Stroke

Among stroke survivors with diabetes or obesity, glucagon-like peptide-1 receptor agonists (GLP-1 RAs) reduced secondary stroke risk by up to 16%, according to authors of a recent meta-analysis. With benefits across administration routes, dosing regimens, type 2 diabetes status, and total and nonfatal strokes, the findings could improve GLP-1 RA implementation by stroke specialists in patients with stroke history and concurrent type 2 diabetes or obesity, authors said. The study was published online in the International Journal of Stoke.

Extending Longevity

Agents including GLP-1 RAs that have been found to reduce cardiovascular events among patients with type 2 diabetes and patients who are overweight or obese also reduce risk of recurrent stroke among patients with a history of stroke who are overweight, obese, or have metabolic disease, said American Heart Association (AHA) Chief Clinical Science Officer Mitchell S. V. Elkind, MD, who was not involved with the study but was asked to comment.

“Stroke is a leading cause of mortality and the leading cause of serious long-term disability,” he added, “so medications that help to reduce that risk can play an important role in improving overall health and well-being and hopefully reducing premature mortality.”

Investigators Anastasia Adamou, MD, an internal medicine resident at AHEPA University Hospital in Thessaloniki, Greece, and colleagues searched MEDLINE and Scopus for cardiovascular outcome trials involving adults randomly assigned to GLP-1 RAs or placebo through November 2023, ultimately analyzing 11 randomized controlled trials (RCTs).

Among 60,380 participants in the nine studies that assessed total strokes, 2.5% of the GLP-1 RA group experienced strokes during follow-up, versus 3% in the placebo group (relative risk [RR] 0.85, 95% confidence interval [CI] 0.77-0.93). Regarding secondary outcomes, the GLP-1 RA group showed a significantly lower rate of nonfatal strokes versus patients on placebo (RR 0.87, 95% CI 0.79-0.95). Conversely, investigators observed no significant risk difference among the groups regarding fatal strokes, probably due to the low rate of events — 0.3% and 0.4% for treated and untreated patients, respectively.

Subgroup analyses revealed no interaction between dosing frequency and total, nonfatal, or fatal strokes. The investigators observed no difference in nonfatal strokes among participants by type 2 diabetes status and medication administration route (oral versus subcutaneous).

“The oral administration route could provide the advantage of lower local ecchymoses and allergic reactions due to subcutaneous infusions,” Dr. Adamou said in an interview. But because oral administration demands daily intake, she added, treatment adherence might be affected. “For this reason, our team performed another subgroup analysis to compare the once-a-day to the once-a-month administration. No interaction effect was again presented between the two subgroups. This outcome allows for personalization of the administration method for each patient.”

Addressing Underutilization

Despite more than 2 decades of widespread use and well-established effects on body weight, HbA1c, and cardiovascular risk, GLP-1 RAs remain underutilized, authors wrote. This is especially true in primary care, noted one study published in Clinical Diabetes.

“GLP-1 RAs have been used for many years to treat diabetic patients,” said Dr. Adamou. But because their impact on cardiovascular health regardless of diabetic status is only recently known, she said, physicians are exercising caution when prescribing this medication to patients without diabetes. “This is why more studies need to be available, especially RCTs.”

Most neurologists traditionally have left management of type 2 diabetes and other metabolic disorders to primary care doctors, said Dr. Elkind. “However, these medications are increasingly important to vascular risk reduction and should be considered part of the stroke specialist’s armamentarium.”

Vascular neurologists can play an important role in managing metabolic disease and obesity by recommending GLP-1 RAs for patients with a history of stroke, or by initiating these medications themselves, Dr. Elkind said. “These drugs are likely to become an important part of stroke patients’ medication regimens, along with antithrombotic agents, blood pressure control, and statins. Neurologists are well-positioned to educate other physicians about the important connections among brain, heart, and metabolic health.”

To that end, he said, the AHA will update guidelines for both primary and secondary stroke prevention as warranted by evidence supporting GLP-1 RAs and other medications that could impact stroke risk in type 2 diabetes and related metabolic disorders. However, no guidelines concerning use of GLP-1 RAs for secondary stroke prevention in obesity exist. Here, said Dr. Elkind, the AHA will continue building on its innovative Cardiovascular-Kidney Metabolic Health program, which includes clinical suggestions and may include more formal clinical practice guidelines as the evidence evolves.

Among the main drivers of the initiative, he said, is the recognition that cardiovascular disease — including stroke — is the major cause of death and morbidity among patients with obesity, type 2 diabetes, and metabolic disorders. “Stroke should be considered an important part of overall cardiovascular risk, and the findings that these drugs can help to reduce the risk of stroke specifically is an important additional reason for their use.”

Dr. Elkind and Dr. Adamou reported no conflicting interests. The authors received no financial support for the study.

Among stroke survivors with diabetes or obesity, glucagon-like peptide-1 receptor agonists (GLP-1 RAs) reduced secondary stroke risk by up to 16%, according to authors of a recent meta-analysis. With benefits across administration routes, dosing regimens, type 2 diabetes status, and total and nonfatal strokes, the findings could improve GLP-1 RA implementation by stroke specialists in patients with stroke history and concurrent type 2 diabetes or obesity, authors said. The study was published online in the International Journal of Stoke.

Extending Longevity

Agents including GLP-1 RAs that have been found to reduce cardiovascular events among patients with type 2 diabetes and patients who are overweight or obese also reduce risk of recurrent stroke among patients with a history of stroke who are overweight, obese, or have metabolic disease, said American Heart Association (AHA) Chief Clinical Science Officer Mitchell S. V. Elkind, MD, who was not involved with the study but was asked to comment.

“Stroke is a leading cause of mortality and the leading cause of serious long-term disability,” he added, “so medications that help to reduce that risk can play an important role in improving overall health and well-being and hopefully reducing premature mortality.”

Investigators Anastasia Adamou, MD, an internal medicine resident at AHEPA University Hospital in Thessaloniki, Greece, and colleagues searched MEDLINE and Scopus for cardiovascular outcome trials involving adults randomly assigned to GLP-1 RAs or placebo through November 2023, ultimately analyzing 11 randomized controlled trials (RCTs).

Among 60,380 participants in the nine studies that assessed total strokes, 2.5% of the GLP-1 RA group experienced strokes during follow-up, versus 3% in the placebo group (relative risk [RR] 0.85, 95% confidence interval [CI] 0.77-0.93). Regarding secondary outcomes, the GLP-1 RA group showed a significantly lower rate of nonfatal strokes versus patients on placebo (RR 0.87, 95% CI 0.79-0.95). Conversely, investigators observed no significant risk difference among the groups regarding fatal strokes, probably due to the low rate of events — 0.3% and 0.4% for treated and untreated patients, respectively.

Subgroup analyses revealed no interaction between dosing frequency and total, nonfatal, or fatal strokes. The investigators observed no difference in nonfatal strokes among participants by type 2 diabetes status and medication administration route (oral versus subcutaneous).

“The oral administration route could provide the advantage of lower local ecchymoses and allergic reactions due to subcutaneous infusions,” Dr. Adamou said in an interview. But because oral administration demands daily intake, she added, treatment adherence might be affected. “For this reason, our team performed another subgroup analysis to compare the once-a-day to the once-a-month administration. No interaction effect was again presented between the two subgroups. This outcome allows for personalization of the administration method for each patient.”

Addressing Underutilization

Despite more than 2 decades of widespread use and well-established effects on body weight, HbA1c, and cardiovascular risk, GLP-1 RAs remain underutilized, authors wrote. This is especially true in primary care, noted one study published in Clinical Diabetes.

“GLP-1 RAs have been used for many years to treat diabetic patients,” said Dr. Adamou. But because their impact on cardiovascular health regardless of diabetic status is only recently known, she said, physicians are exercising caution when prescribing this medication to patients without diabetes. “This is why more studies need to be available, especially RCTs.”

Most neurologists traditionally have left management of type 2 diabetes and other metabolic disorders to primary care doctors, said Dr. Elkind. “However, these medications are increasingly important to vascular risk reduction and should be considered part of the stroke specialist’s armamentarium.”

Vascular neurologists can play an important role in managing metabolic disease and obesity by recommending GLP-1 RAs for patients with a history of stroke, or by initiating these medications themselves, Dr. Elkind said. “These drugs are likely to become an important part of stroke patients’ medication regimens, along with antithrombotic agents, blood pressure control, and statins. Neurologists are well-positioned to educate other physicians about the important connections among brain, heart, and metabolic health.”

To that end, he said, the AHA will update guidelines for both primary and secondary stroke prevention as warranted by evidence supporting GLP-1 RAs and other medications that could impact stroke risk in type 2 diabetes and related metabolic disorders. However, no guidelines concerning use of GLP-1 RAs for secondary stroke prevention in obesity exist. Here, said Dr. Elkind, the AHA will continue building on its innovative Cardiovascular-Kidney Metabolic Health program, which includes clinical suggestions and may include more formal clinical practice guidelines as the evidence evolves.

Among the main drivers of the initiative, he said, is the recognition that cardiovascular disease — including stroke — is the major cause of death and morbidity among patients with obesity, type 2 diabetes, and metabolic disorders. “Stroke should be considered an important part of overall cardiovascular risk, and the findings that these drugs can help to reduce the risk of stroke specifically is an important additional reason for their use.”

Dr. Elkind and Dr. Adamou reported no conflicting interests. The authors received no financial support for the study.

Among stroke survivors with diabetes or obesity, glucagon-like peptide-1 receptor agonists (GLP-1 RAs) reduced secondary stroke risk by up to 16%, according to authors of a recent meta-analysis. With benefits across administration routes, dosing regimens, type 2 diabetes status, and total and nonfatal strokes, the findings could improve GLP-1 RA implementation by stroke specialists in patients with stroke history and concurrent type 2 diabetes or obesity, authors said. The study was published online in the International Journal of Stoke.

Extending Longevity

Agents including GLP-1 RAs that have been found to reduce cardiovascular events among patients with type 2 diabetes and patients who are overweight or obese also reduce risk of recurrent stroke among patients with a history of stroke who are overweight, obese, or have metabolic disease, said American Heart Association (AHA) Chief Clinical Science Officer Mitchell S. V. Elkind, MD, who was not involved with the study but was asked to comment.

“Stroke is a leading cause of mortality and the leading cause of serious long-term disability,” he added, “so medications that help to reduce that risk can play an important role in improving overall health and well-being and hopefully reducing premature mortality.”

Investigators Anastasia Adamou, MD, an internal medicine resident at AHEPA University Hospital in Thessaloniki, Greece, and colleagues searched MEDLINE and Scopus for cardiovascular outcome trials involving adults randomly assigned to GLP-1 RAs or placebo through November 2023, ultimately analyzing 11 randomized controlled trials (RCTs).

Among 60,380 participants in the nine studies that assessed total strokes, 2.5% of the GLP-1 RA group experienced strokes during follow-up, versus 3% in the placebo group (relative risk [RR] 0.85, 95% confidence interval [CI] 0.77-0.93). Regarding secondary outcomes, the GLP-1 RA group showed a significantly lower rate of nonfatal strokes versus patients on placebo (RR 0.87, 95% CI 0.79-0.95). Conversely, investigators observed no significant risk difference among the groups regarding fatal strokes, probably due to the low rate of events — 0.3% and 0.4% for treated and untreated patients, respectively.

Subgroup analyses revealed no interaction between dosing frequency and total, nonfatal, or fatal strokes. The investigators observed no difference in nonfatal strokes among participants by type 2 diabetes status and medication administration route (oral versus subcutaneous).

“The oral administration route could provide the advantage of lower local ecchymoses and allergic reactions due to subcutaneous infusions,” Dr. Adamou said in an interview. But because oral administration demands daily intake, she added, treatment adherence might be affected. “For this reason, our team performed another subgroup analysis to compare the once-a-day to the once-a-month administration. No interaction effect was again presented between the two subgroups. This outcome allows for personalization of the administration method for each patient.”

Addressing Underutilization

Despite more than 2 decades of widespread use and well-established effects on body weight, HbA1c, and cardiovascular risk, GLP-1 RAs remain underutilized, authors wrote. This is especially true in primary care, noted one study published in Clinical Diabetes.

“GLP-1 RAs have been used for many years to treat diabetic patients,” said Dr. Adamou. But because their impact on cardiovascular health regardless of diabetic status is only recently known, she said, physicians are exercising caution when prescribing this medication to patients without diabetes. “This is why more studies need to be available, especially RCTs.”

Most neurologists traditionally have left management of type 2 diabetes and other metabolic disorders to primary care doctors, said Dr. Elkind. “However, these medications are increasingly important to vascular risk reduction and should be considered part of the stroke specialist’s armamentarium.”

Vascular neurologists can play an important role in managing metabolic disease and obesity by recommending GLP-1 RAs for patients with a history of stroke, or by initiating these medications themselves, Dr. Elkind said. “These drugs are likely to become an important part of stroke patients’ medication regimens, along with antithrombotic agents, blood pressure control, and statins. Neurologists are well-positioned to educate other physicians about the important connections among brain, heart, and metabolic health.”

To that end, he said, the AHA will update guidelines for both primary and secondary stroke prevention as warranted by evidence supporting GLP-1 RAs and other medications that could impact stroke risk in type 2 diabetes and related metabolic disorders. However, no guidelines concerning use of GLP-1 RAs for secondary stroke prevention in obesity exist. Here, said Dr. Elkind, the AHA will continue building on its innovative Cardiovascular-Kidney Metabolic Health program, which includes clinical suggestions and may include more formal clinical practice guidelines as the evidence evolves.

Among the main drivers of the initiative, he said, is the recognition that cardiovascular disease — including stroke — is the major cause of death and morbidity among patients with obesity, type 2 diabetes, and metabolic disorders. “Stroke should be considered an important part of overall cardiovascular risk, and the findings that these drugs can help to reduce the risk of stroke specifically is an important additional reason for their use.”

Dr. Elkind and Dr. Adamou reported no conflicting interests. The authors received no financial support for the study.

Women who had overweight or obesity as teens or young adults had more than a twofold increased risk for stroke before age 55, new research suggested.

An analysis of more than five decades of health data on 10,000 adults revealed that close to 5% experienced a stroke during the follow-up period, with the risk for ischemic stroke being more than twice as high in women who had obesity as teens or young adults. The risk was even higher for hemorrhagic stroke in both men and women with a history of obesity in youth.

“Our findings suggest that being overweight may have long-term health effects, even if the excess weight is temporary,” lead author Ursula Mikkola, BM, an investigator in the Research Unit of Population Health at the University of Oulu, Oulu, Finland, said in a news release.

Gender Differences

Childhood obesity has been associated with a heightened risk for cerebrovascular disease later in life, but most studies have focused on body mass index (BMI) at a single time point without considering its fluctuations throughout life, the investigators noted.

For the study, investigators used data from the Northern Finland Birth Cohort 1966, a prospective, general population-based birth cohort that followed 10,491 individuals (5185 women) until 2020 or the first stroke, death, or moving abroad, whichever came first.

Mean (SD) follow-up for each participant was 39 years from age 14 onward and 23 years from age 31 onward. The analysis was conducted between 1980 and 2020.

BMI data were collected from participants at the age of 14 and 31 years. Age 14 covariates included smoking, parental socioeconomic status, and age at menarche (for girls). Age 31 covariates included smoking and participants’ educational level.

During the follow-up period, 4.7% of participants experienced stroke. Of these events, 31% were ischemic strokes and 40% were transient ischemic attacks. The remainder were hemorrhagic or other cerebrovascular events.

Using normal weight as a reference, researchers found that the risk for ischemic stroke was over twice as high for women who had been overweight at ages 14 (hazard ratio [HR], 2.49; 95% confidence interval [CI], 1.44-4.31) and 31 (HR, 2.13; 95% CI, 1.14-3.97) years. The risk was also considerably higher for women who had obesity at ages 14 (HR, 1.87; 95% CI, 0.76-4.58) and 31 (HR, 2.67; 95% CI, 1.26-5.65) years.

The risk for hemorrhagic stroke was even higher, both among women (HR, 3.49; 95% CI, 1.13-10.7) and men (HR, 5.75; 95% CI, 1.43-23.1) who had obesity at age 31.

No similar associations were found among men, and the findings were independent of earlier or later BMI.

The risk for any cerebrovascular disease related to overweight at age 14 was twice as high among girls vs boys (HR, 2.09; 95% CI, 1.06-4.15), and the risk for ischemic stroke related to obesity at age 31 was nearly seven times higher among women vs men (HR, 6.96; 95% CI, 1.36-35.7).

“Stroke at a young age is rare, so the difference of just a few strokes could have an outsized impact on the risk estimates,” the study authors said. “Also, BMI relies solely on a person’s height and weight; therefore, a high BMI may be a misleading way to define obesity, especially in muscular people who may carry little fat even while weighing more.”
 

Caveats

In an accompanying editorial, Larry Goldstein, MD, chair of the Department of Neurology, University of Kentucky, Lexington, Kentucky, and codirector of the Kentucky Neuroscience Institute, said the study “provides additional evidence of an association between overweight/obesity and stroke in young adults.”

However, Dr. Goldstein added that “while it is tempting to assume that reductions in overweight/obesity in younger populations would translate to lower stroke rates in young adults, this remains to be proven.”

Moreover, it is “always important to acknowledge that associations found in observational studies may not reflect causality.”

This study was supported by Orion Research Foundation, Päivikki and Sakari Sohlberg Foundation, and Paulo Foundation. Dr. Mikkola reported no relevant financial relationships. The other authors’ disclosures are listed on the original paper. Dr. Goldstein reported no relevant financial relationships.

