Clinical Endocrinology News

Vitamin D deficiency increases mortality risk and raising levels even slightly could decrease the risk, researchers examining data from the UK Biobank have found.

They used a Mendelian randomization approach, which uses genetic variants as “proxy indicators” for external factors that affect vitamin D levels, such as sun exposure or dietary intake. It allows for analysis of the relationship between deficiency and outcomes including mortality, which can’t be done in randomized clinical trials for ethical reasons.

Using this method, nutritionist Joshua P. Sutherland, PhD, of the Australian Centre for Precision Health, Adelaide, and colleagues found an association between genetically predicted vitamin D levels [25-(OH)D] and mortality from several major causes, with evidence of causality among people with measured concentrations below, but not above, 50 nmol/L. The findings were published online in Annals of Internal Medicine.

Genetic approach reveals causal relationship

The investigators analyzed data from 307,601 individuals in the UK Biobank, a prospective cohort of people recruited from England, Scotland, and Wales during March 2006 and July 2010. Most were of White European ancestry and were aged 37-73 years at baseline.

Genetically predicted vitamin D levels were estimated using 35 confirmed 25-(OH)D variants. Participants were followed for outcomes up to June 2020.

The average baseline measured 25-(OH)D concentration was 45.2 nmol/L, and 11.7% (n = 36,009) of participants had levels between 10.0  and 24.9 nmol/L. Higher levels were seen in people living in southern areas and nonsmokers as well as those with a higher level of physical activity, less socioeconomic deprivation, and lower body mass index.

During follow-up, 6.1% of participants died (n = 18,700). After adjustment for variables, odds ratios for all causes of mortality were highest among people with 25-(OH)D levels below 25 nmol/L and appeared to plateau between 50 and 75 nmol/L, with no further reduction in mortality at values of 75-125 nmol/L.
 

Mortality 36% higher in those deficient in vitamin D

The risk for mortality was a significant 36% higher for participants with 25-(OH)D 25 nmol/L compared with 50 nmol/L.

With the Mendelian randomization, there was an L-shaped association between genetically predicted 25-(OH)D level and all-cause mortality (P for nonlinearity < .001) and for mortality because of cancer and cardiovascular disease (P for nonlinearity ≤ .033).

Again, the strongest association with those outcomes and genetically predicted 25-(OH)D was found at levels below 25 nmol/L and a plateau was seen by 50 nmol/L.

Compared with a measured 25-(OH)D concentration of 50 nmol/L, investigators estimated that the genetically predicted odds of all-cause mortality would increase sixfold (odds ratio, 6.00) for participants at 10 nmol/L and by 25% (OR, 1.25) for those at 25 nmol/L.

And, compared with a measured 25-(OH)D concentration of 50 nmol/L, those with 10 nmol/L had genetically predicted odds ratios of 5.98 for cardiovascular mortality, 3.37 for cancer mortality, and 12.44 for respiratory mortality.

Comparing measured 25-(OH)D concentrations of 25 nmol/L versus 50 nmol/L, odds ratios for those outcomes were 1.25, 1.16, and 1.96 (95% confidence interval, 1.88-4.67), respectively. All were statistically significant.

Consistent results supportive of a causal effect of genetically predicted 25-(OH)D on all-cause mortality in those with low measured vitamin D concentrations were also found in a sensitivity analysis of 20,837 people of non-White ethnic origin.

The study was funded by the Australian National Health and Medical Research Council. Dr. Sutherland’s studentship is funded by an Australian Research Training Program Scholarship.

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

Vitamin D deficiency increases mortality risk and raising levels even slightly could decrease the risk, researchers examining data from the UK Biobank have found.

They used a Mendelian randomization approach, which uses genetic variants as “proxy indicators” for external factors that affect vitamin D levels, such as sun exposure or dietary intake. It allows for analysis of the relationship between deficiency and outcomes including mortality, which can’t be done in randomized clinical trials for ethical reasons.

Using this method, nutritionist Joshua P. Sutherland, PhD, of the Australian Centre for Precision Health, Adelaide, and colleagues found an association between genetically predicted vitamin D levels [25-(OH)D] and mortality from several major causes, with evidence of causality among people with measured concentrations below, but not above, 50 nmol/L. The findings were published online in Annals of Internal Medicine.

Genetic approach reveals causal relationship

The investigators analyzed data from 307,601 individuals in the UK Biobank, a prospective cohort of people recruited from England, Scotland, and Wales during March 2006 and July 2010. Most were of White European ancestry and were aged 37-73 years at baseline.

Genetically predicted vitamin D levels were estimated using 35 confirmed 25-(OH)D variants. Participants were followed for outcomes up to June 2020.

The average baseline measured 25-(OH)D concentration was 45.2 nmol/L, and 11.7% (n = 36,009) of participants had levels between 10.0  and 24.9 nmol/L. Higher levels were seen in people living in southern areas and nonsmokers as well as those with a higher level of physical activity, less socioeconomic deprivation, and lower body mass index.

During follow-up, 6.1% of participants died (n = 18,700). After adjustment for variables, odds ratios for all causes of mortality were highest among people with 25-(OH)D levels below 25 nmol/L and appeared to plateau between 50 and 75 nmol/L, with no further reduction in mortality at values of 75-125 nmol/L.
 

Mortality 36% higher in those deficient in vitamin D

The risk for mortality was a significant 36% higher for participants with 25-(OH)D 25 nmol/L compared with 50 nmol/L.

With the Mendelian randomization, there was an L-shaped association between genetically predicted 25-(OH)D level and all-cause mortality (P for nonlinearity < .001) and for mortality because of cancer and cardiovascular disease (P for nonlinearity ≤ .033).

Again, the strongest association with those outcomes and genetically predicted 25-(OH)D was found at levels below 25 nmol/L and a plateau was seen by 50 nmol/L.

Compared with a measured 25-(OH)D concentration of 50 nmol/L, investigators estimated that the genetically predicted odds of all-cause mortality would increase sixfold (odds ratio, 6.00) for participants at 10 nmol/L and by 25% (OR, 1.25) for those at 25 nmol/L.

And, compared with a measured 25-(OH)D concentration of 50 nmol/L, those with 10 nmol/L had genetically predicted odds ratios of 5.98 for cardiovascular mortality, 3.37 for cancer mortality, and 12.44 for respiratory mortality.

Comparing measured 25-(OH)D concentrations of 25 nmol/L versus 50 nmol/L, odds ratios for those outcomes were 1.25, 1.16, and 1.96 (95% confidence interval, 1.88-4.67), respectively. All were statistically significant.

Consistent results supportive of a causal effect of genetically predicted 25-(OH)D on all-cause mortality in those with low measured vitamin D concentrations were also found in a sensitivity analysis of 20,837 people of non-White ethnic origin.

The study was funded by the Australian National Health and Medical Research Council. Dr. Sutherland’s studentship is funded by an Australian Research Training Program Scholarship.

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

Vitamin D deficiency increases mortality risk and raising levels even slightly could decrease the risk, researchers examining data from the UK Biobank have found.

They used a Mendelian randomization approach, which uses genetic variants as “proxy indicators” for external factors that affect vitamin D levels, such as sun exposure or dietary intake. It allows for analysis of the relationship between deficiency and outcomes including mortality, which can’t be done in randomized clinical trials for ethical reasons.

Using this method, nutritionist Joshua P. Sutherland, PhD, of the Australian Centre for Precision Health, Adelaide, and colleagues found an association between genetically predicted vitamin D levels [25-(OH)D] and mortality from several major causes, with evidence of causality among people with measured concentrations below, but not above, 50 nmol/L. The findings were published online in Annals of Internal Medicine.

Genetic approach reveals causal relationship

The investigators analyzed data from 307,601 individuals in the UK Biobank, a prospective cohort of people recruited from England, Scotland, and Wales during March 2006 and July 2010. Most were of White European ancestry and were aged 37-73 years at baseline.

Genetically predicted vitamin D levels were estimated using 35 confirmed 25-(OH)D variants. Participants were followed for outcomes up to June 2020.

The average baseline measured 25-(OH)D concentration was 45.2 nmol/L, and 11.7% (n = 36,009) of participants had levels between 10.0  and 24.9 nmol/L. Higher levels were seen in people living in southern areas and nonsmokers as well as those with a higher level of physical activity, less socioeconomic deprivation, and lower body mass index.

During follow-up, 6.1% of participants died (n = 18,700). After adjustment for variables, odds ratios for all causes of mortality were highest among people with 25-(OH)D levels below 25 nmol/L and appeared to plateau between 50 and 75 nmol/L, with no further reduction in mortality at values of 75-125 nmol/L.
 

Mortality 36% higher in those deficient in vitamin D

The risk for mortality was a significant 36% higher for participants with 25-(OH)D 25 nmol/L compared with 50 nmol/L.

With the Mendelian randomization, there was an L-shaped association between genetically predicted 25-(OH)D level and all-cause mortality (P for nonlinearity < .001) and for mortality because of cancer and cardiovascular disease (P for nonlinearity ≤ .033).

Again, the strongest association with those outcomes and genetically predicted 25-(OH)D was found at levels below 25 nmol/L and a plateau was seen by 50 nmol/L.

Compared with a measured 25-(OH)D concentration of 50 nmol/L, investigators estimated that the genetically predicted odds of all-cause mortality would increase sixfold (odds ratio, 6.00) for participants at 10 nmol/L and by 25% (OR, 1.25) for those at 25 nmol/L.

And, compared with a measured 25-(OH)D concentration of 50 nmol/L, those with 10 nmol/L had genetically predicted odds ratios of 5.98 for cardiovascular mortality, 3.37 for cancer mortality, and 12.44 for respiratory mortality.

Comparing measured 25-(OH)D concentrations of 25 nmol/L versus 50 nmol/L, odds ratios for those outcomes were 1.25, 1.16, and 1.96 (95% confidence interval, 1.88-4.67), respectively. All were statistically significant.

Consistent results supportive of a causal effect of genetically predicted 25-(OH)D on all-cause mortality in those with low measured vitamin D concentrations were also found in a sensitivity analysis of 20,837 people of non-White ethnic origin.

The study was funded by the Australian National Health and Medical Research Council. Dr. Sutherland’s studentship is funded by an Australian Research Training Program Scholarship.

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

The relationship between estrogen levels and heart health makes it particularly important for clinicians to be aware of those patients who might be at risk for cardiovascular disease despite not having other traditional risk factors, according to a presentation Oct. 12 at the North American Menopause Society annual meeting in Atlanta.

”Endogenous estrogens are protective for cardiovascular disease in premenopausal women,” Chrisandra L. Shufelt, MD, chair of the division of general internal medicine and associate director of the Women’s Health Research Center at Mayo Clinic in Jacksonville, Fla., told attendees. Yet, “a substantial population of young women are dying prematurely from cardiovascular disease,” with rates of cardiovascular death increasing in women aged 35-44 even as rates have decreased in postmenopausal women and in men. One potential reason may be premature estrogen loss.

Dr. Shufelt reminded attendees of four major causes of premature estrogen loss: Natural premature menopause, surgical menopause, chemotherapy-induced menopause, and premature ovarian insufficiency. But she would go on to discuss a less widely recognized condition, functional hypothalamic amenorrhea, that also may be contributing to increased cardiovascular risk.

First, Dr. Shufelt reviewed the evidence supporting the relationship between estrogen and cardiovascular health, starting with the Framingham study’s findings that cardiovascular disease is approximately two to four times more common in postmenopausal women than in premenopausal women, depending on the age range.

“Menopause at an early age, particularly under the age of 40, matters,” Dr. Shufelt said. “So we should be discussing this with our patients.”

Surgical menopause makes a difference to cardiovascular health as well, she said. In women under age 35, for example, the risk of a nonfatal heart attack in those with a bilateral oophorectomy was 7.7 times greater than in women who retained both ovaries and their uterus, and 1.5 times greater in women who had a hysterectomy without bilateral oophorectomy.

In a 2019 study, surgical premature menopause was associated with an 87% increased risk of heart disease even after researchers accounted for age, cardiovascular risk factors, and some forms of hormone therapy. The increased risk from natural premature menopause, on the other hand, was lower – a 36% increased risk of heart disease – compared with those producing endogenous hormones. Although randomized controlled trials are unavailable and unlikely to be done, the Nurses’ Health Study and the Danish Nurses Cohort Study, both observational studies, found that heart disease risk was diminished in those taking hormone therapy after surgical premature menopause.

Recommendations for premature or early menopause, from a wide range of different medical societies including NAMS, are that women without contraindications be given estrogen-based hormone therapy until the average age of natural menopause. Though not included in the same guidance, research has also shown that estrogen after oophorectomy does not increase the risk of breast cancer in women with a BRCA1 mutation, Dr. Shufelt said. Hormone therapy for premature or early menopause should adequately replace the levels women have lost and that means younger menopausal women often need higher doses than what older women receive, such as 2 mg/day of oral estradiol rather than the standard doses of 0.5 or 1 mg/day.
 

Functional hypothalamic amenorrhea and cardiovascular risk

Dr. Shufelt then discussed functional hypothalamic amenorrhea (hypogonadotropic hypogonadism), a common type of secondary amenorrhea that affects at least 1.4 million U.S. women. Diagnosis includes lack of a period for at least 3 months in someone who previously menstruated plus lab values below 50 pg/mL for estradiol, below 10 mIU/L for follicle stimulating hormone, and below 10 mIU/L for luteinizing hormone. Causes of this reversible form of infertility can include stress, overexercising, undereating, or some combination of these, plus an underlying genetic predisposition.

“After ruling out polycystic ovary syndrome, prolactinoma, and thyroid dysfunction, clinicians need to consider the diagnosis of hypothalamic amenorrhea,” Dr. Shufelt said. This condition goes beyond low estrogen levels: Women have elevated cortisol, low thyroid levels, low leptin levels, and increased ghrelin.

”This is not going away,” Dr. Shufelt said, sharing data on stress levels among U.S. adults, particularly Gen Z and millennial adults, noting that the ongoing “national mental health crisis” may be contributing to functional hypothalamic amenorrhea.

A 2020 substudy from the Nurses’ Health Study II found an increased risk of premature death in those who didn’t have a period or always had irregular periods starting as early as 14-17 years old. The increased risk of premature death rose with age in those with irregular or absent cycles – a 37% higher risk in 18- to 22-year-olds and a 39% increased risk in 29- to 46-year-olds.

But clinicians aren’t adequately identifying the “phenotype of the hypothalamic women,” Dr. Shufelt said, despite research showing overlap between hypothalamic amenorrhea and a higher risk of cardiovascular disease. Hypothalamic amenorrhea is so understudied that the last original research on the topic was in 2008, Dr. Shufelt said in an interview. ”No research except mine has been done to evaluate heart health in these young women,” she said.

Dr. Shufelt described a study she led involving 30 women with functional hypothalamic amenorrhea, 29 women with normal menstrual cycles, and 30 women who were recently menopausal and not on hormone therapy. The women with hypothalamic amenorrhea had average stress levels but their depression scores were higher than those of the other two groups.

The results showed that women with hypothalamic amenorrhea had lower estradiol and leptin levels and higher testosterone levels compared with the control group, and they had higher cortisol levels than those of both groups. Despite having similar body mass indexes as the control and menopausal groups, women with hypothalamic amenorrhea had lower blood pressure than that of the other two groups, yet they had higher cholesterol levels than those of the control group. EndoPAT^© (Itamar Medical) testing showed that they had poor vascular function.

“In fact, one-third of the women [with hypothalamic amenorrhea] entered the trial with a diagnosis of what would be considered endothelial dysfunction,” Dr. Shufelt said. “Our results demonstrated significantly higher circulating levels of serum proinflammatory cytokines in the women with hypothalamic amenorrhea compared to eumenorrheic controls.”

Dr. Shufelt’s team then tested whether giving estradiol to the women with hypothalamic amenorrhea for 12 weeks would improve their vascular health, but they saw no significant differences between the women who received estrogen and those who received placebo.

“Endothelial function is partly mediated by estrogen, and it was expected that giving back estrogen would ‘fix’ the endothelium, but that is not what happened,” Nanette Santoro, MD, professor and chair of obstetrics and gynecology at the University of Colorado at Denver, Aurora, said in interview. “The mechanisms that maintain vascular function in women are not limited to hormones,” said Dr. Santoro, who was not involved in Dr. Shufelt’s study but attended her lecture. “We need to think beyond the simple model of estrogen-good, no-estrogen-bad.”

Dr. Santoro noted how easy it is to overlook the women who may have cardiovascular risk because of hypothalamic amenorrhea.

“Because many women with functional hypothalamic amenorrhea are super athletic and do not have the typical features of people with cardiometabolic disease – such as glucose intolerance, obesity, abnormal cholesterol or triglycerides, or high blood pressure – clinicians tend to think of them as healthy and to think that simply giving back hormones will fix the problems with bone density and vascular function, but that is not enough,” Dr. Santoro said. “The cognitive-behavioral therapy model for treatment of women with functional hypothalamic amenorrhea addresses the stress-related factors that drive the disorder, and this needs to be considered the standard of care for treatment.”

Stephanie S. Faubion, MD, professor of medicine and director of Mayo Clinic’s Center for Women’s Health in Jacksonville, Fla., who was not involved in Dr. Shufelt’s presentation, also emphasized the importance of recognizing functional hypothalamic amenorrhea.

