relationships: Serve(d) as a US federal employee for: National Institutes of Health. He had received income in an amount equal to or greater than $250 from: UK Medical Council on Alcohol for his service as editor-in-chief for Alcohol and Alcoholism and received royalties from Rutledge as an editor for a textbook.

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

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This transcript has been edited for clarity. 

Akshay B. Jain, MD: Today we are very excited to have Dr. Leggio join us all the way from the National Institutes of Health (NIH). He is an addiction physician scientist in the intramural research program at NIH. Welcome, Dr. Leggio. Thanks for joining us. 

Lorenzo Leggio, MD, PhD: Thank you so much. 

Dr. Jain: We’ll get right into this. Your session was, in my mind, extremely informative. The session looked at glucagon-like peptide 1 receptor agonist (GLP-1 RA) therapy and its potential effects on mitigating alcohol misuse syndrome, so, reduction of alcohol addiction potentially. 

We’ve seen in some previous clinical trials, including many from your group, that alcohol use is known to be reduced — the overall risk of incidence, as well as recurrence of alcohol use — in individuals who are on GLP-1 RA therapy.

Can you share more insights about the data already out there? 

Dr. Leggio: At the preclinical level, we have a very robust line of studies, experiments, and publications looking at the effect of GLP-1 RAs, starting from exenatide up to, more recently, semaglutide. They show that these GLP-1 RAs do reduce alcohol drinking. They used different animal models of excessive alcohol drinking, using different species — for example, mice, rats, nonhuman primates — models that reflect the excessive alcohol drinking behavior that we see in patients, like physical alcohol dependence or binge-like alcohol drinking, and other behaviors in animal models that reflect the human condition.

In addition to that, we recently have seen an increase in human evidence that GLP-1 RAs may reduce alcohol drinking. For example, there is some anecdotal evidence and some analyses using social media showing that people on GLP-1 RAs report drinking less alcohol. 

There are also some pharmacoepidemiology studies which are very intriguing and quite promising. In this case, people have been looking at electronic medical records; they have used the pharmacoepidemiology approaches to match patients on GLP-1 RAs because of diabetes or obesity, and have compared and matched to patients on different drugs as the controls.

A study was recently published Nature Communications by a group in Cleveland in collaboration with Dr. Nora Volkow from the National Institute on Drug Abuse. This study shows the association between being on a GLP-1 RA and the lower incidence of alcohol use disorder and lower drinking.

There is also some promise from prospective randomized clinical trials. In particular, there was one clinical trial from Denmark, a well-known and -conducted clinical trial where they looked at exenatide, and they didn’t see an effect of exenatide compared with placebo in the main analysis. But in a subanalysis, they did see that exenatide reduced alcohol drinking, but only in patients with alcohol use disorder and obesity.

This suggests that these medications may work for some patients and not for other patients. That’s fine, because just like in any other field in medicine, including diabetes, obesity, hypertension, Parkinson’s, and depression, not all medications work for everybody. If these medications will work for alcohol addiction, we do not expect that they will work for everybody.

One ongoing question in the field is to try to identify the phenotypes or the subgroup of people who may be more responsive to these medications. 

Dr. Jain: This is such a fascinating field, and all these studies are coming out. In your review of all the literature so far, do you think this is dose dependent? Also, we see that, for instance, with certain individuals, when they take GLP-1 RA therapy, they might have a lot of gastrointestinal (GI) side effects. Recent studies have shown that the rate of these GI side effects does not necessarily correlate with the amount of weight loss. In the alcohol addiction field, do you think that the GI side effects, things like nausea, could also have a potential role in mitigating the alcohol addiction?

Dr. Leggio: This is a great question. They may play a role; they may contribute, too, but we don’t think that they are the driving mechanism of why people drink less, for at least a couple of reasons. 

One is that, similar to the obesity field, the data we have so far don’t necessarily show a relationship between the GI side effects and the reduction in drinking. Plus, the reduction in drinking is likely to happen later when many GI side effects are gone or attenuated. 

The second reason is from the neuroscience field. We are starting to better understand the mechanism at the brain level as to how these medications work. We don’t see that the nausea or, more generally, not feeling well — malaise, etc. — are driving mechanisms for how these medications work.

Again, it’s not to discount completely that the GI side effects may play a role, but I would say that, if anything, they may be more contributing to. And if they do, that will not be unique to this class of medication. For example, we have three medications approved by the US Food and Drug Administration (FDA) for alcohol use disorder.

One challenge we have in the addiction field is that many people don’t know that these medications exist — many primary care providers don’t know — and they are completely underutilized. Everybody here who is listening to us knows that roughly 85% of people with diabetes receive a medication for diabetes. For alcohol use disorder, the number is 2%. These are medications approved by the FDA. 

One of them is naltrexone, which does give GI symptoms — in particular, nausea and vomiting. The other medication is acamprosate, which does give diarrhea.

You have medications approved for alcohol disorder where you do have some GI symptoms, but they are not the mechanism either for how these medications help people to curb craving and reduce alcohol drinking.

Dr. Jain: What about the dose-dependent action? Do you think that GLP-1 RAs, at a lower dose, may not have an effect on alcohol use disorder vs at a higher dose, or is everyone a little different? 

Dr. Leggio: That’s a wonderful question. The short answer is, we don’t know, to be honest. Now, in some of the animal studies — my team has been in collaboration with other scientists in the NIH intramural research program, and also with scientists in academia, for example, at Scripps, UCLA — we see a dose response where the higher the dose, the higher the effect of the drug. In this case, semaglutide reduced binge drinking in a rat model of a physical alcohol dependence.