A version of this article appeared on Medscape.com.

Women who had overweight or obesity as teens or young adults had more than a twofold increased risk for stroke before age 55, new research suggested.

An analysis of more than five decades of health data on 10,000 adults revealed that close to 5% experienced a stroke during the follow-up period, with the risk for ischemic stroke being more than twice as high in women who had obesity as teens or young adults. The risk was even higher for hemorrhagic stroke in both men and women with a history of obesity in youth.

“Our findings suggest that being overweight may have long-term health effects, even if the excess weight is temporary,” lead author Ursula Mikkola, BM, an investigator in the Research Unit of Population Health at the University of Oulu, Oulu, Finland, said in a news release.

Gender Differences

Childhood obesity has been associated with a heightened risk for cerebrovascular disease later in life, but most studies have focused on body mass index (BMI) at a single time point without considering its fluctuations throughout life, the investigators noted.

For the study, investigators used data from the Northern Finland Birth Cohort 1966, a prospective, general population-based birth cohort that followed 10,491 individuals (5185 women) until 2020 or the first stroke, death, or moving abroad, whichever came first.

Mean (SD) follow-up for each participant was 39 years from age 14 onward and 23 years from age 31 onward. The analysis was conducted between 1980 and 2020.

BMI data were collected from participants at the age of 14 and 31 years. Age 14 covariates included smoking, parental socioeconomic status, and age at menarche (for girls). Age 31 covariates included smoking and participants’ educational level.

During the follow-up period, 4.7% of participants experienced stroke. Of these events, 31% were ischemic strokes and 40% were transient ischemic attacks. The remainder were hemorrhagic or other cerebrovascular events.

Using normal weight as a reference, researchers found that the risk for ischemic stroke was over twice as high for women who had been overweight at ages 14 (hazard ratio [HR], 2.49; 95% confidence interval [CI], 1.44-4.31) and 31 (HR, 2.13; 95% CI, 1.14-3.97) years. The risk was also considerably higher for women who had obesity at ages 14 (HR, 1.87; 95% CI, 0.76-4.58) and 31 (HR, 2.67; 95% CI, 1.26-5.65) years.

The risk for hemorrhagic stroke was even higher, both among women (HR, 3.49; 95% CI, 1.13-10.7) and men (HR, 5.75; 95% CI, 1.43-23.1) who had obesity at age 31.

No similar associations were found among men, and the findings were independent of earlier or later BMI.

The risk for any cerebrovascular disease related to overweight at age 14 was twice as high among girls vs boys (HR, 2.09; 95% CI, 1.06-4.15), and the risk for ischemic stroke related to obesity at age 31 was nearly seven times higher among women vs men (HR, 6.96; 95% CI, 1.36-35.7).

“Stroke at a young age is rare, so the difference of just a few strokes could have an outsized impact on the risk estimates,” the study authors said. “Also, BMI relies solely on a person’s height and weight; therefore, a high BMI may be a misleading way to define obesity, especially in muscular people who may carry little fat even while weighing more.”
 

Caveats

In an accompanying editorial, Larry Goldstein, MD, chair of the Department of Neurology, University of Kentucky, Lexington, Kentucky, and codirector of the Kentucky Neuroscience Institute, said the study “provides additional evidence of an association between overweight/obesity and stroke in young adults.”

However, Dr. Goldstein added that “while it is tempting to assume that reductions in overweight/obesity in younger populations would translate to lower stroke rates in young adults, this remains to be proven.”

Moreover, it is “always important to acknowledge that associations found in observational studies may not reflect causality.”

This study was supported by Orion Research Foundation, Päivikki and Sakari Sohlberg Foundation, and Paulo Foundation. Dr. Mikkola reported no relevant financial relationships. The other authors’ disclosures are listed on the original paper. Dr. Goldstein reported no relevant financial relationships.

A version of this article appeared on Medscape.com.

Women who had overweight or obesity as teens or young adults had more than a twofold increased risk for stroke before age 55, new research suggested.

An analysis of more than five decades of health data on 10,000 adults revealed that close to 5% experienced a stroke during the follow-up period, with the risk for ischemic stroke being more than twice as high in women who had obesity as teens or young adults. The risk was even higher for hemorrhagic stroke in both men and women with a history of obesity in youth.

“Our findings suggest that being overweight may have long-term health effects, even if the excess weight is temporary,” lead author Ursula Mikkola, BM, an investigator in the Research Unit of Population Health at the University of Oulu, Oulu, Finland, said in a news release.

Gender Differences

Childhood obesity has been associated with a heightened risk for cerebrovascular disease later in life, but most studies have focused on body mass index (BMI) at a single time point without considering its fluctuations throughout life, the investigators noted.

For the study, investigators used data from the Northern Finland Birth Cohort 1966, a prospective, general population-based birth cohort that followed 10,491 individuals (5185 women) until 2020 or the first stroke, death, or moving abroad, whichever came first.

Mean (SD) follow-up for each participant was 39 years from age 14 onward and 23 years from age 31 onward. The analysis was conducted between 1980 and 2020.

BMI data were collected from participants at the age of 14 and 31 years. Age 14 covariates included smoking, parental socioeconomic status, and age at menarche (for girls). Age 31 covariates included smoking and participants’ educational level.

During the follow-up period, 4.7% of participants experienced stroke. Of these events, 31% were ischemic strokes and 40% were transient ischemic attacks. The remainder were hemorrhagic or other cerebrovascular events.

Using normal weight as a reference, researchers found that the risk for ischemic stroke was over twice as high for women who had been overweight at ages 14 (hazard ratio [HR], 2.49; 95% confidence interval [CI], 1.44-4.31) and 31 (HR, 2.13; 95% CI, 1.14-3.97) years. The risk was also considerably higher for women who had obesity at ages 14 (HR, 1.87; 95% CI, 0.76-4.58) and 31 (HR, 2.67; 95% CI, 1.26-5.65) years.

The risk for hemorrhagic stroke was even higher, both among women (HR, 3.49; 95% CI, 1.13-10.7) and men (HR, 5.75; 95% CI, 1.43-23.1) who had obesity at age 31.

No similar associations were found among men, and the findings were independent of earlier or later BMI.

The risk for any cerebrovascular disease related to overweight at age 14 was twice as high among girls vs boys (HR, 2.09; 95% CI, 1.06-4.15), and the risk for ischemic stroke related to obesity at age 31 was nearly seven times higher among women vs men (HR, 6.96; 95% CI, 1.36-35.7).

“Stroke at a young age is rare, so the difference of just a few strokes could have an outsized impact on the risk estimates,” the study authors said. “Also, BMI relies solely on a person’s height and weight; therefore, a high BMI may be a misleading way to define obesity, especially in muscular people who may carry little fat even while weighing more.”
 

Caveats

In an accompanying editorial, Larry Goldstein, MD, chair of the Department of Neurology, University of Kentucky, Lexington, Kentucky, and codirector of the Kentucky Neuroscience Institute, said the study “provides additional evidence of an association between overweight/obesity and stroke in young adults.”

However, Dr. Goldstein added that “while it is tempting to assume that reductions in overweight/obesity in younger populations would translate to lower stroke rates in young adults, this remains to be proven.”

Moreover, it is “always important to acknowledge that associations found in observational studies may not reflect causality.”

This study was supported by Orion Research Foundation, Päivikki and Sakari Sohlberg Foundation, and Paulo Foundation. Dr. Mikkola reported no relevant financial relationships. The other authors’ disclosures are listed on the original paper. Dr. Goldstein reported no relevant financial relationships.

A version of this article appeared on Medscape.com.

HOUSTON — Narcolepsy is associated with a significantly increased risk for cardiovascular disease (CVD) and major adverse cardiac events (MACEs), independent of common comorbid conditions and medications commonly used to treat the chronic sleep disorder, according to two new studies.

A nationwide analysis revealed that people with narcolepsy had a 77% higher risk for CVD and an 82% higher risk for MACE than those without the disorder.

“These findings indicate that it is important for clinicians to regularly monitor patients for cardiovascular disease and take this into consideration when recommending specific treatments for narcolepsy,” study investigators Christopher Kaufmann, PhD; Munaza Riaz, PharmD, MPhil; and Rakesh Bhattacharjee, MD, told this news organization.

“Additionally, physicians should consider monitoring the presence of other health conditions as contributing factors to the risk of CVD,” they said. Dr. Kaufmann and Dr. Riaz are with the University of Florida, Gainesville, Florida, and Dr. Bhattacharjee is with the University of California, San Diego.

They presented their research at SLEEP 2024: 38th Annual Meeting of the Associated Professional Sleep Societies.
 

Independent Risk Factor

The National Institute of Neurological Disorders and Stroke reports an estimated 125,000 to 200,000 people in the United States live with narcolepsy. The condition often coexists with other common health conditions including obstructive sleep apnea (OSA), diabetes, and other comorbidities, which can all contribute to the risk for CVD.

This raises doubt as to whether narcolepsy itself directly leads to CVD or if it is the result of these comorbid health conditions. Additionally, some medications used to treat narcolepsy carry their own cardiovascular risks.

Using the IBM MarketScan Commercial and Medicare supplemental databases, the researchers identified 34,562 adults with a diagnosis of narcolepsy and a propensity-matched comparison cohort of 100,405 adults without narcolepsy. The patients had a mean age of 40 years, and 62% were women.

Compared with adults without narcolepsy, those with the chronic sleep disorder that causes overwhelming daytime drowsiness had a 77% increased risk for any CVD (hazard ratio [HR], 1.77) and an 82% increased risk for MACE (HR, 1.82).

They also had an increased risk for stroke (HR, 2.04), heart failure or myocardial infarction (MI; HR, 1.64), and atrial fibrillation (HR, 1.58).

The results were similar in a separate analysis of the same population that also controlled for baseline use of stimulants, oxybates, and wake-promoting agents — medications commonly used to treat excessive daytime sleepiness associated with narcolepsy.

In this analysis, narcolepsy was associated with an 89% higher risk for CVD (HR, 1.89) and a 95% increased risk for MACE (HR, 1.95). The risk for any stroke (HR, 2.06), heart failure (HR, 1.90), atrial fibrillation (HR, 1.66), and MI (HR, 1.93) was also higher in those with narcolepsy.

“Our study found that even after considering the presence of health conditions like obstructive sleep apnea, diabetes, hypertension, hyperlipidemia, and even depression, as well as medication use, there still appears to be an independent relationship between narcolepsy and CVD,” the investigators said.

They cautioned that the mechanisms explaining the link between CVD and narcolepsy are unclear and warrant further study.

“Sleep fragmentation is a hallmark of narcolepsy, and it is speculated that this fragmentation, which may trigger disturbances in autonomic function, predisposes individuals to CVD. In rodent models, a possible link has been observed between hypocretin — a central neurotransmitter that is reduced or deficient in patients with narcolepsy — and atherosclerosis.

“However, it remains uncertain whether this is the primary mechanism related to CVD,” they commented.
 

Compelling Evidence for Higher CVD

Commenting on the findings for this news organization, Shaheen Lakhan, MD, a neurologist and researcher based in Miami, Florida, called for narcolepsy to be recognized as a significant contributor to higher CVD risk.

“Given the compelling evidence linking narcolepsy to a higher incidence of cardiovascular disease, it is crucial that narcolepsy be included in clinical guidelines and risk assessment tools alongside other known risk factors,” said Dr. Lakhan, who was not involved in this research.

“Physicians and health care providers should proactively address the increased cardiovascular risk associated with narcolepsy by incorporating preventive strategies and interventions into the management of patients with this condition,” Dr. Lakhan suggested.

Regular CVD screening, a healthier lifestyle, and targeted therapies could all decrease cardiac risk, Dr. Lakhan added.

“Ultimately, novel disease-modifying therapies for narcolepsy should target the core mechanisms driving the increased cardiovascular risk associated with this condition. By elucidating the specific biological pathways and developing targeted therapies that address the unique challenges faced by narcolepsy patients, we can effectively mitigate the risk,” Dr. Lakhan said.

The studies were funded by the Sleep Research Society Foundation. The authors and Dr. Lakhan had no relevant disclosures.

A version of this article appeared on Medscape.com.

HOUSTON — Narcolepsy is associated with a significantly increased risk for cardiovascular disease (CVD) and major adverse cardiac events (MACEs), independent of common comorbid conditions and medications commonly used to treat the chronic sleep disorder, according to two new studies.

A nationwide analysis revealed that people with narcolepsy had a 77% higher risk for CVD and an 82% higher risk for MACE than those without the disorder.

“These findings indicate that it is important for clinicians to regularly monitor patients for cardiovascular disease and take this into consideration when recommending specific treatments for narcolepsy,” study investigators Christopher Kaufmann, PhD; Munaza Riaz, PharmD, MPhil; and Rakesh Bhattacharjee, MD, told this news organization.

“Additionally, physicians should consider monitoring the presence of other health conditions as contributing factors to the risk of CVD,” they said. Dr. Kaufmann and Dr. Riaz are with the University of Florida, Gainesville, Florida, and Dr. Bhattacharjee is with the University of California, San Diego.

They presented their research at SLEEP 2024: 38th Annual Meeting of the Associated Professional Sleep Societies.
 

Independent Risk Factor

The National Institute of Neurological Disorders and Stroke reports an estimated 125,000 to 200,000 people in the United States live with narcolepsy. The condition often coexists with other common health conditions including obstructive sleep apnea (OSA), diabetes, and other comorbidities, which can all contribute to the risk for CVD.

This raises doubt as to whether narcolepsy itself directly leads to CVD or if it is the result of these comorbid health conditions. Additionally, some medications used to treat narcolepsy carry their own cardiovascular risks.

Using the IBM MarketScan Commercial and Medicare supplemental databases, the researchers identified 34,562 adults with a diagnosis of narcolepsy and a propensity-matched comparison cohort of 100,405 adults without narcolepsy. The patients had a mean age of 40 years, and 62% were women.

Compared with adults without narcolepsy, those with the chronic sleep disorder that causes overwhelming daytime drowsiness had a 77% increased risk for any CVD (hazard ratio [HR], 1.77) and an 82% increased risk for MACE (HR, 1.82).

They also had an increased risk for stroke (HR, 2.04), heart failure or myocardial infarction (MI; HR, 1.64), and atrial fibrillation (HR, 1.58).

The results were similar in a separate analysis of the same population that also controlled for baseline use of stimulants, oxybates, and wake-promoting agents — medications commonly used to treat excessive daytime sleepiness associated with narcolepsy.

In this analysis, narcolepsy was associated with an 89% higher risk for CVD (HR, 1.89) and a 95% increased risk for MACE (HR, 1.95). The risk for any stroke (HR, 2.06), heart failure (HR, 1.90), atrial fibrillation (HR, 1.66), and MI (HR, 1.93) was also higher in those with narcolepsy.

“Our study found that even after considering the presence of health conditions like obstructive sleep apnea, diabetes, hypertension, hyperlipidemia, and even depression, as well as medication use, there still appears to be an independent relationship between narcolepsy and CVD,” the investigators said.

They cautioned that the mechanisms explaining the link between CVD and narcolepsy are unclear and warrant further study.

“Sleep fragmentation is a hallmark of narcolepsy, and it is speculated that this fragmentation, which may trigger disturbances in autonomic function, predisposes individuals to CVD. In rodent models, a possible link has been observed between hypocretin — a central neurotransmitter that is reduced or deficient in patients with narcolepsy — and atherosclerosis.

“However, it remains uncertain whether this is the primary mechanism related to CVD,” they commented.
 

Compelling Evidence for Higher CVD

Commenting on the findings for this news organization, Shaheen Lakhan, MD, a neurologist and researcher based in Miami, Florida, called for narcolepsy to be recognized as a significant contributor to higher CVD risk.

“Given the compelling evidence linking narcolepsy to a higher incidence of cardiovascular disease, it is crucial that narcolepsy be included in clinical guidelines and risk assessment tools alongside other known risk factors,” said Dr. Lakhan, who was not involved in this research.

“Physicians and health care providers should proactively address the increased cardiovascular risk associated with narcolepsy by incorporating preventive strategies and interventions into the management of patients with this condition,” Dr. Lakhan suggested.

Regular CVD screening, a healthier lifestyle, and targeted therapies could all decrease cardiac risk, Dr. Lakhan added.

“Ultimately, novel disease-modifying therapies for narcolepsy should target the core mechanisms driving the increased cardiovascular risk associated with this condition. By elucidating the specific biological pathways and developing targeted therapies that address the unique challenges faced by narcolepsy patients, we can effectively mitigate the risk,” Dr. Lakhan said.

The studies were funded by the Sleep Research Society Foundation. The authors and Dr. Lakhan had no relevant disclosures.

A version of this article appeared on Medscape.com.

HOUSTON — Narcolepsy is associated with a significantly increased risk for cardiovascular disease (CVD) and major adverse cardiac events (MACEs), independent of common comorbid conditions and medications commonly used to treat the chronic sleep disorder, according to two new studies.

A nationwide analysis revealed that people with narcolepsy had a 77% higher risk for CVD and an 82% higher risk for MACE than those without the disorder.

“These findings indicate that it is important for clinicians to regularly monitor patients for cardiovascular disease and take this into consideration when recommending specific treatments for narcolepsy,” study investigators Christopher Kaufmann, PhD; Munaza Riaz, PharmD, MPhil; and Rakesh Bhattacharjee, MD, told this news organization.