“This is an underrecognized entity to begin with, and the fact that these women appear to be at increased risk for vascular dysfunction and potentially increased risk for cardiovascular disease down the road makes it even more important for clinicians to identify them and provide interventions early on,” Dr. Faubion said in an interview. “These women need to be identified and the etiology of the amenorrhea addressed, whether it relates to overexercising, being underweight, or experiencing significant stressors that have led to the loss of menstrual cycles.”

Dr. Shufelt’s research was funded by the National Institutes of Health. She had no disclosures. Dr. Santoro is a member of the scientific advisory board for Astellas, Menogenix, Amazon Ember, and Que Oncology, and she consults for Ansh Labs. Dr. Faubion had no disclosures.

The relationship between estrogen levels and heart health makes it particularly important for clinicians to be aware of those patients who might be at risk for cardiovascular disease despite not having other traditional risk factors, according to a presentation Oct. 12 at the North American Menopause Society annual meeting in Atlanta.

”Endogenous estrogens are protective for cardiovascular disease in premenopausal women,” Chrisandra L. Shufelt, MD, chair of the division of general internal medicine and associate director of the Women’s Health Research Center at Mayo Clinic in Jacksonville, Fla., told attendees. Yet, “a substantial population of young women are dying prematurely from cardiovascular disease,” with rates of cardiovascular death increasing in women aged 35-44 even as rates have decreased in postmenopausal women and in men. One potential reason may be premature estrogen loss.

Dr. Shufelt reminded attendees of four major causes of premature estrogen loss: Natural premature menopause, surgical menopause, chemotherapy-induced menopause, and premature ovarian insufficiency. But she would go on to discuss a less widely recognized condition, functional hypothalamic amenorrhea, that also may be contributing to increased cardiovascular risk.

First, Dr. Shufelt reviewed the evidence supporting the relationship between estrogen and cardiovascular health, starting with the Framingham study’s findings that cardiovascular disease is approximately two to four times more common in postmenopausal women than in premenopausal women, depending on the age range.

“Menopause at an early age, particularly under the age of 40, matters,” Dr. Shufelt said. “So we should be discussing this with our patients.”

Surgical menopause makes a difference to cardiovascular health as well, she said. In women under age 35, for example, the risk of a nonfatal heart attack in those with a bilateral oophorectomy was 7.7 times greater than in women who retained both ovaries and their uterus, and 1.5 times greater in women who had a hysterectomy without bilateral oophorectomy.

In a 2019 study, surgical premature menopause was associated with an 87% increased risk of heart disease even after researchers accounted for age, cardiovascular risk factors, and some forms of hormone therapy. The increased risk from natural premature menopause, on the other hand, was lower – a 36% increased risk of heart disease – compared with those producing endogenous hormones. Although randomized controlled trials are unavailable and unlikely to be done, the Nurses’ Health Study and the Danish Nurses Cohort Study, both observational studies, found that heart disease risk was diminished in those taking hormone therapy after surgical premature menopause.

Recommendations for premature or early menopause, from a wide range of different medical societies including NAMS, are that women without contraindications be given estrogen-based hormone therapy until the average age of natural menopause. Though not included in the same guidance, research has also shown that estrogen after oophorectomy does not increase the risk of breast cancer in women with a BRCA1 mutation, Dr. Shufelt said. Hormone therapy for premature or early menopause should adequately replace the levels women have lost and that means younger menopausal women often need higher doses than what older women receive, such as 2 mg/day of oral estradiol rather than the standard doses of 0.5 or 1 mg/day.
 

Functional hypothalamic amenorrhea and cardiovascular risk

Dr. Shufelt then discussed functional hypothalamic amenorrhea (hypogonadotropic hypogonadism), a common type of secondary amenorrhea that affects at least 1.4 million U.S. women. Diagnosis includes lack of a period for at least 3 months in someone who previously menstruated plus lab values below 50 pg/mL for estradiol, below 10 mIU/L for follicle stimulating hormone, and below 10 mIU/L for luteinizing hormone. Causes of this reversible form of infertility can include stress, overexercising, undereating, or some combination of these, plus an underlying genetic predisposition.

“After ruling out polycystic ovary syndrome, prolactinoma, and thyroid dysfunction, clinicians need to consider the diagnosis of hypothalamic amenorrhea,” Dr. Shufelt said. This condition goes beyond low estrogen levels: Women have elevated cortisol, low thyroid levels, low leptin levels, and increased ghrelin.

”This is not going away,” Dr. Shufelt said, sharing data on stress levels among U.S. adults, particularly Gen Z and millennial adults, noting that the ongoing “national mental health crisis” may be contributing to functional hypothalamic amenorrhea.

A 2020 substudy from the Nurses’ Health Study II found an increased risk of premature death in those who didn’t have a period or always had irregular periods starting as early as 14-17 years old. The increased risk of premature death rose with age in those with irregular or absent cycles – a 37% higher risk in 18- to 22-year-olds and a 39% increased risk in 29- to 46-year-olds.

But clinicians aren’t adequately identifying the “phenotype of the hypothalamic women,” Dr. Shufelt said, despite research showing overlap between hypothalamic amenorrhea and a higher risk of cardiovascular disease. Hypothalamic amenorrhea is so understudied that the last original research on the topic was in 2008, Dr. Shufelt said in an interview. ”No research except mine has been done to evaluate heart health in these young women,” she said.

Dr. Shufelt described a study she led involving 30 women with functional hypothalamic amenorrhea, 29 women with normal menstrual cycles, and 30 women who were recently menopausal and not on hormone therapy. The women with hypothalamic amenorrhea had average stress levels but their depression scores were higher than those of the other two groups.

The results showed that women with hypothalamic amenorrhea had lower estradiol and leptin levels and higher testosterone levels compared with the control group, and they had higher cortisol levels than those of both groups. Despite having similar body mass indexes as the control and menopausal groups, women with hypothalamic amenorrhea had lower blood pressure than that of the other two groups, yet they had higher cholesterol levels than those of the control group. EndoPAT^© (Itamar Medical) testing showed that they had poor vascular function.

“In fact, one-third of the women [with hypothalamic amenorrhea] entered the trial with a diagnosis of what would be considered endothelial dysfunction,” Dr. Shufelt said. “Our results demonstrated significantly higher circulating levels of serum proinflammatory cytokines in the women with hypothalamic amenorrhea compared to eumenorrheic controls.”

Dr. Shufelt’s team then tested whether giving estradiol to the women with hypothalamic amenorrhea for 12 weeks would improve their vascular health, but they saw no significant differences between the women who received estrogen and those who received placebo.

“Endothelial function is partly mediated by estrogen, and it was expected that giving back estrogen would ‘fix’ the endothelium, but that is not what happened,” Nanette Santoro, MD, professor and chair of obstetrics and gynecology at the University of Colorado at Denver, Aurora, said in interview. “The mechanisms that maintain vascular function in women are not limited to hormones,” said Dr. Santoro, who was not involved in Dr. Shufelt’s study but attended her lecture. “We need to think beyond the simple model of estrogen-good, no-estrogen-bad.”

Dr. Santoro noted how easy it is to overlook the women who may have cardiovascular risk because of hypothalamic amenorrhea.

“Because many women with functional hypothalamic amenorrhea are super athletic and do not have the typical features of people with cardiometabolic disease – such as glucose intolerance, obesity, abnormal cholesterol or triglycerides, or high blood pressure – clinicians tend to think of them as healthy and to think that simply giving back hormones will fix the problems with bone density and vascular function, but that is not enough,” Dr. Santoro said. “The cognitive-behavioral therapy model for treatment of women with functional hypothalamic amenorrhea addresses the stress-related factors that drive the disorder, and this needs to be considered the standard of care for treatment.”

Stephanie S. Faubion, MD, professor of medicine and director of Mayo Clinic’s Center for Women’s Health in Jacksonville, Fla., who was not involved in Dr. Shufelt’s presentation, also emphasized the importance of recognizing functional hypothalamic amenorrhea.

“This is an underrecognized entity to begin with, and the fact that these women appear to be at increased risk for vascular dysfunction and potentially increased risk for cardiovascular disease down the road makes it even more important for clinicians to identify them and provide interventions early on,” Dr. Faubion said in an interview. “These women need to be identified and the etiology of the amenorrhea addressed, whether it relates to overexercising, being underweight, or experiencing significant stressors that have led to the loss of menstrual cycles.”

Dr. Shufelt’s research was funded by the National Institutes of Health. She had no disclosures. Dr. Santoro is a member of the scientific advisory board for Astellas, Menogenix, Amazon Ember, and Que Oncology, and she consults for Ansh Labs. Dr. Faubion had no disclosures.

The relationship between estrogen levels and heart health makes it particularly important for clinicians to be aware of those patients who might be at risk for cardiovascular disease despite not having other traditional risk factors, according to a presentation Oct. 12 at the North American Menopause Society annual meeting in Atlanta.

”Endogenous estrogens are protective for cardiovascular disease in premenopausal women,” Chrisandra L. Shufelt, MD, chair of the division of general internal medicine and associate director of the Women’s Health Research Center at Mayo Clinic in Jacksonville, Fla., told attendees. Yet, “a substantial population of young women are dying prematurely from cardiovascular disease,” with rates of cardiovascular death increasing in women aged 35-44 even as rates have decreased in postmenopausal women and in men. One potential reason may be premature estrogen loss.

Dr. Shufelt reminded attendees of four major causes of premature estrogen loss: Natural premature menopause, surgical menopause, chemotherapy-induced menopause, and premature ovarian insufficiency. But she would go on to discuss a less widely recognized condition, functional hypothalamic amenorrhea, that also may be contributing to increased cardiovascular risk.

First, Dr. Shufelt reviewed the evidence supporting the relationship between estrogen and cardiovascular health, starting with the Framingham study’s findings that cardiovascular disease is approximately two to four times more common in postmenopausal women than in premenopausal women, depending on the age range.

“Menopause at an early age, particularly under the age of 40, matters,” Dr. Shufelt said. “So we should be discussing this with our patients.”

Surgical menopause makes a difference to cardiovascular health as well, she said. In women under age 35, for example, the risk of a nonfatal heart attack in those with a bilateral oophorectomy was 7.7 times greater than in women who retained both ovaries and their uterus, and 1.5 times greater in women who had a hysterectomy without bilateral oophorectomy.

In a 2019 study, surgical premature menopause was associated with an 87% increased risk of heart disease even after researchers accounted for age, cardiovascular risk factors, and some forms of hormone therapy. The increased risk from natural premature menopause, on the other hand, was lower – a 36% increased risk of heart disease – compared with those producing endogenous hormones. Although randomized controlled trials are unavailable and unlikely to be done, the Nurses’ Health Study and the Danish Nurses Cohort Study, both observational studies, found that heart disease risk was diminished in those taking hormone therapy after surgical premature menopause.

Recommendations for premature or early menopause, from a wide range of different medical societies including NAMS, are that women without contraindications be given estrogen-based hormone therapy until the average age of natural menopause. Though not included in the same guidance, research has also shown that estrogen after oophorectomy does not increase the risk of breast cancer in women with a BRCA1 mutation, Dr. Shufelt said. Hormone therapy for premature or early menopause should adequately replace the levels women have lost and that means younger menopausal women often need higher doses than what older women receive, such as 2 mg/day of oral estradiol rather than the standard doses of 0.5 or 1 mg/day.
 

Functional hypothalamic amenorrhea and cardiovascular risk

Dr. Shufelt then discussed functional hypothalamic amenorrhea (hypogonadotropic hypogonadism), a common type of secondary amenorrhea that affects at least 1.4 million U.S. women. Diagnosis includes lack of a period for at least 3 months in someone who previously menstruated plus lab values below 50 pg/mL for estradiol, below 10 mIU/L for follicle stimulating hormone, and below 10 mIU/L for luteinizing hormone. Causes of this reversible form of infertility can include stress, overexercising, undereating, or some combination of these, plus an underlying genetic predisposition.

“After ruling out polycystic ovary syndrome, prolactinoma, and thyroid dysfunction, clinicians need to consider the diagnosis of hypothalamic amenorrhea,” Dr. Shufelt said. This condition goes beyond low estrogen levels: Women have elevated cortisol, low thyroid levels, low leptin levels, and increased ghrelin.

”This is not going away,” Dr. Shufelt said, sharing data on stress levels among U.S. adults, particularly Gen Z and millennial adults, noting that the ongoing “national mental health crisis” may be contributing to functional hypothalamic amenorrhea.

A 2020 substudy from the Nurses’ Health Study II found an increased risk of premature death in those who didn’t have a period or always had irregular periods starting as early as 14-17 years old. The increased risk of premature death rose with age in those with irregular or absent cycles – a 37% higher risk in 18- to 22-year-olds and a 39% increased risk in 29- to 46-year-olds.

But clinicians aren’t adequately identifying the “phenotype of the hypothalamic women,” Dr. Shufelt said, despite research showing overlap between hypothalamic amenorrhea and a higher risk of cardiovascular disease. Hypothalamic amenorrhea is so understudied that the last original research on the topic was in 2008, Dr. Shufelt said in an interview. ”No research except mine has been done to evaluate heart health in these young women,” she said.

Dr. Shufelt described a study she led involving 30 women with functional hypothalamic amenorrhea, 29 women with normal menstrual cycles, and 30 women who were recently menopausal and not on hormone therapy. The women with hypothalamic amenorrhea had average stress levels but their depression scores were higher than those of the other two groups.

The results showed that women with hypothalamic amenorrhea had lower estradiol and leptin levels and higher testosterone levels compared with the control group, and they had higher cortisol levels than those of both groups. Despite having similar body mass indexes as the control and menopausal groups, women with hypothalamic amenorrhea had lower blood pressure than that of the other two groups, yet they had higher cholesterol levels than those of the control group. EndoPAT^© (Itamar Medical) testing showed that they had poor vascular function.

“In fact, one-third of the women [with hypothalamic amenorrhea] entered the trial with a diagnosis of what would be considered endothelial dysfunction,” Dr. Shufelt said. “Our results demonstrated significantly higher circulating levels of serum proinflammatory cytokines in the women with hypothalamic amenorrhea compared to eumenorrheic controls.”

Dr. Shufelt’s team then tested whether giving estradiol to the women with hypothalamic amenorrhea for 12 weeks would improve their vascular health, but they saw no significant differences between the women who received estrogen and those who received placebo.

“Endothelial function is partly mediated by estrogen, and it was expected that giving back estrogen would ‘fix’ the endothelium, but that is not what happened,” Nanette Santoro, MD, professor and chair of obstetrics and gynecology at the University of Colorado at Denver, Aurora, said in interview. “The mechanisms that maintain vascular function in women are not limited to hormones,” said Dr. Santoro, who was not involved in Dr. Shufelt’s study but attended her lecture. “We need to think beyond the simple model of estrogen-good, no-estrogen-bad.”

Dr. Santoro noted how easy it is to overlook the women who may have cardiovascular risk because of hypothalamic amenorrhea.

“Because many women with functional hypothalamic amenorrhea are super athletic and do not have the typical features of people with cardiometabolic disease – such as glucose intolerance, obesity, abnormal cholesterol or triglycerides, or high blood pressure – clinicians tend to think of them as healthy and to think that simply giving back hormones will fix the problems with bone density and vascular function, but that is not enough,” Dr. Santoro said. “The cognitive-behavioral therapy model for treatment of women with functional hypothalamic amenorrhea addresses the stress-related factors that drive the disorder, and this needs to be considered the standard of care for treatment.”

Stephanie S. Faubion, MD, professor of medicine and director of Mayo Clinic’s Center for Women’s Health in Jacksonville, Fla., who was not involved in Dr. Shufelt’s presentation, also emphasized the importance of recognizing functional hypothalamic amenorrhea.

“This is an underrecognized entity to begin with, and the fact that these women appear to be at increased risk for vascular dysfunction and potentially increased risk for cardiovascular disease down the road makes it even more important for clinicians to identify them and provide interventions early on,” Dr. Faubion said in an interview. “These women need to be identified and the etiology of the amenorrhea addressed, whether it relates to overexercising, being underweight, or experiencing significant stressors that have led to the loss of menstrual cycles.”

Dr. Shufelt’s research was funded by the National Institutes of Health. She had no disclosures. Dr. Santoro is a member of the scientific advisory board for Astellas, Menogenix, Amazon Ember, and Que Oncology, and she consults for Ansh Labs. Dr. Faubion had no disclosures.

A new study shows that Black Americans received ventricular assist devices (VADs) and heart transplants about half as often as White Americans, even when receiving care at an advanced heart failure (HF) center.

The analysis, drawn from 377 patients treated at one of 21 VAD centers in the United States as part of the RIVIVAL study, found that 22.3% of White adults received a heart transplant or VAD, compared with 11% of Black adults.

“That’s what is so concerning to us, that we’re seeing this pattern within this select population. I think it would be too reasonable to hypothesize that it very well could be worse in the general population,” study author Thomas Cascino, MD, MSc, University of Michigan, Ann Arbor, commented.

The study was published online in Circulation: Heart Failure, and it builds on previous work by the researchers, showing that patient preference for early VAD therapy is associated with higher New York Heart Association (NYHA) class and lower income level but not race.

In the present analysis, the number of Black and White participants who said they “definitely or probably” wanted VAD therapy was similar (27% vs. 29%), as was the number wanting “any and all life-sustaining therapies” (74% vs. 65%).

Two-thirds of the cohort was NYHA class III, the average EuroQoL visual analog scale (EQ-VAS) score was 64.6 among the 100 participants who identified as Black and 62.1 in the 277 White participants, and the average age was 58 and 61 years, respectively.

