MDedge Endocrinology

Older men with chronic kidney disease (CKD) show higher resting muscle sympathetic nerve activity, but not vascular stiffness, compared with older women, offering clues to the underlying reasons why men with CKD have a higher cardiovascular risk than do women with the disease.

“Although it is well established that sympathetic nerve system activity is chronically elevated in patients with impaired kidney function, we show for the first time that males with CKD have higher resting muscle sympathetic nerve activity compared with females with CKD,” report the authors on research published in the American Journal of Physiology-Renal Physiology.

“For clinicians, the key takeaway is the importance of recognizing sex-specific differences in sympathetic activity and vascular function when assessing cardiovascular risk in CKD patients,” first author Matias G. Zanuzzi, MD, of the Division of Renal Medicine, Department of Medicine, Emory University School of Medicine, Atlanta, Georgia, told this news organization.

In the general population, cardiovascular risk is lower in younger women vs men, but their risks converge in older age as women develop similar levels of sympathetic overactivity, vascular stiffness, and cardiovascular risk.

However, an exception to that pattern is seen in the CKD population, where men continue to have a higher cardiovascular mortality risk vs women even in older age.

Studies evaluating the reasons for that have been conflicting, with some reporting a tendency of higher muscle sympathetic nerve activity in older women compared with men and others suggest the opposite finding — lower activity vs men.

To further investigate, Dr. Zanuzzi and colleagues enrolled 129 participants, including 96 men and 33 women with stage III or IV CKD.

The mean age of the study participants was 64 years for men and65 years for women. Most had obesity, and importantly, more than 80% of participants in each group was Black. There were no significant differences between the groups in terms of body mass index or comorbidities, including smoking, diabetes, or hypertension.

At two separate study visits, vascular stiffness was assessed with carotid-femoral pulse wave velocity measurement, and resting muscle sympathetic nerve activity was measured using microneurography. 

The results showed that men with CKD had significantly higher resting muscle sympathetic nerve activity compared with women with CKD (68 vs 55 bursts per 100 heartbeats; P = .005), whereas no differences in vascular stiffness were observed between the genders (P = .248).

“The findings suggest that the higher cardiovascular disease risk observed in older males with CKD may be influenced by elevated sympathetic activity,” Dr. Zanuzzi explained.

“However, the lack of significant differences in vascular stiffness between genders implies that additional factors beyond vascular remodeling may contribute to the observed sex-specific differences in cardiovascular risk,” he said.

Of note, resting vascular stiffness was not associated with muscular sympathetic nerve activity in either men or women, which was surprising to the authors, Dr. Zanuzzi noted.

“This underscores the multifactorial nature of vascular pathophysiology in CKD and underscores the need for further research to unravel the underlying mechanisms.”

In other findings, although prior studies have shown a positive correlation between age and resting muscle sympathetic nerve activity in White, healthy women and men without obesity,, no similar relationship was observed in men or women with CKD.

“These findings suggest that the protective effect of younger age on sympathetic function may not be present in the setting of decreased kidney function in both males and females,” the authors note.

In addition, whereas previous research has shown a clear association between sympathetic overactivity and a wide variety of measures of obesity, in the current study, that association was only observed in men with CKD.

Important limitations of the study include the cross-sectional design and that the population was predominantly Black, Dr. Zanuzzi noted.

“Generalizability to other demographic groups may be limited, and future longitudinal studies are needed to validate these findings and explore potential causal relationships,” he said.

The findings underscore “the need for novel therapeutic approaches targeting sympathetic overactivity and vascular stiffness in CKD patients, especially considering the observed sex-specific differences,” Dr. Zanuzzi added. 

“Potential interventions may include pharmacological agents that modulate sympathetic tone or vascular remodeling pathways,” he said.

“Lifestyle modifications focusing on stress reduction and cardiovascular health promotion could also play a crucial role in mitigating cardiovascular risk.”

Dr. Zanuzzi concluded that “tailoring treatment strategies to address these differences may lead to more personalized and effective management approaches, ultimately improving clinical outcomes in this high-risk population.”

The authors had no disclosures to report.

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

Older men with chronic kidney disease (CKD) show higher resting muscle sympathetic nerve activity, but not vascular stiffness, compared with older women, offering clues to the underlying reasons why men with CKD have a higher cardiovascular risk than do women with the disease.

“Although it is well established that sympathetic nerve system activity is chronically elevated in patients with impaired kidney function, we show for the first time that males with CKD have higher resting muscle sympathetic nerve activity compared with females with CKD,” report the authors on research published in the American Journal of Physiology-Renal Physiology.

“For clinicians, the key takeaway is the importance of recognizing sex-specific differences in sympathetic activity and vascular function when assessing cardiovascular risk in CKD patients,” first author Matias G. Zanuzzi, MD, of the Division of Renal Medicine, Department of Medicine, Emory University School of Medicine, Atlanta, Georgia, told this news organization.

In the general population, cardiovascular risk is lower in younger women vs men, but their risks converge in older age as women develop similar levels of sympathetic overactivity, vascular stiffness, and cardiovascular risk.

However, an exception to that pattern is seen in the CKD population, where men continue to have a higher cardiovascular mortality risk vs women even in older age.

Studies evaluating the reasons for that have been conflicting, with some reporting a tendency of higher muscle sympathetic nerve activity in older women compared with men and others suggest the opposite finding — lower activity vs men.

To further investigate, Dr. Zanuzzi and colleagues enrolled 129 participants, including 96 men and 33 women with stage III or IV CKD.

The mean age of the study participants was 64 years for men and65 years for women. Most had obesity, and importantly, more than 80% of participants in each group was Black. There were no significant differences between the groups in terms of body mass index or comorbidities, including smoking, diabetes, or hypertension.

At two separate study visits, vascular stiffness was assessed with carotid-femoral pulse wave velocity measurement, and resting muscle sympathetic nerve activity was measured using microneurography. 

The results showed that men with CKD had significantly higher resting muscle sympathetic nerve activity compared with women with CKD (68 vs 55 bursts per 100 heartbeats; P = .005), whereas no differences in vascular stiffness were observed between the genders (P = .248).

“The findings suggest that the higher cardiovascular disease risk observed in older males with CKD may be influenced by elevated sympathetic activity,” Dr. Zanuzzi explained.

“However, the lack of significant differences in vascular stiffness between genders implies that additional factors beyond vascular remodeling may contribute to the observed sex-specific differences in cardiovascular risk,” he said.

Of note, resting vascular stiffness was not associated with muscular sympathetic nerve activity in either men or women, which was surprising to the authors, Dr. Zanuzzi noted.

“This underscores the multifactorial nature of vascular pathophysiology in CKD and underscores the need for further research to unravel the underlying mechanisms.”

In other findings, although prior studies have shown a positive correlation between age and resting muscle sympathetic nerve activity in White, healthy women and men without obesity,, no similar relationship was observed in men or women with CKD.

“These findings suggest that the protective effect of younger age on sympathetic function may not be present in the setting of decreased kidney function in both males and females,” the authors note.

In addition, whereas previous research has shown a clear association between sympathetic overactivity and a wide variety of measures of obesity, in the current study, that association was only observed in men with CKD.

Important limitations of the study include the cross-sectional design and that the population was predominantly Black, Dr. Zanuzzi noted.

“Generalizability to other demographic groups may be limited, and future longitudinal studies are needed to validate these findings and explore potential causal relationships,” he said.

The findings underscore “the need for novel therapeutic approaches targeting sympathetic overactivity and vascular stiffness in CKD patients, especially considering the observed sex-specific differences,” Dr. Zanuzzi added. 

“Potential interventions may include pharmacological agents that modulate sympathetic tone or vascular remodeling pathways,” he said.

“Lifestyle modifications focusing on stress reduction and cardiovascular health promotion could also play a crucial role in mitigating cardiovascular risk.”

Dr. Zanuzzi concluded that “tailoring treatment strategies to address these differences may lead to more personalized and effective management approaches, ultimately improving clinical outcomes in this high-risk population.”

The authors had no disclosures to report.

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

Older men with chronic kidney disease (CKD) show higher resting muscle sympathetic nerve activity, but not vascular stiffness, compared with older women, offering clues to the underlying reasons why men with CKD have a higher cardiovascular risk than do women with the disease.

“Although it is well established that sympathetic nerve system activity is chronically elevated in patients with impaired kidney function, we show for the first time that males with CKD have higher resting muscle sympathetic nerve activity compared with females with CKD,” report the authors on research published in the American Journal of Physiology-Renal Physiology.

“For clinicians, the key takeaway is the importance of recognizing sex-specific differences in sympathetic activity and vascular function when assessing cardiovascular risk in CKD patients,” first author Matias G. Zanuzzi, MD, of the Division of Renal Medicine, Department of Medicine, Emory University School of Medicine, Atlanta, Georgia, told this news organization.

In the general population, cardiovascular risk is lower in younger women vs men, but their risks converge in older age as women develop similar levels of sympathetic overactivity, vascular stiffness, and cardiovascular risk.

However, an exception to that pattern is seen in the CKD population, where men continue to have a higher cardiovascular mortality risk vs women even in older age.

Studies evaluating the reasons for that have been conflicting, with some reporting a tendency of higher muscle sympathetic nerve activity in older women compared with men and others suggest the opposite finding — lower activity vs men.

To further investigate, Dr. Zanuzzi and colleagues enrolled 129 participants, including 96 men and 33 women with stage III or IV CKD.

The mean age of the study participants was 64 years for men and65 years for women. Most had obesity, and importantly, more than 80% of participants in each group was Black. There were no significant differences between the groups in terms of body mass index or comorbidities, including smoking, diabetes, or hypertension.

At two separate study visits, vascular stiffness was assessed with carotid-femoral pulse wave velocity measurement, and resting muscle sympathetic nerve activity was measured using microneurography. 

The results showed that men with CKD had significantly higher resting muscle sympathetic nerve activity compared with women with CKD (68 vs 55 bursts per 100 heartbeats; P = .005), whereas no differences in vascular stiffness were observed between the genders (P = .248).

“The findings suggest that the higher cardiovascular disease risk observed in older males with CKD may be influenced by elevated sympathetic activity,” Dr. Zanuzzi explained.

“However, the lack of significant differences in vascular stiffness between genders implies that additional factors beyond vascular remodeling may contribute to the observed sex-specific differences in cardiovascular risk,” he said.

Of note, resting vascular stiffness was not associated with muscular sympathetic nerve activity in either men or women, which was surprising to the authors, Dr. Zanuzzi noted.

“This underscores the multifactorial nature of vascular pathophysiology in CKD and underscores the need for further research to unravel the underlying mechanisms.”

In other findings, although prior studies have shown a positive correlation between age and resting muscle sympathetic nerve activity in White, healthy women and men without obesity,, no similar relationship was observed in men or women with CKD.

“These findings suggest that the protective effect of younger age on sympathetic function may not be present in the setting of decreased kidney function in both males and females,” the authors note.

In addition, whereas previous research has shown a clear association between sympathetic overactivity and a wide variety of measures of obesity, in the current study, that association was only observed in men with CKD.

Important limitations of the study include the cross-sectional design and that the population was predominantly Black, Dr. Zanuzzi noted.

“Generalizability to other demographic groups may be limited, and future longitudinal studies are needed to validate these findings and explore potential causal relationships,” he said.

The findings underscore “the need for novel therapeutic approaches targeting sympathetic overactivity and vascular stiffness in CKD patients, especially considering the observed sex-specific differences,” Dr. Zanuzzi added. 

“Potential interventions may include pharmacological agents that modulate sympathetic tone or vascular remodeling pathways,” he said.

“Lifestyle modifications focusing on stress reduction and cardiovascular health promotion could also play a crucial role in mitigating cardiovascular risk.”

Dr. Zanuzzi concluded that “tailoring treatment strategies to address these differences may lead to more personalized and effective management approaches, ultimately improving clinical outcomes in this high-risk population.”

The authors had no disclosures to report.

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

Insane hours and work-driven burnout are increasingly pernicious forces in medical workplaces. They apparently also are helping steer more physicians toward locum tenens, or temporary, assignments.

In its “2024 Survey of Locum Tenens Physicians and Advanced Practice Professionals,” Coppell, Texas–based staffing firm AMN Healthcare asked doctors, nurse practitioners, and physician assistants why they chose locum tenens work.

Morsa Images/DigitalVision/Getty Images

The reason chosen most often is improving work hours. Eighty-six percent of respondents said that was the “most important” or a “moderately important” factor. Next was addressing work burnout (80% of respondents), followed by unhappiness with compensation (75%), and dissatisfaction with being a full-time employee (71%).

“During the COVID pandemic, healthcare professionals began to rethink how, when, and where they work,” said Jeff Decker, president of AMN Healthcare’s physician solutions division, adding that he estimates about 52,000 US physicians now work on a locum tenens basis.

“Locum tenens offers relief from the long, inflexible work hours and onerous bureaucratic duties that often cause dissatisfaction and burnout among physicians and other healthcare providers.”

These feelings of dissatisfaction dovetail with findings in recent reports by this news organization based on surveys of physicians about burnout and employment. For example:

• Forty-nine percent of physicians acknowledged feeling burned out, up from 42% 6 years earlier.
• Eighty-three percent of doctors attributed their burnout and/or depression to the job entirely or most of the time.
• Flexibility in work schedules was one of the improvements chosen most often as a potential aid to burnout.
• The leading reasons cited for burnout were the number of bureaucratic tasks and too many hours at work.

Trying Locum Tenens Early in Career

According to AMN Healthcare, 81% of the physicians and APPs in its latest survey said they started taking locum tenens assignments immediately after finishing medical training or in mid-career. Only 19% waited until after retiring from medicine compared with 36% in AMN Healthcare’s 2016 survey.

In the 2024 report, a strong plurality of respondents (47%) said they found locum tenens work more satisfying than permanent healthcare employment. Twelve percent said the opposite, and 30% found the choices about equal.

Even so, it doesn’t appear that locum tenens represents a permanent career path for many. About as many (45%) of physicians and APPs said they would return to full-time employment if progress were made with conditions like hours and burnout, as said they would not (43%).

“Many physicians and other healthcare professionals feel they are being pushed from permanent positions by unsatisfactory work conditions,” Mr. Decker said. “To get them back, employers should offer practice conditions that appeal to today’s providers.”

A version of this article appeared on Medscape.com.

Insane hours and work-driven burnout are increasingly pernicious forces in medical workplaces. They apparently also are helping steer more physicians toward locum tenens, or temporary, assignments.

In its “2024 Survey of Locum Tenens Physicians and Advanced Practice Professionals,” Coppell, Texas–based staffing firm AMN Healthcare asked doctors, nurse practitioners, and physician assistants why they chose locum tenens work.

Morsa Images/DigitalVision/Getty Images

The reason chosen most often is improving work hours. Eighty-six percent of respondents said that was the “most important” or a “moderately important” factor. Next was addressing work burnout (80% of respondents), followed by unhappiness with compensation (75%), and dissatisfaction with being a full-time employee (71%).

“During the COVID pandemic, healthcare professionals began to rethink how, when, and where they work,” said Jeff Decker, president of AMN Healthcare’s physician solutions division, adding that he estimates about 52,000 US physicians now work on a locum tenens basis.

“Locum tenens offers relief from the long, inflexible work hours and onerous bureaucratic duties that often cause dissatisfaction and burnout among physicians and other healthcare providers.”

These feelings of dissatisfaction dovetail with findings in recent reports by this news organization based on surveys of physicians about burnout and employment. For example:

• Forty-nine percent of physicians acknowledged feeling burned out, up from 42% 6 years earlier.
• Eighty-three percent of doctors attributed their burnout and/or depression to the job entirely or most of the time.
• Flexibility in work schedules was one of the improvements chosen most often as a potential aid to burnout.
• The leading reasons cited for burnout were the number of bureaucratic tasks and too many hours at work.

Trying Locum Tenens Early in Career

According to AMN Healthcare, 81% of the physicians and APPs in its latest survey said they started taking locum tenens assignments immediately after finishing medical training or in mid-career. Only 19% waited until after retiring from medicine compared with 36% in AMN Healthcare’s 2016 survey.

In the 2024 report, a strong plurality of respondents (47%) said they found locum tenens work more satisfying than permanent healthcare employment. Twelve percent said the opposite, and 30% found the choices about equal.