“Additionally, physicians should consider monitoring the presence of other health conditions as contributing factors to the risk of CVD,” they said. Dr. Kaufmann and Dr. Riaz are with the University of Florida, Gainesville, Florida, and Dr. Bhattacharjee is with the University of California, San Diego.

They presented their research at SLEEP 2024: 38th Annual Meeting of the Associated Professional Sleep Societies.
 

Independent Risk Factor

The National Institute of Neurological Disorders and Stroke reports an estimated 125,000 to 200,000 people in the United States live with narcolepsy. The condition often coexists with other common health conditions including obstructive sleep apnea (OSA), diabetes, and other comorbidities, which can all contribute to the risk for CVD.

This raises doubt as to whether narcolepsy itself directly leads to CVD or if it is the result of these comorbid health conditions. Additionally, some medications used to treat narcolepsy carry their own cardiovascular risks.

Using the IBM MarketScan Commercial and Medicare supplemental databases, the researchers identified 34,562 adults with a diagnosis of narcolepsy and a propensity-matched comparison cohort of 100,405 adults without narcolepsy. The patients had a mean age of 40 years, and 62% were women.

Compared with adults without narcolepsy, those with the chronic sleep disorder that causes overwhelming daytime drowsiness had a 77% increased risk for any CVD (hazard ratio [HR], 1.77) and an 82% increased risk for MACE (HR, 1.82).

They also had an increased risk for stroke (HR, 2.04), heart failure or myocardial infarction (MI; HR, 1.64), and atrial fibrillation (HR, 1.58).

The results were similar in a separate analysis of the same population that also controlled for baseline use of stimulants, oxybates, and wake-promoting agents — medications commonly used to treat excessive daytime sleepiness associated with narcolepsy.

In this analysis, narcolepsy was associated with an 89% higher risk for CVD (HR, 1.89) and a 95% increased risk for MACE (HR, 1.95). The risk for any stroke (HR, 2.06), heart failure (HR, 1.90), atrial fibrillation (HR, 1.66), and MI (HR, 1.93) was also higher in those with narcolepsy.

“Our study found that even after considering the presence of health conditions like obstructive sleep apnea, diabetes, hypertension, hyperlipidemia, and even depression, as well as medication use, there still appears to be an independent relationship between narcolepsy and CVD,” the investigators said.

They cautioned that the mechanisms explaining the link between CVD and narcolepsy are unclear and warrant further study.

“Sleep fragmentation is a hallmark of narcolepsy, and it is speculated that this fragmentation, which may trigger disturbances in autonomic function, predisposes individuals to CVD. In rodent models, a possible link has been observed between hypocretin — a central neurotransmitter that is reduced or deficient in patients with narcolepsy — and atherosclerosis.

“However, it remains uncertain whether this is the primary mechanism related to CVD,” they commented.
 

Compelling Evidence for Higher CVD

Commenting on the findings for this news organization, Shaheen Lakhan, MD, a neurologist and researcher based in Miami, Florida, called for narcolepsy to be recognized as a significant contributor to higher CVD risk.

“Given the compelling evidence linking narcolepsy to a higher incidence of cardiovascular disease, it is crucial that narcolepsy be included in clinical guidelines and risk assessment tools alongside other known risk factors,” said Dr. Lakhan, who was not involved in this research.

“Physicians and health care providers should proactively address the increased cardiovascular risk associated with narcolepsy by incorporating preventive strategies and interventions into the management of patients with this condition,” Dr. Lakhan suggested.

Regular CVD screening, a healthier lifestyle, and targeted therapies could all decrease cardiac risk, Dr. Lakhan added.

“Ultimately, novel disease-modifying therapies for narcolepsy should target the core mechanisms driving the increased cardiovascular risk associated with this condition. By elucidating the specific biological pathways and developing targeted therapies that address the unique challenges faced by narcolepsy patients, we can effectively mitigate the risk,” Dr. Lakhan said.

The studies were funded by the Sleep Research Society Foundation. The authors and Dr. Lakhan had no relevant disclosures.

A version of this article appeared on Medscape.com.

Humans have used salt for centuries, to preserve or cure food before refrigeration was readily available, and even as currency in some cultures. Though modern food preservation efforts have decreased our reliance on salt, we still heavily incorporate it as a flavor enhancer. 

It’s only relatively recently that we’ve begun limiting salt in our diets, as research has linked high sodium intake with chronic, preventable conditions like hypertension, heart disease, and kidney disease.
 

How to Recommend Restriction in a Helpful Way 

The US Department of Agriculture’s Dietary Guidelines for Americans recommends intake of no more than 2300 mg of sodium daily for adults and children aged 14 years or older. This echoes similar recommendations for people at risk for heart disease, kidney disease, and hypertension. However, the sodium intake of the average American still sits at a whopping 3400 mg daily. 

High sodium intake is primarily the result of modern commercial food processing. Food prepared outside the home accounts for up to 70% of sodium intake in the United States, whereas only about 10% comes from salt that is added to food either during or after cooking. For this reason, I hesitate to recommend withholding salt as a primary focus when counseling on a low-sodium diet. 

To many people, certain foods just taste better with salt. Many of my patients in the southern United States simply will not eat foods like eggs and tomatoes if they cannot salt them. We can spend every moment of patient interaction time explaining why excess sodium is unhealthy, but the fact remains that humans prefer food that tastes good. This is why I try to avoid counseling a “no-added-salt” diet; instead, I recommend a low-sodium diet with a focus on fresh, whole foods and limiting salt to only a few food items. 

Patients should be counseled to slowly restrict their salt intake and be made aware that doing so may increase the time it takes for their sensitivity to the taste of less salty foods to return. But it is also important for them to know that it will return. The surest way to kill progress is for an unprepared patient to believe that their food will taste bland forever. A prepared patient understands that their food may taste different for a couple of weeks, but that the change will not last forever.
 

Types of Salt 

I have often worked with patients who insist that their sodium intake is acceptable because they are using sea salt instead of table salt. This is the result of exceptional marketing and misinformation. 

Specialty salts like sea salt and Himalayan pink salt contain about 560 mg and 590 mg of sodium, respectively, per quarter teaspoon. These products do have a slightly different mineral content, with sea salt typically having a negligible amount of calcium, magnesium, or potassium. The very small amount of these minerals offers no obvious health benefits compared with more affordable table salt. 

The sodium content of iodized table salt is comparable to these products, with about 590 mg of sodium per quarter teaspoon. Though its high sodium content will put some practitioners off, it is also an excellent source of iodine, at about 75 mg per serving. It has been estimated that upward of 35% of the US population has iodine deficiency, most commonly due to pregnancy, avoidance of dairy products, increasing rates of vegetarianism, intake of highly processed foods, and avoidance of added salt. For this reason, and its relative affordability, I find table salt to be far more appropriate for the average American than specialty salts.
 

Salt Substitutes 

Monosodium glutamate (MSG). MSG was previously at the center of public health concern owing to reports of “Chinese restaurant syndrome” that have since been debunked. I often recommend MSG to people trying to decrease sodium intake because the US Food and Drug Administration has designated it as GRAS (“generally recognized as safe”), and it has about one quarter of the sodium content of table salt at 125 mg per quarter teaspoon. Its crystalline structure makes it a lower-sodium salt substitute in savory applications like soups, stews, and gravies. 

Hot sauce. These sauces are generally composed of peppers, vinegar, salt, and sugar. There may be some variation and occasionally added ingredients depending upon the brand. However, I find most hot sauces to be a low-sodium seasoning option that works especially well on proteins like eggs, chicken, and pork. 

Potassium-based substitutes. Salt alternatives such as Nu-Salt and Morton Salt Substitute are sodium-free options with a significant amount of potassium, at 525 mg per quarter-teaspoon serving. These alternatives may not be ideal for patients with kidney problems, but they can be very helpful for those with potassium deficiency. 

Herb-based seasonings. Garlic and onion powder are both sodium-free seasonings that many of my patients have found help to increase palatability while decreasing salt use. Black pepper; lemon and lime juice; salt-free herb mixes like Mrs. Dash; and spices like cumin, paprika, dill, chili powder, and ginger are also sodium-free or low-sodium alternatives that can help to alleviate blandness for someone new to a low-sodium diet. I recommend them often and use them in my own cooking at home.

Plant-based diet. If the goal of care is to improve cardiovascular or kidney health, then I find that working with patients to increase intake of plant foods to be a helpful option. This way of eating encourages replacing highly processed foods that may be high in sodium and sugar with plants that tend to be higher in potassium and calcium. The Dietary Approaches to Stop Hypertension (DASH), Mediterranean, and other plant-based diets have been shown to increase cardiovascular and metabolic health by significantly decreasing serum lipids, blood pressure, and hemoglobin A1c and promoting weight loss. They have also been shown to increase the gut microbiome and promote increased cognitive function. 

I rarely encourage the use of added salt. However, research shows that putting down the salt shaker is probably not the most effective option to restrict sodium intake. For those who can cut back, these options can help keep food flavorful and patients compliant. 

Ms. Winfree is a renal dietitian in private practice in Mary Esther, Florida. She has disclosed no relevant financial relationships.

A version of this article appeared on Medscape.com.

Humans have used salt for centuries, to preserve or cure food before refrigeration was readily available, and even as currency in some cultures. Though modern food preservation efforts have decreased our reliance on salt, we still heavily incorporate it as a flavor enhancer. 

It’s only relatively recently that we’ve begun limiting salt in our diets, as research has linked high sodium intake with chronic, preventable conditions like hypertension, heart disease, and kidney disease.
 

How to Recommend Restriction in a Helpful Way 

The US Department of Agriculture’s Dietary Guidelines for Americans recommends intake of no more than 2300 mg of sodium daily for adults and children aged 14 years or older. This echoes similar recommendations for people at risk for heart disease, kidney disease, and hypertension. However, the sodium intake of the average American still sits at a whopping 3400 mg daily. 

High sodium intake is primarily the result of modern commercial food processing. Food prepared outside the home accounts for up to 70% of sodium intake in the United States, whereas only about 10% comes from salt that is added to food either during or after cooking. For this reason, I hesitate to recommend withholding salt as a primary focus when counseling on a low-sodium diet. 

To many people, certain foods just taste better with salt. Many of my patients in the southern United States simply will not eat foods like eggs and tomatoes if they cannot salt them. We can spend every moment of patient interaction time explaining why excess sodium is unhealthy, but the fact remains that humans prefer food that tastes good. This is why I try to avoid counseling a “no-added-salt” diet; instead, I recommend a low-sodium diet with a focus on fresh, whole foods and limiting salt to only a few food items. 

Patients should be counseled to slowly restrict their salt intake and be made aware that doing so may increase the time it takes for their sensitivity to the taste of less salty foods to return. But it is also important for them to know that it will return. The surest way to kill progress is for an unprepared patient to believe that their food will taste bland forever. A prepared patient understands that their food may taste different for a couple of weeks, but that the change will not last forever.
 

Types of Salt 

I have often worked with patients who insist that their sodium intake is acceptable because they are using sea salt instead of table salt. This is the result of exceptional marketing and misinformation. 

Specialty salts like sea salt and Himalayan pink salt contain about 560 mg and 590 mg of sodium, respectively, per quarter teaspoon. These products do have a slightly different mineral content, with sea salt typically having a negligible amount of calcium, magnesium, or potassium. The very small amount of these minerals offers no obvious health benefits compared with more affordable table salt. 

The sodium content of iodized table salt is comparable to these products, with about 590 mg of sodium per quarter teaspoon. Though its high sodium content will put some practitioners off, it is also an excellent source of iodine, at about 75 mg per serving. It has been estimated that upward of 35% of the US population has iodine deficiency, most commonly due to pregnancy, avoidance of dairy products, increasing rates of vegetarianism, intake of highly processed foods, and avoidance of added salt. For this reason, and its relative affordability, I find table salt to be far more appropriate for the average American than specialty salts.
 

Salt Substitutes 

Monosodium glutamate (MSG). MSG was previously at the center of public health concern owing to reports of “Chinese restaurant syndrome” that have since been debunked. I often recommend MSG to people trying to decrease sodium intake because the US Food and Drug Administration has designated it as GRAS (“generally recognized as safe”), and it has about one quarter of the sodium content of table salt at 125 mg per quarter teaspoon. Its crystalline structure makes it a lower-sodium salt substitute in savory applications like soups, stews, and gravies. 

Hot sauce. These sauces are generally composed of peppers, vinegar, salt, and sugar. There may be some variation and occasionally added ingredients depending upon the brand. However, I find most hot sauces to be a low-sodium seasoning option that works especially well on proteins like eggs, chicken, and pork. 

Potassium-based substitutes. Salt alternatives such as Nu-Salt and Morton Salt Substitute are sodium-free options with a significant amount of potassium, at 525 mg per quarter-teaspoon serving. These alternatives may not be ideal for patients with kidney problems, but they can be very helpful for those with potassium deficiency. 

Herb-based seasonings. Garlic and onion powder are both sodium-free seasonings that many of my patients have found help to increase palatability while decreasing salt use. Black pepper; lemon and lime juice; salt-free herb mixes like Mrs. Dash; and spices like cumin, paprika, dill, chili powder, and ginger are also sodium-free or low-sodium alternatives that can help to alleviate blandness for someone new to a low-sodium diet. I recommend them often and use them in my own cooking at home.

Plant-based diet. If the goal of care is to improve cardiovascular or kidney health, then I find that working with patients to increase intake of plant foods to be a helpful option. This way of eating encourages replacing highly processed foods that may be high in sodium and sugar with plants that tend to be higher in potassium and calcium. The Dietary Approaches to Stop Hypertension (DASH), Mediterranean, and other plant-based diets have been shown to increase cardiovascular and metabolic health by significantly decreasing serum lipids, blood pressure, and hemoglobin A1c and promoting weight loss. They have also been shown to increase the gut microbiome and promote increased cognitive function. 

I rarely encourage the use of added salt. However, research shows that putting down the salt shaker is probably not the most effective option to restrict sodium intake. For those who can cut back, these options can help keep food flavorful and patients compliant. 

Ms. Winfree is a renal dietitian in private practice in Mary Esther, Florida. She has disclosed no relevant financial relationships.

A version of this article appeared on Medscape.com.

Humans have used salt for centuries, to preserve or cure food before refrigeration was readily available, and even as currency in some cultures. Though modern food preservation efforts have decreased our reliance on salt, we still heavily incorporate it as a flavor enhancer. 

It’s only relatively recently that we’ve begun limiting salt in our diets, as research has linked high sodium intake with chronic, preventable conditions like hypertension, heart disease, and kidney disease.
 

How to Recommend Restriction in a Helpful Way 

The US Department of Agriculture’s Dietary Guidelines for Americans recommends intake of no more than 2300 mg of sodium daily for adults and children aged 14 years or older. This echoes similar recommendations for people at risk for heart disease, kidney disease, and hypertension. However, the sodium intake of the average American still sits at a whopping 3400 mg daily. 

High sodium intake is primarily the result of modern commercial food processing. Food prepared outside the home accounts for up to 70% of sodium intake in the United States, whereas only about 10% comes from salt that is added to food either during or after cooking. For this reason, I hesitate to recommend withholding salt as a primary focus when counseling on a low-sodium diet. 

To many people, certain foods just taste better with salt. Many of my patients in the southern United States simply will not eat foods like eggs and tomatoes if they cannot salt them. We can spend every moment of patient interaction time explaining why excess sodium is unhealthy, but the fact remains that humans prefer food that tastes good. This is why I try to avoid counseling a “no-added-salt” diet; instead, I recommend a low-sodium diet with a focus on fresh, whole foods and limiting salt to only a few food items. 

Patients should be counseled to slowly restrict their salt intake and be made aware that doing so may increase the time it takes for their sensitivity to the taste of less salty foods to return. But it is also important for them to know that it will return. The surest way to kill progress is for an unprepared patient to believe that their food will taste bland forever. A prepared patient understands that their food may taste different for a couple of weeks, but that the change will not last forever.
 

Types of Salt 

I have often worked with patients who insist that their sodium intake is acceptable because they are using sea salt instead of table salt. This is the result of exceptional marketing and misinformation. 

Specialty salts like sea salt and Himalayan pink salt contain about 560 mg and 590 mg of sodium, respectively, per quarter teaspoon. These products do have a slightly different mineral content, with sea salt typically having a negligible amount of calcium, magnesium, or potassium. The very small amount of these minerals offers no obvious health benefits compared with more affordable table salt. 

The sodium content of iodized table salt is comparable to these products, with about 590 mg of sodium per quarter teaspoon. Though its high sodium content will put some practitioners off, it is also an excellent source of iodine, at about 75 mg per serving. It has been estimated that upward of 35% of the US population has iodine deficiency, most commonly due to pregnancy, avoidance of dairy products, increasing rates of vegetarianism, intake of highly processed foods, and avoidance of added salt. For this reason, and its relative affordability, I find table salt to be far more appropriate for the average American than specialty salts.
 

Salt Substitutes 

Monosodium glutamate (MSG). MSG was previously at the center of public health concern owing to reports of “Chinese restaurant syndrome” that have since been debunked. I often recommend MSG to people trying to decrease sodium intake because the US Food and Drug Administration has designated it as GRAS (“generally recognized as safe”), and it has about one quarter of the sodium content of table salt at 125 mg per quarter teaspoon. Its crystalline structure makes it a lower-sodium salt substitute in savory applications like soups, stews, and gravies. 

Hot sauce. These sauces are generally composed of peppers, vinegar, salt, and sugar. There may be some variation and occasionally added ingredients depending upon the brand. However, I find most hot sauces to be a low-sodium seasoning option that works especially well on proteins like eggs, chicken, and pork. 