Death rates were also similar during the 2-year follow-up: 18% of Black patients and 13% of White patients.

After controlling for multiple clinical and social determinants of health, including age, Interagency Registry for Mechanically Assisted Circulator Support (INTERMACS) patient profile, EQ-VAS score, and level of education, Black participants had a 55% lower rate of VAD or transplant, compared with White participants (hazard ratio, 0.45; 95% confidence interval, 0.23-0.85). Adding VAD preference to the model did not affect the association.

“Our study suggests that we as providers may be making decisions differently,” Dr. Cascino said. “We can’t say for sure what the reasons are but certainly structural racism, discrimination, and provider biases are the things I worry about.”

“There’s an absolute need for us to look inwards, reflect, and acknowledge that we are likely playing a role in this and then start to be part of the change,” he added.

“The lives disabled or lost are simply too many,” coauthor Wendy Taddei-Peters, PhD, a clinical trials project official at the National Heart, Lung, and Blood Institute, said in an NIH statement. “An immediate step could be to require implicit bias training, particularly for transplant and VAD team members.”

Other suggestions are better tracking of underserved patients and the reasons why they do not receive VAD or become listed for transplant; inclusion of psychosocial components into decision-making about advanced therapy candidacy; and having “disparity experts” join in heart team meetings to help identify biases in real time.

Commenting on the study, Khadijah Breathett, MD, HF/transplant cardiologist and tenured associate professor of medicine, Indiana University Bloomington, said, “I’m glad there’s more push for awareness, because there’s still a population of people that don’t believe this is a real problem.”

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

A new study shows that Black Americans received ventricular assist devices (VADs) and heart transplants about half as often as White Americans, even when receiving care at an advanced heart failure (HF) center.

The analysis, drawn from 377 patients treated at one of 21 VAD centers in the United States as part of the RIVIVAL study, found that 22.3% of White adults received a heart transplant or VAD, compared with 11% of Black adults.

“That’s what is so concerning to us, that we’re seeing this pattern within this select population. I think it would be too reasonable to hypothesize that it very well could be worse in the general population,” study author Thomas Cascino, MD, MSc, University of Michigan, Ann Arbor, commented.

The study was published online in Circulation: Heart Failure, and it builds on previous work by the researchers, showing that patient preference for early VAD therapy is associated with higher New York Heart Association (NYHA) class and lower income level but not race.

In the present analysis, the number of Black and White participants who said they “definitely or probably” wanted VAD therapy was similar (27% vs. 29%), as was the number wanting “any and all life-sustaining therapies” (74% vs. 65%).

Two-thirds of the cohort was NYHA class III, the average EuroQoL visual analog scale (EQ-VAS) score was 64.6 among the 100 participants who identified as Black and 62.1 in the 277 White participants, and the average age was 58 and 61 years, respectively.

Death rates were also similar during the 2-year follow-up: 18% of Black patients and 13% of White patients.

After controlling for multiple clinical and social determinants of health, including age, Interagency Registry for Mechanically Assisted Circulator Support (INTERMACS) patient profile, EQ-VAS score, and level of education, Black participants had a 55% lower rate of VAD or transplant, compared with White participants (hazard ratio, 0.45; 95% confidence interval, 0.23-0.85). Adding VAD preference to the model did not affect the association.

“Our study suggests that we as providers may be making decisions differently,” Dr. Cascino said. “We can’t say for sure what the reasons are but certainly structural racism, discrimination, and provider biases are the things I worry about.”

“There’s an absolute need for us to look inwards, reflect, and acknowledge that we are likely playing a role in this and then start to be part of the change,” he added.

“The lives disabled or lost are simply too many,” coauthor Wendy Taddei-Peters, PhD, a clinical trials project official at the National Heart, Lung, and Blood Institute, said in an NIH statement. “An immediate step could be to require implicit bias training, particularly for transplant and VAD team members.”

Other suggestions are better tracking of underserved patients and the reasons why they do not receive VAD or become listed for transplant; inclusion of psychosocial components into decision-making about advanced therapy candidacy; and having “disparity experts” join in heart team meetings to help identify biases in real time.

Commenting on the study, Khadijah Breathett, MD, HF/transplant cardiologist and tenured associate professor of medicine, Indiana University Bloomington, said, “I’m glad there’s more push for awareness, because there’s still a population of people that don’t believe this is a real problem.”

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

A new study shows that Black Americans received ventricular assist devices (VADs) and heart transplants about half as often as White Americans, even when receiving care at an advanced heart failure (HF) center.

The analysis, drawn from 377 patients treated at one of 21 VAD centers in the United States as part of the RIVIVAL study, found that 22.3% of White adults received a heart transplant or VAD, compared with 11% of Black adults.

“That’s what is so concerning to us, that we’re seeing this pattern within this select population. I think it would be too reasonable to hypothesize that it very well could be worse in the general population,” study author Thomas Cascino, MD, MSc, University of Michigan, Ann Arbor, commented.

The study was published online in Circulation: Heart Failure, and it builds on previous work by the researchers, showing that patient preference for early VAD therapy is associated with higher New York Heart Association (NYHA) class and lower income level but not race.

In the present analysis, the number of Black and White participants who said they “definitely or probably” wanted VAD therapy was similar (27% vs. 29%), as was the number wanting “any and all life-sustaining therapies” (74% vs. 65%).

Two-thirds of the cohort was NYHA class III, the average EuroQoL visual analog scale (EQ-VAS) score was 64.6 among the 100 participants who identified as Black and 62.1 in the 277 White participants, and the average age was 58 and 61 years, respectively.

Death rates were also similar during the 2-year follow-up: 18% of Black patients and 13% of White patients.

After controlling for multiple clinical and social determinants of health, including age, Interagency Registry for Mechanically Assisted Circulator Support (INTERMACS) patient profile, EQ-VAS score, and level of education, Black participants had a 55% lower rate of VAD or transplant, compared with White participants (hazard ratio, 0.45; 95% confidence interval, 0.23-0.85). Adding VAD preference to the model did not affect the association.

“Our study suggests that we as providers may be making decisions differently,” Dr. Cascino said. “We can’t say for sure what the reasons are but certainly structural racism, discrimination, and provider biases are the things I worry about.”

“There’s an absolute need for us to look inwards, reflect, and acknowledge that we are likely playing a role in this and then start to be part of the change,” he added.

“The lives disabled or lost are simply too many,” coauthor Wendy Taddei-Peters, PhD, a clinical trials project official at the National Heart, Lung, and Blood Institute, said in an NIH statement. “An immediate step could be to require implicit bias training, particularly for transplant and VAD team members.”

Other suggestions are better tracking of underserved patients and the reasons why they do not receive VAD or become listed for transplant; inclusion of psychosocial components into decision-making about advanced therapy candidacy; and having “disparity experts” join in heart team meetings to help identify biases in real time.

Commenting on the study, Khadijah Breathett, MD, HF/transplant cardiologist and tenured associate professor of medicine, Indiana University Bloomington, said, “I’m glad there’s more push for awareness, because there’s still a population of people that don’t believe this is a real problem.”

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

Cocaine, methamphetamine, opioids, and cannabis may independently increase risk of atrial fibrillation (AFib), based on data from almost 24 million people.

While more work is needed to uncover causal links, physicians should be aware that these commonly abused substances could be driving new cases of AFib, reported investigators from the University of California, San Francisco.

“Though alcohol and tobacco smoking have each been associated with a heightened risk of [AFib], relationships between other drug use and [AFib] are poorly understood,” they wrote in European Heart Journal.

Some previous studies have ventured into this terrain, but most focused on fatal arrhythmias, or offered anecdotal evidence. This knowledge gap is particularly concerning for cannabis, the researchers noted, as medical and recreational use are on the rise.

American Heart Association

The present analysis included data from 23.5 million adults in California who received care through a hospital, emergency department, or outpatient surgery center during 2005-2015. Based on ICD-9 diagnostic codes, 132,834 of these patients used cannabis, 98,271 used methamphetamines, 48,701 used cocaine, and 10,032 used opiates. Inclusion required lack of AFib at baseline.

Reliance on ICD-9 codes makes the data “quite specific,” but lacking sensitivity, according to principal author Gregory M. Marcus, MD, cardiologist and professor of medicine at UCSF.

“If they were designated as using these drugs, that is very likely true,” Dr. Marcus said in an interview. “But certainly, the absence of any mention of use of these drugs does not exclude the possibility that some people were still using them. That would not create spurious false-positive relationships; if anything, it attenuates existing relationships.”

In other words, using ICD-9 codes reduced the power to detect an association between each drug and AFib, meaning any relationship needed to be sufficiently strong enough to generate a significant result.

At the end of the decade-long study period, 998,747 patients (4.2%) had developed incident AFib. After adjusting for potential confounders and mediators, all four drugs showed significant, independent associations with AFib. Methamphetamines presented the greatest risk (hazard ratio, 1.86%), followed by opiates (HR, 1.74), cocaine (HR, 1.61), and cannabis (HR, 1.35).

“Our findings provide the first evidence utilizing a longitudinal cohort to demonstrate that cannabis use predicts the future onset of AFib,” Dr. Marcus and colleagues wrote.

Dose-response relationships were not detected for any of the substances; however, usage levels were also derived from ICD-9 codes, which may have been insufficient for this purpose, according to the investigators.
 

Causal mechanisms deserve a closer look

Causal links between AFib and each of the drugs remain unclear. Citing prior research, Dr. Marcus and colleagues explained how methamphetamines are capable of “significant cardiac electrical remodeling,” while cocaine may cause sodium channel dysregulation, and opioids can render atrial myocytes more susceptible to oxidative damage. Although cannabis has previously been linked with hospitalization for arrhythmia, a pharmacologic driver of this phenomenon remains largely unexamined.

“We don’t know for sure precisely what the constituents are that are responsible for our findings,” Dr. Marcus said. “It’s possible that there are some effects that are much more generic, such as inhaling a burned substance. There is good evidence that if you inhale pretty much any sort of particulate matter, that increases inflammation in the body. Inflammation is known to be a trigger for atrial fibrillation.”

Alternatively, all four drugs – whether stimulants or depressants – cause “quite dramatic and often rapid effects on the autonomic nervous system,” Dr. Marcus said, noting that these rapid swings are a known trigger for AFib.

Brian Olshansky, MD, emeritus professor of internal medicine-cardiovascular medicine at the University of Iowa, Iowa City, suggested that nonpharmacologic factors are likely also playing a role.

“All these drugs have slightly different mechanisms of action, so there’s not one mechanism that would explain why all of them would cause atrial fibrillation,” Dr. Olshansky said in an interview. “That does suggest that there’s something else going on, besides just the drug itself. It would be potentially concerning if we were to lay the blame totally on these drugs.”

Dr. Olshansky, who recently coauthored a review of stimulant drugs and arrhythmias, suggested that lifestyle, comorbidities, and drug impurities may have added to the risk of AF.

“[The investigators] did try to correct for that kind of stuff, but it’s very hard to correct for a lot of the issues that may be ongoing with individuals who partake in these drugs,” Dr. Olshansky said in an interview. “They may not be a healthy lot, in general.”

Still, considering previous data linking drugs of abuse with arrhythmias, he said the detected risks were “intriguing,” and deserved a closer look.

“It’s a nice groundbreaking study, with regard to the fact that they showed unique relationships that we don’t completely understand,” Dr. Olshansky said. “It opens up a new opportunity for further investigation.”

The investigators disclosed relationships with InCarda, Baylis Medical, Johnson & Johnson, and others. Dr. Olshansky disclosed no relevant competing interests.

Cocaine, methamphetamine, opioids, and cannabis may independently increase risk of atrial fibrillation (AFib), based on data from almost 24 million people.

While more work is needed to uncover causal links, physicians should be aware that these commonly abused substances could be driving new cases of AFib, reported investigators from the University of California, San Francisco.

“Though alcohol and tobacco smoking have each been associated with a heightened risk of [AFib], relationships between other drug use and [AFib] are poorly understood,” they wrote in European Heart Journal.

Some previous studies have ventured into this terrain, but most focused on fatal arrhythmias, or offered anecdotal evidence. This knowledge gap is particularly concerning for cannabis, the researchers noted, as medical and recreational use are on the rise.

American Heart Association

The present analysis included data from 23.5 million adults in California who received care through a hospital, emergency department, or outpatient surgery center during 2005-2015. Based on ICD-9 diagnostic codes, 132,834 of these patients used cannabis, 98,271 used methamphetamines, 48,701 used cocaine, and 10,032 used opiates. Inclusion required lack of AFib at baseline.

Reliance on ICD-9 codes makes the data “quite specific,” but lacking sensitivity, according to principal author Gregory M. Marcus, MD, cardiologist and professor of medicine at UCSF.

“If they were designated as using these drugs, that is very likely true,” Dr. Marcus said in an interview. “But certainly, the absence of any mention of use of these drugs does not exclude the possibility that some people were still using them. That would not create spurious false-positive relationships; if anything, it attenuates existing relationships.”

In other words, using ICD-9 codes reduced the power to detect an association between each drug and AFib, meaning any relationship needed to be sufficiently strong enough to generate a significant result.

At the end of the decade-long study period, 998,747 patients (4.2%) had developed incident AFib. After adjusting for potential confounders and mediators, all four drugs showed significant, independent associations with AFib. Methamphetamines presented the greatest risk (hazard ratio, 1.86%), followed by opiates (HR, 1.74), cocaine (HR, 1.61), and cannabis (HR, 1.35).

“Our findings provide the first evidence utilizing a longitudinal cohort to demonstrate that cannabis use predicts the future onset of AFib,” Dr. Marcus and colleagues wrote.

Dose-response relationships were not detected for any of the substances; however, usage levels were also derived from ICD-9 codes, which may have been insufficient for this purpose, according to the investigators.
 

Causal mechanisms deserve a closer look

Causal links between AFib and each of the drugs remain unclear. Citing prior research, Dr. Marcus and colleagues explained how methamphetamines are capable of “significant cardiac electrical remodeling,” while cocaine may cause sodium channel dysregulation, and opioids can render atrial myocytes more susceptible to oxidative damage. Although cannabis has previously been linked with hospitalization for arrhythmia, a pharmacologic driver of this phenomenon remains largely unexamined.

“We don’t know for sure precisely what the constituents are that are responsible for our findings,” Dr. Marcus said. “It’s possible that there are some effects that are much more generic, such as inhaling a burned substance. There is good evidence that if you inhale pretty much any sort of particulate matter, that increases inflammation in the body. Inflammation is known to be a trigger for atrial fibrillation.”

Alternatively, all four drugs – whether stimulants or depressants – cause “quite dramatic and often rapid effects on the autonomic nervous system,” Dr. Marcus said, noting that these rapid swings are a known trigger for AFib.

Brian Olshansky, MD, emeritus professor of internal medicine-cardiovascular medicine at the University of Iowa, Iowa City, suggested that nonpharmacologic factors are likely also playing a role.

“All these drugs have slightly different mechanisms of action, so there’s not one mechanism that would explain why all of them would cause atrial fibrillation,” Dr. Olshansky said in an interview. “That does suggest that there’s something else going on, besides just the drug itself. It would be potentially concerning if we were to lay the blame totally on these drugs.”

Dr. Olshansky, who recently coauthored a review of stimulant drugs and arrhythmias, suggested that lifestyle, comorbidities, and drug impurities may have added to the risk of AF.

“[The investigators] did try to correct for that kind of stuff, but it’s very hard to correct for a lot of the issues that may be ongoing with individuals who partake in these drugs,” Dr. Olshansky said in an interview. “They may not be a healthy lot, in general.”

Still, considering previous data linking drugs of abuse with arrhythmias, he said the detected risks were “intriguing,” and deserved a closer look.

“It’s a nice groundbreaking study, with regard to the fact that they showed unique relationships that we don’t completely understand,” Dr. Olshansky said. “It opens up a new opportunity for further investigation.”

The investigators disclosed relationships with InCarda, Baylis Medical, Johnson & Johnson, and others. Dr. Olshansky disclosed no relevant competing interests.

Cocaine, methamphetamine, opioids, and cannabis may independently increase risk of atrial fibrillation (AFib), based on data from almost 24 million people.

While more work is needed to uncover causal links, physicians should be aware that these commonly abused substances could be driving new cases of AFib, reported investigators from the University of California, San Francisco.

“Though alcohol and tobacco smoking have each been associated with a heightened risk of [AFib], relationships between other drug use and [AFib] are poorly understood,” they wrote in European Heart Journal.

Some previous studies have ventured into this terrain, but most focused on fatal arrhythmias, or offered anecdotal evidence. This knowledge gap is particularly concerning for cannabis, the researchers noted, as medical and recreational use are on the rise.

American Heart Association

The present analysis included data from 23.5 million adults in California who received care through a hospital, emergency department, or outpatient surgery center during 2005-2015. Based on ICD-9 diagnostic codes, 132,834 of these patients used cannabis, 98,271 used methamphetamines, 48,701 used cocaine, and 10,032 used opiates. Inclusion required lack of AFib at baseline.

Reliance on ICD-9 codes makes the data “quite specific,” but lacking sensitivity, according to principal author Gregory M. Marcus, MD, cardiologist and professor of medicine at UCSF.

“If they were designated as using these drugs, that is very likely true,” Dr. Marcus said in an interview. “But certainly, the absence of any mention of use of these drugs does not exclude the possibility that some people were still using them. That would not create spurious false-positive relationships; if anything, it attenuates existing relationships.”

In other words, using ICD-9 codes reduced the power to detect an association between each drug and AFib, meaning any relationship needed to be sufficiently strong enough to generate a significant result.