That said, I would be very cautious about claiming, based on the rodent data, that humans will have a dose response. It’s an open question. We really don’t know. Some of the pharmacoepidemiology data suggested that even lower doses — for example, using semaglutide for diabetes without going up to the obesity dose — may be just as effective as a higher dose in reducing the incidence of alcohol use disorder. 

It’s important also to keep in mind that the pharmacoepidemiology data are always an association. Reduction in alcohol disorder is associated with the prescription GLP-1 RA, but they don’t really replace the more gold-standard, double-blind, placebo-controlled randomized clinical trial. Nonetheless, with the pharmacoepidemiology data, I think there is an argument to at least hypothesize that people may respond well, even to lower doses. 

This also may be important from a safety standpoint. 

Basically, we need to wait for results in the next years to come from randomized clinical trials to better unfold the question about doses. For example, just anecdotally, I will tell you that in the clinical trial we are conducting right now at the NIH Intramural Research Program, for which I’m the principal investigator (PI), we are going up to 2.4 mg — the highest dose of semaglutide.

We are collaborating with Kyle Simmons, PhD, from Oklahoma State University. Our two studies are not like a two-site clinical trial, but they are harmonized. In Dr. Simmons’ clinical trial, they’re going up to 1.0 mg. We are excited about this team approach because the trials are slightly different, but they’re harmonized to the point that, once the studies are done, we’ll be able to combine and compare data to better answer the question about dosing, and many other questions.

Dr. Jain: From a clinical perspective, we see that many people who are battling alcohol use disorder may not have obesity. They might actually be on the leaner side, and hence, we may not want to use a high dose of GLP-1 RA therapy. It’ll be very exciting to see when these results come out.

This brings me to the next question. I think everyone would love to know why this happens. Why is GLP-1 RA having this effect on alcohol use disorder? I know that your group has done many animal studies, as you pointed out, and one of the postulated theories was the effect on the GABA neurotransmission pathway.

Can you tell us more about what you feel is the underlying mechanism of action here?

Dr. Leggio: I will start by saying that we don’t fully know. There are many open questions. If I can sidetrack for one second: We come up with the idea that, first of all, alcohol use disorder and substance use disorder are addictive behaviors, addictive disorders. We define addiction as a brain disease. 

Granted that addiction is a brain disease, it doesn’t mean that addiction works just in the brain in isolation. As we all know, the brain works in concert with the rest of the body. One specific approach my team has been taking is working on the analogy and the similarities between obesity and addiction to try to understand how the body-brain connection, such as the gut-brain-neuroendocrine pathway, may play a role in patients with addiction.

 

 

With that in mind, a large amount of work in my lab in the past 20 years — since I’ve been a PI — has been focused on studying this neuroendocrine pathways related to the gut-brain axis. For example, we have done work on insulin and leptin, primarily; we had done work on ghrelin, and since 2015 on the GLP-1 RAs.

With that in mind, the framework we are working on, which is also substantiated by many studies done by our team and other teams in the neuroscience field, kind of supports the idea that, similar to what we see in obesity, these medications may work by affecting what we call reward processing, or the seeking for addictive drugs, such as alcohol, and also the drugs such as the stimulants, opioids, nicotine, and so on.

The idea is that the mechanism is driven by the ability of the medication — semaglutide and all the GLP-1 RAs — to reduce the rewarding properties of alcohol and drugs. To maybe make the example more pragmatic, what does that mean? It means, for example, that a patient who typically has 10 drinks per day in the afternoon and night, while they are on the medication they may feel the lack of need to drink up to 10 to feel the same reward. 

They may be able to stop after two or three drinks, which means a significant harm reduction and a beneficial outcome. This also brings us to another mechanism, which may be related to society. We don’t fully understand how much the society mechanism, including society mechanism related to GI motility, may also play a role.

With that said, we don’t think that the effect of the GLP-1 RAs is merely due to alcohol being a calorie-based nutrient because, in fact, we see alcohol as an addictive drug, not as a nutrient. Also, the GLP-1 RAs, at least in animal models, seem to work on other addictive drugs that don’t have calories, such as nicotine, and possibly with cannabis, opioids, and stimulants.

Then on the molecular level, our team recently showed, in collaboration with Dr. Marisa Roberto from Scripps in La Jolla, California, that semaglutide may in fact change the GABA transmission at the level of some brain regions, such as the amygdala and the prefrontal cortex. These are brain regions that are well-established hubs that play a role in the mechanism underlying addiction. 

There are also some very exciting recent data showing how these medications may work not just on GABA or just on dopamine, which is the canonical way we conceive of reward processing, but by working on both by modulating GABA transmission — for example, at the ventral tegmental area and dopamine transmission at the nucleus accumbens.

Bottom line, if I summarize all of this, is that the mechanism is not fully understood, but there is definitely a contribution of this medication to effect and reward processing, possibly by altering the balance between GABA and dopamine. There are still some unknown questions, such as, are these mechanisms all brain driven or are they signaling from the periphery to the brain, or maybe both?

Also, as we all know, there are many differences across all these GLP-1 analogs in brain penetrance. Whether the drug needs to go to the brain to have an effect on alcohol drinking, cocaine seeking, or smoking is really an open question.

Dr. Jain: This is so thought-provoking. I guess the more we uncover, the more mesmerized we get with all the potential crosstalk. There is a large amount of overlap in the brain with each of these different things and how it all interplays with each other. 

Speaking of interplay, I’m thinking about how many people prone to having alcohol use disorder can potentially develop complications, one of these being chronic pancreatitis. This is a well-known complication that can occur in people having alcohol addiction. Along that same line, we know that previous history of pancreatitis is considered a use-with-caution, or we don’t want to use GLP-1 RA therapy in people who have had pancreatitis. 