Potassium-based substitutes. Salt alternatives such as Nu-Salt and Morton Salt Substitute are sodium-free options with a significant amount of potassium, at 525 mg per quarter-teaspoon serving. These alternatives may not be ideal for patients with kidney problems, but they can be very helpful for those with potassium deficiency. 

Herb-based seasonings. Garlic and onion powder are both sodium-free seasonings that many of my patients have found help to increase palatability while decreasing salt use. Black pepper; lemon and lime juice; salt-free herb mixes like Mrs. Dash; and spices like cumin, paprika, dill, chili powder, and ginger are also sodium-free or low-sodium alternatives that can help to alleviate blandness for someone new to a low-sodium diet. I recommend them often and use them in my own cooking at home.

Plant-based diet. If the goal of care is to improve cardiovascular or kidney health, then I find that working with patients to increase intake of plant foods to be a helpful option. This way of eating encourages replacing highly processed foods that may be high in sodium and sugar with plants that tend to be higher in potassium and calcium. The Dietary Approaches to Stop Hypertension (DASH), Mediterranean, and other plant-based diets have been shown to increase cardiovascular and metabolic health by significantly decreasing serum lipids, blood pressure, and hemoglobin A1c and promoting weight loss. They have also been shown to increase the gut microbiome and promote increased cognitive function. 

I rarely encourage the use of added salt. However, research shows that putting down the salt shaker is probably not the most effective option to restrict sodium intake. For those who can cut back, these options can help keep food flavorful and patients compliant. 

Ms. Winfree is a renal dietitian in private practice in Mary Esther, Florida. She has disclosed no relevant financial relationships.

A version of this article appeared on Medscape.com.

High levels of xylitol, a low-calorie sweetener used in many reduced-sugar foods as well as gum and toothpaste, are linked to an increased risk of heart attacks, strokes, and death, says a new study published in the European Heart Journal.

The research team studied more than 3000 people in the US and Europe over 3 years and found that people with the highest amount of xylitol in their plasma were more likely to have a problem with their heart or blood vessels.

To show the early effects of xylitol, researchers studied platelet activity in volunteers who consumed a xylitol-sweetened drink and a glucose-sweetened drink. The xylitol levels went up by 1000 times in people after the xylitol drink but not after the glucose-sweetened drink.

Xylitol is naturally found in small amounts in fruit and vegetables, and it’s been used more as a sugar substitute over the past decade in processed foods, toothpaste, chewing gum, and other products.

“This study again shows the immediate need for investigating sugar alcohols and artificial sweeteners, especially as they continue to be recommended in combating conditions like obesity or diabetes,” Stanley Hazen, MD, chair of the Department of Cardiovascular and Metabolic Sciences at Cleveland Clinic’s Lerner Research Institute, Cleveland, Ohio, said in a news release.

“It does not mean throw out your toothpaste if it has xylitol in it, but we should be aware that consumption of a product containing high levels could increase the risk of blood clot-related events.”

A similar link between erythritol, another sugar substance, and problems with the heart and blood vessels was found last year by the same research team, the release said.

In a response to the study, the Calorie Control Council, a trade association representing the low- and reduced-calorie food and beverage industry, said xylitol has been approved for decades by government agencies. The study results may not apply to the general population because some people in the study already had a higher risk of having problems with their heart and blood vessels, it said.

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

High levels of xylitol, a low-calorie sweetener used in many reduced-sugar foods as well as gum and toothpaste, are linked to an increased risk of heart attacks, strokes, and death, says a new study published in the European Heart Journal.

The research team studied more than 3000 people in the US and Europe over 3 years and found that people with the highest amount of xylitol in their plasma were more likely to have a problem with their heart or blood vessels.

To show the early effects of xylitol, researchers studied platelet activity in volunteers who consumed a xylitol-sweetened drink and a glucose-sweetened drink. The xylitol levels went up by 1000 times in people after the xylitol drink but not after the glucose-sweetened drink.

Xylitol is naturally found in small amounts in fruit and vegetables, and it’s been used more as a sugar substitute over the past decade in processed foods, toothpaste, chewing gum, and other products.

“This study again shows the immediate need for investigating sugar alcohols and artificial sweeteners, especially as they continue to be recommended in combating conditions like obesity or diabetes,” Stanley Hazen, MD, chair of the Department of Cardiovascular and Metabolic Sciences at Cleveland Clinic’s Lerner Research Institute, Cleveland, Ohio, said in a news release.

“It does not mean throw out your toothpaste if it has xylitol in it, but we should be aware that consumption of a product containing high levels could increase the risk of blood clot-related events.”

A similar link between erythritol, another sugar substance, and problems with the heart and blood vessels was found last year by the same research team, the release said.

In a response to the study, the Calorie Control Council, a trade association representing the low- and reduced-calorie food and beverage industry, said xylitol has been approved for decades by government agencies. The study results may not apply to the general population because some people in the study already had a higher risk of having problems with their heart and blood vessels, it said.

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

High levels of xylitol, a low-calorie sweetener used in many reduced-sugar foods as well as gum and toothpaste, are linked to an increased risk of heart attacks, strokes, and death, says a new study published in the European Heart Journal.

The research team studied more than 3000 people in the US and Europe over 3 years and found that people with the highest amount of xylitol in their plasma were more likely to have a problem with their heart or blood vessels.

To show the early effects of xylitol, researchers studied platelet activity in volunteers who consumed a xylitol-sweetened drink and a glucose-sweetened drink. The xylitol levels went up by 1000 times in people after the xylitol drink but not after the glucose-sweetened drink.

Xylitol is naturally found in small amounts in fruit and vegetables, and it’s been used more as a sugar substitute over the past decade in processed foods, toothpaste, chewing gum, and other products.

“This study again shows the immediate need for investigating sugar alcohols and artificial sweeteners, especially as they continue to be recommended in combating conditions like obesity or diabetes,” Stanley Hazen, MD, chair of the Department of Cardiovascular and Metabolic Sciences at Cleveland Clinic’s Lerner Research Institute, Cleveland, Ohio, said in a news release.

“It does not mean throw out your toothpaste if it has xylitol in it, but we should be aware that consumption of a product containing high levels could increase the risk of blood clot-related events.”

A similar link between erythritol, another sugar substance, and problems with the heart and blood vessels was found last year by the same research team, the release said.

In a response to the study, the Calorie Control Council, a trade association representing the low- and reduced-calorie food and beverage industry, said xylitol has been approved for decades by government agencies. The study results may not apply to the general population because some people in the study already had a higher risk of having problems with their heart and blood vessels, it said.

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

When combined with clinical scores, a “game-changing” blood test can expedite the diagnosis and treatment of large vessel occlusion (LVO) stroke, potentially saving many lives, new data suggested.

Using cutoff levels of two blood biomarkers, glial fibrillary acidic protein (GFAP; 213 pg/mL) and D-dimer (600 ng/mL), and the field assessment stroke triage for emergency destination (FAST-ED) (score, > 2), investigators were able to detect LVOs with 81% sensitivity and 93% specificity less than 6 hours from the onset of symptoms.

GFAP has previously been linked to brain bleeds and traumatic brain injury.

The test also ruled out all patients with brain bleeds, and investigators noted that it could also be used to detect intracerebral hemorrhage.

“We have developed a game-changing, accessible tool that could help ensure that more people suffering from stroke are in the right place at the right time to receive critical, life-restoring care,” senior author Joshua Bernstock, MD, PhD, MPH, a clinical fellow in the department of neurosurgery at Brigham and Women’s Hospital in Boston, said in a press release.

The findings were published online on May 17 in Stroke: Vascular and Interventional Neurology.
 

Early Identification Crucial

Acute LVO stroke is one of the most treatable stroke types because of the availability of endovascular thrombectomy (EVT). However, EVT requires specialized equipment and teams that represent a small subset of accredited stroke centers and an even smaller subset of emergency medical facilities, so early identification of LVO is crucial, the investigators noted.

Dr. Bernstock and his team developed the TIME trial to assess the sensitivity and specificity of the blood biomarkers and scale cutoff values for identifying LVO vs non-LVO stroke.

As part of the observational prospective cohort trial, investigators included consecutive patients admitted to the Brandon Regional Hospital Emergency Department in Brandon, Florida, between May 2021 and August 2022 if they were referred for a suspected stroke and the time from symptom onset was under 18 hours.

Patients were excluded if they received thrombolytic therapy before blood was collected or if it was anticipated that blood collection would be difficult.

Investigators gathered information on patients’ clinical data, hematology results, time since last known well, and imaging findings to construct a clinical diagnosis (LVO, non-LVO, ischemic stroke, hemorrhagic stroke, or transient ischemic attack [TIA]).

In addition to the National Institutes of Health Stroke Scale, patients were assessed with the FAST-ED, the Rapid Arterial oCclusion Evaluation (RACE), the Cincinnati Stroke Triage Assessment Tool, and the Emergency Medical Stroke Assessment.

Of 323 patients in the final study sample, 29 (9%) had LVO ischemic stroke, and 48 (15%) had non-LVO ischemic stroke. Another 13 (4%) had hemorrhagic stroke, 12 had TIA (3.7%), and the largest proportion of patients had stroke mimic (n = 220; 68%), which included encephalopathy, hyperglycemia, hypertensive emergency, migraine, posterior reversible encephalopathy syndrome, and undetermined.
 

The Case for Biomarkers

When investigators looked at those with LVO ischemic stroke, they found the concentration of plasma D-dimer was significantly higher than that in patients with non-LVO suspected stroke (LVO suspected stroke, 1213 ng/mL; interquartile range [IQR], 733-1609 vs non-LVO suspected stroke, 617 ng/mL; IQR, 377-1345; P < .001).

In addition, GFAP was significantly increased in the plasma of patients with hemorrhagic stroke vs all other patients with suspected stroke (hemorrhagic stroke, 1464 pg/mL; IQR, 292-2580 vs nonhemorrhagic suspected stroke, 48 pg/mL; IQR, 12-98; P < .005).

Combinations of the blood biomarkers with the scales FAST-ED or RACE showed the best performance for LVO detection, with a specificity of 94% (for either scale combination) and a sensitivity of 71% for both scales.

When investigators analyzed data for just those patients identified within 6 hours of symptom onset, the combination of biomarkers plus FAST-ED resulted in a specificity of 93% and a sensitivity of 81%.

Given that clinical stroke scales in patients with hemorrhagic stroke frequently suggest LVO and that these patients are not candidates for EVT, a tool capable of ruling out hemorrhage and identifying only nonhemorrhagic ischemic LVO is essential, the investigators noted.

“In stroke care, time is brain,” Dr. Bernstock said. “The sooner a patient is put on the right care pathway, the better they are going to do. Whether that means ruling out bleeds or ruling in something that needs an intervention, being able to do this in a prehospital setting with the technology that we built is going to be truly transformative.”

The study was funded by the Innovate UK grant and private funding. Dr. Bernstock has positions and equity in Pockit Diagnostics Ltd. and Treovir Inc. and is on the boards of Centile Bio and NeuroX1. Other disclosures are noted in the original article.
 

A version of this article appeared on Medscape.com.

When combined with clinical scores, a “game-changing” blood test can expedite the diagnosis and treatment of large vessel occlusion (LVO) stroke, potentially saving many lives, new data suggested.

Using cutoff levels of two blood biomarkers, glial fibrillary acidic protein (GFAP; 213 pg/mL) and D-dimer (600 ng/mL), and the field assessment stroke triage for emergency destination (FAST-ED) (score, > 2), investigators were able to detect LVOs with 81% sensitivity and 93% specificity less than 6 hours from the onset of symptoms.

GFAP has previously been linked to brain bleeds and traumatic brain injury.

The test also ruled out all patients with brain bleeds, and investigators noted that it could also be used to detect intracerebral hemorrhage.

“We have developed a game-changing, accessible tool that could help ensure that more people suffering from stroke are in the right place at the right time to receive critical, life-restoring care,” senior author Joshua Bernstock, MD, PhD, MPH, a clinical fellow in the department of neurosurgery at Brigham and Women’s Hospital in Boston, said in a press release.

The findings were published online on May 17 in Stroke: Vascular and Interventional Neurology.
 

Early Identification Crucial

Acute LVO stroke is one of the most treatable stroke types because of the availability of endovascular thrombectomy (EVT). However, EVT requires specialized equipment and teams that represent a small subset of accredited stroke centers and an even smaller subset of emergency medical facilities, so early identification of LVO is crucial, the investigators noted.

Dr. Bernstock and his team developed the TIME trial to assess the sensitivity and specificity of the blood biomarkers and scale cutoff values for identifying LVO vs non-LVO stroke.

As part of the observational prospective cohort trial, investigators included consecutive patients admitted to the Brandon Regional Hospital Emergency Department in Brandon, Florida, between May 2021 and August 2022 if they were referred for a suspected stroke and the time from symptom onset was under 18 hours.

Patients were excluded if they received thrombolytic therapy before blood was collected or if it was anticipated that blood collection would be difficult.

Investigators gathered information on patients’ clinical data, hematology results, time since last known well, and imaging findings to construct a clinical diagnosis (LVO, non-LVO, ischemic stroke, hemorrhagic stroke, or transient ischemic attack [TIA]).

In addition to the National Institutes of Health Stroke Scale, patients were assessed with the FAST-ED, the Rapid Arterial oCclusion Evaluation (RACE), the Cincinnati Stroke Triage Assessment Tool, and the Emergency Medical Stroke Assessment.

Of 323 patients in the final study sample, 29 (9%) had LVO ischemic stroke, and 48 (15%) had non-LVO ischemic stroke. Another 13 (4%) had hemorrhagic stroke, 12 had TIA (3.7%), and the largest proportion of patients had stroke mimic (n = 220; 68%), which included encephalopathy, hyperglycemia, hypertensive emergency, migraine, posterior reversible encephalopathy syndrome, and undetermined.
 

The Case for Biomarkers

When investigators looked at those with LVO ischemic stroke, they found the concentration of plasma D-dimer was significantly higher than that in patients with non-LVO suspected stroke (LVO suspected stroke, 1213 ng/mL; interquartile range [IQR], 733-1609 vs non-LVO suspected stroke, 617 ng/mL; IQR, 377-1345; P < .001).

In addition, GFAP was significantly increased in the plasma of patients with hemorrhagic stroke vs all other patients with suspected stroke (hemorrhagic stroke, 1464 pg/mL; IQR, 292-2580 vs nonhemorrhagic suspected stroke, 48 pg/mL; IQR, 12-98; P < .005).

Combinations of the blood biomarkers with the scales FAST-ED or RACE showed the best performance for LVO detection, with a specificity of 94% (for either scale combination) and a sensitivity of 71% for both scales.

When investigators analyzed data for just those patients identified within 6 hours of symptom onset, the combination of biomarkers plus FAST-ED resulted in a specificity of 93% and a sensitivity of 81%.

Given that clinical stroke scales in patients with hemorrhagic stroke frequently suggest LVO and that these patients are not candidates for EVT, a tool capable of ruling out hemorrhage and identifying only nonhemorrhagic ischemic LVO is essential, the investigators noted.

“In stroke care, time is brain,” Dr. Bernstock said. “The sooner a patient is put on the right care pathway, the better they are going to do. Whether that means ruling out bleeds or ruling in something that needs an intervention, being able to do this in a prehospital setting with the technology that we built is going to be truly transformative.”

The study was funded by the Innovate UK grant and private funding. Dr. Bernstock has positions and equity in Pockit Diagnostics Ltd. and Treovir Inc. and is on the boards of Centile Bio and NeuroX1. Other disclosures are noted in the original article.
 

A version of this article appeared on Medscape.com.

When combined with clinical scores, a “game-changing” blood test can expedite the diagnosis and treatment of large vessel occlusion (LVO) stroke, potentially saving many lives, new data suggested.

Using cutoff levels of two blood biomarkers, glial fibrillary acidic protein (GFAP; 213 pg/mL) and D-dimer (600 ng/mL), and the field assessment stroke triage for emergency destination (FAST-ED) (score, > 2), investigators were able to detect LVOs with 81% sensitivity and 93% specificity less than 6 hours from the onset of symptoms.

GFAP has previously been linked to brain bleeds and traumatic brain injury.

The test also ruled out all patients with brain bleeds, and investigators noted that it could also be used to detect intracerebral hemorrhage.

“We have developed a game-changing, accessible tool that could help ensure that more people suffering from stroke are in the right place at the right time to receive critical, life-restoring care,” senior author Joshua Bernstock, MD, PhD, MPH, a clinical fellow in the department of neurosurgery at Brigham and Women’s Hospital in Boston, said in a press release.

The findings were published online on May 17 in Stroke: Vascular and Interventional Neurology.
 

Early Identification Crucial

Acute LVO stroke is one of the most treatable stroke types because of the availability of endovascular thrombectomy (EVT). However, EVT requires specialized equipment and teams that represent a small subset of accredited stroke centers and an even smaller subset of emergency medical facilities, so early identification of LVO is crucial, the investigators noted.

Dr. Bernstock and his team developed the TIME trial to assess the sensitivity and specificity of the blood biomarkers and scale cutoff values for identifying LVO vs non-LVO stroke.

As part of the observational prospective cohort trial, investigators included consecutive patients admitted to the Brandon Regional Hospital Emergency Department in Brandon, Florida, between May 2021 and August 2022 if they were referred for a suspected stroke and the time from symptom onset was under 18 hours.