At the end of the decade-long study period, 998,747 patients (4.2%) had developed incident AFib. After adjusting for potential confounders and mediators, all four drugs showed significant, independent associations with AFib. Methamphetamines presented the greatest risk (hazard ratio, 1.86%), followed by opiates (HR, 1.74), cocaine (HR, 1.61), and cannabis (HR, 1.35).

“Our findings provide the first evidence utilizing a longitudinal cohort to demonstrate that cannabis use predicts the future onset of AFib,” Dr. Marcus and colleagues wrote.

Dose-response relationships were not detected for any of the substances; however, usage levels were also derived from ICD-9 codes, which may have been insufficient for this purpose, according to the investigators.
 

Causal mechanisms deserve a closer look

Causal links between AFib and each of the drugs remain unclear. Citing prior research, Dr. Marcus and colleagues explained how methamphetamines are capable of “significant cardiac electrical remodeling,” while cocaine may cause sodium channel dysregulation, and opioids can render atrial myocytes more susceptible to oxidative damage. Although cannabis has previously been linked with hospitalization for arrhythmia, a pharmacologic driver of this phenomenon remains largely unexamined.

“We don’t know for sure precisely what the constituents are that are responsible for our findings,” Dr. Marcus said. “It’s possible that there are some effects that are much more generic, such as inhaling a burned substance. There is good evidence that if you inhale pretty much any sort of particulate matter, that increases inflammation in the body. Inflammation is known to be a trigger for atrial fibrillation.”

Alternatively, all four drugs – whether stimulants or depressants – cause “quite dramatic and often rapid effects on the autonomic nervous system,” Dr. Marcus said, noting that these rapid swings are a known trigger for AFib.

Brian Olshansky, MD, emeritus professor of internal medicine-cardiovascular medicine at the University of Iowa, Iowa City, suggested that nonpharmacologic factors are likely also playing a role.

“All these drugs have slightly different mechanisms of action, so there’s not one mechanism that would explain why all of them would cause atrial fibrillation,” Dr. Olshansky said in an interview. “That does suggest that there’s something else going on, besides just the drug itself. It would be potentially concerning if we were to lay the blame totally on these drugs.”

Dr. Olshansky, who recently coauthored a review of stimulant drugs and arrhythmias, suggested that lifestyle, comorbidities, and drug impurities may have added to the risk of AF.

“[The investigators] did try to correct for that kind of stuff, but it’s very hard to correct for a lot of the issues that may be ongoing with individuals who partake in these drugs,” Dr. Olshansky said in an interview. “They may not be a healthy lot, in general.”

Still, considering previous data linking drugs of abuse with arrhythmias, he said the detected risks were “intriguing,” and deserved a closer look.

“It’s a nice groundbreaking study, with regard to the fact that they showed unique relationships that we don’t completely understand,” Dr. Olshansky said. “It opens up a new opportunity for further investigation.”

The investigators disclosed relationships with InCarda, Baylis Medical, Johnson & Johnson, and others. Dr. Olshansky disclosed no relevant competing interests.

MONTREAL – Patients who discontinue levothyroxine for subclinical hypothyroidism may gravitate towards becoming mildly hypothyroid again, but they importantly show no differences in terms of symptoms and quality of life – and sometimes show even improvement – compared with those who continue treatment, new research shows.

“Our results show feasibility of patient enrollment and safety of discontinuing levothyroxine in patients with subclinical hypothyroidism,” said first author Spyridoula Maraka, MD, when presenting the findings at the American Thyroid Association annual meeting.

Recommendations against levothyroxine for subclinical hypothyroidism

Subclinical hypothyroidism is commonly over-diagnosed, and treatment with thyroid hormone replacement, levothyroxine, has been shown to provide little, if any, benefit in terms of quality of life or relief of thyroid-related symptoms for these patients.

The treatment is meanwhile associated with burdens including cost and lifestyle adjustments, and one guideline panel recently issued a strong recommendation against routine levothyroxine use in most adults with subclinical hypothyroidism.

Nevertheless, levothyroxine treatment has soared in popularity and become one of the most commonly prescribed drugs in the United States.

With research lacking on one key solution of discontinuation of the therapy, Dr. Maraka, who is part of the Division of Endocrinology and Metabolism at the University of Arkansas for Medical Sciences, Little Rock, and colleagues conducted a double-blind, placebo-controlled trial at the Central Arkansas Veterans Healthcare System. In total, 50 patients treated for subclinical hypothyroidism were randomized 1:1 to continue receiving levothyroxine (25-75 mcg daily) or to discontinue treatment and receive a placebo instead, with a planned 6-month follow-up.

In the current interim analysis, Dr. Maraka reported results for the first 40 patients, including 20 randomized to levothyroxine and 20 to discontinuation.

There were no significant differences between the discontinuation and levothyroxine groups at baseline, which were of a similar age (66.2 vs. 70.8 years) and gender (75% women vs. 85% men).

The groups had similar baseline thyroid-stimulating hormone (TSH) levels (3.0 vs. 2.6 mIU/L), free T4 (both 0.9 ng/dL), thyroid peroxidase antibody positivity (17% vs. 11%), and similar clinical symptoms. All patients had at least one elevated TSH reading prior to starting levothyroxine.

With a follow-up of 6-8 weeks, 36.8% of patients in the discontinuation group had subclinical hypothyroidism, compared with 10% of patients who remained on levothyroxine (P = .0648), TSH levels were 5.5 versus 2.7 mIU/L (P = .001) and free T4 levels were 0.8 versus 0.9 ng/dL (P = .011).
 

No differences in symptoms, quality of life between groups

Importantly, there were no significant differences between the discontinuation versus levothyroxine groups in terms of symptoms, and even some improvements with discontinuation, including Thyroid-Specific Quality of Life Patient-Reported Outcome (ThyPRO)-Hypothyroid Symptoms score (4.6 reduction vs. 2.2 increase), tiredness (2.6 reduction vs. 1.1 increase), and EuroQoL 5-Dimension Self-Report Questionnaire (EQ-5D) quality of life score, for which there were no differences between groups.

There were no reports of overt hypothyroidism; hyperthyroidism; cardiovascular events including atrial fibrillation, stroke, or heart failure; osteoporotic fractures; or deaths.

One patient in the discontinuation group had a TSH level of 11 mIU/L at 6-8 weeks and switched to open-label levothyroxine 75 mcg daily. Another patient in the discontinuation group switched to open-label levothyroxine 75 mcg daily at 10 weeks due to fatigue; however, the patient was diagnosed with metastatic colon cancer 1 month later.

The finding that only about a third of patients who discontinued levothyroxine developed subclinical hypothyroidism was lower than expected, Dr. Maraka noted.

“This was ... unexpected ... for us,” she said. “We were expecting a larger number of patients to develop hypothyroidism, but to our surprise, that was not the case.”

“But what is more important is that there was no difference in the quality of life measures,” she added. “If anything, the placebo group was a little better, though the [differences] were not statistically significant.”

Dr. Maraka also noted that in further research and a final 6-month analysis, the authors will look at factors associated with developing subclinical hypothyroidism after treatment discontinuation, among other issues.
 

Discontinuation of levothyroxine is manageable

The results are encouraging, as they provide assurance that discontinuation of levothyroxine is manageable.

“This research will pave the way for initiatives to promote levothyroxine deprescription and implementation of evidence-based care for patients with subclinical hypothyroidism,” she said.

In further comments, Dr. Hennessey noted that the dilemma of having patients on levothyroxine who may not be benefitting from treatment is “significant,” with patients sometimes reluctant to discontinue treatment due to concerns of developing hypothyroidism-associated symptoms such as brain fog and weight gain.

He noted, however, that “many with mildly elevated TSH actually go on to normalize with time, so they are not really hypothyroid, [and] if we remove thyroxine from people with normal thyroid function, they will remain normal.”

Dr. Maraka has reported no relevant financial relationships. Dr. Hennessey has reported consulting for pharmaceutical companies to design clinical studies for thyroid medications.

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

MONTREAL – Patients who discontinue levothyroxine for subclinical hypothyroidism may gravitate towards becoming mildly hypothyroid again, but they importantly show no differences in terms of symptoms and quality of life – and sometimes show even improvement – compared with those who continue treatment, new research shows.

“Our results show feasibility of patient enrollment and safety of discontinuing levothyroxine in patients with subclinical hypothyroidism,” said first author Spyridoula Maraka, MD, when presenting the findings at the American Thyroid Association annual meeting.

Recommendations against levothyroxine for subclinical hypothyroidism

Subclinical hypothyroidism is commonly over-diagnosed, and treatment with thyroid hormone replacement, levothyroxine, has been shown to provide little, if any, benefit in terms of quality of life or relief of thyroid-related symptoms for these patients.

The treatment is meanwhile associated with burdens including cost and lifestyle adjustments, and one guideline panel recently issued a strong recommendation against routine levothyroxine use in most adults with subclinical hypothyroidism.

Nevertheless, levothyroxine treatment has soared in popularity and become one of the most commonly prescribed drugs in the United States.

With research lacking on one key solution of discontinuation of the therapy, Dr. Maraka, who is part of the Division of Endocrinology and Metabolism at the University of Arkansas for Medical Sciences, Little Rock, and colleagues conducted a double-blind, placebo-controlled trial at the Central Arkansas Veterans Healthcare System. In total, 50 patients treated for subclinical hypothyroidism were randomized 1:1 to continue receiving levothyroxine (25-75 mcg daily) or to discontinue treatment and receive a placebo instead, with a planned 6-month follow-up.

In the current interim analysis, Dr. Maraka reported results for the first 40 patients, including 20 randomized to levothyroxine and 20 to discontinuation.

There were no significant differences between the discontinuation and levothyroxine groups at baseline, which were of a similar age (66.2 vs. 70.8 years) and gender (75% women vs. 85% men).

The groups had similar baseline thyroid-stimulating hormone (TSH) levels (3.0 vs. 2.6 mIU/L), free T4 (both 0.9 ng/dL), thyroid peroxidase antibody positivity (17% vs. 11%), and similar clinical symptoms. All patients had at least one elevated TSH reading prior to starting levothyroxine.

With a follow-up of 6-8 weeks, 36.8% of patients in the discontinuation group had subclinical hypothyroidism, compared with 10% of patients who remained on levothyroxine (P = .0648), TSH levels were 5.5 versus 2.7 mIU/L (P = .001) and free T4 levels were 0.8 versus 0.9 ng/dL (P = .011).
 

No differences in symptoms, quality of life between groups

Importantly, there were no significant differences between the discontinuation versus levothyroxine groups in terms of symptoms, and even some improvements with discontinuation, including Thyroid-Specific Quality of Life Patient-Reported Outcome (ThyPRO)-Hypothyroid Symptoms score (4.6 reduction vs. 2.2 increase), tiredness (2.6 reduction vs. 1.1 increase), and EuroQoL 5-Dimension Self-Report Questionnaire (EQ-5D) quality of life score, for which there were no differences between groups.

There were no reports of overt hypothyroidism; hyperthyroidism; cardiovascular events including atrial fibrillation, stroke, or heart failure; osteoporotic fractures; or deaths.

One patient in the discontinuation group had a TSH level of 11 mIU/L at 6-8 weeks and switched to open-label levothyroxine 75 mcg daily. Another patient in the discontinuation group switched to open-label levothyroxine 75 mcg daily at 10 weeks due to fatigue; however, the patient was diagnosed with metastatic colon cancer 1 month later.

The finding that only about a third of patients who discontinued levothyroxine developed subclinical hypothyroidism was lower than expected, Dr. Maraka noted.

“This was ... unexpected ... for us,” she said. “We were expecting a larger number of patients to develop hypothyroidism, but to our surprise, that was not the case.”

“But what is more important is that there was no difference in the quality of life measures,” she added. “If anything, the placebo group was a little better, though the [differences] were not statistically significant.”

Dr. Maraka also noted that in further research and a final 6-month analysis, the authors will look at factors associated with developing subclinical hypothyroidism after treatment discontinuation, among other issues.
 

Discontinuation of levothyroxine is manageable

The results are encouraging, as they provide assurance that discontinuation of levothyroxine is manageable.

“This research will pave the way for initiatives to promote levothyroxine deprescription and implementation of evidence-based care for patients with subclinical hypothyroidism,” she said.

In further comments, Dr. Hennessey noted that the dilemma of having patients on levothyroxine who may not be benefitting from treatment is “significant,” with patients sometimes reluctant to discontinue treatment due to concerns of developing hypothyroidism-associated symptoms such as brain fog and weight gain.

He noted, however, that “many with mildly elevated TSH actually go on to normalize with time, so they are not really hypothyroid, [and] if we remove thyroxine from people with normal thyroid function, they will remain normal.”

Dr. Maraka has reported no relevant financial relationships. Dr. Hennessey has reported consulting for pharmaceutical companies to design clinical studies for thyroid medications.

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

MONTREAL – Patients who discontinue levothyroxine for subclinical hypothyroidism may gravitate towards becoming mildly hypothyroid again, but they importantly show no differences in terms of symptoms and quality of life – and sometimes show even improvement – compared with those who continue treatment, new research shows.

“Our results show feasibility of patient enrollment and safety of discontinuing levothyroxine in patients with subclinical hypothyroidism,” said first author Spyridoula Maraka, MD, when presenting the findings at the American Thyroid Association annual meeting.

Recommendations against levothyroxine for subclinical hypothyroidism

Subclinical hypothyroidism is commonly over-diagnosed, and treatment with thyroid hormone replacement, levothyroxine, has been shown to provide little, if any, benefit in terms of quality of life or relief of thyroid-related symptoms for these patients.

The treatment is meanwhile associated with burdens including cost and lifestyle adjustments, and one guideline panel recently issued a strong recommendation against routine levothyroxine use in most adults with subclinical hypothyroidism.

Nevertheless, levothyroxine treatment has soared in popularity and become one of the most commonly prescribed drugs in the United States.

With research lacking on one key solution of discontinuation of the therapy, Dr. Maraka, who is part of the Division of Endocrinology and Metabolism at the University of Arkansas for Medical Sciences, Little Rock, and colleagues conducted a double-blind, placebo-controlled trial at the Central Arkansas Veterans Healthcare System. In total, 50 patients treated for subclinical hypothyroidism were randomized 1:1 to continue receiving levothyroxine (25-75 mcg daily) or to discontinue treatment and receive a placebo instead, with a planned 6-month follow-up.

In the current interim analysis, Dr. Maraka reported results for the first 40 patients, including 20 randomized to levothyroxine and 20 to discontinuation.

There were no significant differences between the discontinuation and levothyroxine groups at baseline, which were of a similar age (66.2 vs. 70.8 years) and gender (75% women vs. 85% men).

The groups had similar baseline thyroid-stimulating hormone (TSH) levels (3.0 vs. 2.6 mIU/L), free T4 (both 0.9 ng/dL), thyroid peroxidase antibody positivity (17% vs. 11%), and similar clinical symptoms. All patients had at least one elevated TSH reading prior to starting levothyroxine.

With a follow-up of 6-8 weeks, 36.8% of patients in the discontinuation group had subclinical hypothyroidism, compared with 10% of patients who remained on levothyroxine (P = .0648), TSH levels were 5.5 versus 2.7 mIU/L (P = .001) and free T4 levels were 0.8 versus 0.9 ng/dL (P = .011).
 

No differences in symptoms, quality of life between groups

Importantly, there were no significant differences between the discontinuation versus levothyroxine groups in terms of symptoms, and even some improvements with discontinuation, including Thyroid-Specific Quality of Life Patient-Reported Outcome (ThyPRO)-Hypothyroid Symptoms score (4.6 reduction vs. 2.2 increase), tiredness (2.6 reduction vs. 1.1 increase), and EuroQoL 5-Dimension Self-Report Questionnaire (EQ-5D) quality of life score, for which there were no differences between groups.

There were no reports of overt hypothyroidism; hyperthyroidism; cardiovascular events including atrial fibrillation, stroke, or heart failure; osteoporotic fractures; or deaths.

One patient in the discontinuation group had a TSH level of 11 mIU/L at 6-8 weeks and switched to open-label levothyroxine 75 mcg daily. Another patient in the discontinuation group switched to open-label levothyroxine 75 mcg daily at 10 weeks due to fatigue; however, the patient was diagnosed with metastatic colon cancer 1 month later.

The finding that only about a third of patients who discontinued levothyroxine developed subclinical hypothyroidism was lower than expected, Dr. Maraka noted.

“This was ... unexpected ... for us,” she said. “We were expecting a larger number of patients to develop hypothyroidism, but to our surprise, that was not the case.”

“But what is more important is that there was no difference in the quality of life measures,” she added. “If anything, the placebo group was a little better, though the [differences] were not statistically significant.”

Dr. Maraka also noted that in further research and a final 6-month analysis, the authors will look at factors associated with developing subclinical hypothyroidism after treatment discontinuation, among other issues.
 

Discontinuation of levothyroxine is manageable

The results are encouraging, as they provide assurance that discontinuation of levothyroxine is manageable.

“This research will pave the way for initiatives to promote levothyroxine deprescription and implementation of evidence-based care for patients with subclinical hypothyroidism,” she said.

In further comments, Dr. Hennessey noted that the dilemma of having patients on levothyroxine who may not be benefitting from treatment is “significant,” with patients sometimes reluctant to discontinue treatment due to concerns of developing hypothyroidism-associated symptoms such as brain fog and weight gain.