Now it becomes this quagmire where people may have chronic pancreatitis, but we may want to consider GLP-1 RA therapy for management of alcohol use disorder. What are your thoughts about this, and the safety, potentially, in using it in these patients? 

Dr. Leggio: This is another wonderful question. That’s definitely a top priority in our mind, to address these kinds of questions. For example, our RCT does have, as core primary outcomes, not only the efficacy defined as a reduction in alcohol drinking, but also safety.

The reason is exactly what you just explained. There are many unanswered questions, including whether giving a GLP-1 RA and alcohol together may have synergistic effects and increase the likelihood of having pancreatitis. 

The good news is that, so far, based on the published literature, including the RCT done with exenatide in Denmark and published in 2022 and also the ongoing clinical trials — including my own clinical trial, but of course we are blind — pancreatitis has not been coming out as an adverse event.

However, it’s also true that it often happens in clinical medication development. Of course, we screen and select our population well. For example, we do exclude people who have a history of pancreatitis. We exclude people with high lipase or with any of the clinical symptomatology that makes us concerned about these people having pancreatitis. 

As often happens when you move a medication from clinical trials to clinical practice, we still need to understand whether this medication works in patients. I’m just speculating, but even if the clinical trials do not raise red flags in terms of increased risk for some side effects such as pancreatitis, I think it will be very important for practitioners to keep a close eye on the death risk regardless. 

It’s very interesting that it’s similar to alcohol liver disease. With pancreatitis, not every single patient with alcohol addiction has pancreatitis. We don’t really fully understand why some people develop pancreatitis and some people do not. The point being that there are many patients with alcohol addiction who don’t have pancreatitis and may benefit from these medications if they work. Again, we have to prove that in patients.

On the other side, as we all know, pancreatitis is a potentially life-threatening condition for those people who either have it or are at risk for it. I think we have to be very careful before we consider giving them a GLP-1 RA.

One could argue that alcohol is the leading cause of mortality and morbidity in the world. For example, right now, alcohol is the leading cause of liver disease. It’s the main reason for liver transplantation in our country. Alcohol is affecting thousands of people in terms of death and emergency room visits.

You could argue that the downside is not treating these people and they die because of alcohol addiction. A GLP-1 RA is not going to be for everybody. I will remind everybody that (1) we do have FDA-approved medications for alcohol addiction; and (2) there are also other medications not approved by the FDA, but with a proven efficacy in some clinical trials — for example, topiramate and gabapentin — and they’ve been endorsed by the American Psychiatric Association. 

There is also some evidence for another medication, baclofen, which has been endorsed by the American College of Gastroenterology for patients with alcohol addiction and liver disease.

The point I’m making is that it’s not that either we use the GLP-1 RAs or we have no other tools. We have other tools. I think we have to personalize the treatment based on the patient’s profile from a safety standpoint and from a phenotypic standpoint. 

Dr. Jain: I love that thought. I think individualization is the key here.

We know that people with diabetes have a higher risk for pancreatitis by virtue of having diabetes. People with obesity also have a higher risk for pancreatitis by virtue of having obesity. These are the two conditions where we are using a large amount of GLP-1 RA therapy. Again, the idea is looking at the person in front of us and then deciding, based on their past medical history and their current risk, whether or not a medication is a right fit for them.

I think more individualization here will come as we start using these medications that might be having potential effects on different organ systems. You mentioned a little bit about the liver, so a thought came in my mind. We know that people with diabetes who have alcohol use disorder are at a higher risk for potential hypoglycemia. If they have events when they have increased consumption of alcohol, there can be more hypoglycemia.

We now could potentially be using semaglutide or other GLP-1 RA therapy for management of alcohol use disorder. In your own experience in the studies that you’ve done or the literature that’s out there, has that been associated with an even higher risk for hypoglycemia? 

Dr. Leggio: It’s a wonderful question. I’m not aware of any formal and published report of that association. That said, your thinking from a physiopathologist standpoint makes total sense. I could not agree more. The fact that nothing has been published, at least to my knowledge, doesn’t mean that the death risk doesn’t exist. In fact, I agree with you that it does exist. 

Alcohol use disorder is interesting and tricky clinically because chronically, alcohol addiction or alcohol use disorder is associated with an increased risk for diabetes. Acutely, as you point out; and this could be with or without alcohol use disorder. An episode of a high volume of binge drinking may lead to hypoglycemia.

This is one of the reasons why people may show up to the emergency room with intoxication, and one of the symptoms detected at the emergency room is that they also have hypoglycemia in addition to vomiting, nausea, and everything else that we see in patients with acute intoxication.

Similar to the discussion about pancreatitis, as we work on understanding the possible role of GLP-1 RA in patients with alcohol use disorder, we do have to keep a close eye on the risk for hypoglycemia. The short answer is that this is not well established, but based on the simple concept of “first, do no harm,” I think we need to track that very carefully. 

In the ongoing clinical trial we’re doing in Maryland in my program at the NIH, we do just that. We are tracking glucose levels. Of course, patients come to clinic weekly, so unless they have symptoms, typically we don’t see anything at the time.

 

 

More important, we educate our patients when they go through the consent process. We tell them that this medication per se does not give hypoglycemia. In fact, we’re including people with diabetes, so for people on other medications like metformin, we explain to them that technically such a risk should not exist, but because you’re drinking alcohol in excessive amounts, you do have a potential higher risk. We just don’t know how significant that risk could be. 