Even so, it doesn’t appear that locum tenens represents a permanent career path for many. About as many (45%) of physicians and APPs said they would return to full-time employment if progress were made with conditions like hours and burnout, as said they would not (43%).

“Many physicians and other healthcare professionals feel they are being pushed from permanent positions by unsatisfactory work conditions,” Mr. Decker said. “To get them back, employers should offer practice conditions that appeal to today’s providers.”

A version of this article appeared on Medscape.com.

Insane hours and work-driven burnout are increasingly pernicious forces in medical workplaces. They apparently also are helping steer more physicians toward locum tenens, or temporary, assignments.

In its “2024 Survey of Locum Tenens Physicians and Advanced Practice Professionals,” Coppell, Texas–based staffing firm AMN Healthcare asked doctors, nurse practitioners, and physician assistants why they chose locum tenens work.

Morsa Images/DigitalVision/Getty Images

The reason chosen most often is improving work hours. Eighty-six percent of respondents said that was the “most important” or a “moderately important” factor. Next was addressing work burnout (80% of respondents), followed by unhappiness with compensation (75%), and dissatisfaction with being a full-time employee (71%).

“During the COVID pandemic, healthcare professionals began to rethink how, when, and where they work,” said Jeff Decker, president of AMN Healthcare’s physician solutions division, adding that he estimates about 52,000 US physicians now work on a locum tenens basis.

“Locum tenens offers relief from the long, inflexible work hours and onerous bureaucratic duties that often cause dissatisfaction and burnout among physicians and other healthcare providers.”

These feelings of dissatisfaction dovetail with findings in recent reports by this news organization based on surveys of physicians about burnout and employment. For example:

• Forty-nine percent of physicians acknowledged feeling burned out, up from 42% 6 years earlier.
• Eighty-three percent of doctors attributed their burnout and/or depression to the job entirely or most of the time.
• Flexibility in work schedules was one of the improvements chosen most often as a potential aid to burnout.
• The leading reasons cited for burnout were the number of bureaucratic tasks and too many hours at work.

Trying Locum Tenens Early in Career

According to AMN Healthcare, 81% of the physicians and APPs in its latest survey said they started taking locum tenens assignments immediately after finishing medical training or in mid-career. Only 19% waited until after retiring from medicine compared with 36% in AMN Healthcare’s 2016 survey.

In the 2024 report, a strong plurality of respondents (47%) said they found locum tenens work more satisfying than permanent healthcare employment. Twelve percent said the opposite, and 30% found the choices about equal.

Even so, it doesn’t appear that locum tenens represents a permanent career path for many. About as many (45%) of physicians and APPs said they would return to full-time employment if progress were made with conditions like hours and burnout, as said they would not (43%).

“Many physicians and other healthcare professionals feel they are being pushed from permanent positions by unsatisfactory work conditions,” Mr. Decker said. “To get them back, employers should offer practice conditions that appeal to today’s providers.”

A version of this article appeared on Medscape.com.

Medical innovations don’t happen overnight — but in today’s digital world, they happen pretty fast. Some are advancing faster than you think.

We’re not talking theory or hoped-for breakthroughs in the next decade. These technologies are already a reality for many doctors and expected to grow rapidly in the next 1-3 years.

Are you ready? Let’s find out.

1. Artificial Intelligence (AI) Medical Scribes

You may already be using this or, at the very least, have heard about it.

Physician burnout is a growing problem, with many doctors spending 2 hours on paperwork for every hour with patients. But some doctors, such as Gregory Ator, MD, chief medical informatics officer at the University of Kansas Medical Center, Kansas City, Kansas, have found a better way.

“I have been using it for 9 months now, and it truly is a life changer,” Dr. Ator said of Abridge, an AI helper that transcribes and summarizes his conversations with patients. “Now, I go into the room, place my phone just about anywhere, and I can just listen.” He estimated that the tech saves him between 3 and 10 minutes per patient. “At 20 patients a day, that saves me around 2 hours,” he said.

Bonus: Patients “get a doctor’s full attention instead of just looking at the top of his head while they play with the computer,” Dr. Ator said. “I have yet to have a patient who didn’t think that was a positive thing.”

Several companies are already selling these AI devices, including Ambience Healthcare, Augmedix, Nuance, and Suki, and they offer more than just transcriptions, said John D. Halamka, MD, president of Mayo Clinic Platform, who oversees Mayo’s adoption of AI. They also generate notes for treatment and billing and update data in the electronic health record.

“It’s preparation of documentation based on ambient listening of doctor-patient conversations,” Dr. Halamka explained. “I’m very optimistic about the use of emerging AI technologies to enable every clinician to practice at the top of their license.”

Patricia Garcia, MD, associate clinical information officer for ambulatory care at Stanford Health Care, has spent much of the last year co-running the medical center’s pilot program for AI scribes, and she’s so impressed with the technology that she “expects it’ll become more widely available as an option for any clinician that wants to use it in the next 12-18 months.”

2. Three-Dimensional (3D) Printing

Although 3D-printed organs may not happen anytime soon, the future is here for some 3D-printed prosthetics and implants — everything from dentures to spinal implants to prosthetic fingers and noses.

“In the next few years, I see rapid growth in the use of 3D printing technology across orthopedic surgery,” said Rishin J. Kadakia, MD, an orthopedic surgeon in Atlanta. “It’s becoming more common not just at large academic institutions. More and more providers will turn to using 3D printing technology to help tackle challenging cases that previously did not have good solutions.”

Dr. Kadakia has experienced this firsthand with his patients at the Emory Orthopaedics & Spine Center. One female patient developed talar avascular necrosis due to a bone break she’d sustained in a serious car crash. An ankle and subtalar joint fusion would repair the damage but limit her mobility and change her gait. So instead, in August of 2021, Dr. Kadakia and fellow orthopedic surgeon Jason Bariteau, MD, created for her a 3D-printed cobalt chrome talus implant.

“It provided an opportunity for her to keep her ankle’s range of motion, and also mobilize faster than with a subtalar and ankle joint fusion,” said Dr. Kadakia.

The technology is also playing a role in customized medical devices — patient-specific tools for greater precision — and 3D-printed anatomical models, built to the exact specifications of individual patients. Mayo Clinic already has 3D modeling units in three states, and other hospitals are following suit. The models not only help doctors prepare for complicated surgeries but also can dramatically cut down on costs. A 2021 study from Durham University reported that 3D models helped reduce surgery time by between 1.5 and 2.5 hours in lengthy procedures.

3. Drones

For patients who can’t make it to a pharmacy to pick up their prescriptions, either because of distance or lack of transportation, drones — which can deliver medications onto a customer’s back yard or front porch — offer a compelling solution.

Several companies and hospitals are already experimenting with drones, like WellSpan Health in Pennsylvania, Amazon Pharmacy, and the Cleveland Clinic, which announced a partnership with drone delivery company Zipline and plans to begin prescription deliveries across Northeast Ohio by 2025.

Healthcare systems are just beginning to explore the potential of drone deliveries, for everything from lab samples to medical and surgical supplies — even defibrillators that could arrive at an ailing patient’s front door before an emergency medical technician arrives.

“For many providers, when you take a sample from a patient, that sample waits around for hours until a courier picks up all of the facility’s samples and drives them to an outside facility for processing,” said Hillary Brendzel, head of Zipline’s US Healthcare Practice.

According to a 2022 survey from American Nurse Journal, 71% of nurses said that medical courier delays and errors negatively affected their ability to provide patient care. But with drone delivery, “lab samples can be sent for processing immediately, on-demand, resulting in faster diagnosis, treatment, and ultimately better outcomes,” said Ms. Brendzel.

4. Portable Ultrasound

Within the next 2 years, portable ultrasound — pocket-sized devices that connect to a smartphone or tablet — will become the “21st-century stethoscope,” said Abhilash Hareendranathan, PhD, assistant professor in the Department of Radiology and Diagnostic Imaging at the University of Alberta, in Edmonton, Alberta, Canada.

AI can make these devices easy to use, allowing clinicians with minimal imaging training to capture clear images and understand the results. Dr. Hareendranathan developed the Ultrasound Arm Injury Detection tool, a portable ultrasound that uses AI to detect fracture.

“We plan to introduce this technology in emergency departments, where it could be used by triage nurses to perform quick examinations to detect fractures of the wrist, elbow, or shoulder,” he said.

More pocket-sized scanners like these could “reshape the way diagnostic care is provided in rural and remote communities,” Dr. Hareendranathan said, and will “reduce wait times in crowded emergency departments.” Bill Gates believes enough in portable ultrasound that last September, the Bill & Melinda Gates Foundation granted $44 million to GE HealthCare to develop the technology for under-resourced communities.

5. Virtual Reality (VR)

When RelieVRx became the first US Food and Drug Administration (FDA)–approved VR therapy for chronic back pain in 2021, the technology was used in just a handful of Veterans Affairs (VA) facilities. But today, thousands of VR headsets have been deployed to more than 160 VA medical centers and clinics across the country.

“The VR experiences encompass pain neuroscience education, mindfulness, pleasant and relaxing distraction, and key skills to calm the nervous system,” said Beth Darnall, PhD, director of the Stanford Pain Relief Innovations Lab, who helped design the RelieVRx. She expects VR to go mainstream soon, not just because of increasing evidence that it works but also thanks to the Centers for Medicare & Medicaid Services, which recently issued a Healthcare Common Procedure Coding System code for VR. “This billing infrastructure will encourage adoption and uptake,” she said.

Hundreds of hospitals across the United States have already adopted the technology, for everything from childbirth pain to wound debridement, said Josh Sackman, the president and cofounder of AppliedVR, the company that developed RelieVRx.

“Over the next few years, we may see hundreds more deploy unique applications [for VR] that can handle multiple clinical indications,” he said. “Given the modality’s ability to scale and reduce reliance on pharmacological interventions, it has the power to improve the cost and quality of care.”

Hospital systems like Geisinger and Cedars-Sinai are already finding unique ways to implement the technology, he said, like using VR to reduce “scanxiety” during imaging service.

Other VR innovations are already being introduced, from the Smileyscope, a VR device for children that’s been proven to lessen the pain of a blood draw or intravenous insertion (it was cleared by the FDA last November) to several VR platforms launched by Cedars-Sinai in recent months, for applications that range from gastrointestinal issues to mental health therapy. “There may already be a thousand hospitals using VR in some capacity,” said Brennan Spiegel, MD, director of Health Services Research at Cedars-Sinai.

A version of this article appeared on Medscape.com.

Medical innovations don’t happen overnight — but in today’s digital world, they happen pretty fast. Some are advancing faster than you think.

We’re not talking theory or hoped-for breakthroughs in the next decade. These technologies are already a reality for many doctors and expected to grow rapidly in the next 1-3 years.

Are you ready? Let’s find out.

1. Artificial Intelligence (AI) Medical Scribes

You may already be using this or, at the very least, have heard about it.

Physician burnout is a growing problem, with many doctors spending 2 hours on paperwork for every hour with patients. But some doctors, such as Gregory Ator, MD, chief medical informatics officer at the University of Kansas Medical Center, Kansas City, Kansas, have found a better way.

“I have been using it for 9 months now, and it truly is a life changer,” Dr. Ator said of Abridge, an AI helper that transcribes and summarizes his conversations with patients. “Now, I go into the room, place my phone just about anywhere, and I can just listen.” He estimated that the tech saves him between 3 and 10 minutes per patient. “At 20 patients a day, that saves me around 2 hours,” he said.

Bonus: Patients “get a doctor’s full attention instead of just looking at the top of his head while they play with the computer,” Dr. Ator said. “I have yet to have a patient who didn’t think that was a positive thing.”

Several companies are already selling these AI devices, including Ambience Healthcare, Augmedix, Nuance, and Suki, and they offer more than just transcriptions, said John D. Halamka, MD, president of Mayo Clinic Platform, who oversees Mayo’s adoption of AI. They also generate notes for treatment and billing and update data in the electronic health record.

“It’s preparation of documentation based on ambient listening of doctor-patient conversations,” Dr. Halamka explained. “I’m very optimistic about the use of emerging AI technologies to enable every clinician to practice at the top of their license.”

Patricia Garcia, MD, associate clinical information officer for ambulatory care at Stanford Health Care, has spent much of the last year co-running the medical center’s pilot program for AI scribes, and she’s so impressed with the technology that she “expects it’ll become more widely available as an option for any clinician that wants to use it in the next 12-18 months.”

2. Three-Dimensional (3D) Printing

Although 3D-printed organs may not happen anytime soon, the future is here for some 3D-printed prosthetics and implants — everything from dentures to spinal implants to prosthetic fingers and noses.

“In the next few years, I see rapid growth in the use of 3D printing technology across orthopedic surgery,” said Rishin J. Kadakia, MD, an orthopedic surgeon in Atlanta. “It’s becoming more common not just at large academic institutions. More and more providers will turn to using 3D printing technology to help tackle challenging cases that previously did not have good solutions.”

Dr. Kadakia has experienced this firsthand with his patients at the Emory Orthopaedics & Spine Center. One female patient developed talar avascular necrosis due to a bone break she’d sustained in a serious car crash. An ankle and subtalar joint fusion would repair the damage but limit her mobility and change her gait. So instead, in August of 2021, Dr. Kadakia and fellow orthopedic surgeon Jason Bariteau, MD, created for her a 3D-printed cobalt chrome talus implant.

“It provided an opportunity for her to keep her ankle’s range of motion, and also mobilize faster than with a subtalar and ankle joint fusion,” said Dr. Kadakia.

The technology is also playing a role in customized medical devices — patient-specific tools for greater precision — and 3D-printed anatomical models, built to the exact specifications of individual patients. Mayo Clinic already has 3D modeling units in three states, and other hospitals are following suit. The models not only help doctors prepare for complicated surgeries but also can dramatically cut down on costs. A 2021 study from Durham University reported that 3D models helped reduce surgery time by between 1.5 and 2.5 hours in lengthy procedures.

3. Drones

For patients who can’t make it to a pharmacy to pick up their prescriptions, either because of distance or lack of transportation, drones — which can deliver medications onto a customer’s back yard or front porch — offer a compelling solution.

Several companies and hospitals are already experimenting with drones, like WellSpan Health in Pennsylvania, Amazon Pharmacy, and the Cleveland Clinic, which announced a partnership with drone delivery company Zipline and plans to begin prescription deliveries across Northeast Ohio by 2025.

Healthcare systems are just beginning to explore the potential of drone deliveries, for everything from lab samples to medical and surgical supplies — even defibrillators that could arrive at an ailing patient’s front door before an emergency medical technician arrives.

“For many providers, when you take a sample from a patient, that sample waits around for hours until a courier picks up all of the facility’s samples and drives them to an outside facility for processing,” said Hillary Brendzel, head of Zipline’s US Healthcare Practice.

According to a 2022 survey from American Nurse Journal, 71% of nurses said that medical courier delays and errors negatively affected their ability to provide patient care. But with drone delivery, “lab samples can be sent for processing immediately, on-demand, resulting in faster diagnosis, treatment, and ultimately better outcomes,” said Ms. Brendzel.

4. Portable Ultrasound

Within the next 2 years, portable ultrasound — pocket-sized devices that connect to a smartphone or tablet — will become the “21st-century stethoscope,” said Abhilash Hareendranathan, PhD, assistant professor in the Department of Radiology and Diagnostic Imaging at the University of Alberta, in Edmonton, Alberta, Canada.

AI can make these devices easy to use, allowing clinicians with minimal imaging training to capture clear images and understand the results. Dr. Hareendranathan developed the Ultrasound Arm Injury Detection tool, a portable ultrasound that uses AI to detect fracture.

“We plan to introduce this technology in emergency departments, where it could be used by triage nurses to perform quick examinations to detect fractures of the wrist, elbow, or shoulder,” he said.

More pocket-sized scanners like these could “reshape the way diagnostic care is provided in rural and remote communities,” Dr. Hareendranathan said, and will “reduce wait times in crowded emergency departments.” Bill Gates believes enough in portable ultrasound that last September, the Bill & Melinda Gates Foundation granted $44 million to GE HealthCare to develop the technology for under-resourced communities.

5. Virtual Reality (VR)

When RelieVRx became the first US Food and Drug Administration (FDA)–approved VR therapy for chronic back pain in 2021, the technology was used in just a handful of Veterans Affairs (VA) facilities. But today, thousands of VR headsets have been deployed to more than 160 VA medical centers and clinics across the country.