He noted, however, that “many with mildly elevated TSH actually go on to normalize with time, so they are not really hypothyroid, [and] if we remove thyroxine from people with normal thyroid function, they will remain normal.”

Dr. Maraka has reported no relevant financial relationships. Dr. Hennessey has reported consulting for pharmaceutical companies to design clinical studies for thyroid medications.

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

An international group representing leading endocrinology associations has recommended that the name “diabetes insipidus” – which in some cases has led to harm – be changed to eliminate confusion with “diabetes mellitus” and to reflect the former condition’s pathophysiology.

The new proposed names are arginine vasopressin deficiency (AVP-D) for central (also called “cranial”) etiologies and arginine vasopressin resistance (AVP-R) for nephrogenic (kidney) etiologies.

“What we’re proposing is to rename the disease according to the pathophysiology that defines it,” statement co-author Joseph G. Verbalis, MD, professor of medicine and chief of endocrinology and metabolism at Georgetown University Medical Center, Washington, told this news organization.

The statement advises that henceforth the new names be used in manuscripts and the medical literature while keeping the old names in parentheses during a transition period, as in “AVP-deficiency (cranial diabetes insipidus)” and “AVP-resistance (nephrogenic diabetes insipidus).”

The condition formerly known as diabetes insipidus is relatively rare, occurring in about 1 person per 10-15,000 population. It is caused by either deficient production or resistance in the kidney to the hormone AVP, normally produced by the hypothalamus and stored in the pituitary gland. AVP, also called antidiuretic hormone, regulates the body’s water level and urine production by the kidney.

Both etiologies lead to extreme thirst and excessive production of urine. Common causes of the deficiency include head trauma or brain tumor, while resistance in the kidney is often congenital. It is currently treated with a synthetic form of AVP called desmopressin and fluid replacement.
 

What’s in a name?

The proposal to change the name by the Working Group for Renaming Diabetes Insipidus is endorsed by The Endocrine Society, European Society of Endocrinology, Pituitary Society, Society for Endocrinology, European Society for Paediatric Endocrinology, Endocrine Society of Australia, Brazilian Endocrine Society, and Japanese Endocrine Society and is under review by several other societies. It was published as a position statement in several of those society’s journals, with more to follow.

Historically, the word “diabetes,” a Greek word meaning “siphon,” was used in the 1st and 2nd century BC to describe excess flow of urine. The Latin word “mellitus” or “honey” was added in the late 17th century to describe the sweetness of the urine in the dysglycemic condition.

A century later, the Latin word “insipidus,” meaning insipid or tasteless, was coined to distinguish between the two types of polyuria, the position statement details.

In the late 19th to early 20th century, the vasopressor and antidiuretic actions of posterior pituitary extracts were discovered and used to treat people with both the central and nephrogenic etiologies, which were also recognized around that time, yet the name “diabetes insipidus” has persisted.

“From a historical perspective, the name is perfectly appropriate. At the time it was identified, and it was realized that it was different from diabetes mellitus, that was a perfectly appropriate terminology based on what was known in the late 19th century – but not now. It has persisted through the years simply because in medicine there’s a lot of inertia for change ... It’s just always been called that. If there’s not a compelling reason to change a name, generally there’s no move to change it,” Dr. Verbalis observed.  
 

‘Dramatic cases of patient mismanagement’ due to name confusion

Unfortunately, the urgency for the change arose from tragedy. In 2009, a 22-year-old man was admitted to the orthopedics department of a London teaching hospital for a hip replacement. Despite his known panhypopituitarism and diabetes insipidus, the nurses continually checked his blood glucose but didn’t give him desmopressin or sufficient fluids. Laboratory testing showed normal glucose, but his serum sodium was 149 mmol/L. The morning after his operation, he had a fatal cardiac arrest with a serum sodium of 169 mmol/L. 

“The nurses thought he had diabetes mellitus ... So that was death due to failure to recognize that diabetes insipidus is not diabetes mellitus,” Dr. Verbalis said. “If he had been admitted to endocrinology, this wouldn’t have happened. But he was admitted to orthopedics. Non-endocrinologists are not so aware of diabetes insipidus, because it is a rare disease.”

In 2016, National Health Service England issued a patient safety alert about the “risk of severe harm or death when desmopressin is omitted or delayed in patients with cranial diabetes insipidus,” citing at least four incidents within the prior 7 years where omission of desmopressin had resulted in severe dehydration and death, with another 76 cases of omission or delay that were acted on before the patients became critically ill.

Further impetus for the name change came from the results of an anonymous web-based survey of 1,034 adult and pediatric patients with central diabetes insipidus conducted between August 2021 and February 2022. Overall, 80% reported encountering situations in which their condition had been confused with diabetes mellitus by health care professionals, and 85% supported renaming the disease.

There was some divergence in opinion as to what the new name(s) should be, but clear agreement that the term “diabetes” should not be part of it.  

“We’ve only become recently aware that there are dramatic cases of patient mismanagement due to the confusion caused by the word ‘diabetes.’ We think patients should have a voice. If a legitimate patient survey says over 80% think this name should be changed, then I think we as endocrinologists need to pay attention to that,” Dr. Verbalis said.

But while endocrinologists are the ones who see these patients the most often, Dr. Verbalis said a main aim of the position statement “is really to change the mindset of non-endocrinologist doctors and nurses and other health care professionals that this is not diabetes mellitus. It’s a totally different disease. And if we give it a totally different name, then I think they will better recognize that.”

As to how long Dr. Verbalis thinks it will take for the new names to catch on, he pointed out that it’s taken about a decade for the rheumatology field to fully adopt the name “granulomatosis with polyangiitis” as a replacement for “Wegener’s granulomatosis” after the eponymous physician’s Nazi ties were revealed.

“So we’re not anticipating that this is going to change terminology tomorrow. It’s a long process. We just wanted to get the process started,” he said.

Dr. Verbalis has reported consulting for Otsuka.

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

An international group representing leading endocrinology associations has recommended that the name “diabetes insipidus” – which in some cases has led to harm – be changed to eliminate confusion with “diabetes mellitus” and to reflect the former condition’s pathophysiology.

The new proposed names are arginine vasopressin deficiency (AVP-D) for central (also called “cranial”) etiologies and arginine vasopressin resistance (AVP-R) for nephrogenic (kidney) etiologies.

“What we’re proposing is to rename the disease according to the pathophysiology that defines it,” statement co-author Joseph G. Verbalis, MD, professor of medicine and chief of endocrinology and metabolism at Georgetown University Medical Center, Washington, told this news organization.

The statement advises that henceforth the new names be used in manuscripts and the medical literature while keeping the old names in parentheses during a transition period, as in “AVP-deficiency (cranial diabetes insipidus)” and “AVP-resistance (nephrogenic diabetes insipidus).”

The condition formerly known as diabetes insipidus is relatively rare, occurring in about 1 person per 10-15,000 population. It is caused by either deficient production or resistance in the kidney to the hormone AVP, normally produced by the hypothalamus and stored in the pituitary gland. AVP, also called antidiuretic hormone, regulates the body’s water level and urine production by the kidney.

Both etiologies lead to extreme thirst and excessive production of urine. Common causes of the deficiency include head trauma or brain tumor, while resistance in the kidney is often congenital. It is currently treated with a synthetic form of AVP called desmopressin and fluid replacement.
 

What’s in a name?

The proposal to change the name by the Working Group for Renaming Diabetes Insipidus is endorsed by The Endocrine Society, European Society of Endocrinology, Pituitary Society, Society for Endocrinology, European Society for Paediatric Endocrinology, Endocrine Society of Australia, Brazilian Endocrine Society, and Japanese Endocrine Society and is under review by several other societies. It was published as a position statement in several of those society’s journals, with more to follow.

Historically, the word “diabetes,” a Greek word meaning “siphon,” was used in the 1st and 2nd century BC to describe excess flow of urine. The Latin word “mellitus” or “honey” was added in the late 17th century to describe the sweetness of the urine in the dysglycemic condition.

A century later, the Latin word “insipidus,” meaning insipid or tasteless, was coined to distinguish between the two types of polyuria, the position statement details.

In the late 19th to early 20th century, the vasopressor and antidiuretic actions of posterior pituitary extracts were discovered and used to treat people with both the central and nephrogenic etiologies, which were also recognized around that time, yet the name “diabetes insipidus” has persisted.

“From a historical perspective, the name is perfectly appropriate. At the time it was identified, and it was realized that it was different from diabetes mellitus, that was a perfectly appropriate terminology based on what was known in the late 19th century – but not now. It has persisted through the years simply because in medicine there’s a lot of inertia for change ... It’s just always been called that. If there’s not a compelling reason to change a name, generally there’s no move to change it,” Dr. Verbalis observed.  
 

‘Dramatic cases of patient mismanagement’ due to name confusion

Unfortunately, the urgency for the change arose from tragedy. In 2009, a 22-year-old man was admitted to the orthopedics department of a London teaching hospital for a hip replacement. Despite his known panhypopituitarism and diabetes insipidus, the nurses continually checked his blood glucose but didn’t give him desmopressin or sufficient fluids. Laboratory testing showed normal glucose, but his serum sodium was 149 mmol/L. The morning after his operation, he had a fatal cardiac arrest with a serum sodium of 169 mmol/L. 

“The nurses thought he had diabetes mellitus ... So that was death due to failure to recognize that diabetes insipidus is not diabetes mellitus,” Dr. Verbalis said. “If he had been admitted to endocrinology, this wouldn’t have happened. But he was admitted to orthopedics. Non-endocrinologists are not so aware of diabetes insipidus, because it is a rare disease.”

In 2016, National Health Service England issued a patient safety alert about the “risk of severe harm or death when desmopressin is omitted or delayed in patients with cranial diabetes insipidus,” citing at least four incidents within the prior 7 years where omission of desmopressin had resulted in severe dehydration and death, with another 76 cases of omission or delay that were acted on before the patients became critically ill.

Further impetus for the name change came from the results of an anonymous web-based survey of 1,034 adult and pediatric patients with central diabetes insipidus conducted between August 2021 and February 2022. Overall, 80% reported encountering situations in which their condition had been confused with diabetes mellitus by health care professionals, and 85% supported renaming the disease.

There was some divergence in opinion as to what the new name(s) should be, but clear agreement that the term “diabetes” should not be part of it.  

“We’ve only become recently aware that there are dramatic cases of patient mismanagement due to the confusion caused by the word ‘diabetes.’ We think patients should have a voice. If a legitimate patient survey says over 80% think this name should be changed, then I think we as endocrinologists need to pay attention to that,” Dr. Verbalis said.

But while endocrinologists are the ones who see these patients the most often, Dr. Verbalis said a main aim of the position statement “is really to change the mindset of non-endocrinologist doctors and nurses and other health care professionals that this is not diabetes mellitus. It’s a totally different disease. And if we give it a totally different name, then I think they will better recognize that.”

As to how long Dr. Verbalis thinks it will take for the new names to catch on, he pointed out that it’s taken about a decade for the rheumatology field to fully adopt the name “granulomatosis with polyangiitis” as a replacement for “Wegener’s granulomatosis” after the eponymous physician’s Nazi ties were revealed.

“So we’re not anticipating that this is going to change terminology tomorrow. It’s a long process. We just wanted to get the process started,” he said.

Dr. Verbalis has reported consulting for Otsuka.

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

An international group representing leading endocrinology associations has recommended that the name “diabetes insipidus” – which in some cases has led to harm – be changed to eliminate confusion with “diabetes mellitus” and to reflect the former condition’s pathophysiology.

The new proposed names are arginine vasopressin deficiency (AVP-D) for central (also called “cranial”) etiologies and arginine vasopressin resistance (AVP-R) for nephrogenic (kidney) etiologies.

“What we’re proposing is to rename the disease according to the pathophysiology that defines it,” statement co-author Joseph G. Verbalis, MD, professor of medicine and chief of endocrinology and metabolism at Georgetown University Medical Center, Washington, told this news organization.

The statement advises that henceforth the new names be used in manuscripts and the medical literature while keeping the old names in parentheses during a transition period, as in “AVP-deficiency (cranial diabetes insipidus)” and “AVP-resistance (nephrogenic diabetes insipidus).”

The condition formerly known as diabetes insipidus is relatively rare, occurring in about 1 person per 10-15,000 population. It is caused by either deficient production or resistance in the kidney to the hormone AVP, normally produced by the hypothalamus and stored in the pituitary gland. AVP, also called antidiuretic hormone, regulates the body’s water level and urine production by the kidney.

Both etiologies lead to extreme thirst and excessive production of urine. Common causes of the deficiency include head trauma or brain tumor, while resistance in the kidney is often congenital. It is currently treated with a synthetic form of AVP called desmopressin and fluid replacement.
 

What’s in a name?

The proposal to change the name by the Working Group for Renaming Diabetes Insipidus is endorsed by The Endocrine Society, European Society of Endocrinology, Pituitary Society, Society for Endocrinology, European Society for Paediatric Endocrinology, Endocrine Society of Australia, Brazilian Endocrine Society, and Japanese Endocrine Society and is under review by several other societies. It was published as a position statement in several of those society’s journals, with more to follow.

Historically, the word “diabetes,” a Greek word meaning “siphon,” was used in the 1st and 2nd century BC to describe excess flow of urine. The Latin word “mellitus” or “honey” was added in the late 17th century to describe the sweetness of the urine in the dysglycemic condition.

A century later, the Latin word “insipidus,” meaning insipid or tasteless, was coined to distinguish between the two types of polyuria, the position statement details.

In the late 19th to early 20th century, the vasopressor and antidiuretic actions of posterior pituitary extracts were discovered and used to treat people with both the central and nephrogenic etiologies, which were also recognized around that time, yet the name “diabetes insipidus” has persisted.

“From a historical perspective, the name is perfectly appropriate. At the time it was identified, and it was realized that it was different from diabetes mellitus, that was a perfectly appropriate terminology based on what was known in the late 19th century – but not now. It has persisted through the years simply because in medicine there’s a lot of inertia for change ... It’s just always been called that. If there’s not a compelling reason to change a name, generally there’s no move to change it,” Dr. Verbalis observed.  
 

‘Dramatic cases of patient mismanagement’ due to name confusion

Unfortunately, the urgency for the change arose from tragedy. In 2009, a 22-year-old man was admitted to the orthopedics department of a London teaching hospital for a hip replacement. Despite his known panhypopituitarism and diabetes insipidus, the nurses continually checked his blood glucose but didn’t give him desmopressin or sufficient fluids. Laboratory testing showed normal glucose, but his serum sodium was 149 mmol/L. The morning after his operation, he had a fatal cardiac arrest with a serum sodium of 169 mmol/L. 

“The nurses thought he had diabetes mellitus ... So that was death due to failure to recognize that diabetes insipidus is not diabetes mellitus,” Dr. Verbalis said. “If he had been admitted to endocrinology, this wouldn’t have happened. But he was admitted to orthopedics. Non-endocrinologists are not so aware of diabetes insipidus, because it is a rare disease.”

In 2016, National Health Service England issued a patient safety alert about the “risk of severe harm or death when desmopressin is omitted or delayed in patients with cranial diabetes insipidus,” citing at least four incidents within the prior 7 years where omission of desmopressin had resulted in severe dehydration and death, with another 76 cases of omission or delay that were acted on before the patients became critically ill.

Further impetus for the name change came from the results of an anonymous web-based survey of 1,034 adult and pediatric patients with central diabetes insipidus conducted between August 2021 and February 2022. Overall, 80% reported encountering situations in which their condition had been confused with diabetes mellitus by health care professionals, and 85% supported renaming the disease.

There was some divergence in opinion as to what the new name(s) should be, but clear agreement that the term “diabetes” should not be part of it.  

“We’ve only become recently aware that there are dramatic cases of patient mismanagement due to the confusion caused by the word ‘diabetes.’ We think patients should have a voice. If a legitimate patient survey says over 80% think this name should be changed, then I think we as endocrinologists need to pay attention to that,” Dr. Verbalis said.

But while endocrinologists are the ones who see these patients the most often, Dr. Verbalis said a main aim of the position statement “is really to change the mindset of non-endocrinologist doctors and nurses and other health care professionals that this is not diabetes mellitus. It’s a totally different disease. And if we give it a totally different name, then I think they will better recognize that.”

As to how long Dr. Verbalis thinks it will take for the new names to catch on, he pointed out that it’s taken about a decade for the rheumatology field to fully adopt the name “granulomatosis with polyangiitis” as a replacement for “Wegener’s granulomatosis” after the eponymous physician’s Nazi ties were revealed.

“So we’re not anticipating that this is going to change terminology tomorrow. It’s a long process. We just wanted to get the process started,” he said.

Dr. Verbalis has reported consulting for Otsuka.

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

What you really don’t want to do, if you want to improve diversity, equity, and inclusion (DEI) at your academic institution, is to recruit diverse people to your program and then have them come and feel not included, said Vivian Asare, MD. “That can work against your efforts,” she stated in an oral presentation at the annual meeting of the American College of Chest Physicians (CHEST). Dr. Asare is assistant professor and vice chief of DEI for Yale Pulmonary, Critical Care, and Sleep Medicine, and associate medical director of Yale Centers for Sleep Medicine, New Haven, Conn.

In offering a path to successful DEI, Dr. Asare said: “The first step is to build a team and discuss your mission. Invite everyone to participate and include your leadership because they’re the ones who set the stage, ensure sustainability, and can be a liaison with faculty.” Then a DEI leader should be elected, she added.