We do a large amount of education at baseline when they enroll in our study. We also educate our patients on how to recognize early on the potential risk for hypoglycemia, exactly for the reasons you said. We explain to them the unknown potential that the GLP-1 RAs and alcohol together may synergize and give hypoglycemia.

Dr. Jain: I don’t know if you got this feeling at the ADA conference, but I felt, when attending all these sessions, that it seems like GLP-1 RA is the gift that keeps giving. We see the effect on diabetes, obesity, metabolic-associated steatotic liver disease, possibly with Alzheimer’s, chronic obstructive pulmonary disease, and so many things.

Now, of course, there’s potential use in alcohol use disorder. Do you think that using GLP-1 RA therapy is ready for prime time? Do you think we are now ready to prescribe this in people with alcohol use disorder?

Dr. Leggio: I would say we’re not there yet. As I mentioned at the beginning, the evidence keeps on growing. It’s getting stronger and stronger because the positive data keep on coming up. We have data from animal models, including the different species, ranging from rodents to nonhuman primates. We have anecdotal evidence and machine-learning approaches using, for example, big data and social media data. Now we have pharmacoepidemiology data and some small, initial, but still good randomized clinical trials.

What we are missing is the final step of having a substantial number of prospective, double-blind, placebo-controlled clinical trials to really prove or disprove whether these medications work, and to also better understand which patients may respond to these medications.

The good news is that there are many ongoing clinical trials. We are conducting a clinical trial in Maryland at the NIH. Dr. Simmons is doing a clinical trial at Oklahoma State University. Dr. Christian Hendershot at UNC is conducting a study at Chapel Hill. Dr. Josh Gowin is doing a study in Colorado. Dr. Anders Fink-Jensen is doing a study in Denmark. The momentum is very high. 

I’m only mentioning those people who are doing alcohol-semaglutide clinical trials. There are also people doing clinical trials on smoking, stimulants, and opioids. There are actually some very fresh, still unpublished data from Penn State that were presented publicly at conferences, showing how these drugs may reduce opioid craving, which is, of course, critically important, given that we’re in the middle of a fentanyl pandemic that is killing one person every 7 minutes, for example, in Baltimore. It’s very alarming and we need more treatments.

The bottom line is that it’s very promising, but we need to wait for these clinical trials to have a definitive answer. I would say that if you have a patient with diabetes, obesity, and also alcohol addiction, and they are on semaglutide or any other GLP-1 RA, and in addition to using the medication for diabetes and obesity, they also have a beneficial effect on their alcohol drinking, then that’s fantastic. At the end of the day, that’s the mission we all share: helping people. 

If it’s someone without obesity and diabetes, personally, at this stage, I will go with other medications that either have FDA approval or at least very solid evidence of efficacy from RCTs rather than going with the GLP-1 RA, at least until I see more definitive data from randomized clinical trials. 

There is a large amount of hope. We are hoping that these clinical trials will be positive. We are very enthusiastic and we’re also very thrilled to see that Novo Nordisk recently launched a gigantic multisite clinical trial with — I forgot how many sites, but it’s very large across Europe, America, and maybe other continents as well.

Their primary outcome is improvement in alcohol-related liver disease, but they’re also looking at alcohol drinking as a secondary outcome. That’s very important because, unlike in the diabetes field, in the addiction field, we do struggle to build partnership with the private sector because sometimes the addiction field is not seen as an appetitive field from pharma. 

We all know that the best success in any medication development story is when you put academia, the government, and pharma together. Think about the COVID-19 vaccine development. That’s unfortunately the exception rather than rule in the addiction field. 

With the company doing a large clinical trial in the alcohol field, although they focus more on the liver but they also looked at drinking, I really hope we’ll see more and more companies in the private sector take more and more interest in addiction. Also, I hope to see more and more partnership between the private sector, the government, and academia. 

Dr. Jain: Such exciting times, indeed. We can’t wait enough for the results of these and many other trials to come out. Dr. Leggio, it was an absolute delight chatting with you today. Thank you so much for joining us from ADA 2024.

Akshay B. Jain, MD, Clinical Instructor, Department of Endocrinology, University of British Columbia; Endocrinologist, TLC Diabetes and Endocrinology, Vancouver, British Columbia, Canada, has disclosed the following relevant financial relationships: Serve(d) as a speaker or a member of a speakers bureau for: Abbott; Acerus; AstraZeneca; Amgen; Bausch Healthcare; Bayer; Boehringer Ingelheim; Care to Know; CCRN; Connected in Motion; CPD Network; Dexcom; Diabetes Canada; Eli Lilly; GSK; HLS Therapeutics; Janssen; Master Clinician Alliance; MDBriefcase; Merck; Medtronic; Moderna; Novartis; Novo Nordisk; Partners in Progressive Medical Education; Pfizer; Sanofi Aventis; Timed Right; WebMD. Received research grants/research support from: Abbott; Amgen; Novo Nordisk. Received consulting fees from: Abbott; Acerus; AstraZeneca; Amgen; Bausch Healthcare; Bayer; Boehringer Ingelheim; Dexcom; Eli Lilly; Gilead Sciences; GSK; HLS Therapeutics; Insulet; Janssen; Medtronic; Novo Nordisk; Partners in Progressive Medical Education; PocketPills; Roche; Sanofi Aventis; Takeda. Lorenzo Leggio, MD, PhD, Clinical Director, Deputy Scientific Director, National Institute on Drug Abuse Intramural Research Program, National Institutes of Health, Baltimore, Maryland, has disclosed the following relevant financial relationships: Serve(d) as a US federal employee for: National Institutes of Health. He had received income in an amount equal to or greater than $250 from: UK Medical Council on Alcohol for his service as editor-in-chief for Alcohol and Alcoholism and received royalties from Rutledge as an editor for a textbook.