Patients were excluded if they received thrombolytic therapy before blood was collected or if it was anticipated that blood collection would be difficult.

Investigators gathered information on patients’ clinical data, hematology results, time since last known well, and imaging findings to construct a clinical diagnosis (LVO, non-LVO, ischemic stroke, hemorrhagic stroke, or transient ischemic attack [TIA]).

In addition to the National Institutes of Health Stroke Scale, patients were assessed with the FAST-ED, the Rapid Arterial oCclusion Evaluation (RACE), the Cincinnati Stroke Triage Assessment Tool, and the Emergency Medical Stroke Assessment.

Of 323 patients in the final study sample, 29 (9%) had LVO ischemic stroke, and 48 (15%) had non-LVO ischemic stroke. Another 13 (4%) had hemorrhagic stroke, 12 had TIA (3.7%), and the largest proportion of patients had stroke mimic (n = 220; 68%), which included encephalopathy, hyperglycemia, hypertensive emergency, migraine, posterior reversible encephalopathy syndrome, and undetermined.
 

The Case for Biomarkers

When investigators looked at those with LVO ischemic stroke, they found the concentration of plasma D-dimer was significantly higher than that in patients with non-LVO suspected stroke (LVO suspected stroke, 1213 ng/mL; interquartile range [IQR], 733-1609 vs non-LVO suspected stroke, 617 ng/mL; IQR, 377-1345; P < .001).

In addition, GFAP was significantly increased in the plasma of patients with hemorrhagic stroke vs all other patients with suspected stroke (hemorrhagic stroke, 1464 pg/mL; IQR, 292-2580 vs nonhemorrhagic suspected stroke, 48 pg/mL; IQR, 12-98; P < .005).

Combinations of the blood biomarkers with the scales FAST-ED or RACE showed the best performance for LVO detection, with a specificity of 94% (for either scale combination) and a sensitivity of 71% for both scales.

When investigators analyzed data for just those patients identified within 6 hours of symptom onset, the combination of biomarkers plus FAST-ED resulted in a specificity of 93% and a sensitivity of 81%.

Given that clinical stroke scales in patients with hemorrhagic stroke frequently suggest LVO and that these patients are not candidates for EVT, a tool capable of ruling out hemorrhage and identifying only nonhemorrhagic ischemic LVO is essential, the investigators noted.

“In stroke care, time is brain,” Dr. Bernstock said. “The sooner a patient is put on the right care pathway, the better they are going to do. Whether that means ruling out bleeds or ruling in something that needs an intervention, being able to do this in a prehospital setting with the technology that we built is going to be truly transformative.”

The study was funded by the Innovate UK grant and private funding. Dr. Bernstock has positions and equity in Pockit Diagnostics Ltd. and Treovir Inc. and is on the boards of Centile Bio and NeuroX1. Other disclosures are noted in the original article.
 

A version of this article appeared on Medscape.com.

Five commonly prescribed drugs may be associated with a lower risk for aneurysmal subarachnoid hemorrhage (aSAH), a drug-wide association study suggested.

The blood pressure drug lisinopril; the cholesterol drug simvastatin; the diabetes drug metformin; and the drug tamsulosin, prescribed for an enlarged prostate, were all associated with decreased aSAH risk, investigators found.

Conversely, four other drugs were associated with an increased risk for this severely morbid, often deadly, condition.

“The motivation for this study was the fact that we can currently prevent bleeding from intracranial aneurysms only by invasive treatment of those aneurysms with inherent complication risks,” said study investigator Ynte Ruigrok, MD, PhD, associate professor of neurology and neurosurgery, University Medical Center Utrecht, Utrecht, the Netherlands. “Drugs to reduce or eliminate this risk are not yet available. This study is a first step in identifying such drugs.”

The findings were published online in Neurology.
 

Surprising Results

For the study, the researchers used the Secure Anonymized Information Linkage data bank in Wales to identify 4879 patients with aSAH between January 2000 and December 2019 and 43,911 patients without aSAH matched on age, sex, and year of database entry. Clustering resulted in 2023 unique drugs, of which 205 were commonly prescribed.

After adjusting for other factors such as high blood pressure, alcohol abuse, smoking, and a total number of health conditions, the results yielded two surprises, Dr. Ruigrok observed.

The first was a significant decrease in aSAH risk for current use of lisinopril, compared with nonuse (odds ratio [OR], 0.63; 95% confidence interval [CI], 0.44-0.90), and a nonsignificant decrease with current use of amlodipine (OR, 0.82; 95% CI, 0.65-1.04).

“Hypertension is a major risk factor for occurrence and bleeding from aneurysms. If there is indeed a specific blood pressure–lowering drug that not only has a blood pressure–lowering effect but also has additional protection against aSAH, then perhaps that drug should become the drug of choice in aneurysm patients in the future,” he said.

Notably, recent use of both drugs, defined as between 1 year and 3 months before the index date, was associated with an increased risk for aSAH. This trend was not found for other antihypertensives and was significant for amlodipine but not lisinopril.

The reasons are unclear, but “we trust the findings on lisinopril more,” Dr. Ruigrok said. “The findings on amlodipine may be due to confounding by indication, specifically caused by hypertension. Therefore, it is important to validate our findings in an independent research cohort, and we are in the process of doing so.”

The study’s second surprise was the antidiabetic drug metformin and cholesterol-lowering drug simvastatin were also associated with reduced aSAH risk, Dr. Ruigrok noted.

“We already knew from previous studies that diabetes and high cholesterol are protective factors for aSAH,” he said. “Our results suggest that perhaps not the conditions themselves are protective for aSAH but rather the drugs used to treat these conditions with are.”

The risk for a ruptured brain aneurysm among current users was 42% lower with metformin (OR, 0.58; 95% CI, 0.43-0.78), 22% lower with simvastatin (OR, 0.78; 95% CI, 0.64-0.96), and 45% lower with tamsulosin (OR, 0.55; 95% CI, 0.32-0.93).

An increased risk for aSAH was found only in current users of warfarin (OR, 1.35; 95% CI, 1.02-1.79), venlafaxine (OR, 1.67; 95% CI, 1.01-2.75), prochlorperazine (OR, 2.15; 95% CI, 1.45-3.18), and co-codamol (OR, 1.31; 95% CI, 1.10-1.56).

Other drugs within the classes of vitamin K antagonists, serotonin reuptake inhibitors, conventional antipsychotics, and compound analgesics did not show an association with aSAH.

The study was limited by the use of drug prescriptions, and patients may not take their drugs or use them incorrectly, noted the researchers, led by Jos P. Kanning, MSc, also with University Medical Center Utrecht.

The study was supported by the European Research Council. The authors reported no relevant financial relationships.

A version of this article appeared on Medscape.com.

Five commonly prescribed drugs may be associated with a lower risk for aneurysmal subarachnoid hemorrhage (aSAH), a drug-wide association study suggested.

The blood pressure drug lisinopril; the cholesterol drug simvastatin; the diabetes drug metformin; and the drug tamsulosin, prescribed for an enlarged prostate, were all associated with decreased aSAH risk, investigators found.

Conversely, four other drugs were associated with an increased risk for this severely morbid, often deadly, condition.

“The motivation for this study was the fact that we can currently prevent bleeding from intracranial aneurysms only by invasive treatment of those aneurysms with inherent complication risks,” said study investigator Ynte Ruigrok, MD, PhD, associate professor of neurology and neurosurgery, University Medical Center Utrecht, Utrecht, the Netherlands. “Drugs to reduce or eliminate this risk are not yet available. This study is a first step in identifying such drugs.”

The findings were published online in Neurology.
 

Surprising Results

For the study, the researchers used the Secure Anonymized Information Linkage data bank in Wales to identify 4879 patients with aSAH between January 2000 and December 2019 and 43,911 patients without aSAH matched on age, sex, and year of database entry. Clustering resulted in 2023 unique drugs, of which 205 were commonly prescribed.

After adjusting for other factors such as high blood pressure, alcohol abuse, smoking, and a total number of health conditions, the results yielded two surprises, Dr. Ruigrok observed.

The first was a significant decrease in aSAH risk for current use of lisinopril, compared with nonuse (odds ratio [OR], 0.63; 95% confidence interval [CI], 0.44-0.90), and a nonsignificant decrease with current use of amlodipine (OR, 0.82; 95% CI, 0.65-1.04).

“Hypertension is a major risk factor for occurrence and bleeding from aneurysms. If there is indeed a specific blood pressure–lowering drug that not only has a blood pressure–lowering effect but also has additional protection against aSAH, then perhaps that drug should become the drug of choice in aneurysm patients in the future,” he said.

Notably, recent use of both drugs, defined as between 1 year and 3 months before the index date, was associated with an increased risk for aSAH. This trend was not found for other antihypertensives and was significant for amlodipine but not lisinopril.

The reasons are unclear, but “we trust the findings on lisinopril more,” Dr. Ruigrok said. “The findings on amlodipine may be due to confounding by indication, specifically caused by hypertension. Therefore, it is important to validate our findings in an independent research cohort, and we are in the process of doing so.”

The study’s second surprise was the antidiabetic drug metformin and cholesterol-lowering drug simvastatin were also associated with reduced aSAH risk, Dr. Ruigrok noted.

“We already knew from previous studies that diabetes and high cholesterol are protective factors for aSAH,” he said. “Our results suggest that perhaps not the conditions themselves are protective for aSAH but rather the drugs used to treat these conditions with are.”

The risk for a ruptured brain aneurysm among current users was 42% lower with metformin (OR, 0.58; 95% CI, 0.43-0.78), 22% lower with simvastatin (OR, 0.78; 95% CI, 0.64-0.96), and 45% lower with tamsulosin (OR, 0.55; 95% CI, 0.32-0.93).

An increased risk for aSAH was found only in current users of warfarin (OR, 1.35; 95% CI, 1.02-1.79), venlafaxine (OR, 1.67; 95% CI, 1.01-2.75), prochlorperazine (OR, 2.15; 95% CI, 1.45-3.18), and co-codamol (OR, 1.31; 95% CI, 1.10-1.56).

Other drugs within the classes of vitamin K antagonists, serotonin reuptake inhibitors, conventional antipsychotics, and compound analgesics did not show an association with aSAH.

The study was limited by the use of drug prescriptions, and patients may not take their drugs or use them incorrectly, noted the researchers, led by Jos P. Kanning, MSc, also with University Medical Center Utrecht.

The study was supported by the European Research Council. The authors reported no relevant financial relationships.

A version of this article appeared on Medscape.com.

Five commonly prescribed drugs may be associated with a lower risk for aneurysmal subarachnoid hemorrhage (aSAH), a drug-wide association study suggested.

The blood pressure drug lisinopril; the cholesterol drug simvastatin; the diabetes drug metformin; and the drug tamsulosin, prescribed for an enlarged prostate, were all associated with decreased aSAH risk, investigators found.

Conversely, four other drugs were associated with an increased risk for this severely morbid, often deadly, condition.

“The motivation for this study was the fact that we can currently prevent bleeding from intracranial aneurysms only by invasive treatment of those aneurysms with inherent complication risks,” said study investigator Ynte Ruigrok, MD, PhD, associate professor of neurology and neurosurgery, University Medical Center Utrecht, Utrecht, the Netherlands. “Drugs to reduce or eliminate this risk are not yet available. This study is a first step in identifying such drugs.”

The findings were published online in Neurology.
 

Surprising Results

For the study, the researchers used the Secure Anonymized Information Linkage data bank in Wales to identify 4879 patients with aSAH between January 2000 and December 2019 and 43,911 patients without aSAH matched on age, sex, and year of database entry. Clustering resulted in 2023 unique drugs, of which 205 were commonly prescribed.

After adjusting for other factors such as high blood pressure, alcohol abuse, smoking, and a total number of health conditions, the results yielded two surprises, Dr. Ruigrok observed.

The first was a significant decrease in aSAH risk for current use of lisinopril, compared with nonuse (odds ratio [OR], 0.63; 95% confidence interval [CI], 0.44-0.90), and a nonsignificant decrease with current use of amlodipine (OR, 0.82; 95% CI, 0.65-1.04).

“Hypertension is a major risk factor for occurrence and bleeding from aneurysms. If there is indeed a specific blood pressure–lowering drug that not only has a blood pressure–lowering effect but also has additional protection against aSAH, then perhaps that drug should become the drug of choice in aneurysm patients in the future,” he said.

Notably, recent use of both drugs, defined as between 1 year and 3 months before the index date, was associated with an increased risk for aSAH. This trend was not found for other antihypertensives and was significant for amlodipine but not lisinopril.

The reasons are unclear, but “we trust the findings on lisinopril more,” Dr. Ruigrok said. “The findings on amlodipine may be due to confounding by indication, specifically caused by hypertension. Therefore, it is important to validate our findings in an independent research cohort, and we are in the process of doing so.”

The study’s second surprise was the antidiabetic drug metformin and cholesterol-lowering drug simvastatin were also associated with reduced aSAH risk, Dr. Ruigrok noted.

“We already knew from previous studies that diabetes and high cholesterol are protective factors for aSAH,” he said. “Our results suggest that perhaps not the conditions themselves are protective for aSAH but rather the drugs used to treat these conditions with are.”

The risk for a ruptured brain aneurysm among current users was 42% lower with metformin (OR, 0.58; 95% CI, 0.43-0.78), 22% lower with simvastatin (OR, 0.78; 95% CI, 0.64-0.96), and 45% lower with tamsulosin (OR, 0.55; 95% CI, 0.32-0.93).

An increased risk for aSAH was found only in current users of warfarin (OR, 1.35; 95% CI, 1.02-1.79), venlafaxine (OR, 1.67; 95% CI, 1.01-2.75), prochlorperazine (OR, 2.15; 95% CI, 1.45-3.18), and co-codamol (OR, 1.31; 95% CI, 1.10-1.56).

Other drugs within the classes of vitamin K antagonists, serotonin reuptake inhibitors, conventional antipsychotics, and compound analgesics did not show an association with aSAH.

The study was limited by the use of drug prescriptions, and patients may not take their drugs or use them incorrectly, noted the researchers, led by Jos P. Kanning, MSc, also with University Medical Center Utrecht.

The study was supported by the European Research Council. The authors reported no relevant financial relationships.

A version of this article appeared on Medscape.com.

BASEL, SWITZERLAND — The anti-inflammatory agent colchicine failed to show significant benefit in the treatment of patients with non-cardioembolic ischemic stroke in the primary analysis of the CONVINCE trial. However, the results did reveal a significant reduction in recurrent stroke and cardiovascular events in the per-protocol analysis and in the subgroup of patients with coronary artery disease.

“Although the primary endpoint was neutral, the CONVINCE results support the hypothesis that long-term anti-inflammatory therapy with colchicine may reduce recurrent stroke and cardiovascular events, specifically in stroke patients with atherosclerosis,” lead investigator Peter Kelly, MD, University College Dublin School of Medicine, Dublin, Ireland, concluded.

The results were presented at the European Stroke Organization Conference (ESOC) 2024.

Inflammation, Dr. Kelly said, plays an important role in the pathophysiology of atherosclerotic plaque, a major cause of cardiovascular events and ischemic strokes.

Colchicine, an established, widely available, low-cost drug that reduces inflammatory response, has been shown to reduce recurrent vascular events in patients with coronary artery disease.

The CONVINCE trial was conducted to see whether colchicine could show similar benefits in patients with non-severe, non-cardioembolic stroke or transient ischemic attack.

Conducted in 16 European countries and Canada, the CONVINCE trial included 3154 patients with a recent non-cardioembolic nondisabling ischemic stroke or high-risk transient ischemic attack. They were randomly assigned to receive colchicine (0.5 mg/d) or placebo.

Key exclusion criteria included evidence of atrial fibrillation or other source of cardioembolism, a defined cause of stroke other than atherosclerosis or small vessel disease, a glomerular filtration rate below 50 mL/min, and the use of drugs that interact with colchicine.

The primary endpoint was a composite of first recurrent ischemic stroke, myocardial infarction, cardiac arrest, or hospitalization for unstable angina. Study participants were followed-up over 36 months.

Results of the primary intention-to-treat analysis showed that the primary endpoint occurred in 153 patients randomized to low-dose colchicine (9.8%) versus 185 in the placebo group (11.8%). This translated into a hazard ratio (HR) of 0.84 (95% CI, 0.68-1.05; P = .12) — a nonsignificant result.

Reduced levels of C-reactive protein in the colchicine group showed the anti-inflammatory effect of treatment with colchicine, Dr. Kelly reported.

In a prespecified on-treatment analysis (excluding patients with major protocol violations), colchicine did show a significant benefit in the primary endpoint (HR, 0.80; 95% CI, 0.63-0.99).
 

A Novel Target for Stroke Treatment

In addition, significantly reduced rates of recurrent stroke or cardiovascular events were observed in the subgroup of patients with a history of coronary artery disease.

In an updated meta-analysis of existing colchicine studies including CONVINCE, there was a significant reduction in the risk for ischemic stroke (risk ratio, 0.73; 95% CI, 0.58-0.90).

“The signals of benefit of colchicine in secondary analyses are in line with findings from previous trials and indicate the potential of colchicine in prevention after stroke,” Dr. Kelly said.

He pointed out that the COVID pandemic reduced the planned follow-up time in the CONVINCE trial, which led to the study being underpowered for the primary analysis.

“Further trials are needed in all stroke subtypes, but with particular focus on patients with objective evidence of atherosclerosis,” he said.

Commenting on the findings, Mira Katan, MD, University Hospital of Basel, Switzerland, noted that inflammation represents a novel target for stroke treatment.