“The VR experiences encompass pain neuroscience education, mindfulness, pleasant and relaxing distraction, and key skills to calm the nervous system,” said Beth Darnall, PhD, director of the Stanford Pain Relief Innovations Lab, who helped design the RelieVRx. She expects VR to go mainstream soon, not just because of increasing evidence that it works but also thanks to the Centers for Medicare & Medicaid Services, which recently issued a Healthcare Common Procedure Coding System code for VR. “This billing infrastructure will encourage adoption and uptake,” she said.

Hundreds of hospitals across the United States have already adopted the technology, for everything from childbirth pain to wound debridement, said Josh Sackman, the president and cofounder of AppliedVR, the company that developed RelieVRx.

“Over the next few years, we may see hundreds more deploy unique applications [for VR] that can handle multiple clinical indications,” he said. “Given the modality’s ability to scale and reduce reliance on pharmacological interventions, it has the power to improve the cost and quality of care.”

Hospital systems like Geisinger and Cedars-Sinai are already finding unique ways to implement the technology, he said, like using VR to reduce “scanxiety” during imaging service.

Other VR innovations are already being introduced, from the Smileyscope, a VR device for children that’s been proven to lessen the pain of a blood draw or intravenous insertion (it was cleared by the FDA last November) to several VR platforms launched by Cedars-Sinai in recent months, for applications that range from gastrointestinal issues to mental health therapy. “There may already be a thousand hospitals using VR in some capacity,” said Brennan Spiegel, MD, director of Health Services Research at Cedars-Sinai.

A version of this article appeared on Medscape.com.

Medical innovations don’t happen overnight — but in today’s digital world, they happen pretty fast. Some are advancing faster than you think.

We’re not talking theory or hoped-for breakthroughs in the next decade. These technologies are already a reality for many doctors and expected to grow rapidly in the next 1-3 years.

Are you ready? Let’s find out.

1. Artificial Intelligence (AI) Medical Scribes

You may already be using this or, at the very least, have heard about it.

Physician burnout is a growing problem, with many doctors spending 2 hours on paperwork for every hour with patients. But some doctors, such as Gregory Ator, MD, chief medical informatics officer at the University of Kansas Medical Center, Kansas City, Kansas, have found a better way.

“I have been using it for 9 months now, and it truly is a life changer,” Dr. Ator said of Abridge, an AI helper that transcribes and summarizes his conversations with patients. “Now, I go into the room, place my phone just about anywhere, and I can just listen.” He estimated that the tech saves him between 3 and 10 minutes per patient. “At 20 patients a day, that saves me around 2 hours,” he said.

Bonus: Patients “get a doctor’s full attention instead of just looking at the top of his head while they play with the computer,” Dr. Ator said. “I have yet to have a patient who didn’t think that was a positive thing.”

Several companies are already selling these AI devices, including Ambience Healthcare, Augmedix, Nuance, and Suki, and they offer more than just transcriptions, said John D. Halamka, MD, president of Mayo Clinic Platform, who oversees Mayo’s adoption of AI. They also generate notes for treatment and billing and update data in the electronic health record.

“It’s preparation of documentation based on ambient listening of doctor-patient conversations,” Dr. Halamka explained. “I’m very optimistic about the use of emerging AI technologies to enable every clinician to practice at the top of their license.”

Patricia Garcia, MD, associate clinical information officer for ambulatory care at Stanford Health Care, has spent much of the last year co-running the medical center’s pilot program for AI scribes, and she’s so impressed with the technology that she “expects it’ll become more widely available as an option for any clinician that wants to use it in the next 12-18 months.”

2. Three-Dimensional (3D) Printing

Although 3D-printed organs may not happen anytime soon, the future is here for some 3D-printed prosthetics and implants — everything from dentures to spinal implants to prosthetic fingers and noses.

“In the next few years, I see rapid growth in the use of 3D printing technology across orthopedic surgery,” said Rishin J. Kadakia, MD, an orthopedic surgeon in Atlanta. “It’s becoming more common not just at large academic institutions. More and more providers will turn to using 3D printing technology to help tackle challenging cases that previously did not have good solutions.”

Dr. Kadakia has experienced this firsthand with his patients at the Emory Orthopaedics & Spine Center. One female patient developed talar avascular necrosis due to a bone break she’d sustained in a serious car crash. An ankle and subtalar joint fusion would repair the damage but limit her mobility and change her gait. So instead, in August of 2021, Dr. Kadakia and fellow orthopedic surgeon Jason Bariteau, MD, created for her a 3D-printed cobalt chrome talus implant.

“It provided an opportunity for her to keep her ankle’s range of motion, and also mobilize faster than with a subtalar and ankle joint fusion,” said Dr. Kadakia.

The technology is also playing a role in customized medical devices — patient-specific tools for greater precision — and 3D-printed anatomical models, built to the exact specifications of individual patients. Mayo Clinic already has 3D modeling units in three states, and other hospitals are following suit. The models not only help doctors prepare for complicated surgeries but also can dramatically cut down on costs. A 2021 study from Durham University reported that 3D models helped reduce surgery time by between 1.5 and 2.5 hours in lengthy procedures.

3. Drones

For patients who can’t make it to a pharmacy to pick up their prescriptions, either because of distance or lack of transportation, drones — which can deliver medications onto a customer’s back yard or front porch — offer a compelling solution.

Several companies and hospitals are already experimenting with drones, like WellSpan Health in Pennsylvania, Amazon Pharmacy, and the Cleveland Clinic, which announced a partnership with drone delivery company Zipline and plans to begin prescription deliveries across Northeast Ohio by 2025.

Healthcare systems are just beginning to explore the potential of drone deliveries, for everything from lab samples to medical and surgical supplies — even defibrillators that could arrive at an ailing patient’s front door before an emergency medical technician arrives.

“For many providers, when you take a sample from a patient, that sample waits around for hours until a courier picks up all of the facility’s samples and drives them to an outside facility for processing,” said Hillary Brendzel, head of Zipline’s US Healthcare Practice.

According to a 2022 survey from American Nurse Journal, 71% of nurses said that medical courier delays and errors negatively affected their ability to provide patient care. But with drone delivery, “lab samples can be sent for processing immediately, on-demand, resulting in faster diagnosis, treatment, and ultimately better outcomes,” said Ms. Brendzel.

4. Portable Ultrasound

Within the next 2 years, portable ultrasound — pocket-sized devices that connect to a smartphone or tablet — will become the “21st-century stethoscope,” said Abhilash Hareendranathan, PhD, assistant professor in the Department of Radiology and Diagnostic Imaging at the University of Alberta, in Edmonton, Alberta, Canada.

AI can make these devices easy to use, allowing clinicians with minimal imaging training to capture clear images and understand the results. Dr. Hareendranathan developed the Ultrasound Arm Injury Detection tool, a portable ultrasound that uses AI to detect fracture.

“We plan to introduce this technology in emergency departments, where it could be used by triage nurses to perform quick examinations to detect fractures of the wrist, elbow, or shoulder,” he said.

More pocket-sized scanners like these could “reshape the way diagnostic care is provided in rural and remote communities,” Dr. Hareendranathan said, and will “reduce wait times in crowded emergency departments.” Bill Gates believes enough in portable ultrasound that last September, the Bill & Melinda Gates Foundation granted $44 million to GE HealthCare to develop the technology for under-resourced communities.

5. Virtual Reality (VR)

When RelieVRx became the first US Food and Drug Administration (FDA)–approved VR therapy for chronic back pain in 2021, the technology was used in just a handful of Veterans Affairs (VA) facilities. But today, thousands of VR headsets have been deployed to more than 160 VA medical centers and clinics across the country.

“The VR experiences encompass pain neuroscience education, mindfulness, pleasant and relaxing distraction, and key skills to calm the nervous system,” said Beth Darnall, PhD, director of the Stanford Pain Relief Innovations Lab, who helped design the RelieVRx. She expects VR to go mainstream soon, not just because of increasing evidence that it works but also thanks to the Centers for Medicare & Medicaid Services, which recently issued a Healthcare Common Procedure Coding System code for VR. “This billing infrastructure will encourage adoption and uptake,” she said.

Hundreds of hospitals across the United States have already adopted the technology, for everything from childbirth pain to wound debridement, said Josh Sackman, the president and cofounder of AppliedVR, the company that developed RelieVRx.

“Over the next few years, we may see hundreds more deploy unique applications [for VR] that can handle multiple clinical indications,” he said. “Given the modality’s ability to scale and reduce reliance on pharmacological interventions, it has the power to improve the cost and quality of care.”

Hospital systems like Geisinger and Cedars-Sinai are already finding unique ways to implement the technology, he said, like using VR to reduce “scanxiety” during imaging service.

Other VR innovations are already being introduced, from the Smileyscope, a VR device for children that’s been proven to lessen the pain of a blood draw or intravenous insertion (it was cleared by the FDA last November) to several VR platforms launched by Cedars-Sinai in recent months, for applications that range from gastrointestinal issues to mental health therapy. “There may already be a thousand hospitals using VR in some capacity,” said Brennan Spiegel, MD, director of Health Services Research at Cedars-Sinai.

A version of this article appeared on Medscape.com.

ASUNCIÓN, PARAGUAY — The Lancet Diabetes & Endocrinology’s Commission for the Definition and Diagnosis of Clinical Obesity will soon publish criteria for distinguishing between clinical obesity and other preclinical phases. The criteria are intended to limit the negative connotations and misunderstandings associated with the word obesity and to clearly convey the idea that it is a disease and not just a condition that increases the risk for other pathologies.

One of the two Latin American experts on the 60-member commission, Ricardo Cohen, MD, PhD, coordinator of the Obesity and Diabetes Center at the Oswaldo Cruz German Hospital in São Paulo, Brazil, discussed this effort with this news organization.

The proposal being finalized would acknowledge a preclinical stage of obesity characterized by alterations in cells or tissues that lead to changes in organ structure, but not function. This stage can be measured by body mass index (BMI) or waist circumference.

The clinical stage occurs when “obesity already affects [the function of] organs, tissues, and functions like mobility. Here, it is a disease per se. And an active disease requires treatment,” said Dr. Cohen. The health risks associated with excess adiposity have already materialized and can be objectively documented through specific signs and symptoms.

Various experts from Latin America who participated in the XV Congress of the Latin American Obesity Societies (FLASO) and II Paraguayan Obesity Congress expressed to this news organization their reservations about the proposed name change and its practical effects. They highlighted the pros and cons of various terminologies that had been considered in recent years.

“Stigma undoubtedly exists. There’s also no doubt that this stigma and daily pressure on a person’s self-esteem influence behavior and condition a poor future clinical outcome because they promote denial of the disease. Healthcare professionals can make these mistakes. But I’m not sure that changing the name of a known disease will make a difference,” said Rafael Figueredo Grijalba, MD, president of FLASO and director of the Nutrition program at the Faculty of Health Sciences of the Nuestra Señora de la Asunción Catholic University in Paraguay.

Spotlight on Adiposity 

An alternative term for obesity proposed in 2016 by what is now the American Association of Clinical Endocrinology and by the American College of Endocrinology is “adiposity-based chronic disease (ABCD).” This designation “is on the right track,” said Violeta Jiménez, MD, internal medicine and endocrinology specialist at the Clinical Hospital of the National University of Asunción and the Comprehensive Diabetes Care Network of the Paraguay Social Security Institute.

The word obese is perceived as an insult, and the health impact of obesity is related to the quantity, distribution, and function of adipose tissue, said Dr. Jiménez. The BMI, the most used parameter in practice to determine overweight and obesity, “does not predict excess adiposity or determine a disease here and now, just as waist circumference does not confirm the condition.” 

Will the public be attracted to ABCD? What disease do these initials refer to, asked Dr. Jiménez. “What I like about the term ABCD is that it is not solely based on weight. It brings up the issue that a person who may not have obesity by BMI has adiposity and therefore has a disease brewing inside them.”

“Any obesity denomination is useful as long as the impact of comorbidities is taken into account, as well as the fact that it is not an aesthetic problem and treatment will be escalated aiming to benefit not only weight loss but also comorbidities,” said Paul Camperos Sánchez, MD, internal medicine and endocrinology specialist and head of research at La Trinidad Teaching Medical Center in Caracas, Venezuela, and former president of the Venezuelan Association for the Study of Obesity. 

Dr. Camperos Sánchez added that the classification of overweight and obesity into grades on the basis of BMI, which is recognized by the World Health Organization, “is the most known and for me remains the most comfortable. I will accept any other approach, but in my clinical practice, I continue to do it this way.” 

Fundamentally, knowledge can reduce social stigma and even prejudice from the medical community itself. “We must be respectful and compassionate and understand well what we are treating and the best way to approach each patient with realistic expectations. Evaluate whether, in addition to medication or intensive lifestyle changes, behavioral interventions or physiotherapy are required. If you don’t manage it well and find it challenging, perhaps that’s why we see so much stigmatization or humiliation of the patient. And that has nothing to do with the name [of the disease],” said Dr. Camperos Sánchez.

‘Biological Injustices’

Julio Montero, MD, nutritionist, president of the Argentine Society of Obesity and Eating Disorders, and former president of FLASO, told this news organization that the topic of nomenclatures “provides a lot of grounds for debate,” but he prefers the term “clinical obesity” because it has a medical meaning, is appropriate for statistical purposes, better conveys the concept of obesity as a disease, and distinguishes patients who have high weight or a spherical figure but may be free of weight-dependent conditions.

“Clinical obesity suggests that it is a person with high weight who has health problems and life expectancy issues related to excessive corpulence (weight-fat). The addition of the adjective clinical suggests that the patient has been evaluated by phenotype, fat distribution, hypertension, blood glucose, triglycerides, apnea, cardiac dilation, and mechanical problems, and based on that analysis, the diagnosis has been made,” said Dr. Montero.

Other positive aspects of the designation include not assuming that comorbidities are a direct consequence of adipose tissue accumulation because “lean mass often increases in patients with obesity, and diet and sedentary lifestyle also have an influence” nor does the term exclude people with central obesity. On the other hand, it does not propose a specific weight or fat that defines the disease, just like BMI does (which defines obesity but not its clinical consequences).

Regarding the proposed term ABCD, Montero pointed out that it focuses the diagnosis on the concept that adipose fat and adipocyte function are protagonists of the disease in question, even though there are chronic metabolic diseases like gout, porphyrias, and type 1 diabetes that do not depend on adiposity.

“ABCD also involves some degree of biological injustice, since femorogluteal adiposity (aside from aesthetic problems and excluding possible mechanical effects) is normal and healthy during pregnancy, lactation, growth, or situations of food scarcity risk, among others. Besides, it is an expression that is difficult to interpret for the untrained professional and even more so for communication to the population,” Dr. Montero concluded.

Dr. Cohen, Dr. Figueredo Grijalba, Dr. Jiménez, Dr. Camperos Sánchez, and Dr. Montero declared no relevant financial conflicts of interest. 

This story was translated from the Medscape Spanish 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.

ASUNCIÓN, PARAGUAY — The Lancet Diabetes & Endocrinology’s Commission for the Definition and Diagnosis of Clinical Obesity will soon publish criteria for distinguishing between clinical obesity and other preclinical phases. The criteria are intended to limit the negative connotations and misunderstandings associated with the word obesity and to clearly convey the idea that it is a disease and not just a condition that increases the risk for other pathologies.

One of the two Latin American experts on the 60-member commission, Ricardo Cohen, MD, PhD, coordinator of the Obesity and Diabetes Center at the Oswaldo Cruz German Hospital in São Paulo, Brazil, discussed this effort with this news organization.

The proposal being finalized would acknowledge a preclinical stage of obesity characterized by alterations in cells or tissues that lead to changes in organ structure, but not function. This stage can be measured by body mass index (BMI) or waist circumference.

The clinical stage occurs when “obesity already affects [the function of] organs, tissues, and functions like mobility. Here, it is a disease per se. And an active disease requires treatment,” said Dr. Cohen. The health risks associated with excess adiposity have already materialized and can be objectively documented through specific signs and symptoms.