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

 

This transcript has been edited for clarity. 

Akshay B. Jain, MD: Today we are very excited to have Dr. Leggio join us all the way from the National Institutes of Health (NIH). He is an addiction physician scientist in the intramural research program at NIH. Welcome, Dr. Leggio. Thanks for joining us. 

Lorenzo Leggio, MD, PhD: Thank you so much. 

Dr. Jain: We’ll get right into this. Your session was, in my mind, extremely informative. The session looked at glucagon-like peptide 1 receptor agonist (GLP-1 RA) therapy and its potential effects on mitigating alcohol misuse syndrome, so, reduction of alcohol addiction potentially. 

We’ve seen in some previous clinical trials, including many from your group, that alcohol use is known to be reduced — the overall risk of incidence, as well as recurrence of alcohol use — in individuals who are on GLP-1 RA therapy.

Can you share more insights about the data already out there? 

Dr. Leggio: At the preclinical level, we have a very robust line of studies, experiments, and publications looking at the effect of GLP-1 RAs, starting from exenatide up to, more recently, semaglutide. They show that these GLP-1 RAs do reduce alcohol drinking. They used different animal models of excessive alcohol drinking, using different species — for example, mice, rats, nonhuman primates — models that reflect the excessive alcohol drinking behavior that we see in patients, like physical alcohol dependence or binge-like alcohol drinking, and other behaviors in animal models that reflect the human condition.

In addition to that, we recently have seen an increase in human evidence that GLP-1 RAs may reduce alcohol drinking. For example, there is some anecdotal evidence and some analyses using social media showing that people on GLP-1 RAs report drinking less alcohol. 

There are also some pharmacoepidemiology studies which are very intriguing and quite promising. In this case, people have been looking at electronic medical records; they have used the pharmacoepidemiology approaches to match patients on GLP-1 RAs because of diabetes or obesity, and have compared and matched to patients on different drugs as the controls.

A study was recently published Nature Communications by a group in Cleveland in collaboration with Dr. Nora Volkow from the National Institute on Drug Abuse. This study shows the association between being on a GLP-1 RA and the lower incidence of alcohol use disorder and lower drinking.

There is also some promise from prospective randomized clinical trials. In particular, there was one clinical trial from Denmark, a well-known and -conducted clinical trial where they looked at exenatide, and they didn’t see an effect of exenatide compared with placebo in the main analysis. But in a subanalysis, they did see that exenatide reduced alcohol drinking, but only in patients with alcohol use disorder and obesity.

This suggests that these medications may work for some patients and not for other patients. That’s fine, because just like in any other field in medicine, including diabetes, obesity, hypertension, Parkinson’s, and depression, not all medications work for everybody. If these medications will work for alcohol addiction, we do not expect that they will work for everybody.

One ongoing question in the field is to try to identify the phenotypes or the subgroup of people who may be more responsive to these medications. 

Dr. Jain: This is such a fascinating field, and all these studies are coming out. In your review of all the literature so far, do you think this is dose dependent? Also, we see that, for instance, with certain individuals, when they take GLP-1 RA therapy, they might have a lot of gastrointestinal (GI) side effects. Recent studies have shown that the rate of these GI side effects does not necessarily correlate with the amount of weight loss. In the alcohol addiction field, do you think that the GI side effects, things like nausea, could also have a potential role in mitigating the alcohol addiction?

Dr. Leggio: This is a great question. They may play a role; they may contribute, too, but we don’t think that they are the driving mechanism of why people drink less, for at least a couple of reasons. 

One is that, similar to the obesity field, the data we have so far don’t necessarily show a relationship between the GI side effects and the reduction in drinking. Plus, the reduction in drinking is likely to happen later when many GI side effects are gone or attenuated. 

The second reason is from the neuroscience field. We are starting to better understand the mechanism at the brain level as to how these medications work. We don’t see that the nausea or, more generally, not feeling well — malaise, etc. — are driving mechanisms for how these medications work.

Again, it’s not to discount completely that the GI side effects may play a role, but I would say that, if anything, they may be more contributing to. And if they do, that will not be unique to this class of medication. For example, we have three medications approved by the US Food and Drug Administration (FDA) for alcohol use disorder.

One challenge we have in the addiction field is that many people don’t know that these medications exist — many primary care providers don’t know — and they are completely underutilized. Everybody here who is listening to us knows that roughly 85% of people with diabetes receive a medication for diabetes. For alcohol use disorder, the number is 2%. These are medications approved by the FDA. 

One of them is naltrexone, which does give GI symptoms — in particular, nausea and vomiting. The other medication is acamprosate, which does give diarrhea.

You have medications approved for alcohol disorder where you do have some GI symptoms, but they are not the mechanism either for how these medications help people to curb craving and reduce alcohol drinking.

Dr. Jain: What about the dose-dependent action? Do you think that GLP-1 RAs, at a lower dose, may not have an effect on alcohol use disorder vs at a higher dose, or is everyone a little different? 

Dr. Leggio: That’s a wonderful question. The short answer is, we don’t know, to be honest. Now, in some of the animal studies — my team has been in collaboration with other scientists in the NIH intramural research program, and also with scientists in academia, for example, at Scripps, UCLA — we see a dose response where the higher the dose, the higher the effect of the drug. In this case, semaglutide reduced binge drinking in a rat model of a physical alcohol dependence.