“We have never before looked at treating inflammation in stroke. Although the primary endpoint was not reached in the CONVINCE study, the on-treatment analysis and meta-analysis showed a risk reduction, and we know colchicine works in cardiology. I think this is a fantastic trial, giving us a new target for stroke therapy,” Dr. Katan said.

“I think we have a new tool, but of course we need further trials to confirm that,” she added.

The CONVINCE trial was supported by Health Research Board Ireland, Deutsche Forschungsgesellschaft, Fonds Wetenschappelijk Onderzoek (FWO), and the Irish Heart Foundation. Dr. Kelly received funding from the Irish Heart Foundation. Dr. Katan reported no relevant disclosures.
 

A version of this article appeared on Medscape.com.

BASEL, SWITZERLAND — The anti-inflammatory agent colchicine failed to show significant benefit in the treatment of patients with non-cardioembolic ischemic stroke in the primary analysis of the CONVINCE trial. However, the results did reveal a significant reduction in recurrent stroke and cardiovascular events in the per-protocol analysis and in the subgroup of patients with coronary artery disease.

“Although the primary endpoint was neutral, the CONVINCE results support the hypothesis that long-term anti-inflammatory therapy with colchicine may reduce recurrent stroke and cardiovascular events, specifically in stroke patients with atherosclerosis,” lead investigator Peter Kelly, MD, University College Dublin School of Medicine, Dublin, Ireland, concluded.

The results were presented at the European Stroke Organization Conference (ESOC) 2024.

Inflammation, Dr. Kelly said, plays an important role in the pathophysiology of atherosclerotic plaque, a major cause of cardiovascular events and ischemic strokes.

Colchicine, an established, widely available, low-cost drug that reduces inflammatory response, has been shown to reduce recurrent vascular events in patients with coronary artery disease.

The CONVINCE trial was conducted to see whether colchicine could show similar benefits in patients with non-severe, non-cardioembolic stroke or transient ischemic attack.

Conducted in 16 European countries and Canada, the CONVINCE trial included 3154 patients with a recent non-cardioembolic nondisabling ischemic stroke or high-risk transient ischemic attack. They were randomly assigned to receive colchicine (0.5 mg/d) or placebo.

Key exclusion criteria included evidence of atrial fibrillation or other source of cardioembolism, a defined cause of stroke other than atherosclerosis or small vessel disease, a glomerular filtration rate below 50 mL/min, and the use of drugs that interact with colchicine.

The primary endpoint was a composite of first recurrent ischemic stroke, myocardial infarction, cardiac arrest, or hospitalization for unstable angina. Study participants were followed-up over 36 months.

Results of the primary intention-to-treat analysis showed that the primary endpoint occurred in 153 patients randomized to low-dose colchicine (9.8%) versus 185 in the placebo group (11.8%). This translated into a hazard ratio (HR) of 0.84 (95% CI, 0.68-1.05; P = .12) — a nonsignificant result.

Reduced levels of C-reactive protein in the colchicine group showed the anti-inflammatory effect of treatment with colchicine, Dr. Kelly reported.

In a prespecified on-treatment analysis (excluding patients with major protocol violations), colchicine did show a significant benefit in the primary endpoint (HR, 0.80; 95% CI, 0.63-0.99).
 

A Novel Target for Stroke Treatment

In addition, significantly reduced rates of recurrent stroke or cardiovascular events were observed in the subgroup of patients with a history of coronary artery disease.

In an updated meta-analysis of existing colchicine studies including CONVINCE, there was a significant reduction in the risk for ischemic stroke (risk ratio, 0.73; 95% CI, 0.58-0.90).

“The signals of benefit of colchicine in secondary analyses are in line with findings from previous trials and indicate the potential of colchicine in prevention after stroke,” Dr. Kelly said.

He pointed out that the COVID pandemic reduced the planned follow-up time in the CONVINCE trial, which led to the study being underpowered for the primary analysis.

“Further trials are needed in all stroke subtypes, but with particular focus on patients with objective evidence of atherosclerosis,” he said.

Commenting on the findings, Mira Katan, MD, University Hospital of Basel, Switzerland, noted that inflammation represents a novel target for stroke treatment.

“We have never before looked at treating inflammation in stroke. Although the primary endpoint was not reached in the CONVINCE study, the on-treatment analysis and meta-analysis showed a risk reduction, and we know colchicine works in cardiology. I think this is a fantastic trial, giving us a new target for stroke therapy,” Dr. Katan said.

“I think we have a new tool, but of course we need further trials to confirm that,” she added.

The CONVINCE trial was supported by Health Research Board Ireland, Deutsche Forschungsgesellschaft, Fonds Wetenschappelijk Onderzoek (FWO), and the Irish Heart Foundation. Dr. Kelly received funding from the Irish Heart Foundation. Dr. Katan reported no relevant disclosures.
 

A version of this article appeared on Medscape.com.

BASEL, SWITZERLAND — The anti-inflammatory agent colchicine failed to show significant benefit in the treatment of patients with non-cardioembolic ischemic stroke in the primary analysis of the CONVINCE trial. However, the results did reveal a significant reduction in recurrent stroke and cardiovascular events in the per-protocol analysis and in the subgroup of patients with coronary artery disease.

“Although the primary endpoint was neutral, the CONVINCE results support the hypothesis that long-term anti-inflammatory therapy with colchicine may reduce recurrent stroke and cardiovascular events, specifically in stroke patients with atherosclerosis,” lead investigator Peter Kelly, MD, University College Dublin School of Medicine, Dublin, Ireland, concluded.

The results were presented at the European Stroke Organization Conference (ESOC) 2024.

Inflammation, Dr. Kelly said, plays an important role in the pathophysiology of atherosclerotic plaque, a major cause of cardiovascular events and ischemic strokes.

Colchicine, an established, widely available, low-cost drug that reduces inflammatory response, has been shown to reduce recurrent vascular events in patients with coronary artery disease.

The CONVINCE trial was conducted to see whether colchicine could show similar benefits in patients with non-severe, non-cardioembolic stroke or transient ischemic attack.

Conducted in 16 European countries and Canada, the CONVINCE trial included 3154 patients with a recent non-cardioembolic nondisabling ischemic stroke or high-risk transient ischemic attack. They were randomly assigned to receive colchicine (0.5 mg/d) or placebo.

Key exclusion criteria included evidence of atrial fibrillation or other source of cardioembolism, a defined cause of stroke other than atherosclerosis or small vessel disease, a glomerular filtration rate below 50 mL/min, and the use of drugs that interact with colchicine.

The primary endpoint was a composite of first recurrent ischemic stroke, myocardial infarction, cardiac arrest, or hospitalization for unstable angina. Study participants were followed-up over 36 months.

Results of the primary intention-to-treat analysis showed that the primary endpoint occurred in 153 patients randomized to low-dose colchicine (9.8%) versus 185 in the placebo group (11.8%). This translated into a hazard ratio (HR) of 0.84 (95% CI, 0.68-1.05; P = .12) — a nonsignificant result.

Reduced levels of C-reactive protein in the colchicine group showed the anti-inflammatory effect of treatment with colchicine, Dr. Kelly reported.

In a prespecified on-treatment analysis (excluding patients with major protocol violations), colchicine did show a significant benefit in the primary endpoint (HR, 0.80; 95% CI, 0.63-0.99).
 

A Novel Target for Stroke Treatment

In addition, significantly reduced rates of recurrent stroke or cardiovascular events were observed in the subgroup of patients with a history of coronary artery disease.

In an updated meta-analysis of existing colchicine studies including CONVINCE, there was a significant reduction in the risk for ischemic stroke (risk ratio, 0.73; 95% CI, 0.58-0.90).

“The signals of benefit of colchicine in secondary analyses are in line with findings from previous trials and indicate the potential of colchicine in prevention after stroke,” Dr. Kelly said.

He pointed out that the COVID pandemic reduced the planned follow-up time in the CONVINCE trial, which led to the study being underpowered for the primary analysis.

“Further trials are needed in all stroke subtypes, but with particular focus on patients with objective evidence of atherosclerosis,” he said.

Commenting on the findings, Mira Katan, MD, University Hospital of Basel, Switzerland, noted that inflammation represents a novel target for stroke treatment.

“We have never before looked at treating inflammation in stroke. Although the primary endpoint was not reached in the CONVINCE study, the on-treatment analysis and meta-analysis showed a risk reduction, and we know colchicine works in cardiology. I think this is a fantastic trial, giving us a new target for stroke therapy,” Dr. Katan said.

“I think we have a new tool, but of course we need further trials to confirm that,” she added.

The CONVINCE trial was supported by Health Research Board Ireland, Deutsche Forschungsgesellschaft, Fonds Wetenschappelijk Onderzoek (FWO), and the Irish Heart Foundation. Dr. Kelly received funding from the Irish Heart Foundation. Dr. Katan reported no relevant disclosures.
 

A version of this article appeared on Medscape.com.

Exercise recommendations typically focus on the duration of physical activity. For example, the World Health Organization advises at least 150 minutes of moderate physical activity per week. A new analysis of data from the Women’s Health Study, published in JAMA Internal Medicine, suggested that step count could also be a useful metric. For some, such a recommendation might be easier to follow.

“It’s not so easy to keep track of how long you’ve been moderately active in a given week,” Cary P. Gross, MD, from the Department of Medicine at Yale University in New Haven, Connecticut, wrote in an editorial. “Counting steps might be easier for some people, especially since most carry a phone that can serve as a pedometer.”
 

The 10,000-Step Recommendation

However, there are no well-founded recommendations for step counts, partly due to a lack of scientific evidence linking steps with mortality and cardiovascular diseases. The often-cited 10,000 steps per day originated from a marketing campaign in Japan in the 1960s.

The research team led by Rikuta Hamaya, MD, from the Division of Preventive Medicine at Brigham and Women’s Hospital in Boston, analyzed data from participants in the Women’s Health Study. This clinical trial in the United States from 1992 to 2004 investigated the use of aspirin and vitamin E for cancer and cardiovascular disease prevention.

The current analysis included 14,399 women who were aged ≥ 62 years and had not developed cardiovascular disease or cancer. Between 2011 and 2015, they measured their physical activity and step count over 7 days using an accelerometer. They were followed-up for an average of 9 years.
 

Risk Reduction With Both Parameters

Moderate physical activity among the participants amounted to a median of 62 minutes per week, with a median daily step count of 5183. Hamaya and his colleagues found that both physical activity parameters were associated with lower mortality and reduced risk for cardiovascular diseases.

Participants who engaged in more than the recommended 150 minutes of moderate-intensity activity per week had a 32% lower mortality risk than those who were the least physically active. Women with > 7000 steps per day had a 42% lower mortality risk than those with the lowest daily step count.

Women in the top three quartiles of physical activity outlived those in the lowest quartile by an average of 2.22 months (time) or 2.36 months (steps), according to Hamaya and his team. The survival advantage was independent of body mass index.

For the endpoint of cardiovascular diseases (heart attack, stroke, and cardiovascular mortality), the researchers observed similar results as for mortality.
 

More Ways to Reach the Goal

Dr. Hamaya emphasized the importance of offering multiple ways to meet exercise recommendations: “For some, especially younger people, physical activity includes sports like tennis, soccer, walking, or jogging. All these can be tracked well with step counting. But for others, activity means cycling or swimming, which is easier to measure by duration.”

For Dr. Gross, the new findings provide a basis for using step counts to set physical activity goals — both in individual patient counseling and in formal guidelines. However, he stressed that further studies are necessary.

“The results need to be replicated in various populations, not just among men and younger people but also among ethnic minorities and lower-income populations, who often have less time and space for structured physical activity.”
 

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

Exercise recommendations typically focus on the duration of physical activity. For example, the World Health Organization advises at least 150 minutes of moderate physical activity per week. A new analysis of data from the Women’s Health Study, published in JAMA Internal Medicine, suggested that step count could also be a useful metric. For some, such a recommendation might be easier to follow.

“It’s not so easy to keep track of how long you’ve been moderately active in a given week,” Cary P. Gross, MD, from the Department of Medicine at Yale University in New Haven, Connecticut, wrote in an editorial. “Counting steps might be easier for some people, especially since most carry a phone that can serve as a pedometer.”
 

The 10,000-Step Recommendation

However, there are no well-founded recommendations for step counts, partly due to a lack of scientific evidence linking steps with mortality and cardiovascular diseases. The often-cited 10,000 steps per day originated from a marketing campaign in Japan in the 1960s.

The research team led by Rikuta Hamaya, MD, from the Division of Preventive Medicine at Brigham and Women’s Hospital in Boston, analyzed data from participants in the Women’s Health Study. This clinical trial in the United States from 1992 to 2004 investigated the use of aspirin and vitamin E for cancer and cardiovascular disease prevention.

The current analysis included 14,399 women who were aged ≥ 62 years and had not developed cardiovascular disease or cancer. Between 2011 and 2015, they measured their physical activity and step count over 7 days using an accelerometer. They were followed-up for an average of 9 years.
 

Risk Reduction With Both Parameters

Moderate physical activity among the participants amounted to a median of 62 minutes per week, with a median daily step count of 5183. Hamaya and his colleagues found that both physical activity parameters were associated with lower mortality and reduced risk for cardiovascular diseases.

Participants who engaged in more than the recommended 150 minutes of moderate-intensity activity per week had a 32% lower mortality risk than those who were the least physically active. Women with > 7000 steps per day had a 42% lower mortality risk than those with the lowest daily step count.

Women in the top three quartiles of physical activity outlived those in the lowest quartile by an average of 2.22 months (time) or 2.36 months (steps), according to Hamaya and his team. The survival advantage was independent of body mass index.

For the endpoint of cardiovascular diseases (heart attack, stroke, and cardiovascular mortality), the researchers observed similar results as for mortality.
 

More Ways to Reach the Goal

Dr. Hamaya emphasized the importance of offering multiple ways to meet exercise recommendations: “For some, especially younger people, physical activity includes sports like tennis, soccer, walking, or jogging. All these can be tracked well with step counting. But for others, activity means cycling or swimming, which is easier to measure by duration.”

For Dr. Gross, the new findings provide a basis for using step counts to set physical activity goals — both in individual patient counseling and in formal guidelines. However, he stressed that further studies are necessary.

“The results need to be replicated in various populations, not just among men and younger people but also among ethnic minorities and lower-income populations, who often have less time and space for structured physical activity.”
 

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

Exercise recommendations typically focus on the duration of physical activity. For example, the World Health Organization advises at least 150 minutes of moderate physical activity per week. A new analysis of data from the Women’s Health Study, published in JAMA Internal Medicine, suggested that step count could also be a useful metric. For some, such a recommendation might be easier to follow.

“It’s not so easy to keep track of how long you’ve been moderately active in a given week,” Cary P. Gross, MD, from the Department of Medicine at Yale University in New Haven, Connecticut, wrote in an editorial. “Counting steps might be easier for some people, especially since most carry a phone that can serve as a pedometer.”
 

The 10,000-Step Recommendation

However, there are no well-founded recommendations for step counts, partly due to a lack of scientific evidence linking steps with mortality and cardiovascular diseases. The often-cited 10,000 steps per day originated from a marketing campaign in Japan in the 1960s.

The research team led by Rikuta Hamaya, MD, from the Division of Preventive Medicine at Brigham and Women’s Hospital in Boston, analyzed data from participants in the Women’s Health Study. This clinical trial in the United States from 1992 to 2004 investigated the use of aspirin and vitamin E for cancer and cardiovascular disease prevention.

The current analysis included 14,399 women who were aged ≥ 62 years and had not developed cardiovascular disease or cancer. Between 2011 and 2015, they measured their physical activity and step count over 7 days using an accelerometer. They were followed-up for an average of 9 years.
 

Risk Reduction With Both Parameters

Moderate physical activity among the participants amounted to a median of 62 minutes per week, with a median daily step count of 5183. Hamaya and his colleagues found that both physical activity parameters were associated with lower mortality and reduced risk for cardiovascular diseases.

Participants who engaged in more than the recommended 150 minutes of moderate-intensity activity per week had a 32% lower mortality risk than those who were the least physically active. Women with > 7000 steps per day had a 42% lower mortality risk than those with the lowest daily step count.

Women in the top three quartiles of physical activity outlived those in the lowest quartile by an average of 2.22 months (time) or 2.36 months (steps), according to Hamaya and his team. The survival advantage was independent of body mass index.

For the endpoint of cardiovascular diseases (heart attack, stroke, and cardiovascular mortality), the researchers observed similar results as for mortality.
 

More Ways to Reach the Goal

Dr. Hamaya emphasized the importance of offering multiple ways to meet exercise recommendations: “For some, especially younger people, physical activity includes sports like tennis, soccer, walking, or jogging. All these can be tracked well with step counting. But for others, activity means cycling or swimming, which is easier to measure by duration.”

For Dr. Gross, the new findings provide a basis for using step counts to set physical activity goals — both in individual patient counseling and in formal guidelines. However, he stressed that further studies are necessary.

“The results need to be replicated in various populations, not just among men and younger people but also among ethnic minorities and lower-income populations, who often have less time and space for structured physical activity.”
 

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

What if there were tests that could tell you whether the following drugs were a good match for your patients: Antidepressants, statins, painkillers, anticlotting medicines, chemotherapy agents, HIV treatments, organ transplant antirejection drugs, proton pump inhibitors for heartburn, and more?

That’s quite a list. And that’s pharmacogenetics, testing patients for genetic differences that affect how well a given drug will work for them and what kind of side effects to expect.