Various experts from Latin America who participated in the XV Congress of the Latin American Obesity Societies (FLASO) and II Paraguayan Obesity Congress expressed to this news organization their reservations about the proposed name change and its practical effects. They highlighted the pros and cons of various terminologies that had been considered in recent years.

“Stigma undoubtedly exists. There’s also no doubt that this stigma and daily pressure on a person’s self-esteem influence behavior and condition a poor future clinical outcome because they promote denial of the disease. Healthcare professionals can make these mistakes. But I’m not sure that changing the name of a known disease will make a difference,” said Rafael Figueredo Grijalba, MD, president of FLASO and director of the Nutrition program at the Faculty of Health Sciences of the Nuestra Señora de la Asunción Catholic University in Paraguay.

Spotlight on Adiposity 

An alternative term for obesity proposed in 2016 by what is now the American Association of Clinical Endocrinology and by the American College of Endocrinology is “adiposity-based chronic disease (ABCD).” This designation “is on the right track,” said Violeta Jiménez, MD, internal medicine and endocrinology specialist at the Clinical Hospital of the National University of Asunción and the Comprehensive Diabetes Care Network of the Paraguay Social Security Institute.

The word obese is perceived as an insult, and the health impact of obesity is related to the quantity, distribution, and function of adipose tissue, said Dr. Jiménez. The BMI, the most used parameter in practice to determine overweight and obesity, “does not predict excess adiposity or determine a disease here and now, just as waist circumference does not confirm the condition.” 

Will the public be attracted to ABCD? What disease do these initials refer to, asked Dr. Jiménez. “What I like about the term ABCD is that it is not solely based on weight. It brings up the issue that a person who may not have obesity by BMI has adiposity and therefore has a disease brewing inside them.”

“Any obesity denomination is useful as long as the impact of comorbidities is taken into account, as well as the fact that it is not an aesthetic problem and treatment will be escalated aiming to benefit not only weight loss but also comorbidities,” said Paul Camperos Sánchez, MD, internal medicine and endocrinology specialist and head of research at La Trinidad Teaching Medical Center in Caracas, Venezuela, and former president of the Venezuelan Association for the Study of Obesity. 

Dr. Camperos Sánchez added that the classification of overweight and obesity into grades on the basis of BMI, which is recognized by the World Health Organization, “is the most known and for me remains the most comfortable. I will accept any other approach, but in my clinical practice, I continue to do it this way.” 

Fundamentally, knowledge can reduce social stigma and even prejudice from the medical community itself. “We must be respectful and compassionate and understand well what we are treating and the best way to approach each patient with realistic expectations. Evaluate whether, in addition to medication or intensive lifestyle changes, behavioral interventions or physiotherapy are required. If you don’t manage it well and find it challenging, perhaps that’s why we see so much stigmatization or humiliation of the patient. And that has nothing to do with the name [of the disease],” said Dr. Camperos Sánchez.

‘Biological Injustices’

Julio Montero, MD, nutritionist, president of the Argentine Society of Obesity and Eating Disorders, and former president of FLASO, told this news organization that the topic of nomenclatures “provides a lot of grounds for debate,” but he prefers the term “clinical obesity” because it has a medical meaning, is appropriate for statistical purposes, better conveys the concept of obesity as a disease, and distinguishes patients who have high weight or a spherical figure but may be free of weight-dependent conditions.

“Clinical obesity suggests that it is a person with high weight who has health problems and life expectancy issues related to excessive corpulence (weight-fat). The addition of the adjective clinical suggests that the patient has been evaluated by phenotype, fat distribution, hypertension, blood glucose, triglycerides, apnea, cardiac dilation, and mechanical problems, and based on that analysis, the diagnosis has been made,” said Dr. Montero.

Other positive aspects of the designation include not assuming that comorbidities are a direct consequence of adipose tissue accumulation because “lean mass often increases in patients with obesity, and diet and sedentary lifestyle also have an influence” nor does the term exclude people with central obesity. On the other hand, it does not propose a specific weight or fat that defines the disease, just like BMI does (which defines obesity but not its clinical consequences).

Regarding the proposed term ABCD, Montero pointed out that it focuses the diagnosis on the concept that adipose fat and adipocyte function are protagonists of the disease in question, even though there are chronic metabolic diseases like gout, porphyrias, and type 1 diabetes that do not depend on adiposity.

“ABCD also involves some degree of biological injustice, since femorogluteal adiposity (aside from aesthetic problems and excluding possible mechanical effects) is normal and healthy during pregnancy, lactation, growth, or situations of food scarcity risk, among others. Besides, it is an expression that is difficult to interpret for the untrained professional and even more so for communication to the population,” Dr. Montero concluded.

Dr. Cohen, Dr. Figueredo Grijalba, Dr. Jiménez, Dr. Camperos Sánchez, and Dr. Montero declared no relevant financial conflicts of interest. 

This story was translated from the Medscape Spanish 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.

ASUNCIÓN, PARAGUAY — The Lancet Diabetes & Endocrinology’s Commission for the Definition and Diagnosis of Clinical Obesity will soon publish criteria for distinguishing between clinical obesity and other preclinical phases. The criteria are intended to limit the negative connotations and misunderstandings associated with the word obesity and to clearly convey the idea that it is a disease and not just a condition that increases the risk for other pathologies.

One of the two Latin American experts on the 60-member commission, Ricardo Cohen, MD, PhD, coordinator of the Obesity and Diabetes Center at the Oswaldo Cruz German Hospital in São Paulo, Brazil, discussed this effort with this news organization.

The proposal being finalized would acknowledge a preclinical stage of obesity characterized by alterations in cells or tissues that lead to changes in organ structure, but not function. This stage can be measured by body mass index (BMI) or waist circumference.

The clinical stage occurs when “obesity already affects [the function of] organs, tissues, and functions like mobility. Here, it is a disease per se. And an active disease requires treatment,” said Dr. Cohen. The health risks associated with excess adiposity have already materialized and can be objectively documented through specific signs and symptoms.

Various experts from Latin America who participated in the XV Congress of the Latin American Obesity Societies (FLASO) and II Paraguayan Obesity Congress expressed to this news organization their reservations about the proposed name change and its practical effects. They highlighted the pros and cons of various terminologies that had been considered in recent years.

“Stigma undoubtedly exists. There’s also no doubt that this stigma and daily pressure on a person’s self-esteem influence behavior and condition a poor future clinical outcome because they promote denial of the disease. Healthcare professionals can make these mistakes. But I’m not sure that changing the name of a known disease will make a difference,” said Rafael Figueredo Grijalba, MD, president of FLASO and director of the Nutrition program at the Faculty of Health Sciences of the Nuestra Señora de la Asunción Catholic University in Paraguay.

Spotlight on Adiposity 

An alternative term for obesity proposed in 2016 by what is now the American Association of Clinical Endocrinology and by the American College of Endocrinology is “adiposity-based chronic disease (ABCD).” This designation “is on the right track,” said Violeta Jiménez, MD, internal medicine and endocrinology specialist at the Clinical Hospital of the National University of Asunción and the Comprehensive Diabetes Care Network of the Paraguay Social Security Institute.

The word obese is perceived as an insult, and the health impact of obesity is related to the quantity, distribution, and function of adipose tissue, said Dr. Jiménez. The BMI, the most used parameter in practice to determine overweight and obesity, “does not predict excess adiposity or determine a disease here and now, just as waist circumference does not confirm the condition.” 

Will the public be attracted to ABCD? What disease do these initials refer to, asked Dr. Jiménez. “What I like about the term ABCD is that it is not solely based on weight. It brings up the issue that a person who may not have obesity by BMI has adiposity and therefore has a disease brewing inside them.”

“Any obesity denomination is useful as long as the impact of comorbidities is taken into account, as well as the fact that it is not an aesthetic problem and treatment will be escalated aiming to benefit not only weight loss but also comorbidities,” said Paul Camperos Sánchez, MD, internal medicine and endocrinology specialist and head of research at La Trinidad Teaching Medical Center in Caracas, Venezuela, and former president of the Venezuelan Association for the Study of Obesity. 

Dr. Camperos Sánchez added that the classification of overweight and obesity into grades on the basis of BMI, which is recognized by the World Health Organization, “is the most known and for me remains the most comfortable. I will accept any other approach, but in my clinical practice, I continue to do it this way.” 

Fundamentally, knowledge can reduce social stigma and even prejudice from the medical community itself. “We must be respectful and compassionate and understand well what we are treating and the best way to approach each patient with realistic expectations. Evaluate whether, in addition to medication or intensive lifestyle changes, behavioral interventions or physiotherapy are required. If you don’t manage it well and find it challenging, perhaps that’s why we see so much stigmatization or humiliation of the patient. And that has nothing to do with the name [of the disease],” said Dr. Camperos Sánchez.

‘Biological Injustices’

Julio Montero, MD, nutritionist, president of the Argentine Society of Obesity and Eating Disorders, and former president of FLASO, told this news organization that the topic of nomenclatures “provides a lot of grounds for debate,” but he prefers the term “clinical obesity” because it has a medical meaning, is appropriate for statistical purposes, better conveys the concept of obesity as a disease, and distinguishes patients who have high weight or a spherical figure but may be free of weight-dependent conditions.

“Clinical obesity suggests that it is a person with high weight who has health problems and life expectancy issues related to excessive corpulence (weight-fat). The addition of the adjective clinical suggests that the patient has been evaluated by phenotype, fat distribution, hypertension, blood glucose, triglycerides, apnea, cardiac dilation, and mechanical problems, and based on that analysis, the diagnosis has been made,” said Dr. Montero.

Other positive aspects of the designation include not assuming that comorbidities are a direct consequence of adipose tissue accumulation because “lean mass often increases in patients with obesity, and diet and sedentary lifestyle also have an influence” nor does the term exclude people with central obesity. On the other hand, it does not propose a specific weight or fat that defines the disease, just like BMI does (which defines obesity but not its clinical consequences).

Regarding the proposed term ABCD, Montero pointed out that it focuses the diagnosis on the concept that adipose fat and adipocyte function are protagonists of the disease in question, even though there are chronic metabolic diseases like gout, porphyrias, and type 1 diabetes that do not depend on adiposity.

“ABCD also involves some degree of biological injustice, since femorogluteal adiposity (aside from aesthetic problems and excluding possible mechanical effects) is normal and healthy during pregnancy, lactation, growth, or situations of food scarcity risk, among others. Besides, it is an expression that is difficult to interpret for the untrained professional and even more so for communication to the population,” Dr. Montero concluded.

Dr. Cohen, Dr. Figueredo Grijalba, Dr. Jiménez, Dr. Camperos Sánchez, and Dr. Montero declared no relevant financial conflicts of interest. 

This story was translated from the Medscape Spanish 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.

TOPLINE: 

Two days a week of a medically supervised energy-restricted diet may lower blood glucose levels in adults with overweight or obesity and type 2 diabetes (T2D).

METHODOLOGY:

• Daily calorie restrictions and increased physical activity improve glycemic control and induce diabetes remission in patients with T2D, but these approaches are challenging to adhere to.
• Researchers tested whether 2 days a week (a 5:2 regimen) of either a very low-calorie formula diet or a “weekend warrior” physical activity pattern would be effective and more convenient.
• The three-arm IDEATE study enrolled 326 Asian participants with overweight or mild obesity (body mass index, 25.0-39.9) and T2D (diagnosed within prior 2 years; A1c, 7.0-8.9%; not on insulin) and randomly assigned them to receive a diet intervention, an exercise intervention, or routine lifestyle education (control group) for 12 weeks.
• The diet intervention group received an energy-restricted diet of 790 kcal/d on 2 days each week, and the exercise intervention group performed high-intensity interval training (4 minutes of aerobic activity, with a 10-minute total warm-up and cool-down) and resistance training twice a week (four exercises, two sets of eight to 12 repetitions).
• The primary outcome was the change in glycemic control between the diet or exercise intervention group and the control group after 12 weeks. Follow-up continued up to 1 year after intervention.

TAKEAWAY:

• Compared with the control group, patients in the diet intervention group achieved greater reductions in A1c after 12 weeks (difference, -0.34; P =.007), whereas A1c reductions in the exercise intervention group did not differ significantly from the control group.
• The likelihood of achieving diabetes remission was higher in the diet intervention vs the control group (adjusted odds ratio, 3.60; P = .008) but not in the exercise intervention group (P =.52).
• Body weight, body mass index, and high-density lipoprtein cholesterol levels were more effectively controlled in the diet intervention group only.
• However, participants in both the diet and exercise intervention groups showed reduced adiposity, liver fat content, and diastolic blood pressure compared with those in the control group.

IN PRACTICE:

“The diet intervention group experienced a greater energy deficit with a more pronounced metabolic benefit,” the authors wrote. “Our study suggests that a medically supervised 5:2 energy-restricted diet could serve as an alternative strategy for improving glycemic control.” 

SOURCE:

Mian Li, of the Department of Endocrine and Metabolic Diseases, Shanghai Institute of Endocrine and Metabolic Diseases, Ruijin Hospital, Shanghai Jiao Tong University School of Medicine, Shanghai, China, led the study, which was published online in Diabetes Care.

LIMITATIONS:

Body composition was analyzed using bioelectrical impedance analysis, which is a less accurate technique than dual-energy x-ray absorptiometry. The study used finger-prick tests to monitor blood glucose levels, which could have underestimated both hyperglycemic and hypoglycemic episodes. No information was collected on whether the participants maintained the diet or exercise regimen during the postintervention follow-up period.

DISCLOSURES:

This study was supported by the National Key Research and Development Program of China, National Natural Science Foundation of China, Shanghai Rising Star Program grant, and other sources. The authors declared no conflicts of interest.

A version of this article appeared on Medscape.com.

TOPLINE: 

Two days a week of a medically supervised energy-restricted diet may lower blood glucose levels in adults with overweight or obesity and type 2 diabetes (T2D).

METHODOLOGY:

• Daily calorie restrictions and increased physical activity improve glycemic control and induce diabetes remission in patients with T2D, but these approaches are challenging to adhere to.
• Researchers tested whether 2 days a week (a 5:2 regimen) of either a very low-calorie formula diet or a “weekend warrior” physical activity pattern would be effective and more convenient.
• The three-arm IDEATE study enrolled 326 Asian participants with overweight or mild obesity (body mass index, 25.0-39.9) and T2D (diagnosed within prior 2 years; A1c, 7.0-8.9%; not on insulin) and randomly assigned them to receive a diet intervention, an exercise intervention, or routine lifestyle education (control group) for 12 weeks.
• The diet intervention group received an energy-restricted diet of 790 kcal/d on 2 days each week, and the exercise intervention group performed high-intensity interval training (4 minutes of aerobic activity, with a 10-minute total warm-up and cool-down) and resistance training twice a week (four exercises, two sets of eight to 12 repetitions).
• The primary outcome was the change in glycemic control between the diet or exercise intervention group and the control group after 12 weeks. Follow-up continued up to 1 year after intervention.

TAKEAWAY:

• Compared with the control group, patients in the diet intervention group achieved greater reductions in A1c after 12 weeks (difference, -0.34; P =.007), whereas A1c reductions in the exercise intervention group did not differ significantly from the control group.
• The likelihood of achieving diabetes remission was higher in the diet intervention vs the control group (adjusted odds ratio, 3.60; P = .008) but not in the exercise intervention group (P =.52).
• Body weight, body mass index, and high-density lipoprtein cholesterol levels were more effectively controlled in the diet intervention group only.
• However, participants in both the diet and exercise intervention groups showed reduced adiposity, liver fat content, and diastolic blood pressure compared with those in the control group.

IN PRACTICE:

“The diet intervention group experienced a greater energy deficit with a more pronounced metabolic benefit,” the authors wrote. “Our study suggests that a medically supervised 5:2 energy-restricted diet could serve as an alternative strategy for improving glycemic control.” 

SOURCE:

Mian Li, of the Department of Endocrine and Metabolic Diseases, Shanghai Institute of Endocrine and Metabolic Diseases, Ruijin Hospital, Shanghai Jiao Tong University School of Medicine, Shanghai, China, led the study, which was published online in Diabetes Care.

LIMITATIONS:

Body composition was analyzed using bioelectrical impedance analysis, which is a less accurate technique than dual-energy x-ray absorptiometry. The study used finger-prick tests to monitor blood glucose levels, which could have underestimated both hyperglycemic and hypoglycemic episodes. No information was collected on whether the participants maintained the diet or exercise regimen during the postintervention follow-up period.