The next and very important step is to survey the current institutional climate. “You need to tap into how people feel about DEI in your program.” That entails speaking directly with the stakeholders (faculty, staff, trainees) and identifying their specific concerns and what they think is lacking. Retreats, serious group discussions, and self-reflecting (asking “what initiatives would be good for us?”), and meeting one-on-one with individuals for a truly personalized approach are among potentially productive strategies for identifying the priorities and DEI-related topics specific to a particular academic sleep program.

Dr. Asare offered up a sample DEI survey (Am J Obstet Gynecol. 2020 Nov;223[5]:715.e1-715.e7), that made direct statements inviting the respondent to check off one of the following responses: Yes, No, Somewhat, Do not know, and Not applicable. Among sample statements:

• Our department is actively committed to issues of diversity, equity, and inclusion.
• Faculty searches in the department regularly attract a diverse pool of highly qualified candidates and/or attract a pool that represents the availability of MDs in this field.
• Our outreach and recruitment processes employ targeted practices for attracting diverse populations.

Dr. Asare said that a survey can be a simple approach for garnering information that can be useful for prioritizing DEI topics of concern and igniting interest in them. Engagement requires regular DEI committee meetings with minutes or a newsletter and with updates and topics brought to faculty meetings.
 

Key DEI areas of focus

Dr. Asare listed several key DEI areas: Recruitment/retention, mentorship, scholarship, and inclusion and community engagement. Under scholarship, for example, she cited topics for potential inclusion in a DEI curriculum: Unconscious bias and anti-racism training, racism, discrimination and microaggression education (bystander/deescalation training), cultural competency and awareness, workplace civility, and health disparities. “We all know that implicit bias in providers is a reality, unfortunately,” Dr. Asare said. Being aware of these implicit biases is a start, but instruction on how to actively overcome them has to be provided. Tools may include perspective-taking, exploring common identity, and self-reflection.

To create an inclusive environment for all faculty, trainees, and staff may involve establishing a “welcome committee” for new faculty, perhaps with designating a “peer buddy,” creating social events and other opportunities for all opinions and ideas to be heard and valued. Particularly for underserved and disadvantaged patient populations, patient advocacy and community service need to be fostered through support groups and provision of resources.

Summarizing, Dr. Asare reiterated several key elements for a successful DEI program: Build a team and discuss the mission, survey the current climate allowing open communication and dialogue, plan and engage, organize, and form areas of DEI focus. Find out where you are and where you want to be with respect to DEI, she concluded.

Dr. Asare declared that she had no conflicts of interest.

What you really don’t want to do, if you want to improve diversity, equity, and inclusion (DEI) at your academic institution, is to recruit diverse people to your program and then have them come and feel not included, said Vivian Asare, MD. “That can work against your efforts,” she stated in an oral presentation at the annual meeting of the American College of Chest Physicians (CHEST). Dr. Asare is assistant professor and vice chief of DEI for Yale Pulmonary, Critical Care, and Sleep Medicine, and associate medical director of Yale Centers for Sleep Medicine, New Haven, Conn.

In offering a path to successful DEI, Dr. Asare said: “The first step is to build a team and discuss your mission. Invite everyone to participate and include your leadership because they’re the ones who set the stage, ensure sustainability, and can be a liaison with faculty.” Then a DEI leader should be elected, she added.

The next and very important step is to survey the current institutional climate. “You need to tap into how people feel about DEI in your program.” That entails speaking directly with the stakeholders (faculty, staff, trainees) and identifying their specific concerns and what they think is lacking. Retreats, serious group discussions, and self-reflecting (asking “what initiatives would be good for us?”), and meeting one-on-one with individuals for a truly personalized approach are among potentially productive strategies for identifying the priorities and DEI-related topics specific to a particular academic sleep program.

Dr. Asare offered up a sample DEI survey (Am J Obstet Gynecol. 2020 Nov;223[5]:715.e1-715.e7), that made direct statements inviting the respondent to check off one of the following responses: Yes, No, Somewhat, Do not know, and Not applicable. Among sample statements:

• Our department is actively committed to issues of diversity, equity, and inclusion.
• Faculty searches in the department regularly attract a diverse pool of highly qualified candidates and/or attract a pool that represents the availability of MDs in this field.
• Our outreach and recruitment processes employ targeted practices for attracting diverse populations.

Dr. Asare said that a survey can be a simple approach for garnering information that can be useful for prioritizing DEI topics of concern and igniting interest in them. Engagement requires regular DEI committee meetings with minutes or a newsletter and with updates and topics brought to faculty meetings.
 

Key DEI areas of focus

Dr. Asare listed several key DEI areas: Recruitment/retention, mentorship, scholarship, and inclusion and community engagement. Under scholarship, for example, she cited topics for potential inclusion in a DEI curriculum: Unconscious bias and anti-racism training, racism, discrimination and microaggression education (bystander/deescalation training), cultural competency and awareness, workplace civility, and health disparities. “We all know that implicit bias in providers is a reality, unfortunately,” Dr. Asare said. Being aware of these implicit biases is a start, but instruction on how to actively overcome them has to be provided. Tools may include perspective-taking, exploring common identity, and self-reflection.

To create an inclusive environment for all faculty, trainees, and staff may involve establishing a “welcome committee” for new faculty, perhaps with designating a “peer buddy,” creating social events and other opportunities for all opinions and ideas to be heard and valued. Particularly for underserved and disadvantaged patient populations, patient advocacy and community service need to be fostered through support groups and provision of resources.

Summarizing, Dr. Asare reiterated several key elements for a successful DEI program: Build a team and discuss the mission, survey the current climate allowing open communication and dialogue, plan and engage, organize, and form areas of DEI focus. Find out where you are and where you want to be with respect to DEI, she concluded.

Dr. Asare declared that she had no conflicts of interest.

What you really don’t want to do, if you want to improve diversity, equity, and inclusion (DEI) at your academic institution, is to recruit diverse people to your program and then have them come and feel not included, said Vivian Asare, MD. “That can work against your efforts,” she stated in an oral presentation at the annual meeting of the American College of Chest Physicians (CHEST). Dr. Asare is assistant professor and vice chief of DEI for Yale Pulmonary, Critical Care, and Sleep Medicine, and associate medical director of Yale Centers for Sleep Medicine, New Haven, Conn.

In offering a path to successful DEI, Dr. Asare said: “The first step is to build a team and discuss your mission. Invite everyone to participate and include your leadership because they’re the ones who set the stage, ensure sustainability, and can be a liaison with faculty.” Then a DEI leader should be elected, she added.

The next and very important step is to survey the current institutional climate. “You need to tap into how people feel about DEI in your program.” That entails speaking directly with the stakeholders (faculty, staff, trainees) and identifying their specific concerns and what they think is lacking. Retreats, serious group discussions, and self-reflecting (asking “what initiatives would be good for us?”), and meeting one-on-one with individuals for a truly personalized approach are among potentially productive strategies for identifying the priorities and DEI-related topics specific to a particular academic sleep program.

Dr. Asare offered up a sample DEI survey (Am J Obstet Gynecol. 2020 Nov;223[5]:715.e1-715.e7), that made direct statements inviting the respondent to check off one of the following responses: Yes, No, Somewhat, Do not know, and Not applicable. Among sample statements:

• Our department is actively committed to issues of diversity, equity, and inclusion.
• Faculty searches in the department regularly attract a diverse pool of highly qualified candidates and/or attract a pool that represents the availability of MDs in this field.
• Our outreach and recruitment processes employ targeted practices for attracting diverse populations.

Dr. Asare said that a survey can be a simple approach for garnering information that can be useful for prioritizing DEI topics of concern and igniting interest in them. Engagement requires regular DEI committee meetings with minutes or a newsletter and with updates and topics brought to faculty meetings.
 

Key DEI areas of focus

Dr. Asare listed several key DEI areas: Recruitment/retention, mentorship, scholarship, and inclusion and community engagement. Under scholarship, for example, she cited topics for potential inclusion in a DEI curriculum: Unconscious bias and anti-racism training, racism, discrimination and microaggression education (bystander/deescalation training), cultural competency and awareness, workplace civility, and health disparities. “We all know that implicit bias in providers is a reality, unfortunately,” Dr. Asare said. Being aware of these implicit biases is a start, but instruction on how to actively overcome them has to be provided. Tools may include perspective-taking, exploring common identity, and self-reflection.

To create an inclusive environment for all faculty, trainees, and staff may involve establishing a “welcome committee” for new faculty, perhaps with designating a “peer buddy,” creating social events and other opportunities for all opinions and ideas to be heard and valued. Particularly for underserved and disadvantaged patient populations, patient advocacy and community service need to be fostered through support groups and provision of resources.

Summarizing, Dr. Asare reiterated several key elements for a successful DEI program: Build a team and discuss the mission, survey the current climate allowing open communication and dialogue, plan and engage, organize, and form areas of DEI focus. Find out where you are and where you want to be with respect to DEI, she concluded.

Dr. Asare declared that she had no conflicts of interest.

Most adolescents with gender dysphoria who took puberty-blocking drugs for at least 3 months and then progressed to cross-sex hormone treatment were still taking hormones as they entered adulthood, new research of patients at a pioneering Dutch clinic shows.

The study negates past findings that large numbers of youth regret transitioning, say Maria Anna Theodora Catharina van der Loos, MD, and colleagues from the Centre of Expertise on Gender Dysphoria, Amsterdam, in their article published online in The Lancet Child & Adolescent Health. They believe the difference between their findings and those of other studies lies in proper diagnostic evaluation.

“The study aims to demonstrate, with a methodology that is more than adequate, that transgender people who begin their transition in childhood-adolescence do not give up,” Adrián Carrasco Munera, MD, a specialist in family and community medicine and member of the LGTBIQ+ Health Group of the Madrid Society of Family and Community Medicine told the UK Science Media Centre.

The cohort included 720 youth: 220 (31%) were assigned male at birth (AMAB) and 500 (69%) were assigned female at birth (AFAB). At the start of puberty-blocking treatment with a gonadotrophin-releasing hormone agonist, the median age of patients was 14.1 years for AMAB and 16.0 years for AFAB.

Of that cohort, 704 (98%) continued hormone therapy to the end of data collection (Dec. 31, 2018), at which point the median age of patients was 20 years for AMAB and 19 years for AFAB.

Careful consideration of patient needs

All the patients received care at the “Dutch Clinic,” which more than 20 years ago pioneered the approach of giving puberty-blocking drugs to children looking to transition, followed by cross-sex hormones. The study includes the “complete adolescent population” at the facility who met the inclusion criteria.

A similar U.S. study published earlier this year found that 74.4% of individuals who had started gender-affirming hormones before age 18 were still on them 4 years after starting medical treatment.

“However, it is unclear how many of these adolescents [in the U.S. study] used puberty-suppressing treatment before gender-affirming hormone treatment and to what extent they underwent diagnostic evaluation before initiation of medical treatment,” say Dr. van der Loos and colleagues.

She told this news organization that her clinic provides “a thorough diagnostic and mental health assessment” and discussion of fertility preservation prior to any youth being prescribed puberty blockers or cross-sex hormones.

About 40% of adolescents assessed by the gender clinic in Amsterdam go on to receive hormonal treatment.

“The gender identity unit of the Amsterdam UMC is a world leader in all aspects of transgender medicine and is governed by protocolized actions. This is reflected in the quality of the data and methodology of the study, and therefore of its conclusions,” endocrinologist Gilberto Pérez López, MD, Gregorio Marañón General University Hospital, Madrid, told the UK Science Media Centre.

“These findings can and should help and guide the current public and legal debate on the initiation of medical treatment in transgender minors.”

However, he cautioned the study is limited by the fact that the data come from a registry and they looked at only prescriptions issued and not compliance.

Another interesting thing to note in the research is that almost 70% of patients were born girls and they presented at the gender clinics later in adolescence than the natal boys.

“We don’t have a sound reason for this,” Dr. van der Loos noted.

Study limitations

She also acknowledges that the short follow-up data in some individuals make it difficult to draw conclusions about regret, to some extent.

The average use of cross-sex hormones in their study was 3.5 years for males transitioning to females and 2.3 years for females transitioning to males, so on average, this wouldn’t be long enough to see regret, she acknowledged.

Prior research shows that if youth decide to detransition to their natal sex, this can take, on average, 5 years from the start of medical therapy among born females and 7 years among born males.

However, some born males in the study had been taking hormones for 20 years and some natal females for 15 years, said Dr. van der Loos.

Another limitation is that the research only followed individuals until the end of 2018 while some government data estimate that the number of teens identifying as transgender has nearly doubled over the past 5 years.

The authors, Dr. Munera, and Dr. Lopez have reported no relevant financial relationships.

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

Most adolescents with gender dysphoria who took puberty-blocking drugs for at least 3 months and then progressed to cross-sex hormone treatment were still taking hormones as they entered adulthood, new research of patients at a pioneering Dutch clinic shows.

The study negates past findings that large numbers of youth regret transitioning, say Maria Anna Theodora Catharina van der Loos, MD, and colleagues from the Centre of Expertise on Gender Dysphoria, Amsterdam, in their article published online in The Lancet Child & Adolescent Health. They believe the difference between their findings and those of other studies lies in proper diagnostic evaluation.

“The study aims to demonstrate, with a methodology that is more than adequate, that transgender people who begin their transition in childhood-adolescence do not give up,” Adrián Carrasco Munera, MD, a specialist in family and community medicine and member of the LGTBIQ+ Health Group of the Madrid Society of Family and Community Medicine told the UK Science Media Centre.

The cohort included 720 youth: 220 (31%) were assigned male at birth (AMAB) and 500 (69%) were assigned female at birth (AFAB). At the start of puberty-blocking treatment with a gonadotrophin-releasing hormone agonist, the median age of patients was 14.1 years for AMAB and 16.0 years for AFAB.

Of that cohort, 704 (98%) continued hormone therapy to the end of data collection (Dec. 31, 2018), at which point the median age of patients was 20 years for AMAB and 19 years for AFAB.

Careful consideration of patient needs

All the patients received care at the “Dutch Clinic,” which more than 20 years ago pioneered the approach of giving puberty-blocking drugs to children looking to transition, followed by cross-sex hormones. The study includes the “complete adolescent population” at the facility who met the inclusion criteria.

A similar U.S. study published earlier this year found that 74.4% of individuals who had started gender-affirming hormones before age 18 were still on them 4 years after starting medical treatment.

“However, it is unclear how many of these adolescents [in the U.S. study] used puberty-suppressing treatment before gender-affirming hormone treatment and to what extent they underwent diagnostic evaluation before initiation of medical treatment,” say Dr. van der Loos and colleagues.

She told this news organization that her clinic provides “a thorough diagnostic and mental health assessment” and discussion of fertility preservation prior to any youth being prescribed puberty blockers or cross-sex hormones.

About 40% of adolescents assessed by the gender clinic in Amsterdam go on to receive hormonal treatment.

“The gender identity unit of the Amsterdam UMC is a world leader in all aspects of transgender medicine and is governed by protocolized actions. This is reflected in the quality of the data and methodology of the study, and therefore of its conclusions,” endocrinologist Gilberto Pérez López, MD, Gregorio Marañón General University Hospital, Madrid, told the UK Science Media Centre.

“These findings can and should help and guide the current public and legal debate on the initiation of medical treatment in transgender minors.”

However, he cautioned the study is limited by the fact that the data come from a registry and they looked at only prescriptions issued and not compliance.

Another interesting thing to note in the research is that almost 70% of patients were born girls and they presented at the gender clinics later in adolescence than the natal boys.

“We don’t have a sound reason for this,” Dr. van der Loos noted.

Study limitations

She also acknowledges that the short follow-up data in some individuals make it difficult to draw conclusions about regret, to some extent.

The average use of cross-sex hormones in their study was 3.5 years for males transitioning to females and 2.3 years for females transitioning to males, so on average, this wouldn’t be long enough to see regret, she acknowledged.

Prior research shows that if youth decide to detransition to their natal sex, this can take, on average, 5 years from the start of medical therapy among born females and 7 years among born males.

However, some born males in the study had been taking hormones for 20 years and some natal females for 15 years, said Dr. van der Loos.

Another limitation is that the research only followed individuals until the end of 2018 while some government data estimate that the number of teens identifying as transgender has nearly doubled over the past 5 years.

The authors, Dr. Munera, and Dr. Lopez have reported no relevant financial relationships.

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

Most adolescents with gender dysphoria who took puberty-blocking drugs for at least 3 months and then progressed to cross-sex hormone treatment were still taking hormones as they entered adulthood, new research of patients at a pioneering Dutch clinic shows.

The study negates past findings that large numbers of youth regret transitioning, say Maria Anna Theodora Catharina van der Loos, MD, and colleagues from the Centre of Expertise on Gender Dysphoria, Amsterdam, in their article published online in The Lancet Child & Adolescent Health. They believe the difference between their findings and those of other studies lies in proper diagnostic evaluation.

“The study aims to demonstrate, with a methodology that is more than adequate, that transgender people who begin their transition in childhood-adolescence do not give up,” Adrián Carrasco Munera, MD, a specialist in family and community medicine and member of the LGTBIQ+ Health Group of the Madrid Society of Family and Community Medicine told the UK Science Media Centre.

The cohort included 720 youth: 220 (31%) were assigned male at birth (AMAB) and 500 (69%) were assigned female at birth (AFAB). At the start of puberty-blocking treatment with a gonadotrophin-releasing hormone agonist, the median age of patients was 14.1 years for AMAB and 16.0 years for AFAB.