“About 9 out of 10 people will have a genetic difference in their DNA that can impact how they respond to common medications,” said Emily J. Cicali, PharmD, a clinical associate at the University of Florida College of Pharmacy, Gainesville.

Dr. Cicali is the clinical director of UF Health’s MyRx, a virtual program that gives Florida and New Jersey residents access to pharmacogenetic (PGx) tests plus expert interpretation by the health system’s pharmacists. Genetic factors are thought to contribute to about 25% or more of inappropriate drug responses or adverse events, said Kristin Wiisanen, PharmD, dean of the College of Pharmacy at Rosalind Franklin University of Medicine and Science in North Chicago.

“Pharmacogenetics helps consumers avoid drugs that may not work well for them or could cause serious adverse events. It’s personalized medicine,” Dr. Cicali said.

Through a cheek swab or blood sample, the MyRx program — and a growing number of health system programs, doctors’ offices, and home tests available across the United States — gives consumers a window on inherited gene variants that can affect how their body activates, metabolizes, and clears away medications from a long list of widely used drugs.

Why PGx Tests Can Have a Big Impact

These tests work by looking for genes that control drug metabolism.

“You have several different drug-metabolizing enzymes in your liver,” Dr. Cicali explained. “Pharmacogenetic tests look for gene variants that encode for these enzymes. If you’re an ultrarapid metabolizer, you have more of the enzymes that metabolize certain drugs, and there could be a risk the drug won’t work well because it doesn’t stay in the body long enough. On the other end of the spectrum, poor metabolizers have low levels of enzymes that affect certain drugs, so the drugs hang around longer and cause side effects.”

While pharmacogenetics is still considered an emerging science, it’s becoming more mainstream as test prices drop, insurance coverage expands, and an explosion of new research boosts understanding of gene-drug interactions, Dr. Wiisanen said.

Politicians are trying to extend its reach, too. The Right Drug Dose Now Act of 2024, introduced in Congress in late March, aims to accelerate the use of PGx by boosting public awareness and by inserting PGx test results into consumers’ electronic health records. (Though a similar bill died in a US House subcommittee in 2023.)

“The use of pharmacogenetic data to guide prescribing is growing rapidly,” Dr. Wiisanen said. “It’s becoming a routine part of drug therapy for many medications.”

What the Research Shows

When researchers sequenced the DNA of more than 10,000 Mayo Clinic patients, they made a discovery that might surprise many Americans: Gene variants that affect the effectiveness and safety of widely used drugs are not rare glitches. More than 99% of study participants had at least one. And 79% had three or more.

The Mayo-Baylor RIGHT 10K Study — one of the largest PGx studies ever conducted in the United States — looked at 77 gene variants, most involved with drug metabolism in the liver. Researchers focused closely on 13 with extensively studied, gene-based prescribing recommendations for 21 drugs including antidepressants, statins, pain killers, anticlotting medications for heart conditions, HIV treatments, chemotherapy agents, and antirejection drugs for organ transplants.

When researchers added participants’ genetic data to their electronic health records, they also sent semi-urgent alerts, which are alerts with the potential for severe harm, to the clinicians of 61 study volunteers. Over half changed patients’ drugs or doses.

The changes made a difference. One participant taking the pain drug tramadol turned out to be a poor metabolizer and was having dizzy spells because blood levels of the drug stayed high for long periods. Stopping tramadol stopped the dizziness. A participant taking escitalopram plus bupropion for major depression found out that the combo was likely ineffective because they metabolized escitalopram rapidly. A switch to a higher dose of bupropion alone put their depression into full remission.

“So many factors play into how you respond to medications,” said Mayo Clinic pharmacogenomics pharmacist Jessica Wright, PharmD, BCACP, one of the study authors. “Genetics is one of those pieces. Pharmacogenetic testing can reveal things that clinicians may not have been aware of or could help explain a patient’s exaggerated side effect.”

Pharmacogenetics is also called pharmacogenomics. The terms are often used interchangeably, even among PGx pharmacists, though the first refers to how individual genes influence drug response and the second to the effects of multiple genes, said Kelly E. Caudle, PharmD, PhD, an associate member of the Department of Pharmacy and Pharmaceutical Sciences at St. Jude Children’s Research Hospital in Memphis, Tennessee. Dr. Caudle is also co-principal investigator and director of the National Institutes of Health (NIH)-funded Clinical Pharmacogenetics Implementation Consortium (CPIC). The group creates, publishes, and posts evidence-based clinical practice guidelines for drugs with well-researched PGx influences.

By any name, PGx may help explain, predict, and sidestep unpredictable responses to a variety of drugs:

• In a 2023 multicenter study of 6944 people from seven European countries in The Lancet, those given customized drug treatments based on a 12-gene PGx panel had 30% fewer side effects than those who didn’t get this personalized prescribing. People in the study were being treated for cancer, heart disease, and mental health issues, among other conditions.
• In a 2023  from China’s Tongji University, Shanghai, of 650 survivors of strokes and transient ischemic attacks, those whose antiplatelet drugs (such as clopidogrel) were customized based on PGx testing had a lower risk for stroke and other vascular events in the next 90 days. The study was published in Frontiers in Pharmacology.
• In a University of Pennsylvania  of 1944 adults with major depression, published in the Journal of the American Medical Association, those whose antidepressants were guided by PGx test results were 28% more likely to go into remission during the first 24 weeks of treatment than those in a control group. But by 24 weeks, equal numbers were in remission. A 2023 Chinese  of 11 depression studies, published in BMC Psychiatry, came to a similar conclusion: PGx-guided antidepressant prescriptions may help people feel better quicker, perhaps by avoiding some of the usual trial-and-error of different depression drugs.

PGx checks are already strongly recommended or considered routine before some medications are prescribed. These include abacavir (Ziagen), an antiviral treatment for HIV that can have severe side effects in people with one gene variant.

The US Food and Drug Administration (FDA) recommends genetic testing for people with colon cancer before starting the drug irinotecan (Camptosar), which can cause severe diarrhea and raise infection risk in people with a gene variant that slows the drug’s elimination from the body.

Genetic testing is also recommended by the FDA for people with acute lymphoblastic leukemia before receiving the chemotherapy drug mercaptopurine (Purinethol) because a gene variant that affects drug processing can trigger serious side effects and raise the risk for infection at standard dosages.

“One of the key benefits of pharmacogenomic testing is in preventing adverse drug reactions,” Dr. Wiisanen said. “Testing of the thiopurine methyltransferase enzyme to guide dosing with 6-mercaptopurine or azathioprine can help prevent myelosuppression, a serious adverse drug reaction caused by lower production of blood cells in bone marrow.”

When, Why, and How to Test

“A family doctor should consider a PGx test if a patient is planning on taking a medication for which there is a CPIC guideline with a dosing recommendation,” said Teri Klein, PhD, professor of biomedical data science at Stanford University in California, and principal investigator at PharmGKB, an online resource funded by the NIH that provides information for healthcare practitioners, researchers, and consumers about PGx. Affiliated with CPIC, it’s based at Stanford University.

You might also consider it for patients already on a drug who are “not responding or experiencing side effects,” Dr. Caudle said.

Here’s how four PGx experts suggest consumers and physicians approach this option.

Find a Test

More than a dozen PGx tests are on the market — some only a provider can order, others a consumer can order after a review by their provider or by a provider from the testing company. Some of the tests (using saliva) may be administered at home, while blood tests are done in a doctor’s office or laboratory. Companies that offer the tests include ARUP Laboratories, Genomind, Labcorp, Mayo Clinic Laboratories, Myriad Neuroscience, Precision Sciences Inc., Tempus, and OneOme, but there are many others online. (Keep in mind that many laboratories offer “lab-developed tests” — created for use in a single laboratory — but these can be harder to verify. “The FDA regulates pharmacogenomic testing in laboratories,” Dr. Wiisanen said, “but many of the regulatory parameters are still being defined.”)

Because PGx is so new, there is no official list of recommended tests. So you’ll have to do a little homework. You can check that the laboratory is accredited by searching for it in the NIH Genetic Testing Laboratory Registry database. Beyond that, you’ll have to consult other evidence-based resources to confirm that the drug you’re interested in has research-backed data about specific gene variants (alleles) that affect metabolism as well as research-based clinical guidelines for using PGx results to make prescribing decisions.

The CPIC’s guidelines include dosing and alternate drug recommendations for more than 100 antidepressants, chemotherapy drugs, the antiplatelet and anticlotting drugs clopidogrel and warfarin, local anesthetics, antivirals and antibacterials, pain killers and anti-inflammatory drugs, and some cholesterol-lowering statins such as lovastatin and fluvastatin.

For help figuring out if a test looks for the right gene variants, Dr. Caudle and Dr. Wright recommended checking with the Association for Molecular Pathology’s website. The group published a brief list of best practices for pharmacogenomic testing in 2019. And it keeps a list of gene variants (alleles) that should be included in tests. Clinical guidelines from the CPIC and other groups, available on PharmGKB’s website, also list gene variants that affect the metabolism of the drug.

Consider Cost

The price tag for a test is typically several hundred dollars — but it can run as high as $1000-$2500. And health insurance doesn’t always pick up the tab.

In a 2023 University of Florida study of more than 1000 insurance claims for PGx testing, the number reimbursed varied from 72% for a pain diagnosis to 52% for cardiology to 46% for psychiatry.

Medicare covers some PGx testing when a consumer and their providers meet certain criteria, including whether a drug being considered has a significant gene-drug interaction. California’s Medi-Cal health insurance program covers PGx as do Medicaid programs in some states, including Arkansas and Rhode Island. You can find state-by-state coverage information on the Genetics Policy Hub’s website.

Understand the Results

As more insurers cover PGx, Dr. Klein and Dr. Wiisanen say the field will grow and more providers will use it to inform prescribing. But some health systems aren’t waiting.

In addition to UF Health’s MyRx, PGx is part of personalized medicine programs at the University of Pennsylvania in Philadelphia, Endeavor Health in Chicago, the Mayo Clinic, the University of California, San Francisco, Sanford Health in Sioux Falls, South Dakota, and St. Jude Children’s Research Hospital in Memphis, Tennessee.

Beyond testing, they offer a very useful service: A consult with a pharmacogenetics pharmacist to review the results and explain what they mean for a consumer’s current and future medications.

Physicians and curious consumers can also consult CPIC’s guidelines, which give recommendations about how to interpret the results of a PGx test, said Dr. Klein, a co-principal investigator at CPIC. CPIC has a grading system for both the evidence that supports the recommendation (high, moderate, or weak) and the recommendation itself (strong, moderate, or optional).

Currently, labeling for 456 prescription drugs sold in the United States includes some type of PGx information, according to the FDA’s Table of Pharmacogenomic Biomarkers in Drug Labeling and an annotated guide from PharmGKB.

Just 108 drug labels currently tell doctors and patients what to do with the information — such as requiring or suggesting testing or offering prescribing recommendations, according to PharmGKB. In contrast, PharmGKB’s online resources include evidence-based clinical guidelines for 201 drugs from CPIC and from professional PGx societies in the Netherlands, Canada, France, and elsewhere.

Consumers and physicians can also look for a pharmacist with pharmacogenetics training in their area or through a nearby medical center to learn more, Dr. Wright suggested. And while consumers can test without working with their own physician, the experts advise against it. Don’t stop or change the dose of medications you already take on your own, they say . And do work with your primary care practitioner or specialist to get tested and understand how the results fit into the bigger picture of how your body responds to your medications.

A version of this article appeared on Medscape.com.

What if there were tests that could tell you whether the following drugs were a good match for your patients: Antidepressants, statins, painkillers, anticlotting medicines, chemotherapy agents, HIV treatments, organ transplant antirejection drugs, proton pump inhibitors for heartburn, and more?

That’s quite a list. And that’s pharmacogenetics, testing patients for genetic differences that affect how well a given drug will work for them and what kind of side effects to expect.

“About 9 out of 10 people will have a genetic difference in their DNA that can impact how they respond to common medications,” said Emily J. Cicali, PharmD, a clinical associate at the University of Florida College of Pharmacy, Gainesville.

Dr. Cicali is the clinical director of UF Health’s MyRx, a virtual program that gives Florida and New Jersey residents access to pharmacogenetic (PGx) tests plus expert interpretation by the health system’s pharmacists. Genetic factors are thought to contribute to about 25% or more of inappropriate drug responses or adverse events, said Kristin Wiisanen, PharmD, dean of the College of Pharmacy at Rosalind Franklin University of Medicine and Science in North Chicago.

“Pharmacogenetics helps consumers avoid drugs that may not work well for them or could cause serious adverse events. It’s personalized medicine,” Dr. Cicali said.

Through a cheek swab or blood sample, the MyRx program — and a growing number of health system programs, doctors’ offices, and home tests available across the United States — gives consumers a window on inherited gene variants that can affect how their body activates, metabolizes, and clears away medications from a long list of widely used drugs.

Why PGx Tests Can Have a Big Impact

These tests work by looking for genes that control drug metabolism.

“You have several different drug-metabolizing enzymes in your liver,” Dr. Cicali explained. “Pharmacogenetic tests look for gene variants that encode for these enzymes. If you’re an ultrarapid metabolizer, you have more of the enzymes that metabolize certain drugs, and there could be a risk the drug won’t work well because it doesn’t stay in the body long enough. On the other end of the spectrum, poor metabolizers have low levels of enzymes that affect certain drugs, so the drugs hang around longer and cause side effects.”

While pharmacogenetics is still considered an emerging science, it’s becoming more mainstream as test prices drop, insurance coverage expands, and an explosion of new research boosts understanding of gene-drug interactions, Dr. Wiisanen said.

Politicians are trying to extend its reach, too. The Right Drug Dose Now Act of 2024, introduced in Congress in late March, aims to accelerate the use of PGx by boosting public awareness and by inserting PGx test results into consumers’ electronic health records. (Though a similar bill died in a US House subcommittee in 2023.)

“The use of pharmacogenetic data to guide prescribing is growing rapidly,” Dr. Wiisanen said. “It’s becoming a routine part of drug therapy for many medications.”

What the Research Shows

When researchers sequenced the DNA of more than 10,000 Mayo Clinic patients, they made a discovery that might surprise many Americans: Gene variants that affect the effectiveness and safety of widely used drugs are not rare glitches. More than 99% of study participants had at least one. And 79% had three or more.

The Mayo-Baylor RIGHT 10K Study — one of the largest PGx studies ever conducted in the United States — looked at 77 gene variants, most involved with drug metabolism in the liver. Researchers focused closely on 13 with extensively studied, gene-based prescribing recommendations for 21 drugs including antidepressants, statins, pain killers, anticlotting medications for heart conditions, HIV treatments, chemotherapy agents, and antirejection drugs for organ transplants.

When researchers added participants’ genetic data to their electronic health records, they also sent semi-urgent alerts, which are alerts with the potential for severe harm, to the clinicians of 61 study volunteers. Over half changed patients’ drugs or doses.

The changes made a difference. One participant taking the pain drug tramadol turned out to be a poor metabolizer and was having dizzy spells because blood levels of the drug stayed high for long periods. Stopping tramadol stopped the dizziness. A participant taking escitalopram plus bupropion for major depression found out that the combo was likely ineffective because they metabolized escitalopram rapidly. A switch to a higher dose of bupropion alone put their depression into full remission.

“So many factors play into how you respond to medications,” said Mayo Clinic pharmacogenomics pharmacist Jessica Wright, PharmD, BCACP, one of the study authors. “Genetics is one of those pieces. Pharmacogenetic testing can reveal things that clinicians may not have been aware of or could help explain a patient’s exaggerated side effect.”

Pharmacogenetics is also called pharmacogenomics. The terms are often used interchangeably, even among PGx pharmacists, though the first refers to how individual genes influence drug response and the second to the effects of multiple genes, said Kelly E. Caudle, PharmD, PhD, an associate member of the Department of Pharmacy and Pharmaceutical Sciences at St. Jude Children’s Research Hospital in Memphis, Tennessee. Dr. Caudle is also co-principal investigator and director of the National Institutes of Health (NIH)-funded Clinical Pharmacogenetics Implementation Consortium (CPIC). The group creates, publishes, and posts evidence-based clinical practice guidelines for drugs with well-researched PGx influences.

By any name, PGx may help explain, predict, and sidestep unpredictable responses to a variety of drugs:

• In a 2023 multicenter study of 6944 people from seven European countries in The Lancet, those given customized drug treatments based on a 12-gene PGx panel had 30% fewer side effects than those who didn’t get this personalized prescribing. People in the study were being treated for cancer, heart disease, and mental health issues, among other conditions.
• In a 2023  from China’s Tongji University, Shanghai, of 650 survivors of strokes and transient ischemic attacks, those whose antiplatelet drugs (such as clopidogrel) were customized based on PGx testing had a lower risk for stroke and other vascular events in the next 90 days. The study was published in Frontiers in Pharmacology.
• In a University of Pennsylvania  of 1944 adults with major depression, published in the Journal of the American Medical Association, those whose antidepressants were guided by PGx test results were 28% more likely to go into remission during the first 24 weeks of treatment than those in a control group. But by 24 weeks, equal numbers were in remission. A 2023 Chinese  of 11 depression studies, published in BMC Psychiatry, came to a similar conclusion: PGx-guided antidepressant prescriptions may help people feel better quicker, perhaps by avoiding some of the usual trial-and-error of different depression drugs.

PGx checks are already strongly recommended or considered routine before some medications are prescribed. These include abacavir (Ziagen), an antiviral treatment for HIV that can have severe side effects in people with one gene variant.