That said, I would be very cautious about claiming, based on the rodent data, that humans will have a dose response. It’s an open question. We really don’t know. Some of the pharmacoepidemiology data suggested that even lower doses — for example, using semaglutide for diabetes without going up to the obesity dose — may be just as effective as a higher dose in reducing the incidence of alcohol use disorder. 

It’s important also to keep in mind that the pharmacoepidemiology data are always an association. Reduction in alcohol disorder is associated with the prescription GLP-1 RA, but they don’t really replace the more gold-standard, double-blind, placebo-controlled randomized clinical trial. Nonetheless, with the pharmacoepidemiology data, I think there is an argument to at least hypothesize that people may respond well, even to lower doses. 

This also may be important from a safety standpoint. 

Basically, we need to wait for results in the next years to come from randomized clinical trials to better unfold the question about doses. For example, just anecdotally, I will tell you that in the clinical trial we are conducting right now at the NIH Intramural Research Program, for which I’m the principal investigator (PI), we are going up to 2.4 mg — the highest dose of semaglutide.

We are collaborating with Kyle Simmons, PhD, from Oklahoma State University. Our two studies are not like a two-site clinical trial, but they are harmonized. In Dr. Simmons’ clinical trial, they’re going up to 1.0 mg. We are excited about this team approach because the trials are slightly different, but they’re harmonized to the point that, once the studies are done, we’ll be able to combine and compare data to better answer the question about dosing, and many other questions.

Dr. Jain: From a clinical perspective, we see that many people who are battling alcohol use disorder may not have obesity. They might actually be on the leaner side, and hence, we may not want to use a high dose of GLP-1 RA therapy. It’ll be very exciting to see when these results come out.

This brings me to the next question. I think everyone would love to know why this happens. Why is GLP-1 RA having this effect on alcohol use disorder? I know that your group has done many animal studies, as you pointed out, and one of the postulated theories was the effect on the GABA neurotransmission pathway.

Can you tell us more about what you feel is the underlying mechanism of action here?

Dr. Leggio: I will start by saying that we don’t fully know. There are many open questions. If I can sidetrack for one second: We come up with the idea that, first of all, alcohol use disorder and substance use disorder are addictive behaviors, addictive disorders. We define addiction as a brain disease. 

Granted that addiction is a brain disease, it doesn’t mean that addiction works just in the brain in isolation. As we all know, the brain works in concert with the rest of the body. One specific approach my team has been taking is working on the analogy and the similarities between obesity and addiction to try to understand how the body-brain connection, such as the gut-brain-neuroendocrine pathway, may play a role in patients with addiction.

 

 

With that in mind, a large amount of work in my lab in the past 20 years — since I’ve been a PI — has been focused on studying this neuroendocrine pathways related to the gut-brain axis. For example, we have done work on insulin and leptin, primarily; we had done work on ghrelin, and since 2015 on the GLP-1 RAs.

With that in mind, the framework we are working on, which is also substantiated by many studies done by our team and other teams in the neuroscience field, kind of supports the idea that, similar to what we see in obesity, these medications may work by affecting what we call reward processing, or the seeking for addictive drugs, such as alcohol, and also the drugs such as the stimulants, opioids, nicotine, and so on.

The idea is that the mechanism is driven by the ability of the medication — semaglutide and all the GLP-1 RAs — to reduce the rewarding properties of alcohol and drugs. To maybe make the example more pragmatic, what does that mean? It means, for example, that a patient who typically has 10 drinks per day in the afternoon and night, while they are on the medication they may feel the lack of need to drink up to 10 to feel the same reward. 

They may be able to stop after two or three drinks, which means a significant harm reduction and a beneficial outcome. This also brings us to another mechanism, which may be related to society. We don’t fully understand how much the society mechanism, including society mechanism related to GI motility, may also play a role.

With that said, we don’t think that the effect of the GLP-1 RAs is merely due to alcohol being a calorie-based nutrient because, in fact, we see alcohol as an addictive drug, not as a nutrient. Also, the GLP-1 RAs, at least in animal models, seem to work on other addictive drugs that don’t have calories, such as nicotine, and possibly with cannabis, opioids, and stimulants.

Then on the molecular level, our team recently showed, in collaboration with Dr. Marisa Roberto from Scripps in La Jolla, California, that semaglutide may in fact change the GABA transmission at the level of some brain regions, such as the amygdala and the prefrontal cortex. These are brain regions that are well-established hubs that play a role in the mechanism underlying addiction. 

There are also some very exciting recent data showing how these medications may work not just on GABA or just on dopamine, which is the canonical way we conceive of reward processing, but by working on both by modulating GABA transmission — for example, at the ventral tegmental area and dopamine transmission at the nucleus accumbens.

Bottom line, if I summarize all of this, is that the mechanism is not fully understood, but there is definitely a contribution of this medication to effect and reward processing, possibly by altering the balance between GABA and dopamine. There are still some unknown questions, such as, are these mechanisms all brain driven or are they signaling from the periphery to the brain, or maybe both?

Also, as we all know, there are many differences across all these GLP-1 analogs in brain penetrance. Whether the drug needs to go to the brain to have an effect on alcohol drinking, cocaine seeking, or smoking is really an open question.

Dr. Jain: This is so thought-provoking. I guess the more we uncover, the more mesmerized we get with all the potential crosstalk. There is a large amount of overlap in the brain with each of these different things and how it all interplays with each other. 

Speaking of interplay, I’m thinking about how many people prone to having alcohol use disorder can potentially develop complications, one of these being chronic pancreatitis. This is a well-known complication that can occur in people having alcohol addiction. Along that same line, we know that previous history of pancreatitis is considered a use-with-caution, or we don’t want to use GLP-1 RA therapy in people who have had pancreatitis. 