DISCLOSURES:

This study was supported by the National Key Research and Development Program of China, National Natural Science Foundation of China, Shanghai Rising Star Program grant, and other sources. The authors declared no conflicts of interest.

A version of this article appeared on Medscape.com.

TOPLINE: 

Two days a week of a medically supervised energy-restricted diet may lower blood glucose levels in adults with overweight or obesity and type 2 diabetes (T2D).

METHODOLOGY:

• Daily calorie restrictions and increased physical activity improve glycemic control and induce diabetes remission in patients with T2D, but these approaches are challenging to adhere to.
• Researchers tested whether 2 days a week (a 5:2 regimen) of either a very low-calorie formula diet or a “weekend warrior” physical activity pattern would be effective and more convenient.
• The three-arm IDEATE study enrolled 326 Asian participants with overweight or mild obesity (body mass index, 25.0-39.9) and T2D (diagnosed within prior 2 years; A1c, 7.0-8.9%; not on insulin) and randomly assigned them to receive a diet intervention, an exercise intervention, or routine lifestyle education (control group) for 12 weeks.
• The diet intervention group received an energy-restricted diet of 790 kcal/d on 2 days each week, and the exercise intervention group performed high-intensity interval training (4 minutes of aerobic activity, with a 10-minute total warm-up and cool-down) and resistance training twice a week (four exercises, two sets of eight to 12 repetitions).
• The primary outcome was the change in glycemic control between the diet or exercise intervention group and the control group after 12 weeks. Follow-up continued up to 1 year after intervention.

TAKEAWAY:

• Compared with the control group, patients in the diet intervention group achieved greater reductions in A1c after 12 weeks (difference, -0.34; P =.007), whereas A1c reductions in the exercise intervention group did not differ significantly from the control group.
• The likelihood of achieving diabetes remission was higher in the diet intervention vs the control group (adjusted odds ratio, 3.60; P = .008) but not in the exercise intervention group (P =.52).
• Body weight, body mass index, and high-density lipoprtein cholesterol levels were more effectively controlled in the diet intervention group only.
• However, participants in both the diet and exercise intervention groups showed reduced adiposity, liver fat content, and diastolic blood pressure compared with those in the control group.

IN PRACTICE:

“The diet intervention group experienced a greater energy deficit with a more pronounced metabolic benefit,” the authors wrote. “Our study suggests that a medically supervised 5:2 energy-restricted diet could serve as an alternative strategy for improving glycemic control.” 

SOURCE:

Mian Li, of the Department of Endocrine and Metabolic Diseases, Shanghai Institute of Endocrine and Metabolic Diseases, Ruijin Hospital, Shanghai Jiao Tong University School of Medicine, Shanghai, China, led the study, which was published online in Diabetes Care.

LIMITATIONS:

Body composition was analyzed using bioelectrical impedance analysis, which is a less accurate technique than dual-energy x-ray absorptiometry. The study used finger-prick tests to monitor blood glucose levels, which could have underestimated both hyperglycemic and hypoglycemic episodes. No information was collected on whether the participants maintained the diet or exercise regimen during the postintervention follow-up period.

DISCLOSURES:

This study was supported by the National Key Research and Development Program of China, National Natural Science Foundation of China, Shanghai Rising Star Program grant, and other sources. The authors declared no conflicts of interest.

A version of this article appeared on Medscape.com.

ASUNCIÓN, PARAGUAY — Sarcopenic obesity, which is characterized by excess adiposity and muscle loss, is an “underestimated and underdiagnosed” condition, said the panelists at a session of the XV Latin American Obesity Congress (FLASO 2024) and II Paraguayan Congress of Obesity. The condition often affects older adults but can also occur at any age as a result of unhealthy habits or intensive or repeated weight loss efforts. 

“The drugs currently used for managing obesity promote significant weight loss, but by losing fat, muscle is also lost,” said Fabiola Romero Gómez, MD, a professor of medicine at the National University of Asunción and president of the Paraguayan Society of Endocrinology and Metabolism. “We must handle [these drugs] with extreme care. When we employ a strategy that achieves this significant weight loss, we must ensure that the patient receives a good protein intake and engages in resistance exercises, because otherwise, the cure may be worse than the disease.”

Some patients develop sarcopenic obesity after using glucagon-like peptide-1 (GLP-1) analogs, undergoing bariatric surgery, or pursuing restrictive diets, Dr. Romero said in an interview. The condition is more common when there are long-standing cycles of weight loss and subsequent gain, “which accounts for the majority of our patients,” she said.

“An important, largely ignored aspect of weight loss, whether through pharmacological or lifestyle intervention, is that a portion of the weight loss comprises lean muscle,” according to a recent editorial in Nature Medicine. “Weight regain, however, is almost entirely fat. People with chronic obesity often lose and regain weight in repeated cycles, each of which results in body-composition changes (even if they experience some net weight loss). This cycling puts people unable to sustain weight loss at risk of being metabolically less healthy than they were before the initial weight loss was achieved — in effect, at risk of developing sarcopenic obesity.”
 

A ‘Hidden’ Problem

Sarcopenic obesity is “something hidden, something that we often do not see. Why? Because if we do not make measurements of body composition, we will not realize it,” said Dr. Romero.

According to the 2022 consensus of the European Society for Clinical Nutrition and Metabolism and the European Association for the Study of Obesity, clinical signs or factors suggesting sarcopenic obesity include age over 70 years, diagnosis of a chronic disease, repeated falls or weakness, and nutritional events such as recent weight loss or rapid gain, long-standing restrictive diets, and bariatric surgery. 

The European guidelines also propose screening in individuals at risk to check for an increased body mass index (BMI) or waist circumference and suspicion parameters of sarcopenia. In this group of patients, the diagnosis should be made based on the analysis of alterations in muscle-skeletal functional parameters, such as grip or pinch strength or the 30-second chair stand test, followed by a determination of body mass alteration using dual-energy x-ray absorptiometry or electrical bioimpedance. 

Electrical bioimpedance is Dr. Romero’s preferred method. It is an economical, simple, and easily transportable test that calculates lean muscle mass, fat mass, and body water based on electrical conductivity, she said. Experts have pointed out that bioimpedance scales “will revolutionize the way we measure obesity,” she added. 

In an as-yet-unpublished study that received an honorable mention at the 3rd Paraguayan Congress of Endocrinology, Diabetes, and Metabolism last year, Dr. Romero and colleagues studied 126 patients (median age, 45 years) with obesity defined by percentage of fat mass determined by bioimpedance. When their BMI was analyzed, 11.1% were “normal” weight, and 35.7% were “overweight.” Even waist circumference measurement suggested that about 15% of participants were without obesity. Moreover, almost one in four participants presented with sarcopenia, “implying a decrease in quality of life and physical disability in the future if not investigated, diagnosed, and treated correctly,” said Dr. Romero. 
 

Prevention and Recommendations

Exercise and nutrition are two key components in the prevention and management of sarcopenic obesity. Physicians prescribing GLP-1 receptor agonists “must also counsel patients about incorporating aerobic exercise and resistance training as part of the treatment plan, as well as ensuring they eat a high-protein diet,” Yoon Ji Ahn, MD, and Vibha Singhal, MD, MPH, of the Weight Management Center of Massachusetts General Hospital in Boston, wrote in a commentary published by this news organization.

Paraguayan nutritionist Patricia López Soto, a diabetes educator with postgraduate degrees in obesity, diabetes, and bariatric surgery from Favaloro University in Buenos Aires, shared with this news organization the following general recommendations to prevent sarcopenic obesity in patients undergoing weight loss treatment: 

• Follow a healthy and balanced Mediterranean or DASH-style diet.
• Increase protein intake at the three to four main meals to a minimum of 1.4-1.5 g/kg/day.
• Try to make the protein intake mostly of high biological value: Beef, chicken, fish, eggs, seafood, cheese, skim milk, and yogurt.
• Ensure protein intake at each meal of between 25 g and 30 g to increase protein synthesis. For example, a 150 g portion of meat or chicken provides 30 g of protein.
• If the protein intake is not achieved through food, a supplement measure like isolated and hydrolyzed whey protein is a good option.
• Engage in strength or resistance training (weightlifting) three to four times per week and 30 minutes of cardiovascular exercise every day.
• To improve adherence, treatment should be carried out with a multidisciplinary team that includes a physician, nutritionist, and physical trainer, with frequent check-ups and body composition studies by bioimpedance.

Dr. Romero and Ms. López declared no relevant financial relationships. 
 

This story was translated from the Medscape Spanish 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.

ASUNCIÓN, PARAGUAY — Sarcopenic obesity, which is characterized by excess adiposity and muscle loss, is an “underestimated and underdiagnosed” condition, said the panelists at a session of the XV Latin American Obesity Congress (FLASO 2024) and II Paraguayan Congress of Obesity. The condition often affects older adults but can also occur at any age as a result of unhealthy habits or intensive or repeated weight loss efforts. 

“The drugs currently used for managing obesity promote significant weight loss, but by losing fat, muscle is also lost,” said Fabiola Romero Gómez, MD, a professor of medicine at the National University of Asunción and president of the Paraguayan Society of Endocrinology and Metabolism. “We must handle [these drugs] with extreme care. When we employ a strategy that achieves this significant weight loss, we must ensure that the patient receives a good protein intake and engages in resistance exercises, because otherwise, the cure may be worse than the disease.”

Some patients develop sarcopenic obesity after using glucagon-like peptide-1 (GLP-1) analogs, undergoing bariatric surgery, or pursuing restrictive diets, Dr. Romero said in an interview. The condition is more common when there are long-standing cycles of weight loss and subsequent gain, “which accounts for the majority of our patients,” she said.

“An important, largely ignored aspect of weight loss, whether through pharmacological or lifestyle intervention, is that a portion of the weight loss comprises lean muscle,” according to a recent editorial in Nature Medicine. “Weight regain, however, is almost entirely fat. People with chronic obesity often lose and regain weight in repeated cycles, each of which results in body-composition changes (even if they experience some net weight loss). This cycling puts people unable to sustain weight loss at risk of being metabolically less healthy than they were before the initial weight loss was achieved — in effect, at risk of developing sarcopenic obesity.”
 

A ‘Hidden’ Problem

Sarcopenic obesity is “something hidden, something that we often do not see. Why? Because if we do not make measurements of body composition, we will not realize it,” said Dr. Romero.

According to the 2022 consensus of the European Society for Clinical Nutrition and Metabolism and the European Association for the Study of Obesity, clinical signs or factors suggesting sarcopenic obesity include age over 70 years, diagnosis of a chronic disease, repeated falls or weakness, and nutritional events such as recent weight loss or rapid gain, long-standing restrictive diets, and bariatric surgery. 

The European guidelines also propose screening in individuals at risk to check for an increased body mass index (BMI) or waist circumference and suspicion parameters of sarcopenia. In this group of patients, the diagnosis should be made based on the analysis of alterations in muscle-skeletal functional parameters, such as grip or pinch strength or the 30-second chair stand test, followed by a determination of body mass alteration using dual-energy x-ray absorptiometry or electrical bioimpedance. 

Electrical bioimpedance is Dr. Romero’s preferred method. It is an economical, simple, and easily transportable test that calculates lean muscle mass, fat mass, and body water based on electrical conductivity, she said. Experts have pointed out that bioimpedance scales “will revolutionize the way we measure obesity,” she added. 

In an as-yet-unpublished study that received an honorable mention at the 3rd Paraguayan Congress of Endocrinology, Diabetes, and Metabolism last year, Dr. Romero and colleagues studied 126 patients (median age, 45 years) with obesity defined by percentage of fat mass determined by bioimpedance. When their BMI was analyzed, 11.1% were “normal” weight, and 35.7% were “overweight.” Even waist circumference measurement suggested that about 15% of participants were without obesity. Moreover, almost one in four participants presented with sarcopenia, “implying a decrease in quality of life and physical disability in the future if not investigated, diagnosed, and treated correctly,” said Dr. Romero. 
 

Prevention and Recommendations

Exercise and nutrition are two key components in the prevention and management of sarcopenic obesity. Physicians prescribing GLP-1 receptor agonists “must also counsel patients about incorporating aerobic exercise and resistance training as part of the treatment plan, as well as ensuring they eat a high-protein diet,” Yoon Ji Ahn, MD, and Vibha Singhal, MD, MPH, of the Weight Management Center of Massachusetts General Hospital in Boston, wrote in a commentary published by this news organization.

Paraguayan nutritionist Patricia López Soto, a diabetes educator with postgraduate degrees in obesity, diabetes, and bariatric surgery from Favaloro University in Buenos Aires, shared with this news organization the following general recommendations to prevent sarcopenic obesity in patients undergoing weight loss treatment: 

• Follow a healthy and balanced Mediterranean or DASH-style diet.
• Increase protein intake at the three to four main meals to a minimum of 1.4-1.5 g/kg/day.
• Try to make the protein intake mostly of high biological value: Beef, chicken, fish, eggs, seafood, cheese, skim milk, and yogurt.
• Ensure protein intake at each meal of between 25 g and 30 g to increase protein synthesis. For example, a 150 g portion of meat or chicken provides 30 g of protein.
• If the protein intake is not achieved through food, a supplement measure like isolated and hydrolyzed whey protein is a good option.
• Engage in strength or resistance training (weightlifting) three to four times per week and 30 minutes of cardiovascular exercise every day.
• To improve adherence, treatment should be carried out with a multidisciplinary team that includes a physician, nutritionist, and physical trainer, with frequent check-ups and body composition studies by bioimpedance.

Dr. Romero and Ms. López declared no relevant financial relationships. 
 

This story was translated from the Medscape Spanish 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.

ASUNCIÓN, PARAGUAY — Sarcopenic obesity, which is characterized by excess adiposity and muscle loss, is an “underestimated and underdiagnosed” condition, said the panelists at a session of the XV Latin American Obesity Congress (FLASO 2024) and II Paraguayan Congress of Obesity. The condition often affects older adults but can also occur at any age as a result of unhealthy habits or intensive or repeated weight loss efforts. 

“The drugs currently used for managing obesity promote significant weight loss, but by losing fat, muscle is also lost,” said Fabiola Romero Gómez, MD, a professor of medicine at the National University of Asunción and president of the Paraguayan Society of Endocrinology and Metabolism. “We must handle [these drugs] with extreme care. When we employ a strategy that achieves this significant weight loss, we must ensure that the patient receives a good protein intake and engages in resistance exercises, because otherwise, the cure may be worse than the disease.”

Some patients develop sarcopenic obesity after using glucagon-like peptide-1 (GLP-1) analogs, undergoing bariatric surgery, or pursuing restrictive diets, Dr. Romero said in an interview. The condition is more common when there are long-standing cycles of weight loss and subsequent gain, “which accounts for the majority of our patients,” she said.

“An important, largely ignored aspect of weight loss, whether through pharmacological or lifestyle intervention, is that a portion of the weight loss comprises lean muscle,” according to a recent editorial in Nature Medicine. “Weight regain, however, is almost entirely fat. People with chronic obesity often lose and regain weight in repeated cycles, each of which results in body-composition changes (even if they experience some net weight loss). This cycling puts people unable to sustain weight loss at risk of being metabolically less healthy than they were before the initial weight loss was achieved — in effect, at risk of developing sarcopenic obesity.”
 

A ‘Hidden’ Problem

Sarcopenic obesity is “something hidden, something that we often do not see. Why? Because if we do not make measurements of body composition, we will not realize it,” said Dr. Romero.

According to the 2022 consensus of the European Society for Clinical Nutrition and Metabolism and the European Association for the Study of Obesity, clinical signs or factors suggesting sarcopenic obesity include age over 70 years, diagnosis of a chronic disease, repeated falls or weakness, and nutritional events such as recent weight loss or rapid gain, long-standing restrictive diets, and bariatric surgery. 

The European guidelines also propose screening in individuals at risk to check for an increased body mass index (BMI) or waist circumference and suspicion parameters of sarcopenia. In this group of patients, the diagnosis should be made based on the analysis of alterations in muscle-skeletal functional parameters, such as grip or pinch strength or the 30-second chair stand test, followed by a determination of body mass alteration using dual-energy x-ray absorptiometry or electrical bioimpedance. 