The US Food and Drug Administration (FDA) recommends genetic testing for people with colon cancer before starting the drug irinotecan (Camptosar), which can cause severe diarrhea and raise infection risk in people with a gene variant that slows the drug’s elimination from the body.

Genetic testing is also recommended by the FDA for people with acute lymphoblastic leukemia before receiving the chemotherapy drug mercaptopurine (Purinethol) because a gene variant that affects drug processing can trigger serious side effects and raise the risk for infection at standard dosages.

“One of the key benefits of pharmacogenomic testing is in preventing adverse drug reactions,” Dr. Wiisanen said. “Testing of the thiopurine methyltransferase enzyme to guide dosing with 6-mercaptopurine or azathioprine can help prevent myelosuppression, a serious adverse drug reaction caused by lower production of blood cells in bone marrow.”

When, Why, and How to Test

“A family doctor should consider a PGx test if a patient is planning on taking a medication for which there is a CPIC guideline with a dosing recommendation,” said Teri Klein, PhD, professor of biomedical data science at Stanford University in California, and principal investigator at PharmGKB, an online resource funded by the NIH that provides information for healthcare practitioners, researchers, and consumers about PGx. Affiliated with CPIC, it’s based at Stanford University.

You might also consider it for patients already on a drug who are “not responding or experiencing side effects,” Dr. Caudle said.

Here’s how four PGx experts suggest consumers and physicians approach this option.

Find a Test

More than a dozen PGx tests are on the market — some only a provider can order, others a consumer can order after a review by their provider or by a provider from the testing company. Some of the tests (using saliva) may be administered at home, while blood tests are done in a doctor’s office or laboratory. Companies that offer the tests include ARUP Laboratories, Genomind, Labcorp, Mayo Clinic Laboratories, Myriad Neuroscience, Precision Sciences Inc., Tempus, and OneOme, but there are many others online. (Keep in mind that many laboratories offer “lab-developed tests” — created for use in a single laboratory — but these can be harder to verify. “The FDA regulates pharmacogenomic testing in laboratories,” Dr. Wiisanen said, “but many of the regulatory parameters are still being defined.”)

Because PGx is so new, there is no official list of recommended tests. So you’ll have to do a little homework. You can check that the laboratory is accredited by searching for it in the NIH Genetic Testing Laboratory Registry database. Beyond that, you’ll have to consult other evidence-based resources to confirm that the drug you’re interested in has research-backed data about specific gene variants (alleles) that affect metabolism as well as research-based clinical guidelines for using PGx results to make prescribing decisions.

The CPIC’s guidelines include dosing and alternate drug recommendations for more than 100 antidepressants, chemotherapy drugs, the antiplatelet and anticlotting drugs clopidogrel and warfarin, local anesthetics, antivirals and antibacterials, pain killers and anti-inflammatory drugs, and some cholesterol-lowering statins such as lovastatin and fluvastatin.

For help figuring out if a test looks for the right gene variants, Dr. Caudle and Dr. Wright recommended checking with the Association for Molecular Pathology’s website. The group published a brief list of best practices for pharmacogenomic testing in 2019. And it keeps a list of gene variants (alleles) that should be included in tests. Clinical guidelines from the CPIC and other groups, available on PharmGKB’s website, also list gene variants that affect the metabolism of the drug.

Consider Cost

The price tag for a test is typically several hundred dollars — but it can run as high as $1000-$2500. And health insurance doesn’t always pick up the tab.

In a 2023 University of Florida study of more than 1000 insurance claims for PGx testing, the number reimbursed varied from 72% for a pain diagnosis to 52% for cardiology to 46% for psychiatry.

Medicare covers some PGx testing when a consumer and their providers meet certain criteria, including whether a drug being considered has a significant gene-drug interaction. California’s Medi-Cal health insurance program covers PGx as do Medicaid programs in some states, including Arkansas and Rhode Island. You can find state-by-state coverage information on the Genetics Policy Hub’s website.

Understand the Results

As more insurers cover PGx, Dr. Klein and Dr. Wiisanen say the field will grow and more providers will use it to inform prescribing. But some health systems aren’t waiting.

In addition to UF Health’s MyRx, PGx is part of personalized medicine programs at the University of Pennsylvania in Philadelphia, Endeavor Health in Chicago, the Mayo Clinic, the University of California, San Francisco, Sanford Health in Sioux Falls, South Dakota, and St. Jude Children’s Research Hospital in Memphis, Tennessee.

Beyond testing, they offer a very useful service: A consult with a pharmacogenetics pharmacist to review the results and explain what they mean for a consumer’s current and future medications.

Physicians and curious consumers can also consult CPIC’s guidelines, which give recommendations about how to interpret the results of a PGx test, said Dr. Klein, a co-principal investigator at CPIC. CPIC has a grading system for both the evidence that supports the recommendation (high, moderate, or weak) and the recommendation itself (strong, moderate, or optional).

Currently, labeling for 456 prescription drugs sold in the United States includes some type of PGx information, according to the FDA’s Table of Pharmacogenomic Biomarkers in Drug Labeling and an annotated guide from PharmGKB.

Just 108 drug labels currently tell doctors and patients what to do with the information — such as requiring or suggesting testing or offering prescribing recommendations, according to PharmGKB. In contrast, PharmGKB’s online resources include evidence-based clinical guidelines for 201 drugs from CPIC and from professional PGx societies in the Netherlands, Canada, France, and elsewhere.

Consumers and physicians can also look for a pharmacist with pharmacogenetics training in their area or through a nearby medical center to learn more, Dr. Wright suggested. And while consumers can test without working with their own physician, the experts advise against it. Don’t stop or change the dose of medications you already take on your own, they say . And do work with your primary care practitioner or specialist to get tested and understand how the results fit into the bigger picture of how your body responds to your medications.

A version of this article appeared on Medscape.com.

What if there were tests that could tell you whether the following drugs were a good match for your patients: Antidepressants, statins, painkillers, anticlotting medicines, chemotherapy agents, HIV treatments, organ transplant antirejection drugs, proton pump inhibitors for heartburn, and more?

That’s quite a list. And that’s pharmacogenetics, testing patients for genetic differences that affect how well a given drug will work for them and what kind of side effects to expect.

“About 9 out of 10 people will have a genetic difference in their DNA that can impact how they respond to common medications,” said Emily J. Cicali, PharmD, a clinical associate at the University of Florida College of Pharmacy, Gainesville.

Dr. Cicali is the clinical director of UF Health’s MyRx, a virtual program that gives Florida and New Jersey residents access to pharmacogenetic (PGx) tests plus expert interpretation by the health system’s pharmacists. Genetic factors are thought to contribute to about 25% or more of inappropriate drug responses or adverse events, said Kristin Wiisanen, PharmD, dean of the College of Pharmacy at Rosalind Franklin University of Medicine and Science in North Chicago.

“Pharmacogenetics helps consumers avoid drugs that may not work well for them or could cause serious adverse events. It’s personalized medicine,” Dr. Cicali said.

Through a cheek swab or blood sample, the MyRx program — and a growing number of health system programs, doctors’ offices, and home tests available across the United States — gives consumers a window on inherited gene variants that can affect how their body activates, metabolizes, and clears away medications from a long list of widely used drugs.

Why PGx Tests Can Have a Big Impact

These tests work by looking for genes that control drug metabolism.

“You have several different drug-metabolizing enzymes in your liver,” Dr. Cicali explained. “Pharmacogenetic tests look for gene variants that encode for these enzymes. If you’re an ultrarapid metabolizer, you have more of the enzymes that metabolize certain drugs, and there could be a risk the drug won’t work well because it doesn’t stay in the body long enough. On the other end of the spectrum, poor metabolizers have low levels of enzymes that affect certain drugs, so the drugs hang around longer and cause side effects.”

While pharmacogenetics is still considered an emerging science, it’s becoming more mainstream as test prices drop, insurance coverage expands, and an explosion of new research boosts understanding of gene-drug interactions, Dr. Wiisanen said.

Politicians are trying to extend its reach, too. The Right Drug Dose Now Act of 2024, introduced in Congress in late March, aims to accelerate the use of PGx by boosting public awareness and by inserting PGx test results into consumers’ electronic health records. (Though a similar bill died in a US House subcommittee in 2023.)

“The use of pharmacogenetic data to guide prescribing is growing rapidly,” Dr. Wiisanen said. “It’s becoming a routine part of drug therapy for many medications.”

What the Research Shows

When researchers sequenced the DNA of more than 10,000 Mayo Clinic patients, they made a discovery that might surprise many Americans: Gene variants that affect the effectiveness and safety of widely used drugs are not rare glitches. More than 99% of study participants had at least one. And 79% had three or more.

The Mayo-Baylor RIGHT 10K Study — one of the largest PGx studies ever conducted in the United States — looked at 77 gene variants, most involved with drug metabolism in the liver. Researchers focused closely on 13 with extensively studied, gene-based prescribing recommendations for 21 drugs including antidepressants, statins, pain killers, anticlotting medications for heart conditions, HIV treatments, chemotherapy agents, and antirejection drugs for organ transplants.

When researchers added participants’ genetic data to their electronic health records, they also sent semi-urgent alerts, which are alerts with the potential for severe harm, to the clinicians of 61 study volunteers. Over half changed patients’ drugs or doses.

The changes made a difference. One participant taking the pain drug tramadol turned out to be a poor metabolizer and was having dizzy spells because blood levels of the drug stayed high for long periods. Stopping tramadol stopped the dizziness. A participant taking escitalopram plus bupropion for major depression found out that the combo was likely ineffective because they metabolized escitalopram rapidly. A switch to a higher dose of bupropion alone put their depression into full remission.

“So many factors play into how you respond to medications,” said Mayo Clinic pharmacogenomics pharmacist Jessica Wright, PharmD, BCACP, one of the study authors. “Genetics is one of those pieces. Pharmacogenetic testing can reveal things that clinicians may not have been aware of or could help explain a patient’s exaggerated side effect.”

Pharmacogenetics is also called pharmacogenomics. The terms are often used interchangeably, even among PGx pharmacists, though the first refers to how individual genes influence drug response and the second to the effects of multiple genes, said Kelly E. Caudle, PharmD, PhD, an associate member of the Department of Pharmacy and Pharmaceutical Sciences at St. Jude Children’s Research Hospital in Memphis, Tennessee. Dr. Caudle is also co-principal investigator and director of the National Institutes of Health (NIH)-funded Clinical Pharmacogenetics Implementation Consortium (CPIC). The group creates, publishes, and posts evidence-based clinical practice guidelines for drugs with well-researched PGx influences.

By any name, PGx may help explain, predict, and sidestep unpredictable responses to a variety of drugs:

• In a 2023 multicenter study of 6944 people from seven European countries in The Lancet, those given customized drug treatments based on a 12-gene PGx panel had 30% fewer side effects than those who didn’t get this personalized prescribing. People in the study were being treated for cancer, heart disease, and mental health issues, among other conditions.
• In a 2023  from China’s Tongji University, Shanghai, of 650 survivors of strokes and transient ischemic attacks, those whose antiplatelet drugs (such as clopidogrel) were customized based on PGx testing had a lower risk for stroke and other vascular events in the next 90 days. The study was published in Frontiers in Pharmacology.
• In a University of Pennsylvania  of 1944 adults with major depression, published in the Journal of the American Medical Association, those whose antidepressants were guided by PGx test results were 28% more likely to go into remission during the first 24 weeks of treatment than those in a control group. But by 24 weeks, equal numbers were in remission. A 2023 Chinese  of 11 depression studies, published in BMC Psychiatry, came to a similar conclusion: PGx-guided antidepressant prescriptions may help people feel better quicker, perhaps by avoiding some of the usual trial-and-error of different depression drugs.

PGx checks are already strongly recommended or considered routine before some medications are prescribed. These include abacavir (Ziagen), an antiviral treatment for HIV that can have severe side effects in people with one gene variant.

The US Food and Drug Administration (FDA) recommends genetic testing for people with colon cancer before starting the drug irinotecan (Camptosar), which can cause severe diarrhea and raise infection risk in people with a gene variant that slows the drug’s elimination from the body.

Genetic testing is also recommended by the FDA for people with acute lymphoblastic leukemia before receiving the chemotherapy drug mercaptopurine (Purinethol) because a gene variant that affects drug processing can trigger serious side effects and raise the risk for infection at standard dosages.

“One of the key benefits of pharmacogenomic testing is in preventing adverse drug reactions,” Dr. Wiisanen said. “Testing of the thiopurine methyltransferase enzyme to guide dosing with 6-mercaptopurine or azathioprine can help prevent myelosuppression, a serious adverse drug reaction caused by lower production of blood cells in bone marrow.”

When, Why, and How to Test

“A family doctor should consider a PGx test if a patient is planning on taking a medication for which there is a CPIC guideline with a dosing recommendation,” said Teri Klein, PhD, professor of biomedical data science at Stanford University in California, and principal investigator at PharmGKB, an online resource funded by the NIH that provides information for healthcare practitioners, researchers, and consumers about PGx. Affiliated with CPIC, it’s based at Stanford University.

You might also consider it for patients already on a drug who are “not responding or experiencing side effects,” Dr. Caudle said.

Here’s how four PGx experts suggest consumers and physicians approach this option.

Find a Test

More than a dozen PGx tests are on the market — some only a provider can order, others a consumer can order after a review by their provider or by a provider from the testing company. Some of the tests (using saliva) may be administered at home, while blood tests are done in a doctor’s office or laboratory. Companies that offer the tests include ARUP Laboratories, Genomind, Labcorp, Mayo Clinic Laboratories, Myriad Neuroscience, Precision Sciences Inc., Tempus, and OneOme, but there are many others online. (Keep in mind that many laboratories offer “lab-developed tests” — created for use in a single laboratory — but these can be harder to verify. “The FDA regulates pharmacogenomic testing in laboratories,” Dr. Wiisanen said, “but many of the regulatory parameters are still being defined.”)

Because PGx is so new, there is no official list of recommended tests. So you’ll have to do a little homework. You can check that the laboratory is accredited by searching for it in the NIH Genetic Testing Laboratory Registry database. Beyond that, you’ll have to consult other evidence-based resources to confirm that the drug you’re interested in has research-backed data about specific gene variants (alleles) that affect metabolism as well as research-based clinical guidelines for using PGx results to make prescribing decisions.

The CPIC’s guidelines include dosing and alternate drug recommendations for more than 100 antidepressants, chemotherapy drugs, the antiplatelet and anticlotting drugs clopidogrel and warfarin, local anesthetics, antivirals and antibacterials, pain killers and anti-inflammatory drugs, and some cholesterol-lowering statins such as lovastatin and fluvastatin.

For help figuring out if a test looks for the right gene variants, Dr. Caudle and Dr. Wright recommended checking with the Association for Molecular Pathology’s website. The group published a brief list of best practices for pharmacogenomic testing in 2019. And it keeps a list of gene variants (alleles) that should be included in tests. Clinical guidelines from the CPIC and other groups, available on PharmGKB’s website, also list gene variants that affect the metabolism of the drug.

Consider Cost

The price tag for a test is typically several hundred dollars — but it can run as high as $1000-$2500. And health insurance doesn’t always pick up the tab.

In a 2023 University of Florida study of more than 1000 insurance claims for PGx testing, the number reimbursed varied from 72% for a pain diagnosis to 52% for cardiology to 46% for psychiatry.

Medicare covers some PGx testing when a consumer and their providers meet certain criteria, including whether a drug being considered has a significant gene-drug interaction. California’s Medi-Cal health insurance program covers PGx as do Medicaid programs in some states, including Arkansas and Rhode Island. You can find state-by-state coverage information on the Genetics Policy Hub’s website.

Understand the Results

As more insurers cover PGx, Dr. Klein and Dr. Wiisanen say the field will grow and more providers will use it to inform prescribing. But some health systems aren’t waiting.

In addition to UF Health’s MyRx, PGx is part of personalized medicine programs at the University of Pennsylvania in Philadelphia, Endeavor Health in Chicago, the Mayo Clinic, the University of California, San Francisco, Sanford Health in Sioux Falls, South Dakota, and St. Jude Children’s Research Hospital in Memphis, Tennessee.

Beyond testing, they offer a very useful service: A consult with a pharmacogenetics pharmacist to review the results and explain what they mean for a consumer’s current and future medications.

Physicians and curious consumers can also consult CPIC’s guidelines, which give recommendations about how to interpret the results of a PGx test, said Dr. Klein, a co-principal investigator at CPIC. CPIC has a grading system for both the evidence that supports the recommendation (high, moderate, or weak) and the recommendation itself (strong, moderate, or optional).

Currently, labeling for 456 prescription drugs sold in the United States includes some type of PGx information, according to the FDA’s Table of Pharmacogenomic Biomarkers in Drug Labeling and an annotated guide from PharmGKB.

Just 108 drug labels currently tell doctors and patients what to do with the information — such as requiring or suggesting testing or offering prescribing recommendations, according to PharmGKB. In contrast, PharmGKB’s online resources include evidence-based clinical guidelines for 201 drugs from CPIC and from professional PGx societies in the Netherlands, Canada, France, and elsewhere.

Consumers and physicians can also look for a pharmacist with pharmacogenetics training in their area or through a nearby medical center to learn more, Dr. Wright suggested. And while consumers can test without working with their own physician, the experts advise against it. Don’t stop or change the dose of medications you already take on your own, they say . And do work with your primary care practitioner or specialist to get tested and understand how the results fit into the bigger picture of how your body responds to your medications.

A version of this article appeared on Medscape.com.