Now it becomes this quagmire where people may have chronic pancreatitis, but we may want to consider GLP-1 RA therapy for management of alcohol use disorder. What are your thoughts about this, and the safety, potentially, in using it in these patients? 

Dr. Leggio: This is another wonderful question. That’s definitely a top priority in our mind, to address these kinds of questions. For example, our RCT does have, as core primary outcomes, not only the efficacy defined as a reduction in alcohol drinking, but also safety.

The reason is exactly what you just explained. There are many unanswered questions, including whether giving a GLP-1 RA and alcohol together may have synergistic effects and increase the likelihood of having pancreatitis. 

The good news is that, so far, based on the published literature, including the RCT done with exenatide in Denmark and published in 2022 and also the ongoing clinical trials — including my own clinical trial, but of course we are blind — pancreatitis has not been coming out as an adverse event.

However, it’s also true that it often happens in clinical medication development. Of course, we screen and select our population well. For example, we do exclude people who have a history of pancreatitis. We exclude people with high lipase or with any of the clinical symptomatology that makes us concerned about these people having pancreatitis. 

As often happens when you move a medication from clinical trials to clinical practice, we still need to understand whether this medication works in patients. I’m just speculating, but even if the clinical trials do not raise red flags in terms of increased risk for some side effects such as pancreatitis, I think it will be very important for practitioners to keep a close eye on the death risk regardless. 

It’s very interesting that it’s similar to alcohol liver disease. With pancreatitis, not every single patient with alcohol addiction has pancreatitis. We don’t really fully understand why some people develop pancreatitis and some people do not. The point being that there are many patients with alcohol addiction who don’t have pancreatitis and may benefit from these medications if they work. Again, we have to prove that in patients.

On the other side, as we all know, pancreatitis is a potentially life-threatening condition for those people who either have it or are at risk for it. I think we have to be very careful before we consider giving them a GLP-1 RA.

One could argue that alcohol is the leading cause of mortality and morbidity in the world. For example, right now, alcohol is the leading cause of liver disease. It’s the main reason for liver transplantation in our country. Alcohol is affecting thousands of people in terms of death and emergency room visits.

You could argue that the downside is not treating these people and they die because of alcohol addiction. A GLP-1 RA is not going to be for everybody. I will remind everybody that (1) we do have FDA-approved medications for alcohol addiction; and (2) there are also other medications not approved by the FDA, but with a proven efficacy in some clinical trials — for example, topiramate and gabapentin — and they’ve been endorsed by the American Psychiatric Association. 

There is also some evidence for another medication, baclofen, which has been endorsed by the American College of Gastroenterology for patients with alcohol addiction and liver disease.

The point I’m making is that it’s not that either we use the GLP-1 RAs or we have no other tools. We have other tools. I think we have to personalize the treatment based on the patient’s profile from a safety standpoint and from a phenotypic standpoint. 

Dr. Jain: I love that thought. I think individualization is the key here.

We know that people with diabetes have a higher risk for pancreatitis by virtue of having diabetes. People with obesity also have a higher risk for pancreatitis by virtue of having obesity. These are the two conditions where we are using a large amount of GLP-1 RA therapy. Again, the idea is looking at the person in front of us and then deciding, based on their past medical history and their current risk, whether or not a medication is a right fit for them.

I think more individualization here will come as we start using these medications that might be having potential effects on different organ systems. You mentioned a little bit about the liver, so a thought came in my mind. We know that people with diabetes who have alcohol use disorder are at a higher risk for potential hypoglycemia. If they have events when they have increased consumption of alcohol, there can be more hypoglycemia.

We now could potentially be using semaglutide or other GLP-1 RA therapy for management of alcohol use disorder. In your own experience in the studies that you’ve done or the literature that’s out there, has that been associated with an even higher risk for hypoglycemia? 

Dr. Leggio: It’s a wonderful question. I’m not aware of any formal and published report of that association. That said, your thinking from a physiopathologist standpoint makes total sense. I could not agree more. The fact that nothing has been published, at least to my knowledge, doesn’t mean that the death risk doesn’t exist. In fact, I agree with you that it does exist. 

Alcohol use disorder is interesting and tricky clinically because chronically, alcohol addiction or alcohol use disorder is associated with an increased risk for diabetes. Acutely, as you point out; and this could be with or without alcohol use disorder. An episode of a high volume of binge drinking may lead to hypoglycemia.

This is one of the reasons why people may show up to the emergency room with intoxication, and one of the symptoms detected at the emergency room is that they also have hypoglycemia in addition to vomiting, nausea, and everything else that we see in patients with acute intoxication.

Similar to the discussion about pancreatitis, as we work on understanding the possible role of GLP-1 RA in patients with alcohol use disorder, we do have to keep a close eye on the risk for hypoglycemia. The short answer is that this is not well established, but based on the simple concept of “first, do no harm,” I think we need to track that very carefully. 

In the ongoing clinical trial we’re doing in Maryland in my program at the NIH, we do just that. We are tracking glucose levels. Of course, patients come to clinic weekly, so unless they have symptoms, typically we don’t see anything at the time.

 

 

More important, we educate our patients when they go through the consent process. We tell them that this medication per se does not give hypoglycemia. In fact, we’re including people with diabetes, so for people on other medications like metformin, we explain to them that technically such a risk should not exist, but because you’re drinking alcohol in excessive amounts, you do have a potential higher risk. We just don’t know how significant that risk could be. 

We do a large amount of education at baseline when they enroll in our study. We also educate our patients on how to recognize early on the potential risk for hypoglycemia, exactly for the reasons you said. We explain to them the unknown potential that the GLP-1 RAs and alcohol together may synergize and give hypoglycemia.