Of that cohort, 704 (98%) continued hormone therapy to the end of data collection (Dec. 31, 2018), at which point the median age of patients was 20 years for AMAB and 19 years for AFAB.

Careful consideration of patient needs

All the patients received care at the “Dutch Clinic,” which more than 20 years ago pioneered the approach of giving puberty-blocking drugs to children looking to transition, followed by cross-sex hormones. The study includes the “complete adolescent population” at the facility who met the inclusion criteria.

A similar U.S. study published earlier this year found that 74.4% of individuals who had started gender-affirming hormones before age 18 were still on them 4 years after starting medical treatment.

“However, it is unclear how many of these adolescents [in the U.S. study] used puberty-suppressing treatment before gender-affirming hormone treatment and to what extent they underwent diagnostic evaluation before initiation of medical treatment,” say Dr. van der Loos and colleagues.

She told this news organization that her clinic provides “a thorough diagnostic and mental health assessment” and discussion of fertility preservation prior to any youth being prescribed puberty blockers or cross-sex hormones.

About 40% of adolescents assessed by the gender clinic in Amsterdam go on to receive hormonal treatment.

“The gender identity unit of the Amsterdam UMC is a world leader in all aspects of transgender medicine and is governed by protocolized actions. This is reflected in the quality of the data and methodology of the study, and therefore of its conclusions,” endocrinologist Gilberto Pérez López, MD, Gregorio Marañón General University Hospital, Madrid, told the UK Science Media Centre.

“These findings can and should help and guide the current public and legal debate on the initiation of medical treatment in transgender minors.”

However, he cautioned the study is limited by the fact that the data come from a registry and they looked at only prescriptions issued and not compliance.

Another interesting thing to note in the research is that almost 70% of patients were born girls and they presented at the gender clinics later in adolescence than the natal boys.

“We don’t have a sound reason for this,” Dr. van der Loos noted.

Study limitations

She also acknowledges that the short follow-up data in some individuals make it difficult to draw conclusions about regret, to some extent.

The average use of cross-sex hormones in their study was 3.5 years for males transitioning to females and 2.3 years for females transitioning to males, so on average, this wouldn’t be long enough to see regret, she acknowledged.

Prior research shows that if youth decide to detransition to their natal sex, this can take, on average, 5 years from the start of medical therapy among born females and 7 years among born males.

However, some born males in the study had been taking hormones for 20 years and some natal females for 15 years, said Dr. van der Loos.

Another limitation is that the research only followed individuals until the end of 2018 while some government data estimate that the number of teens identifying as transgender has nearly doubled over the past 5 years.

The authors, Dr. Munera, and Dr. Lopez have reported no relevant financial relationships.

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

The elderly transgender population is rapidly expanding and remains significantly overlooked. Although emerging evidence provides some guidance for medical and surgical treatment for transgender youth, there is still a paucity of research directed at the management of gender-diverse elders.

To a large extent, the challenges that transgender elders face are no different from those experienced by the general elder population. Irrespective of gender identity, patients begin to undergo cognitive and physical changes, encounter difficulties with activities of daily living, suffer the loss of social networks and friends, and face end-of-life issues.¹ Attributes that contribute to successful aging in the general population include good health, social engagement and support, and having a positive outlook on life.¹ Yet, stigma surrounding gender identity and sexual orientation continues to negatively affect elder transgender people.

Many members of the LGBTQIA+ population have higher rates of obesity, sedentary lifestyle, smoking, cardiovascular disease, substance abuse, depression, suicide, and intimate partner violence than the general same-age cohort.² Compared with lesbian, gay, and bisexual elders of age-matched cohorts, transgender elders have significantly poorer overall physical health, disability, depressive symptoms, and perceived stress.²

Rates of sexually transmitted infections are also rising in the aging general population and increased by 30% between 2014 and 2017.² There have been no current studies examining these rates in the LGBTQIA+ population. As providers interact more frequently with these patients, it’s not only essential to screen for conditions such as diabetes, lipid disorders, and sexually transmitted infections, but also to evaluate current gender-affirming hormone therapy (GAHT) regimens and order appropriate screening tests.

Hormonal therapy for transfeminine patients should be continued as patients age. One of the biggest concerns providers have in continuing hormone therapy is the development of cardiovascular disease (CVD) and increasing thromboembolic risk, both of which tend to occur naturally as patients age. Overall, studies on the prevalence of CVD or stroke in gender-diverse individuals indicate an elevated risk independent of GAHT.³ While the overall rates of thromboembolic events are low in transfeminine populations, estrogen therapy does confer an increased risk. However, most transgender women who have experienced cardiac events or stroke were over the age of 50, had one or more CVD risk factors, or were using synthetic estrogens.³

How these studies affect screening is unclear. Current guidelines recommend using tailored risk-based calculators, which take into consideration the patient’s sex assigned at birth, hormone regimen, length of hormone usage, and additional modifiable risk factors, such as diabetes, obesity, and smoking.³ For transfeminine patients who want to continue GAHT but either develop a venous thromboembolism on estrogen or have increased risk for VTE, providers should consider transitioning them to a transdermal application. Patients who stay on GAHT should be counseled accordingly on the heightened risk of VTE recurrence. It is not unreasonable to consider life-long anticoagulation for patients who remain on estrogen therapy after a VTE.⁴

While exogenous estrogen exposure is one risk factor for the development of breast cancer in cisgender females, the role of GAHT in breast cancer in transgender women is ambiguous. Therefore, breast screening guidelines should follow current recommendations for cisgender female patients with some caveats. The provider must also take into consideration current estrogen dosage, the age at which hormones were initiated, and whether a patient has undergone an augmentation mammaplasty.³

Both estrogen and testosterone play an important role in bone formation and health. Patients who undergo either medical or surgical interventions that alter sex hormone production, such as GAHT, orchiectomy, or androgen blockade, may be at elevated risk for osteoporosis. Providers should take a thorough medical history to determine patients who may be at risk for osteoporosis and treat them accordingly. Overall, GAHT has a positive effect on bone mineral density. Conversely, gonadectomy, particularly if a patient is not taking GAHT, can decrease bone density. Generally, transgender women, like cisgender women, should undergo DEXA scans starting at the age of 65, with earlier screening considered if they have undergone an orchiectomy and are not currently taking GAHT.³

There is no evidence that GAHT or surgery increases the rate of prostate cancer. Providers should note that the prostate is not removed at the time of gender-affirming surgery and that malignancy or benign prostatic hypertrophy can still occur. The U.S. Preventive Services Task Force recommends that clinicians have a discussion with cisgender men between the ages of 55 and 69 about the risks and benefits of prostate-specific antigen (PSA) screening.⁵ For cisgender men aged 70 and older, the USPSTF recommends against PSA-based screening.⁵ If digital examination of the prostate is warranted for transfeminine patients, the examination is performed through the neovaginal canal.

Caring for elderly transgender patients is complex. Even though evidence guiding the management of elderly transgender patients is improving, there are still not enough definitive long-term data on this dynamic demographic. Like clinical approaches with hormonal or surgical treatments, caring for transgender elders is also multidisciplinary. Providers should be prepared to work with social workers, geriatric care physicians, endocrinologists, surgeons, and other relevant specialists to assist with potential knowledge gaps. The goals for the aging transgender population are the same as those for cisgender patients – preventing preventable diseases and reducing overall mortality so our patients can enjoy their golden years.
 

Dr. Brandt is an ob.gyn. and fellowship-trained gender-affirming surgeon in West Reading, Pa. Contact her at [email protected].

References

1. Carroll L. Psychiatr Clin N Am. 2017;40:127-40.

2. Selix NW et al. Clinical care of the aging LGBT population. J Nurse Pract. 2020;16(7):349-54.

3. World Professional Association for Transgender Health. Standards of care for the health of transgender and gender diverse people. 2022;8th version.

4. Shatzel JJ et al. Am J Hematol. 2017;92(2):204-8.

5. Wolf-Gould CS and Wolf-Gould CH. Primary and preventative care for transgender patients. In: Ferrando CA, ed. Comprehensive Care of the Transgender Patient. Philadelphia: Elsevier, 2020, p. 114-30.

The elderly transgender population is rapidly expanding and remains significantly overlooked. Although emerging evidence provides some guidance for medical and surgical treatment for transgender youth, there is still a paucity of research directed at the management of gender-diverse elders.

To a large extent, the challenges that transgender elders face are no different from those experienced by the general elder population. Irrespective of gender identity, patients begin to undergo cognitive and physical changes, encounter difficulties with activities of daily living, suffer the loss of social networks and friends, and face end-of-life issues.¹ Attributes that contribute to successful aging in the general population include good health, social engagement and support, and having a positive outlook on life.¹ Yet, stigma surrounding gender identity and sexual orientation continues to negatively affect elder transgender people.

Many members of the LGBTQIA+ population have higher rates of obesity, sedentary lifestyle, smoking, cardiovascular disease, substance abuse, depression, suicide, and intimate partner violence than the general same-age cohort.² Compared with lesbian, gay, and bisexual elders of age-matched cohorts, transgender elders have significantly poorer overall physical health, disability, depressive symptoms, and perceived stress.²

Rates of sexually transmitted infections are also rising in the aging general population and increased by 30% between 2014 and 2017.² There have been no current studies examining these rates in the LGBTQIA+ population. As providers interact more frequently with these patients, it’s not only essential to screen for conditions such as diabetes, lipid disorders, and sexually transmitted infections, but also to evaluate current gender-affirming hormone therapy (GAHT) regimens and order appropriate screening tests.

Hormonal therapy for transfeminine patients should be continued as patients age. One of the biggest concerns providers have in continuing hormone therapy is the development of cardiovascular disease (CVD) and increasing thromboembolic risk, both of which tend to occur naturally as patients age. Overall, studies on the prevalence of CVD or stroke in gender-diverse individuals indicate an elevated risk independent of GAHT.³ While the overall rates of thromboembolic events are low in transfeminine populations, estrogen therapy does confer an increased risk. However, most transgender women who have experienced cardiac events or stroke were over the age of 50, had one or more CVD risk factors, or were using synthetic estrogens.³

How these studies affect screening is unclear. Current guidelines recommend using tailored risk-based calculators, which take into consideration the patient’s sex assigned at birth, hormone regimen, length of hormone usage, and additional modifiable risk factors, such as diabetes, obesity, and smoking.³ For transfeminine patients who want to continue GAHT but either develop a venous thromboembolism on estrogen or have increased risk for VTE, providers should consider transitioning them to a transdermal application. Patients who stay on GAHT should be counseled accordingly on the heightened risk of VTE recurrence. It is not unreasonable to consider life-long anticoagulation for patients who remain on estrogen therapy after a VTE.⁴

While exogenous estrogen exposure is one risk factor for the development of breast cancer in cisgender females, the role of GAHT in breast cancer in transgender women is ambiguous. Therefore, breast screening guidelines should follow current recommendations for cisgender female patients with some caveats. The provider must also take into consideration current estrogen dosage, the age at which hormones were initiated, and whether a patient has undergone an augmentation mammaplasty.³

Both estrogen and testosterone play an important role in bone formation and health. Patients who undergo either medical or surgical interventions that alter sex hormone production, such as GAHT, orchiectomy, or androgen blockade, may be at elevated risk for osteoporosis. Providers should take a thorough medical history to determine patients who may be at risk for osteoporosis and treat them accordingly. Overall, GAHT has a positive effect on bone mineral density. Conversely, gonadectomy, particularly if a patient is not taking GAHT, can decrease bone density. Generally, transgender women, like cisgender women, should undergo DEXA scans starting at the age of 65, with earlier screening considered if they have undergone an orchiectomy and are not currently taking GAHT.³

There is no evidence that GAHT or surgery increases the rate of prostate cancer. Providers should note that the prostate is not removed at the time of gender-affirming surgery and that malignancy or benign prostatic hypertrophy can still occur. The U.S. Preventive Services Task Force recommends that clinicians have a discussion with cisgender men between the ages of 55 and 69 about the risks and benefits of prostate-specific antigen (PSA) screening.⁵ For cisgender men aged 70 and older, the USPSTF recommends against PSA-based screening.⁵ If digital examination of the prostate is warranted for transfeminine patients, the examination is performed through the neovaginal canal.

Caring for elderly transgender patients is complex. Even though evidence guiding the management of elderly transgender patients is improving, there are still not enough definitive long-term data on this dynamic demographic. Like clinical approaches with hormonal or surgical treatments, caring for transgender elders is also multidisciplinary. Providers should be prepared to work with social workers, geriatric care physicians, endocrinologists, surgeons, and other relevant specialists to assist with potential knowledge gaps. The goals for the aging transgender population are the same as those for cisgender patients – preventing preventable diseases and reducing overall mortality so our patients can enjoy their golden years.
 

Dr. Brandt is an ob.gyn. and fellowship-trained gender-affirming surgeon in West Reading, Pa. Contact her at [email protected].

References

1. Carroll L. Psychiatr Clin N Am. 2017;40:127-40.

2. Selix NW et al. Clinical care of the aging LGBT population. J Nurse Pract. 2020;16(7):349-54.

3. World Professional Association for Transgender Health. Standards of care for the health of transgender and gender diverse people. 2022;8th version.

4. Shatzel JJ et al. Am J Hematol. 2017;92(2):204-8.

5. Wolf-Gould CS and Wolf-Gould CH. Primary and preventative care for transgender patients. In: Ferrando CA, ed. Comprehensive Care of the Transgender Patient. Philadelphia: Elsevier, 2020, p. 114-30.

The elderly transgender population is rapidly expanding and remains significantly overlooked. Although emerging evidence provides some guidance for medical and surgical treatment for transgender youth, there is still a paucity of research directed at the management of gender-diverse elders.

To a large extent, the challenges that transgender elders face are no different from those experienced by the general elder population. Irrespective of gender identity, patients begin to undergo cognitive and physical changes, encounter difficulties with activities of daily living, suffer the loss of social networks and friends, and face end-of-life issues.¹ Attributes that contribute to successful aging in the general population include good health, social engagement and support, and having a positive outlook on life.¹ Yet, stigma surrounding gender identity and sexual orientation continues to negatively affect elder transgender people.

Many members of the LGBTQIA+ population have higher rates of obesity, sedentary lifestyle, smoking, cardiovascular disease, substance abuse, depression, suicide, and intimate partner violence than the general same-age cohort.² Compared with lesbian, gay, and bisexual elders of age-matched cohorts, transgender elders have significantly poorer overall physical health, disability, depressive symptoms, and perceived stress.²

Rates of sexually transmitted infections are also rising in the aging general population and increased by 30% between 2014 and 2017.² There have been no current studies examining these rates in the LGBTQIA+ population. As providers interact more frequently with these patients, it’s not only essential to screen for conditions such as diabetes, lipid disorders, and sexually transmitted infections, but also to evaluate current gender-affirming hormone therapy (GAHT) regimens and order appropriate screening tests.

Hormonal therapy for transfeminine patients should be continued as patients age. One of the biggest concerns providers have in continuing hormone therapy is the development of cardiovascular disease (CVD) and increasing thromboembolic risk, both of which tend to occur naturally as patients age. Overall, studies on the prevalence of CVD or stroke in gender-diverse individuals indicate an elevated risk independent of GAHT.³ While the overall rates of thromboembolic events are low in transfeminine populations, estrogen therapy does confer an increased risk. However, most transgender women who have experienced cardiac events or stroke were over the age of 50, had one or more CVD risk factors, or were using synthetic estrogens.³

How these studies affect screening is unclear. Current guidelines recommend using tailored risk-based calculators, which take into consideration the patient’s sex assigned at birth, hormone regimen, length of hormone usage, and additional modifiable risk factors, such as diabetes, obesity, and smoking.³ For transfeminine patients who want to continue GAHT but either develop a venous thromboembolism on estrogen or have increased risk for VTE, providers should consider transitioning them to a transdermal application. Patients who stay on GAHT should be counseled accordingly on the heightened risk of VTE recurrence. It is not unreasonable to consider life-long anticoagulation for patients who remain on estrogen therapy after a VTE.⁴

While exogenous estrogen exposure is one risk factor for the development of breast cancer in cisgender females, the role of GAHT in breast cancer in transgender women is ambiguous. Therefore, breast screening guidelines should follow current recommendations for cisgender female patients with some caveats. The provider must also take into consideration current estrogen dosage, the age at which hormones were initiated, and whether a patient has undergone an augmentation mammaplasty.³

Both estrogen and testosterone play an important role in bone formation and health. Patients who undergo either medical or surgical interventions that alter sex hormone production, such as GAHT, orchiectomy, or androgen blockade, may be at elevated risk for osteoporosis. Providers should take a thorough medical history to determine patients who may be at risk for osteoporosis and treat them accordingly. Overall, GAHT has a positive effect on bone mineral density. Conversely, gonadectomy, particularly if a patient is not taking GAHT, can decrease bone density. Generally, transgender women, like cisgender women, should undergo DEXA scans starting at the age of 65, with earlier screening considered if they have undergone an orchiectomy and are not currently taking GAHT.³

There is no evidence that GAHT or surgery increases the rate of prostate cancer. Providers should note that the prostate is not removed at the time of gender-affirming surgery and that malignancy or benign prostatic hypertrophy can still occur. The U.S. Preventive Services Task Force recommends that clinicians have a discussion with cisgender men between the ages of 55 and 69 about the risks and benefits of prostate-specific antigen (PSA) screening.⁵ For cisgender men aged 70 and older, the USPSTF recommends against PSA-based screening.⁵ If digital examination of the prostate is warranted for transfeminine patients, the examination is performed through the neovaginal canal.