Electrical bioimpedance is Dr. Romero’s preferred method. It is an economical, simple, and easily transportable test that calculates lean muscle mass, fat mass, and body water based on electrical conductivity, she said. Experts have pointed out that bioimpedance scales “will revolutionize the way we measure obesity,” she added. 

In an as-yet-unpublished study that received an honorable mention at the 3rd Paraguayan Congress of Endocrinology, Diabetes, and Metabolism last year, Dr. Romero and colleagues studied 126 patients (median age, 45 years) with obesity defined by percentage of fat mass determined by bioimpedance. When their BMI was analyzed, 11.1% were “normal” weight, and 35.7% were “overweight.” Even waist circumference measurement suggested that about 15% of participants were without obesity. Moreover, almost one in four participants presented with sarcopenia, “implying a decrease in quality of life and physical disability in the future if not investigated, diagnosed, and treated correctly,” said Dr. Romero. 
 

Prevention and Recommendations

Exercise and nutrition are two key components in the prevention and management of sarcopenic obesity. Physicians prescribing GLP-1 receptor agonists “must also counsel patients about incorporating aerobic exercise and resistance training as part of the treatment plan, as well as ensuring they eat a high-protein diet,” Yoon Ji Ahn, MD, and Vibha Singhal, MD, MPH, of the Weight Management Center of Massachusetts General Hospital in Boston, wrote in a commentary published by this news organization.

Paraguayan nutritionist Patricia López Soto, a diabetes educator with postgraduate degrees in obesity, diabetes, and bariatric surgery from Favaloro University in Buenos Aires, shared with this news organization the following general recommendations to prevent sarcopenic obesity in patients undergoing weight loss treatment: 

• Follow a healthy and balanced Mediterranean or DASH-style diet.
• Increase protein intake at the three to four main meals to a minimum of 1.4-1.5 g/kg/day.
• Try to make the protein intake mostly of high biological value: Beef, chicken, fish, eggs, seafood, cheese, skim milk, and yogurt.
• Ensure protein intake at each meal of between 25 g and 30 g to increase protein synthesis. For example, a 150 g portion of meat or chicken provides 30 g of protein.
• If the protein intake is not achieved through food, a supplement measure like isolated and hydrolyzed whey protein is a good option.
• Engage in strength or resistance training (weightlifting) three to four times per week and 30 minutes of cardiovascular exercise every day.
• To improve adherence, treatment should be carried out with a multidisciplinary team that includes a physician, nutritionist, and physical trainer, with frequent check-ups and body composition studies by bioimpedance.

Dr. Romero and Ms. López declared no relevant financial relationships. 
 

This story was translated from the Medscape Spanish 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.

TOPLINE:

Excessive intrapancreatic fat deposition (IPFD) leading to fatty change of the pancreas (FP) was prevalent in almost 18% of participants in a large population-based cohort, and both IPFD and FP were associated with an increased risk for diabetes, acute pancreatitis, and pancreatic cancer.

METHODOLOGY:

• Excessive IPFD is a common pancreatic disorder in the general population; however, there is a paucity of longitudinal studies investigating the relationship between FP and the risk for exocrine and endocrine pancreatic diseases.
• This prospective cohort study conducted from July 2014 to January 2023 investigated the prevalence of FP and the link between IPFD and pancreatic diseases in 42,599 participants (median age, 65 years; 46.6% men) from the UK Biobank who underwent abdominal Dixon MRI.
• IPFD levels were measured using MRI and a deep learning-based framework called nnUNet.
• The outcomes assessed in this study were diseases of the exocrine pancreas and endocrine pancreas, including acute pancreatitis, pancreatic cancer, diabetes, and other pancreatic conditions.

TAKEAWAY:

• The prevalence of FP was 17.86%.
• Elevation in IPFD levels by one quintile increased the risk for the development of acute pancreatitis by 51.3% (P = .001), pancreatic cancer by 36.5% (P = .017), diabetes by 22.1% (P < .001), and all pancreatic diseases by 22.7% (P < .001).
• FP increased the risk for acute pancreatitis by 298.2% (P < .001), pancreatic cancer by 97.6% (P = .034), diabetes by 33.7% (P = .001), and all pancreatic diseases by 44.1% (P < .001).
• An increasing trend in the prevalence of FP with advancing age was observed in both men and women.

IN PRACTICE:

“FP is a common pancreatic disorder. Fat in the pancreas is an independent risk factor for diseases of both the exocrine pancreas and endocrine pancreas,” the authors wrote.

SOURCE:

This study, led by Xiaowu Dong, MD, of the Pancreatic Center, Department of Gastroenterology, Yangzhou Key Laboratory of Pancreatic Disease, Affiliated Hospital of Yangzhou University, Yangzhou University, Yangzhou, China, was published online in The American Journal of Gastroenterology.

LIMITATIONS:

The authors acknowledged that most of the enrolled participants were White and older than 45 years. A low response rate to recruitment invitations in the UK Biobank database may have introduced self-selection bias. The median follow-up duration of 4.61 years was short and may be insufficient to fully capture the impact of IPFD. Additionally, the use of the average fat fraction for the entire pancreas may have led to spatial variations being ignored.

DISCLOSURES:

This work was supported by the National Natural Science Foundation of China, Cultivation Foundation of Yangzhou Municipal Key Laboratory, The Medical Research Project of Jiangsu Provincial Health Commission, Yangzhou key research and development plan, and Suzhou Innovation Platform Construction Projects-Municipal Key Laboratory Construction. The authors declared no conflicts of interest.
 

A version of this article appeared on Medscape.com.

TOPLINE:

Excessive intrapancreatic fat deposition (IPFD) leading to fatty change of the pancreas (FP) was prevalent in almost 18% of participants in a large population-based cohort, and both IPFD and FP were associated with an increased risk for diabetes, acute pancreatitis, and pancreatic cancer.

METHODOLOGY:

• Excessive IPFD is a common pancreatic disorder in the general population; however, there is a paucity of longitudinal studies investigating the relationship between FP and the risk for exocrine and endocrine pancreatic diseases.
• This prospective cohort study conducted from July 2014 to January 2023 investigated the prevalence of FP and the link between IPFD and pancreatic diseases in 42,599 participants (median age, 65 years; 46.6% men) from the UK Biobank who underwent abdominal Dixon MRI.
• IPFD levels were measured using MRI and a deep learning-based framework called nnUNet.
• The outcomes assessed in this study were diseases of the exocrine pancreas and endocrine pancreas, including acute pancreatitis, pancreatic cancer, diabetes, and other pancreatic conditions.

TAKEAWAY:

• The prevalence of FP was 17.86%.
• Elevation in IPFD levels by one quintile increased the risk for the development of acute pancreatitis by 51.3% (P = .001), pancreatic cancer by 36.5% (P = .017), diabetes by 22.1% (P < .001), and all pancreatic diseases by 22.7% (P < .001).
• FP increased the risk for acute pancreatitis by 298.2% (P < .001), pancreatic cancer by 97.6% (P = .034), diabetes by 33.7% (P = .001), and all pancreatic diseases by 44.1% (P < .001).
• An increasing trend in the prevalence of FP with advancing age was observed in both men and women.

IN PRACTICE:

“FP is a common pancreatic disorder. Fat in the pancreas is an independent risk factor for diseases of both the exocrine pancreas and endocrine pancreas,” the authors wrote.

SOURCE:

This study, led by Xiaowu Dong, MD, of the Pancreatic Center, Department of Gastroenterology, Yangzhou Key Laboratory of Pancreatic Disease, Affiliated Hospital of Yangzhou University, Yangzhou University, Yangzhou, China, was published online in The American Journal of Gastroenterology.

LIMITATIONS:

The authors acknowledged that most of the enrolled participants were White and older than 45 years. A low response rate to recruitment invitations in the UK Biobank database may have introduced self-selection bias. The median follow-up duration of 4.61 years was short and may be insufficient to fully capture the impact of IPFD. Additionally, the use of the average fat fraction for the entire pancreas may have led to spatial variations being ignored.

DISCLOSURES:

This work was supported by the National Natural Science Foundation of China, Cultivation Foundation of Yangzhou Municipal Key Laboratory, The Medical Research Project of Jiangsu Provincial Health Commission, Yangzhou key research and development plan, and Suzhou Innovation Platform Construction Projects-Municipal Key Laboratory Construction. The authors declared no conflicts of interest.
 

A version of this article appeared on Medscape.com.

TOPLINE:

Excessive intrapancreatic fat deposition (IPFD) leading to fatty change of the pancreas (FP) was prevalent in almost 18% of participants in a large population-based cohort, and both IPFD and FP were associated with an increased risk for diabetes, acute pancreatitis, and pancreatic cancer.

METHODOLOGY:

• Excessive IPFD is a common pancreatic disorder in the general population; however, there is a paucity of longitudinal studies investigating the relationship between FP and the risk for exocrine and endocrine pancreatic diseases.
• This prospective cohort study conducted from July 2014 to January 2023 investigated the prevalence of FP and the link between IPFD and pancreatic diseases in 42,599 participants (median age, 65 years; 46.6% men) from the UK Biobank who underwent abdominal Dixon MRI.
• IPFD levels were measured using MRI and a deep learning-based framework called nnUNet.
• The outcomes assessed in this study were diseases of the exocrine pancreas and endocrine pancreas, including acute pancreatitis, pancreatic cancer, diabetes, and other pancreatic conditions.

TAKEAWAY:

• The prevalence of FP was 17.86%.
• Elevation in IPFD levels by one quintile increased the risk for the development of acute pancreatitis by 51.3% (P = .001), pancreatic cancer by 36.5% (P = .017), diabetes by 22.1% (P < .001), and all pancreatic diseases by 22.7% (P < .001).
• FP increased the risk for acute pancreatitis by 298.2% (P < .001), pancreatic cancer by 97.6% (P = .034), diabetes by 33.7% (P = .001), and all pancreatic diseases by 44.1% (P < .001).
• An increasing trend in the prevalence of FP with advancing age was observed in both men and women.

IN PRACTICE:

“FP is a common pancreatic disorder. Fat in the pancreas is an independent risk factor for diseases of both the exocrine pancreas and endocrine pancreas,” the authors wrote.

SOURCE:

This study, led by Xiaowu Dong, MD, of the Pancreatic Center, Department of Gastroenterology, Yangzhou Key Laboratory of Pancreatic Disease, Affiliated Hospital of Yangzhou University, Yangzhou University, Yangzhou, China, was published online in The American Journal of Gastroenterology.

LIMITATIONS:

The authors acknowledged that most of the enrolled participants were White and older than 45 years. A low response rate to recruitment invitations in the UK Biobank database may have introduced self-selection bias. The median follow-up duration of 4.61 years was short and may be insufficient to fully capture the impact of IPFD. Additionally, the use of the average fat fraction for the entire pancreas may have led to spatial variations being ignored.

DISCLOSURES:

This work was supported by the National Natural Science Foundation of China, Cultivation Foundation of Yangzhou Municipal Key Laboratory, The Medical Research Project of Jiangsu Provincial Health Commission, Yangzhou key research and development plan, and Suzhou Innovation Platform Construction Projects-Municipal Key Laboratory Construction. The authors declared no conflicts of interest.
 

A version of this article appeared on Medscape.com.

TOPLINE:

Metabolic dysfunction-associated steatotic liver disease (MASLD) co-occurring with HIV infection does not appear to increase the risk for cirrhosis or hepatocellular carcinoma (HCC) compared with MASLD alone. However, the incidence of major adverse cardiovascular events (MACE) is significantly increased among patients with MASLD and HIV, a large study suggested.

METHODOLOGY:

• MASLD is highly prevalent in people living with HIV, but the impact of HIV on liver and cardiovascular disease (CVD) outcomes in people with MASLD remains unclear.
• To investigate, researchers created a propensity score-matched cohort of veterans with noncirrhotic MASLD, with and without HIV (920 patients in each group).
• They evaluated the incidence of cirrhosis, HCC, and MACE, as well as overall survival, among the two groups. They also assessed these outcomes in MASLD patients with HIV on the basis of whether they were on antiretroviral therapy (ART).

TAKEAWAY:

• During a median follow-up of 10.4 years in the MASLD with HIV group and 11.8 years in the MASLD-only group, the overall incidence of cirrhosis and HCC was similar in MASLD with vs without HIV (cirrhosis: 0.97 vs 1.06 per 100 person-years, P = .54; HCC: 0.26 vs 0.17 per 100,000 person-years, P = .23), regardless of ART use.

• In contrast, the incidence of MACE was significantly higher in MASLD with vs without HIV (5.18 vs 4.48 per 100 person-years, P = .03). The incidence also was higher in patients with MASLD and HIV who were not on ART compared with those on ART (5.83 vs 4.7 per 100 person-years, P = .07).

• Compared with MASLD without HIV, the overall 5-year survival was significantly lower in MASLD with HIV (91.3% vs 85.7%). In MASLD with HIV, receipt of ART was associated with a significantly higher 5-year survival than no ART (87.4% vs 81.6%).

IN PRACTICE:

“Ensuring timely and appropriate initiation of HIV treatment is critical in patients with MASLD who have concurrent HIV infection, as well as optimizing metabolic comorbidities that may also contribute to increased risks of CVD and increased mortality,” the authors wrote.

SOURCE:

The study, led by Robert J. Wong, MD, Division of Gastroenterology and Hepatology, Stanford University School of Medicine, Palo Alto, California, was published online in the American Journal of Gastroenterology.

LIMITATIONS:

The study cohort consisted predominantly of older men, which may limit generalizability to women and younger populations. Metabolic comorbidities are more common in veterans compared with the general population, potentially affecting the generalizability of the CVD risk findings.

DISCLOSURES:

The study was supported by an investigator-initiated research grant from Theratechnologies. Wong has received funding for his institution from Gilead Sciences, Exact Sciences, and Durect Corporation and has served as a consultant for Gilead Sciences.
 

A version of this article appeared on Medscape.com.

TOPLINE:

Metabolic dysfunction-associated steatotic liver disease (MASLD) co-occurring with HIV infection does not appear to increase the risk for cirrhosis or hepatocellular carcinoma (HCC) compared with MASLD alone. However, the incidence of major adverse cardiovascular events (MACE) is significantly increased among patients with MASLD and HIV, a large study suggested.

METHODOLOGY:

• MASLD is highly prevalent in people living with HIV, but the impact of HIV on liver and cardiovascular disease (CVD) outcomes in people with MASLD remains unclear.
• To investigate, researchers created a propensity score-matched cohort of veterans with noncirrhotic MASLD, with and without HIV (920 patients in each group).
• They evaluated the incidence of cirrhosis, HCC, and MACE, as well as overall survival, among the two groups. They also assessed these outcomes in MASLD patients with HIV on the basis of whether they were on antiretroviral therapy (ART).

TAKEAWAY:

• During a median follow-up of 10.4 years in the MASLD with HIV group and 11.8 years in the MASLD-only group, the overall incidence of cirrhosis and HCC was similar in MASLD with vs without HIV (cirrhosis: 0.97 vs 1.06 per 100 person-years, P = .54; HCC: 0.26 vs 0.17 per 100,000 person-years, P = .23), regardless of ART use.

• In contrast, the incidence of MACE was significantly higher in MASLD with vs without HIV (5.18 vs 4.48 per 100 person-years, P = .03). The incidence also was higher in patients with MASLD and HIV who were not on ART compared with those on ART (5.83 vs 4.7 per 100 person-years, P = .07).

• Compared with MASLD without HIV, the overall 5-year survival was significantly lower in MASLD with HIV (91.3% vs 85.7%). In MASLD with HIV, receipt of ART was associated with a significantly higher 5-year survival than no ART (87.4% vs 81.6%).

IN PRACTICE:

“Ensuring timely and appropriate initiation of HIV treatment is critical in patients with MASLD who have concurrent HIV infection, as well as optimizing metabolic comorbidities that may also contribute to increased risks of CVD and increased mortality,” the authors wrote.

SOURCE:

The study, led by Robert J. Wong, MD, Division of Gastroenterology and Hepatology, Stanford University School of Medicine, Palo Alto, California, was published online in the American Journal of Gastroenterology.

LIMITATIONS:

The study cohort consisted predominantly of older men, which may limit generalizability to women and younger populations. Metabolic comorbidities are more common in veterans compared with the general population, potentially affecting the generalizability of the CVD risk findings.