Dr. Jain: I don’t know if you got this feeling at the ADA conference, but I felt, when attending all these sessions, that it seems like GLP-1 RA is the gift that keeps giving. We see the effect on diabetes, obesity, metabolic-associated steatotic liver disease, possibly with Alzheimer’s, chronic obstructive pulmonary disease, and so many things.

Now, of course, there’s potential use in alcohol use disorder. Do you think that using GLP-1 RA therapy is ready for prime time? Do you think we are now ready to prescribe this in people with alcohol use disorder?

Dr. Leggio: I would say we’re not there yet. As I mentioned at the beginning, the evidence keeps on growing. It’s getting stronger and stronger because the positive data keep on coming up. We have data from animal models, including the different species, ranging from rodents to nonhuman primates. We have anecdotal evidence and machine-learning approaches using, for example, big data and social media data. Now we have pharmacoepidemiology data and some small, initial, but still good randomized clinical trials.

What we are missing is the final step of having a substantial number of prospective, double-blind, placebo-controlled clinical trials to really prove or disprove whether these medications work, and to also better understand which patients may respond to these medications.

The good news is that there are many ongoing clinical trials. We are conducting a clinical trial in Maryland at the NIH. Dr. Simmons is doing a clinical trial at Oklahoma State University. Dr. Christian Hendershot at UNC is conducting a study at Chapel Hill. Dr. Josh Gowin is doing a study in Colorado. Dr. Anders Fink-Jensen is doing a study in Denmark. The momentum is very high. 

I’m only mentioning those people who are doing alcohol-semaglutide clinical trials. There are also people doing clinical trials on smoking, stimulants, and opioids. There are actually some very fresh, still unpublished data from Penn State that were presented publicly at conferences, showing how these drugs may reduce opioid craving, which is, of course, critically important, given that we’re in the middle of a fentanyl pandemic that is killing one person every 7 minutes, for example, in Baltimore. It’s very alarming and we need more treatments.

The bottom line is that it’s very promising, but we need to wait for these clinical trials to have a definitive answer. I would say that if you have a patient with diabetes, obesity, and also alcohol addiction, and they are on semaglutide or any other GLP-1 RA, and in addition to using the medication for diabetes and obesity, they also have a beneficial effect on their alcohol drinking, then that’s fantastic. At the end of the day, that’s the mission we all share: helping people. 

If it’s someone without obesity and diabetes, personally, at this stage, I will go with other medications that either have FDA approval or at least very solid evidence of efficacy from RCTs rather than going with the GLP-1 RA, at least until I see more definitive data from randomized clinical trials. 

There is a large amount of hope. We are hoping that these clinical trials will be positive. We are very enthusiastic and we’re also very thrilled to see that Novo Nordisk recently launched a gigantic multisite clinical trial with — I forgot how many sites, but it’s very large across Europe, America, and maybe other continents as well.

Their primary outcome is improvement in alcohol-related liver disease, but they’re also looking at alcohol drinking as a secondary outcome. That’s very important because, unlike in the diabetes field, in the addiction field, we do struggle to build partnership with the private sector because sometimes the addiction field is not seen as an appetitive field from pharma. 

We all know that the best success in any medication development story is when you put academia, the government, and pharma together. Think about the COVID-19 vaccine development. That’s unfortunately the exception rather than rule in the addiction field. 

With the company doing a large clinical trial in the alcohol field, although they focus more on the liver but they also looked at drinking, I really hope we’ll see more and more companies in the private sector take more and more interest in addiction. Also, I hope to see more and more partnership between the private sector, the government, and academia. 

Dr. Jain: Such exciting times, indeed. We can’t wait enough for the results of these and many other trials to come out. Dr. Leggio, it was an absolute delight chatting with you today. Thank you so much for joining us from ADA 2024.

Akshay B. Jain, MD, Clinical Instructor, Department of Endocrinology, University of British Columbia; Endocrinologist, TLC Diabetes and Endocrinology, Vancouver, British Columbia, Canada, has disclosed the following relevant financial relationships: Serve(d) as a speaker or a member of a speakers bureau for: Abbott; Acerus; AstraZeneca; Amgen; Bausch Healthcare; Bayer; Boehringer Ingelheim; Care to Know; CCRN; Connected in Motion; CPD Network; Dexcom; Diabetes Canada; Eli Lilly; GSK; HLS Therapeutics; Janssen; Master Clinician Alliance; MDBriefcase; Merck; Medtronic; Moderna; Novartis; Novo Nordisk; Partners in Progressive Medical Education; Pfizer; Sanofi Aventis; Timed Right; WebMD. Received research grants/research support from: Abbott; Amgen; Novo Nordisk. Received consulting fees from: Abbott; Acerus; AstraZeneca; Amgen; Bausch Healthcare; Bayer; Boehringer Ingelheim; Dexcom; Eli Lilly; Gilead Sciences; GSK; HLS Therapeutics; Insulet; Janssen; Medtronic; Novo Nordisk; Partners in Progressive Medical Education; PocketPills; Roche; Sanofi Aventis; Takeda. Lorenzo Leggio, MD, PhD, Clinical Director, Deputy Scientific Director, National Institute on Drug Abuse Intramural Research Program, National Institutes of Health, Baltimore, Maryland, has disclosed the following relevant financial relationships: Serve(d) as a US federal employee for: National Institutes of Health. He had received income in an amount equal to or greater than $250 from: UK Medical Council on Alcohol for his service as editor-in-chief for Alcohol and Alcoholism and received royalties from Rutledge as an editor for a textbook.

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

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