Caring for elderly transgender patients is complex. Even though evidence guiding the management of elderly transgender patients is improving, there are still not enough definitive long-term data on this dynamic demographic. Like clinical approaches with hormonal or surgical treatments, caring for transgender elders is also multidisciplinary. Providers should be prepared to work with social workers, geriatric care physicians, endocrinologists, surgeons, and other relevant specialists to assist with potential knowledge gaps. The goals for the aging transgender population are the same as those for cisgender patients – preventing preventable diseases and reducing overall mortality so our patients can enjoy their golden years.
 

Dr. Brandt is an ob.gyn. and fellowship-trained gender-affirming surgeon in West Reading, Pa. Contact her at [email protected].

References

1. Carroll L. Psychiatr Clin N Am. 2017;40:127-40.

2. Selix NW et al. Clinical care of the aging LGBT population. J Nurse Pract. 2020;16(7):349-54.

3. World Professional Association for Transgender Health. Standards of care for the health of transgender and gender diverse people. 2022;8th version.

4. Shatzel JJ et al. Am J Hematol. 2017;92(2):204-8.

5. Wolf-Gould CS and Wolf-Gould CH. Primary and preventative care for transgender patients. In: Ferrando CA, ed. Comprehensive Care of the Transgender Patient. Philadelphia: Elsevier, 2020, p. 114-30.

MONTREAL – Amid common patient concerns about weight gain in the treatment of hyperthyroidism, findings from a large study suggest the therapy with the most favorable survival rate – radioiodine – is not associated with an increased risk of weight gain or obesity.

“EGRET is the first large study using population-based linked community and hospital data to elucidate the long-term consequences of treatment modalities for hyperthyroidism,” said co-author Kristien Boelaert, MD, PhD, while presenting the research at the American Thyroid Association annual meeting.

“The administration of [radioiodine] for hyperthyroidism is associated with a survival benefit for patients with hyperthyroidism and is not associated with increased risks of becoming obese,” Dr. Boelaert, a professor of endocrinology and consultant endocrinologist with the Institute of Applied Health Research, University of Birmingham, England, told this news organization.

However, “overall, there was a nearly 10% risk of major adverse cardiac events [MACE] in patients with hyperthyroidism regardless of the treatment modality used,” she noted.

Commenting on the findings, Jonathon O. Russell, MD, said the study offers surprising – but encouraging – results.

The discovery that radioiodine shows no increase in weight gain “contradicts numerous previous studies which have consistently demonstrated weight gain following definitive radioiodine,” Dr. Russell told this news organization.

Overall, however, “these findings reinforce our knowledge that definitive treatment of an overactive thyroid leads to a longer life – even if there is some weight gain,” added Dr. Russell, who is chief of the Division of Head and Neck Endocrine Surgery at Johns Hopkins, Baltimore.
 

Hyperthyroidism associated with serious long-term cardiometabolic issues

Hyperthyroidism is associated with serious long-term cardiovascular and metabolic morbidity and mortality, and treatment is therefore essential. However, the swing to hypothyroidism that often occurs afterward commonly results in regaining the weight lost due to the hyperthyroidism, if not more, potentially leading to obesity and its attendant health risks.

To investigate those risks in relation to the three key hyperthyroidism treatments, the authors conducted the EGRET trial. They identified 62,474 patients in the United Kingdom population-based electronic health record database who had newly diagnosed hyperthyroidism and were treated with antithyroid drugs (73.4%), radioiodine (19.5%), or thyroidectomy (7.1%) between April 1997 and December 2015.

Exclusion criteria included those with less than 6 months of antithyroid drugs as the only form of treatment, thyroid cancer, or pregnancy during the first episode.

With a median follow-up of about 8 years, those who were treated with thyroidectomy had a significantly increased risk of gaining weight, compared with the general population (P < .001), and of developing obesity (body mass index > 30 kg/m2; P = .003), while the corresponding increases with antithyroid drugs and radioiodine were not significantly different, compared with the general population over the same period.

In terms of survival, with an average follow-up of about 11 years per person, about 14% of the cohort died, with rates of 14.4% in the antithyroid drug group, 15.8% in the radioiodine group, and 9.2% in the thyroidectomy group.

Mortality rates were further assessed based on an average treatment effects analysis in which the average change was estimated, compared with the index of antithyroid drugs – for instance, if all were treated instead with radioiodine. In that extension of life analysis, those treated with radioiodine could be expected to die, on average, 1.2 years later than those taking antithyroid drugs (P < .001), while those treated with thyroidectomy would be expected to die 0.6 years later, which was not statistically significant.

Using the same average treatment effects analysis, Dr. Boelaert noted, “we found a slightly increased risk of major adverse cardiovascular events following radioiodine, compared with antithyroid drugs; [however], the risk was very small and may not be clinically relevant.”

“Previous data from our and other groups have shown reduced risks of mortality and cardiovascular death following radioiodine-induced hypothyroidism, although this is not confirmed in all studies.”
 

Weight gain after hyperthyroid treatment drives concerns

The findings are important because weight gain associated with hyperthyroidism treatment is no small matter for many patients, even prompting a lack of adherence to therapy for some, despite its importance, Dr. Boelaert noted.

“Since the majority of patients lose weight as a consequence of being hyperthyroid, it can be expected that they will at least regain the lost weight and possibly even have a weight overshoot,” she explained. “Indeed, many patients are reluctant to accept definitive treatment with surgery or radioiodine out of fear of weight gain.”

“This may cause difficulties to some patients who occasionally may even stop taking antithyroid drugs to prevent this weight regain. Such lack of adherence may have dire consequences and is likely a contributing factor to the increased mortality in these patients,” she observed.

In a previous study of 1,373 patients, Dr. Boelaert and colleagues found that men treated for hyperthyroidism gained an average of 8.0 kg (17.6 lb), and women gained an average of 5.5 kg (12.1 lb).

Compared with the background population, men were significantly more likely to gain weight over the study period (odds ratio, 1.7; P < .001) as were women (OR, 1.3; P < .001). Also in that study, radioiodine was associated with greater weight gain (0.6 kg; P < .001), compared with antithyroid drug treatment alone.

Dr. Russell added that even when weight gain does occur, the payoff of having treated the potentially serious state of hyperthyroidism is a highly beneficial trade-off.

Ultimately, “the goal of treating any patient with Graves’ should be to get them to become hypothyroid as quickly as possible,” he said. “Patients have options, and all of these options can be safe in the right situation.”

“It is unrealistic to think that going from a hyperthyroid state to a low thyroid state will not result in weight gain for many patients,” Dr. Russell added. “But the key point is that overall health is better despite this weight gain.”

Dr. Boelaert has disclosed consulting fees paid to the University of Birmingham by Lilly and Eisai. Dr. Russell has reported no relevant financial relationships.

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

MONTREAL – Amid common patient concerns about weight gain in the treatment of hyperthyroidism, findings from a large study suggest the therapy with the most favorable survival rate – radioiodine – is not associated with an increased risk of weight gain or obesity.

“EGRET is the first large study using population-based linked community and hospital data to elucidate the long-term consequences of treatment modalities for hyperthyroidism,” said co-author Kristien Boelaert, MD, PhD, while presenting the research at the American Thyroid Association annual meeting.

“The administration of [radioiodine] for hyperthyroidism is associated with a survival benefit for patients with hyperthyroidism and is not associated with increased risks of becoming obese,” Dr. Boelaert, a professor of endocrinology and consultant endocrinologist with the Institute of Applied Health Research, University of Birmingham, England, told this news organization.

However, “overall, there was a nearly 10% risk of major adverse cardiac events [MACE] in patients with hyperthyroidism regardless of the treatment modality used,” she noted.

Commenting on the findings, Jonathon O. Russell, MD, said the study offers surprising – but encouraging – results.

The discovery that radioiodine shows no increase in weight gain “contradicts numerous previous studies which have consistently demonstrated weight gain following definitive radioiodine,” Dr. Russell told this news organization.

Overall, however, “these findings reinforce our knowledge that definitive treatment of an overactive thyroid leads to a longer life – even if there is some weight gain,” added Dr. Russell, who is chief of the Division of Head and Neck Endocrine Surgery at Johns Hopkins, Baltimore.
 

Hyperthyroidism associated with serious long-term cardiometabolic issues

Hyperthyroidism is associated with serious long-term cardiovascular and metabolic morbidity and mortality, and treatment is therefore essential. However, the swing to hypothyroidism that often occurs afterward commonly results in regaining the weight lost due to the hyperthyroidism, if not more, potentially leading to obesity and its attendant health risks.

To investigate those risks in relation to the three key hyperthyroidism treatments, the authors conducted the EGRET trial. They identified 62,474 patients in the United Kingdom population-based electronic health record database who had newly diagnosed hyperthyroidism and were treated with antithyroid drugs (73.4%), radioiodine (19.5%), or thyroidectomy (7.1%) between April 1997 and December 2015.

Exclusion criteria included those with less than 6 months of antithyroid drugs as the only form of treatment, thyroid cancer, or pregnancy during the first episode.

With a median follow-up of about 8 years, those who were treated with thyroidectomy had a significantly increased risk of gaining weight, compared with the general population (P < .001), and of developing obesity (body mass index > 30 kg/m2; P = .003), while the corresponding increases with antithyroid drugs and radioiodine were not significantly different, compared with the general population over the same period.

In terms of survival, with an average follow-up of about 11 years per person, about 14% of the cohort died, with rates of 14.4% in the antithyroid drug group, 15.8% in the radioiodine group, and 9.2% in the thyroidectomy group.

Mortality rates were further assessed based on an average treatment effects analysis in which the average change was estimated, compared with the index of antithyroid drugs – for instance, if all were treated instead with radioiodine. In that extension of life analysis, those treated with radioiodine could be expected to die, on average, 1.2 years later than those taking antithyroid drugs (P < .001), while those treated with thyroidectomy would be expected to die 0.6 years later, which was not statistically significant.

Using the same average treatment effects analysis, Dr. Boelaert noted, “we found a slightly increased risk of major adverse cardiovascular events following radioiodine, compared with antithyroid drugs; [however], the risk was very small and may not be clinically relevant.”

“Previous data from our and other groups have shown reduced risks of mortality and cardiovascular death following radioiodine-induced hypothyroidism, although this is not confirmed in all studies.”
 

Weight gain after hyperthyroid treatment drives concerns

The findings are important because weight gain associated with hyperthyroidism treatment is no small matter for many patients, even prompting a lack of adherence to therapy for some, despite its importance, Dr. Boelaert noted.

“Since the majority of patients lose weight as a consequence of being hyperthyroid, it can be expected that they will at least regain the lost weight and possibly even have a weight overshoot,” she explained. “Indeed, many patients are reluctant to accept definitive treatment with surgery or radioiodine out of fear of weight gain.”

“This may cause difficulties to some patients who occasionally may even stop taking antithyroid drugs to prevent this weight regain. Such lack of adherence may have dire consequences and is likely a contributing factor to the increased mortality in these patients,” she observed.

In a previous study of 1,373 patients, Dr. Boelaert and colleagues found that men treated for hyperthyroidism gained an average of 8.0 kg (17.6 lb), and women gained an average of 5.5 kg (12.1 lb).

Compared with the background population, men were significantly more likely to gain weight over the study period (odds ratio, 1.7; P < .001) as were women (OR, 1.3; P < .001). Also in that study, radioiodine was associated with greater weight gain (0.6 kg; P < .001), compared with antithyroid drug treatment alone.

Dr. Russell added that even when weight gain does occur, the payoff of having treated the potentially serious state of hyperthyroidism is a highly beneficial trade-off.

Ultimately, “the goal of treating any patient with Graves’ should be to get them to become hypothyroid as quickly as possible,” he said. “Patients have options, and all of these options can be safe in the right situation.”

“It is unrealistic to think that going from a hyperthyroid state to a low thyroid state will not result in weight gain for many patients,” Dr. Russell added. “But the key point is that overall health is better despite this weight gain.”

Dr. Boelaert has disclosed consulting fees paid to the University of Birmingham by Lilly and Eisai. Dr. Russell has reported no relevant financial relationships.

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

MONTREAL – Amid common patient concerns about weight gain in the treatment of hyperthyroidism, findings from a large study suggest the therapy with the most favorable survival rate – radioiodine – is not associated with an increased risk of weight gain or obesity.

“EGRET is the first large study using population-based linked community and hospital data to elucidate the long-term consequences of treatment modalities for hyperthyroidism,” said co-author Kristien Boelaert, MD, PhD, while presenting the research at the American Thyroid Association annual meeting.

“The administration of [radioiodine] for hyperthyroidism is associated with a survival benefit for patients with hyperthyroidism and is not associated with increased risks of becoming obese,” Dr. Boelaert, a professor of endocrinology and consultant endocrinologist with the Institute of Applied Health Research, University of Birmingham, England, told this news organization.

However, “overall, there was a nearly 10% risk of major adverse cardiac events [MACE] in patients with hyperthyroidism regardless of the treatment modality used,” she noted.

Commenting on the findings, Jonathon O. Russell, MD, said the study offers surprising – but encouraging – results.

The discovery that radioiodine shows no increase in weight gain “contradicts numerous previous studies which have consistently demonstrated weight gain following definitive radioiodine,” Dr. Russell told this news organization.

Overall, however, “these findings reinforce our knowledge that definitive treatment of an overactive thyroid leads to a longer life – even if there is some weight gain,” added Dr. Russell, who is chief of the Division of Head and Neck Endocrine Surgery at Johns Hopkins, Baltimore.
 

Hyperthyroidism associated with serious long-term cardiometabolic issues

Hyperthyroidism is associated with serious long-term cardiovascular and metabolic morbidity and mortality, and treatment is therefore essential. However, the swing to hypothyroidism that often occurs afterward commonly results in regaining the weight lost due to the hyperthyroidism, if not more, potentially leading to obesity and its attendant health risks.

To investigate those risks in relation to the three key hyperthyroidism treatments, the authors conducted the EGRET trial. They identified 62,474 patients in the United Kingdom population-based electronic health record database who had newly diagnosed hyperthyroidism and were treated with antithyroid drugs (73.4%), radioiodine (19.5%), or thyroidectomy (7.1%) between April 1997 and December 2015.

Exclusion criteria included those with less than 6 months of antithyroid drugs as the only form of treatment, thyroid cancer, or pregnancy during the first episode.

With a median follow-up of about 8 years, those who were treated with thyroidectomy had a significantly increased risk of gaining weight, compared with the general population (P < .001), and of developing obesity (body mass index > 30 kg/m2; P = .003), while the corresponding increases with antithyroid drugs and radioiodine were not significantly different, compared with the general population over the same period.

In terms of survival, with an average follow-up of about 11 years per person, about 14% of the cohort died, with rates of 14.4% in the antithyroid drug group, 15.8% in the radioiodine group, and 9.2% in the thyroidectomy group.

Mortality rates were further assessed based on an average treatment effects analysis in which the average change was estimated, compared with the index of antithyroid drugs – for instance, if all were treated instead with radioiodine. In that extension of life analysis, those treated with radioiodine could be expected to die, on average, 1.2 years later than those taking antithyroid drugs (P < .001), while those treated with thyroidectomy would be expected to die 0.6 years later, which was not statistically significant.

Using the same average treatment effects analysis, Dr. Boelaert noted, “we found a slightly increased risk of major adverse cardiovascular events following radioiodine, compared with antithyroid drugs; [however], the risk was very small and may not be clinically relevant.”

“Previous data from our and other groups have shown reduced risks of mortality and cardiovascular death following radioiodine-induced hypothyroidism, although this is not confirmed in all studies.”
 

Weight gain after hyperthyroid treatment drives concerns

The findings are important because weight gain associated with hyperthyroidism treatment is no small matter for many patients, even prompting a lack of adherence to therapy for some, despite its importance, Dr. Boelaert noted.

“Since the majority of patients lose weight as a consequence of being hyperthyroid, it can be expected that they will at least regain the lost weight and possibly even have a weight overshoot,” she explained. “Indeed, many patients are reluctant to accept definitive treatment with surgery or radioiodine out of fear of weight gain.”

“This may cause difficulties to some patients who occasionally may even stop taking antithyroid drugs to prevent this weight regain. Such lack of adherence may have dire consequences and is likely a contributing factor to the increased mortality in these patients,” she observed.

In a previous study of 1,373 patients, Dr. Boelaert and colleagues found that men treated for hyperthyroidism gained an average of 8.0 kg (17.6 lb), and women gained an average of 5.5 kg (12.1 lb).

Compared with the background population, men were significantly more likely to gain weight over the study period (odds ratio, 1.7; P < .001) as were women (OR, 1.3; P < .001). Also in that study, radioiodine was associated with greater weight gain (0.6 kg; P < .001), compared with antithyroid drug treatment alone.

Dr. Russell added that even when weight gain does occur, the payoff of having treated the potentially serious state of hyperthyroidism is a highly beneficial trade-off.

Ultimately, “the goal of treating any patient with Graves’ should be to get them to become hypothyroid as quickly as possible,” he said. “Patients have options, and all of these options can be safe in the right situation.”

“It is unrealistic to think that going from a hyperthyroid state to a low thyroid state will not result in weight gain for many patients,” Dr. Russell added. “But the key point is that overall health is better despite this weight gain.”

Dr. Boelaert has disclosed consulting fees paid to the University of Birmingham by Lilly and Eisai. Dr. Russell has reported no relevant financial relationships.

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