DISCLOSURES:

The study was supported by an investigator-initiated research grant from Theratechnologies. Wong has received funding for his institution from Gilead Sciences, Exact Sciences, and Durect Corporation and has served as a consultant for Gilead Sciences.
 

A version of this article appeared on Medscape.com.

TOPLINE:

Metabolic dysfunction-associated steatotic liver disease (MASLD) co-occurring with HIV infection does not appear to increase the risk for cirrhosis or hepatocellular carcinoma (HCC) compared with MASLD alone. However, the incidence of major adverse cardiovascular events (MACE) is significantly increased among patients with MASLD and HIV, a large study suggested.

METHODOLOGY:

• MASLD is highly prevalent in people living with HIV, but the impact of HIV on liver and cardiovascular disease (CVD) outcomes in people with MASLD remains unclear.
• To investigate, researchers created a propensity score-matched cohort of veterans with noncirrhotic MASLD, with and without HIV (920 patients in each group).
• They evaluated the incidence of cirrhosis, HCC, and MACE, as well as overall survival, among the two groups. They also assessed these outcomes in MASLD patients with HIV on the basis of whether they were on antiretroviral therapy (ART).

TAKEAWAY:

• During a median follow-up of 10.4 years in the MASLD with HIV group and 11.8 years in the MASLD-only group, the overall incidence of cirrhosis and HCC was similar in MASLD with vs without HIV (cirrhosis: 0.97 vs 1.06 per 100 person-years, P = .54; HCC: 0.26 vs 0.17 per 100,000 person-years, P = .23), regardless of ART use.

• In contrast, the incidence of MACE was significantly higher in MASLD with vs without HIV (5.18 vs 4.48 per 100 person-years, P = .03). The incidence also was higher in patients with MASLD and HIV who were not on ART compared with those on ART (5.83 vs 4.7 per 100 person-years, P = .07).

• Compared with MASLD without HIV, the overall 5-year survival was significantly lower in MASLD with HIV (91.3% vs 85.7%). In MASLD with HIV, receipt of ART was associated with a significantly higher 5-year survival than no ART (87.4% vs 81.6%).

IN PRACTICE:

“Ensuring timely and appropriate initiation of HIV treatment is critical in patients with MASLD who have concurrent HIV infection, as well as optimizing metabolic comorbidities that may also contribute to increased risks of CVD and increased mortality,” the authors wrote.

SOURCE:

The study, led by Robert J. Wong, MD, Division of Gastroenterology and Hepatology, Stanford University School of Medicine, Palo Alto, California, was published online in the American Journal of Gastroenterology.

LIMITATIONS:

The study cohort consisted predominantly of older men, which may limit generalizability to women and younger populations. Metabolic comorbidities are more common in veterans compared with the general population, potentially affecting the generalizability of the CVD risk findings.

DISCLOSURES:

The study was supported by an investigator-initiated research grant from Theratechnologies. Wong has received funding for his institution from Gilead Sciences, Exact Sciences, and Durect Corporation and has served as a consultant for Gilead Sciences.
 

A version of this article appeared on Medscape.com.

When child psychiatrist Javeed Sukhera, MD, PhD, was a few years into his career, he found himself doing it all. “I was in a leadership role academically at the medical school, I had a leadership role at the hospital, and I was seeing as many patients as I could. I could work all day every day.”

“It still wouldn’t have been enough,” he said.

Whenever there was a shift available, Dr. Sukhera would take it. His job was stressful, but as a new physician with a young family, he saw this obsession with work as necessary. “I began to cope with the stress from work by doing extra work and feeling like I needed to be everywhere. It was like I became a hamster on a spinning wheel. I was just running, running, running.”

Things shifted for Dr. Sukhera when he realized that while he was emotionally available for the children who were his patients, at home, his own children weren’t getting the best of him. “There was a specific moment when I thought my son was afraid of me,” he said. “I just stopped and realized that there was something happening that I needed to break. I needed to make a change.”

Dr. Sukhera, now chair of psychiatry at the Institute of Living and chief of the Department of Psychiatry at Hartford Hospital, Hartford, Connecticut, believes what he experienced was a steep fall into work addiction. “Workaholism,” often dismissed as simply working hard, is a nonclinical addiction that could fall under the umbrella of a behavioral addiction, and healthcare professionals may be especially at risk.
 

What Does Work Addiction Look Like for Doctors?

Behavioral addictions are fairly new in the addiction space. When gambling disorder, the first and only behavioral addiction in the Diagnostic and Statistical Manual of Mental Disorders, Fifth Edition, was added in 2013, it was seen as a “breakthrough addiction,” said Mark D. Griffiths, PhD, a leading behavioral addiction researcher and a distinguished professor at Nottingham Trent University.

Because there is not enough evidence yet to classify work addiction as a formal diagnosis, there is no clear consensus on how to define it. To further complicate things, the terms “workaholism” and “work addiction” can be used interchangeably, and some experts say the two are not the same, though they can overlap.

That said, a 2018 review of literature from several countries found that work addiction “fits very well into recently postulated criteria for conceptualization of a behavioral addiction.

“If you accept that gambling can be genuinely addictive, then there’s no reason to think that something like work, exercise, or video game playing couldn’t be an addiction as well,” said Dr. Griffiths.

“The neurobiology of addiction is that we get drawn to something that gives us a dopamine hit,” Dr. Sukhera added. “But to do that all day, every day, has consequences. It drains our emotional reserves, and it can greatly impact our relationships.”

On top of that, work addiction has been linked with poor sleep, poor cardiovascular health, high blood pressure, burnout, the development of autoimmune disorders, and other health issues.

Physicians are particularly susceptible. Doctors, after all, are expected to work long hours and put their patients’ needs first, even at the expense of their own health and well-being.

“Workaholism is not just socially acceptable in medicine,” said Dr. Sukhera. “It’s baked into the system and built into the structures. The healthcare system has largely functioned on the emotional labor of health workers, whose tendency to show up and work harder can, at times, in certain organizations, be exploited.”

Dr. Griffiths agreed that with the limited amount of data available, work addiction does appear to exist at higher rates in medicine than in other fields. As early as the 1970s, medical literature describes work as a “socially acceptable” addiction among doctors. A 2014 study published in Occupational Medicine reported that of 445 physicians who took part in the research, nearly half exhibited some level of work addiction with 13% “highly work addicted.”

Of course, working hard or even meeting unreasonable demands from work is not the same as work addiction, as Dr. Griffiths clarified in a 2023 editorial in BMJ Quality & Safety. The difference, as with other behavioral addictions, is when people obsess about work and use it to cope with stress. It can be easier to stay distracted and busy to gain a sense of control rather than learning to deal with complex emotions.

A 2021 study that Dr. Sukhera conducted with resident physicians found that working harder was one of the main ways they dealt with stress during the COVID-19 pandemic. “This idea that we deal with the stress of being burnt out by doing more and more of what burns us out is fairly ubiquitous at all stages of medical professionals’ careers,” he said.

Financial incentives also can fuel work addiction, said Dr. Sukhera. In residency, there are some safeguards around overwork and duty hours. When you become an attending, those limits no longer exist. As a young physician, Dr. Sukhera had student debt to pay off and a family to support. When he found opportunities to earn more by working more, his answer was always “yes.”

Pressure to produce medical research also can pose issues. Some physicians can become addicted to publishing studies, fearing that they might lose their professional status or position if they stop. It’s a cycle that can force a doctor to not only work long hours doing their job but also practically take on a second one.
 

How Physicians Can Recognize Work Addiction in Themselves

Work addiction can look and feel different for every person, said Malissa Clark, PhD, associate professor at the University of Georgia and author of the recent book Never Not Working: Why the Always-On Culture Is Bad for Business—and How to Fix It.

Dr. Clark noted that people who are highly engaged in their work tend to be driven by intrinsic motivation: “You work because you love it.” With work addiction, “you work because you feel like you ought to be working all the time.”

Of course, it’s not always so cut and dried; you can experience both forms of motivation and not necessarily become addicted to work. But if you are solely driven by the feeling that you ought to be working all the time, that can be a red flag.

Dr. Griffiths said that while many people may have problematic work habits or work too much, true work addicts must meet six criteria that apply to all addictions:

1. Salience: Work is the single most important thing in your life, to the point of neglecting everything else. Even if you’re on vacation, your mind might be flooded with work thoughts.

2. Mood modification: You use work to modify your mood, either to get a “high” or to cope with stress.

3. Tolerance: Over time, you’ve gone from working 8 or 10 hours a day to 12 hours a day, to a point where you’re working all the time.

4. Withdrawal: On a physiological level, you will have symptoms such as anxiety, nausea, or headaches when unable to work.

5. Conflict: You feel conflicted with yourself (you know you’re working too much) or with others (partners, friends, and children) about work, but you can’t stop.

6. Relapse: If you manage to cut down your hours but can’t resist overworking 1 day, you wind up right back where you were.
 

When It’s Time to Address Work Addiction

The lack of a formal diagnosis for work addiction makes getting treatment difficult. But there are ways to seek help. Unlike the drug and alcohol literature, abstinence is not the goal. “The therapeutic goal is getting a behavior under control and looking for the triggers of why you’re compulsively working,” said Dr. Griffiths.

Practice self-compassion

Dr. Sukhera eventually realized that his work addiction stemmed from the fear of being somehow excluded or unworthy. He actively corrected much of this through self-compassion and self-kindness, which helped him set boundaries. “Self-compassion is the root of everything,” he said. “Reminding ourselves that we’re doing our best is an important ingredient in breaking the cycle.”

Slowly expose yourself to relaxation

Many workaholics find rest very difficult. “When I conducted interviews with people [who considered themselves workaholics], a very common thing I heard was, ‘I have a very hard time being idle,’ ” said Dr. Clark. If rest feels hard, Dr. Sukhera suggests practicing relaxation for 2 minutes to start. Even small periods of downtime can challenge the belief that you must be constantly productive.

Reframe your to-do list 

For work addicts, to-do lists can seem like they must be finished, which prolongs work hours. Instead, use to-do lists to help prioritize what is urgent, identify what can wait, and delegate out tasks to others, Dr. Clark recommends.

Pick up a mastery experience

Research from professor Sabine Sonnentag, Dr. rer. nat., at the University of Mannheim, Mannheim, Germany, suggests that mastery experiences — leisure activities that require thought and focus like learning a new language or taking a woodworking class — can help you actively disengage from work.

Try cognitive behavioral therapy

Widely used for other forms of addiction, cognitive behavioral therapy centers around recognizing emotions, challenging thought patterns, and changing behaviors. However, Dr. Clark admits the research on its impact on work addiction, in particular, is “pretty nascent.”

Shift your mindset

It seems logical to think that detaching from your feelings will allow you to “do more,” but experts say that idea is both untrue and dangerous. “The safest hospitals are the hospitals where people are attuned to their humanness,” said Dr. Sukhera. “It’s normal to overwork in medicine, and if you’re challenging a norm, you really have to be thoughtful about how you frame that for yourself.”

Most importantly: Seek support

Today, there is increased awareness about work addiction and more resources for physicians who are struggling, including programs such as Workaholics Anonymous or Physicians Anonymous and workplace wellness initiatives. But try not to overwhelm yourself with choosing whom to talk to or what specific resource to utilize, Dr. Sukhera advised. “Just talk to someone about it. You don’t have to carry this on your own.”
 

A version of this article appeared on Medscape.com.

When child psychiatrist Javeed Sukhera, MD, PhD, was a few years into his career, he found himself doing it all. “I was in a leadership role academically at the medical school, I had a leadership role at the hospital, and I was seeing as many patients as I could. I could work all day every day.”

“It still wouldn’t have been enough,” he said.

Whenever there was a shift available, Dr. Sukhera would take it. His job was stressful, but as a new physician with a young family, he saw this obsession with work as necessary. “I began to cope with the stress from work by doing extra work and feeling like I needed to be everywhere. It was like I became a hamster on a spinning wheel. I was just running, running, running.”

Things shifted for Dr. Sukhera when he realized that while he was emotionally available for the children who were his patients, at home, his own children weren’t getting the best of him. “There was a specific moment when I thought my son was afraid of me,” he said. “I just stopped and realized that there was something happening that I needed to break. I needed to make a change.”

Dr. Sukhera, now chair of psychiatry at the Institute of Living and chief of the Department of Psychiatry at Hartford Hospital, Hartford, Connecticut, believes what he experienced was a steep fall into work addiction. “Workaholism,” often dismissed as simply working hard, is a nonclinical addiction that could fall under the umbrella of a behavioral addiction, and healthcare professionals may be especially at risk.
 

What Does Work Addiction Look Like for Doctors?

Behavioral addictions are fairly new in the addiction space. When gambling disorder, the first and only behavioral addiction in the Diagnostic and Statistical Manual of Mental Disorders, Fifth Edition, was added in 2013, it was seen as a “breakthrough addiction,” said Mark D. Griffiths, PhD, a leading behavioral addiction researcher and a distinguished professor at Nottingham Trent University.

Because there is not enough evidence yet to classify work addiction as a formal diagnosis, there is no clear consensus on how to define it. To further complicate things, the terms “workaholism” and “work addiction” can be used interchangeably, and some experts say the two are not the same, though they can overlap.

That said, a 2018 review of literature from several countries found that work addiction “fits very well into recently postulated criteria for conceptualization of a behavioral addiction.

“If you accept that gambling can be genuinely addictive, then there’s no reason to think that something like work, exercise, or video game playing couldn’t be an addiction as well,” said Dr. Griffiths.

“The neurobiology of addiction is that we get drawn to something that gives us a dopamine hit,” Dr. Sukhera added. “But to do that all day, every day, has consequences. It drains our emotional reserves, and it can greatly impact our relationships.”

On top of that, work addiction has been linked with poor sleep, poor cardiovascular health, high blood pressure, burnout, the development of autoimmune disorders, and other health issues.

Physicians are particularly susceptible. Doctors, after all, are expected to work long hours and put their patients’ needs first, even at the expense of their own health and well-being.

“Workaholism is not just socially acceptable in medicine,” said Dr. Sukhera. “It’s baked into the system and built into the structures. The healthcare system has largely functioned on the emotional labor of health workers, whose tendency to show up and work harder can, at times, in certain organizations, be exploited.”

Dr. Griffiths agreed that with the limited amount of data available, work addiction does appear to exist at higher rates in medicine than in other fields. As early as the 1970s, medical literature describes work as a “socially acceptable” addiction among doctors. A 2014 study published in Occupational Medicine reported that of 445 physicians who took part in the research, nearly half exhibited some level of work addiction with 13% “highly work addicted.”

Of course, working hard or even meeting unreasonable demands from work is not the same as work addiction, as Dr. Griffiths clarified in a 2023 editorial in BMJ Quality & Safety. The difference, as with other behavioral addictions, is when people obsess about work and use it to cope with stress. It can be easier to stay distracted and busy to gain a sense of control rather than learning to deal with complex emotions.

A 2021 study that Dr. Sukhera conducted with resident physicians found that working harder was one of the main ways they dealt with stress during the COVID-19 pandemic. “This idea that we deal with the stress of being burnt out by doing more and more of what burns us out is fairly ubiquitous at all stages of medical professionals’ careers,” he said.

Financial incentives also can fuel work addiction, said Dr. Sukhera. In residency, there are some safeguards around overwork and duty hours. When you become an attending, those limits no longer exist. As a young physician, Dr. Sukhera had student debt to pay off and a family to support. When he found opportunities to earn more by working more, his answer was always “yes.”

Pressure to produce medical research also can pose issues. Some physicians can become addicted to publishing studies, fearing that they might lose their professional status or position if they stop. It’s a cycle that can force a doctor to not only work long hours doing their job but also practically take on a second one.
 

How Physicians Can Recognize Work Addiction in Themselves

Work addiction can look and feel different for every person, said Malissa Clark, PhD, associate professor at the University of Georgia and author of the recent book Never Not Working: Why the Always-On Culture Is Bad for Business—and How to Fix It.

Dr. Clark noted that people who are highly engaged in their work tend to be driven by intrinsic motivation: “You work because you love it.” With work addiction, “you work because you feel like you ought to be working all the time.”

Of course, it’s not always so cut and dried; you can experience both forms of motivation and not necessarily become addicted to work. But if you are solely driven by the feeling that you ought to be working all the time, that can be a red flag.

Dr. Griffiths said that while many people may have problematic work habits or work too much, true work addicts must meet six criteria that apply to all addictions:

1. Salience: Work is the single most important thing in your life, to the point of neglecting everything else. Even if you’re on vacation, your mind might be flooded with work thoughts.

2. Mood modification: You use work to modify your mood, either to get a “high” or to cope with stress.

3. Tolerance: Over time, you’ve gone from working 8 or 10 hours a day to 12 hours a day, to a point where you’re working all the time.

4. Withdrawal: On a physiological level, you will have symptoms such as anxiety, nausea, or headaches when unable to work.

5. Conflict: You feel conflicted with yourself (you know you’re working too much) or with others (partners, friends, and children) about work, but you can’t stop.

6. Relapse: If you manage to cut down your hours but can’t resist overworking 1 day, you wind up right back where you were.
 

When It’s Time to Address Work Addiction

The lack of a formal diagnosis for work addiction makes getting treatment difficult. But there are ways to seek help. Unlike the drug and alcohol literature, abstinence is not the goal. “The therapeutic goal is getting a behavior under control and looking for the triggers of why you’re compulsively working,” said Dr. Griffiths.

Practice self-compassion

Dr. Sukhera eventually realized that his work addiction stemmed from the fear of being somehow excluded or unworthy. He actively corrected much of this through self-compassion and self-kindness, which helped him set boundaries. “Self-compassion is the root of everything,” he said. “Reminding ourselves that we’re doing our best is an important ingredient in breaking the cycle.”

Slowly expose yourself to relaxation

Many workaholics find rest very difficult. “When I conducted interviews with people [who considered themselves workaholics], a very common thing I heard was, ‘I have a very hard time being idle,’ ” said Dr. Clark. If rest feels hard, Dr. Sukhera suggests practicing relaxation for 2 minutes to start. Even small periods of downtime can challenge the belief that you must be constantly productive.

Reframe your to-do list 

For work addicts, to-do lists can seem like they must be finished, which prolongs work hours. Instead, use to-do lists to help prioritize what is urgent, identify what can wait, and delegate out tasks to others, Dr. Clark recommends.

Pick up a mastery experience

Research from professor Sabine Sonnentag, Dr. rer. nat., at the University of Mannheim, Mannheim, Germany, suggests that mastery experiences — leisure activities that require thought and focus like learning a new language or taking a woodworking class — can help you actively disengage from work.

Try cognitive behavioral therapy

Widely used for other forms of addiction, cognitive behavioral therapy centers around recognizing emotions, challenging thought patterns, and changing behaviors. However, Dr. Clark admits the research on its impact on work addiction, in particular, is “pretty nascent.”

Shift your mindset

It seems logical to think that detaching from your feelings will allow you to “do more,” but experts say that idea is both untrue and dangerous. “The safest hospitals are the hospitals where people are attuned to their humanness,” said Dr. Sukhera. “It’s normal to overwork in medicine, and if you’re challenging a norm, you really have to be thoughtful about how you frame that for yourself.”

Most importantly: Seek support

Today, there is increased awareness about work addiction and more resources for physicians who are struggling, including programs such as Workaholics Anonymous or Physicians Anonymous and workplace wellness initiatives. But try not to overwhelm yourself with choosing whom to talk to or what specific resource to utilize, Dr. Sukhera advised. “Just talk to someone about it. You don’t have to carry this on your own.”
 

A version of this article appeared on Medscape.com.

When child psychiatrist Javeed Sukhera, MD, PhD, was a few years into his career, he found himself doing it all. “I was in a leadership role academically at the medical school, I had a leadership role at the hospital, and I was seeing as many patients as I could. I could work all day every day.”

“It still wouldn’t have been enough,” he said.

Whenever there was a shift available, Dr. Sukhera would take it. His job was stressful, but as a new physician with a young family, he saw this obsession with work as necessary. “I began to cope with the stress from work by doing extra work and feeling like I needed to be everywhere. It was like I became a hamster on a spinning wheel. I was just running, running, running.”

Things shifted for Dr. Sukhera when he realized that while he was emotionally available for the children who were his patients, at home, his own children weren’t getting the best of him. “There was a specific moment when I thought my son was afraid of me,” he said. “I just stopped and realized that there was something happening that I needed to break. I needed to make a change.”

Dr. Sukhera, now chair of psychiatry at the Institute of Living and chief of the Department of Psychiatry at Hartford Hospital, Hartford, Connecticut, believes what he experienced was a steep fall into work addiction. “Workaholism,” often dismissed as simply working hard, is a nonclinical addiction that could fall under the umbrella of a behavioral addiction, and healthcare professionals may be especially at risk.
 

What Does Work Addiction Look Like for Doctors?

Behavioral addictions are fairly new in the addiction space. When gambling disorder, the first and only behavioral addiction in the Diagnostic and Statistical Manual of Mental Disorders, Fifth Edition, was added in 2013, it was seen as a “breakthrough addiction,” said Mark D. Griffiths, PhD, a leading behavioral addiction researcher and a distinguished professor at Nottingham Trent University.

Because there is not enough evidence yet to classify work addiction as a formal diagnosis, there is no clear consensus on how to define it. To further complicate things, the terms “workaholism” and “work addiction” can be used interchangeably, and some experts say the two are not the same, though they can overlap.

That said, a 2018 review of literature from several countries found that work addiction “fits very well into recently postulated criteria for conceptualization of a behavioral addiction.

“If you accept that gambling can be genuinely addictive, then there’s no reason to think that something like work, exercise, or video game playing couldn’t be an addiction as well,” said Dr. Griffiths.

“The neurobiology of addiction is that we get drawn to something that gives us a dopamine hit,” Dr. Sukhera added. “But to do that all day, every day, has consequences. It drains our emotional reserves, and it can greatly impact our relationships.”

On top of that, work addiction has been linked with poor sleep, poor cardiovascular health, high blood pressure, burnout, the development of autoimmune disorders, and other health issues.

Physicians are particularly susceptible. Doctors, after all, are expected to work long hours and put their patients’ needs first, even at the expense of their own health and well-being.

“Workaholism is not just socially acceptable in medicine,” said Dr. Sukhera. “It’s baked into the system and built into the structures. The healthcare system has largely functioned on the emotional labor of health workers, whose tendency to show up and work harder can, at times, in certain organizations, be exploited.”

Dr. Griffiths agreed that with the limited amount of data available, work addiction does appear to exist at higher rates in medicine than in other fields. As early as the 1970s, medical literature describes work as a “socially acceptable” addiction among doctors. A 2014 study published in Occupational Medicine reported that of 445 physicians who took part in the research, nearly half exhibited some level of work addiction with 13% “highly work addicted.”

Of course, working hard or even meeting unreasonable demands from work is not the same as work addiction, as Dr. Griffiths clarified in a 2023 editorial in BMJ Quality & Safety. The difference, as with other behavioral addictions, is when people obsess about work and use it to cope with stress. It can be easier to stay distracted and busy to gain a sense of control rather than learning to deal with complex emotions.

A 2021 study that Dr. Sukhera conducted with resident physicians found that working harder was one of the main ways they dealt with stress during the COVID-19 pandemic. “This idea that we deal with the stress of being burnt out by doing more and more of what burns us out is fairly ubiquitous at all stages of medical professionals’ careers,” he said.

Financial incentives also can fuel work addiction, said Dr. Sukhera. In residency, there are some safeguards around overwork and duty hours. When you become an attending, those limits no longer exist. As a young physician, Dr. Sukhera had student debt to pay off and a family to support. When he found opportunities to earn more by working more, his answer was always “yes.”

Pressure to produce medical research also can pose issues. Some physicians can become addicted to publishing studies, fearing that they might lose their professional status or position if they stop. It’s a cycle that can force a doctor to not only work long hours doing their job but also practically take on a second one.
 

How Physicians Can Recognize Work Addiction in Themselves

Work addiction can look and feel different for every person, said Malissa Clark, PhD, associate professor at the University of Georgia and author of the recent book Never Not Working: Why the Always-On Culture Is Bad for Business—and How to Fix It.

Dr. Clark noted that people who are highly engaged in their work tend to be driven by intrinsic motivation: “You work because you love it.” With work addiction, “you work because you feel like you ought to be working all the time.”

Of course, it’s not always so cut and dried; you can experience both forms of motivation and not necessarily become addicted to work. But if you are solely driven by the feeling that you ought to be working all the time, that can be a red flag.

Dr. Griffiths said that while many people may have problematic work habits or work too much, true work addicts must meet six criteria that apply to all addictions:

1. Salience: Work is the single most important thing in your life, to the point of neglecting everything else. Even if you’re on vacation, your mind might be flooded with work thoughts.

2. Mood modification: You use work to modify your mood, either to get a “high” or to cope with stress.

3. Tolerance: Over time, you’ve gone from working 8 or 10 hours a day to 12 hours a day, to a point where you’re working all the time.

4. Withdrawal: On a physiological level, you will have symptoms such as anxiety, nausea, or headaches when unable to work.

5. Conflict: You feel conflicted with yourself (you know you’re working too much) or with others (partners, friends, and children) about work, but you can’t stop.

6. Relapse: If you manage to cut down your hours but can’t resist overworking 1 day, you wind up right back where you were.
 

When It’s Time to Address Work Addiction

The lack of a formal diagnosis for work addiction makes getting treatment difficult. But there are ways to seek help. Unlike the drug and alcohol literature, abstinence is not the goal. “The therapeutic goal is getting a behavior under control and looking for the triggers of why you’re compulsively working,” said Dr. Griffiths.

Practice self-compassion

Dr. Sukhera eventually realized that his work addiction stemmed from the fear of being somehow excluded or unworthy. He actively corrected much of this through self-compassion and self-kindness, which helped him set boundaries. “Self-compassion is the root of everything,” he said. “Reminding ourselves that we’re doing our best is an important ingredient in breaking the cycle.”

Slowly expose yourself to relaxation

Many workaholics find rest very difficult. “When I conducted interviews with people [who considered themselves workaholics], a very common thing I heard was, ‘I have a very hard time being idle,’ ” said Dr. Clark. If rest feels hard, Dr. Sukhera suggests practicing relaxation for 2 minutes to start. Even small periods of downtime can challenge the belief that you must be constantly productive.

Reframe your to-do list 

For work addicts, to-do lists can seem like they must be finished, which prolongs work hours. Instead, use to-do lists to help prioritize what is urgent, identify what can wait, and delegate out tasks to others, Dr. Clark recommends.

Pick up a mastery experience

Research from professor Sabine Sonnentag, Dr. rer. nat., at the University of Mannheim, Mannheim, Germany, suggests that mastery experiences — leisure activities that require thought and focus like learning a new language or taking a woodworking class — can help you actively disengage from work.

Try cognitive behavioral therapy

Widely used for other forms of addiction, cognitive behavioral therapy centers around recognizing emotions, challenging thought patterns, and changing behaviors. However, Dr. Clark admits the research on its impact on work addiction, in particular, is “pretty nascent.”

Shift your mindset

It seems logical to think that detaching from your feelings will allow you to “do more,” but experts say that idea is both untrue and dangerous. “The safest hospitals are the hospitals where people are attuned to their humanness,” said Dr. Sukhera. “It’s normal to overwork in medicine, and if you’re challenging a norm, you really have to be thoughtful about how you frame that for yourself.”

Most importantly: Seek support

Today, there is increased awareness about work addiction and more resources for physicians who are struggling, including programs such as Workaholics Anonymous or Physicians Anonymous and workplace wellness initiatives. But try not to overwhelm yourself with choosing whom to talk to or what specific resource to utilize, Dr. Sukhera advised. “Just talk to someone about it. You don’t have to carry this on your own.”
 

A version of this article appeared on Medscape.com.

On April 4, Oregon’s Governor Tina Kotek signed a bill into law that officially changed the title of “physician assistants” to “physician associates” in the state. The switch is the first of its kind in the United States and comes on the heels of a decision from 2021 by the American Academy of Physician Associates (AAPA) to change the meaning of “PA” to “physician associate” from “physician assistant.”

In the Medscape Physician Assistant Career Satisfaction Report 2023, a diverse range of opinions on the title switch was reflected. Only 40% of PAs favored the name change at the time, 45% neither opposed nor favored it, and 15% opposed the name change, reflecting the complexity of the issue.

According to the AAPA, the change came about to better reflect the work PAs do in not just “assisting” physicians but in working independently with patients. Some also felt that the word “assistant” implies dependence. However, despite associate’s more accurate reflection of the job, PAs mostly remain split on whether they want the new moniker.

Many say that the name change will be confusing for the public and their patients, while others say that physician assistant was already not well understood, as patients often thought of the profession as a doctor’s helper or an assistant, like a medical assistant.

Yet many long-time PAs say that they prefer the title they’ve always had and that explaining to patients the new associate title will be equally confusing. Some mentioned patients may think they’re a business associate of the physician.

Oregon PAs won’t immediately switch to the new name. The new law takes effect on June 6, 2024. The Oregon Medical Board will establish regulations and guidance before PAs adopt the new name in their practices.

The law only changes the name of PAs in Oregon, not in other states. In fact, prematurely using the title of physician associate could subject a PA to regulatory challenges or disciplinary actions.

A version of this article appeared on Medscape.com.

On April 4, Oregon’s Governor Tina Kotek signed a bill into law that officially changed the title of “physician assistants” to “physician associates” in the state. The switch is the first of its kind in the United States and comes on the heels of a decision from 2021 by the American Academy of Physician Associates (AAPA) to change the meaning of “PA” to “physician associate” from “physician assistant.”

In the Medscape Physician Assistant Career Satisfaction Report 2023, a diverse range of opinions on the title switch was reflected. Only 40% of PAs favored the name change at the time, 45% neither opposed nor favored it, and 15% opposed the name change, reflecting the complexity of the issue.

According to the AAPA, the change came about to better reflect the work PAs do in not just “assisting” physicians but in working independently with patients. Some also felt that the word “assistant” implies dependence. However, despite associate’s more accurate reflection of the job, PAs mostly remain split on whether they want the new moniker.

Many say that the name change will be confusing for the public and their patients, while others say that physician assistant was already not well understood, as patients often thought of the profession as a doctor’s helper or an assistant, like a medical assistant.

Yet many long-time PAs say that they prefer the title they’ve always had and that explaining to patients the new associate title will be equally confusing. Some mentioned patients may think they’re a business associate of the physician.

Oregon PAs won’t immediately switch to the new name. The new law takes effect on June 6, 2024. The Oregon Medical Board will establish regulations and guidance before PAs adopt the new name in their practices.

The law only changes the name of PAs in Oregon, not in other states. In fact, prematurely using the title of physician associate could subject a PA to regulatory challenges or disciplinary actions.

A version of this article appeared on Medscape.com.

On April 4, Oregon’s Governor Tina Kotek signed a bill into law that officially changed the title of “physician assistants” to “physician associates” in the state. The switch is the first of its kind in the United States and comes on the heels of a decision from 2021 by the American Academy of Physician Associates (AAPA) to change the meaning of “PA” to “physician associate” from “physician assistant.”

In the Medscape Physician Assistant Career Satisfaction Report 2023, a diverse range of opinions on the title switch was reflected. Only 40% of PAs favored the name change at the time, 45% neither opposed nor favored it, and 15% opposed the name change, reflecting the complexity of the issue.

According to the AAPA, the change came about to better reflect the work PAs do in not just “assisting” physicians but in working independently with patients. Some also felt that the word “assistant” implies dependence. However, despite associate’s more accurate reflection of the job, PAs mostly remain split on whether they want the new moniker.

Many say that the name change will be confusing for the public and their patients, while others say that physician assistant was already not well understood, as patients often thought of the profession as a doctor’s helper or an assistant, like a medical assistant.

Yet many long-time PAs say that they prefer the title they’ve always had and that explaining to patients the new associate title will be equally confusing. Some mentioned patients may think they’re a business associate of the physician.

Oregon PAs won’t immediately switch to the new name. The new law takes effect on June 6, 2024. The Oregon Medical Board will establish regulations and guidance before PAs adopt the new name in their practices.

The law only changes the name of PAs in Oregon, not in other states. In fact, prematurely using the title of physician associate could subject a PA to regulatory challenges or disciplinary actions.

A version of this article appeared on Medscape.com.