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Myth busting: Sudden cardiac death in athletes
SNOWMASS, COLO. – Myths and misconceptions abound regarding the merits of universal incorporation of the resting 12-lead ECG into preparticipation cardiovascular screening of young athletes, Aaron L. Baggish, MD, declared at the annual Cardiovascular Conference at Snowmass sponsored by the American College of Cardiology.
Dr. Baggish, director of the Cardiovascular Performance Program at Massachusetts General Hospital and a cardiologist at Harvard Medical School, Boston, set out to pop the balloons of a handful of these widely floating myths. These are commonly held fictions: In an electronic poll at the outset of his talk, only one in five members of his large audience recognized all of the following boldface statements as false.
“Preparticipation cardiovascular screening (PPCVS) has been shown to reduce the incidence of sudden cardiac death (SCD) among young competitive athletes.”
FALSE. Not for PPCVS by history and physical examination alone, or with the addition of a screening 12-lead ECG. In Italy, where a cluster of high-profile sudden cardiac deaths led to passage of a 1982 national law mandating 12-lead ECG screening as part of the PPCVS, investigators presented studies purporting to demonstrate a subsequent reduction in the risk of SCD. But those studies were subsequently shown to be fraught with problems. And a high-quality study capable of convincingly demonstrating such a benefit would need to be prohibitively large and expensive. “Don’t hold your breath waiting for that to happen anytime soon,” advised Dr. Baggish, who is medical director for the Boston Marathon, as well as team cardiologist for Harvard University Athletics, the New England Patriots, the Boston Bruins, USRowing, and U.S. Soccer.
“Hypertrophic cardiomyopathy is the leading cause of sudden death among young competitive athletes.”
FALSE. A study of the National Collegiate Athletic Association (NCAA) comprehensive database, with 4.2 million athlete-years of follow-up, showed that the most common cause of SCD was autopsy-negative sudden unexplained death (SUD), accounting for 25% of cases. Hypertrophic cardiomyopathy was deemed the cause of 8% of the SCDs (Circulation. 2015 Jul 7;132[1]:10-9).
“The same thing has been shown in studies done in the United Kingdom and in Australia: . Over the next 10 years, I suspect that one of the most important areas that we’ll be looking into will be this SUD area, perhaps using molecular autopsy to make some headway there,” according to the cardiologist.
SCD is rare. In the NCAA study, the incidence was 1 in 53,703 athlete-years. In sobering contrast, accidents, suicide, and homicide accounted for 50% of all deaths in the collegiate athletes.
“When you think about what’s important in terms of educating young people to be safe, the history and physical exam and 12-lead ECG are nowhere near as important as talking with them about minimizing accident risk and staying away from guns,” Dr. Baggish commented.
“Contemporary ECG interpretation criteria designed specifically for use in young athletes have eliminated the problem of false-positive testing.”
FALSE. The story of adding ECG screening to the PPCVS is one of dramatically improved sensitivity over history and physical exam alone, but always at the cost of reduced specificity. In the Harvard Athlete Initiative Study, Dr. Baggish and coworkers reported that adding the 12-lead ECG resulted in a 17% false-positive rate (Ann Intern Med. 2010 Mar 2;152[5]:269-75). Similar findings were reported in independent studies at two other large universities.
“An ECG false-positive rate of 16%-20%? That’s big trouble. Remember, the conditions we’re looking for are uncommon, with a prevalence of maybe 1 in 500 at most. So if you’re flagging one-fifth or one-sixth of your athletes, the ECG is really not an appropriate tool for screening,” he commented.
Recognition of this limitation has led to development of refined, improved ECG criteria: most notably, the 2012 Seattle criteria, with an associated false-positive rate of 4%-8%, followed by the 2017 International Consensus Criteria (J Am Coll Cardiol. 2017 Feb 28;69[8]:1057-75), with a false-positive rate of 1%-2%. That’s a great improvement. Still, when Dr. Baggish, a marathoner himself, thinks about the roughly 32,000 Boston Marathon runners at the starting line each year, that false-positive rate would translate into 320-640 of those individuals being needlessly subjected to the not-insignificant time and expense of further testing, along with considerable anxiety for the runners and their families, and perhaps even inappropriate disqualification.
“Current ACC/AHA guidelines recommend against the use of the 12-lead ECG during the PPCVS.”
FALSE. Dr. Baggish was a coauthor of the current guidelines, which he described as “an open-door invitation to local decisions, with some important caveats” (Circulation. 2015 Dec 1;132[22]:e267-72).
The guidelines state that the minimum requirement and legal standard for PPCVS of young competitive athletes is a focused history and physical examination, such as the American College of Cardiology/American Heart Association 14-point screen, which consists of 10 elements addressing personal and family history and 4 focused on the physical examination, or the American Academy of Pediatrics Preparticipation Physical Evaluation. Further, while mandatory universal inclusion of the 12-lead ECG is not recommended – it’s rated Class III, meaning don’t do it – the guidelines state that screening programs are at liberty to choose the 12-lead ECG as an additional tool, “provided that close physician involvement and sufficient quality control can be achieved. If undertaken, such initiatives should recognize the known and anticipated limitations of the 12-lead ECG as a population screening test, including the expected frequency of false-positive and false-negative test results, as well as the cost required to support these initiatives over time.”
Dr. Baggish considers the ACC/AHA guidelines to be one of the two most important developments in the field of SCD during sports in recent years. The other is the NCAA-sponsored multidisciplinary Interassociation Consensus Statement on Cardiovascular Care of College Student-Athletes, which he also coauthored (J Am Coll Cardiol. 2016 Jun 28;67[25]:2981-95).
The report lays out the case for a much broader than traditional view of the PPCVS, with “goals that extend beyond detection of occult high-risk pathology.”
“The NCAA has done something very interesting,” Dr. Baggish explained. “It has said that, if we’re going to be screening, we should be thinking about screening with a much broader rationale. It’s not just about finding the needle-in-a-haystack hypertrophic cardiomyopathy or anomalous coronary arteries, it’s about engaging student-athletes at an early point in their collegiate career and trying to improve their health overall – and not just while they’re in college, but over their lifespan.”
He reported having no financial conflicts regarding his presentation.
SNOWMASS, COLO. – Myths and misconceptions abound regarding the merits of universal incorporation of the resting 12-lead ECG into preparticipation cardiovascular screening of young athletes, Aaron L. Baggish, MD, declared at the annual Cardiovascular Conference at Snowmass sponsored by the American College of Cardiology.
Dr. Baggish, director of the Cardiovascular Performance Program at Massachusetts General Hospital and a cardiologist at Harvard Medical School, Boston, set out to pop the balloons of a handful of these widely floating myths. These are commonly held fictions: In an electronic poll at the outset of his talk, only one in five members of his large audience recognized all of the following boldface statements as false.
“Preparticipation cardiovascular screening (PPCVS) has been shown to reduce the incidence of sudden cardiac death (SCD) among young competitive athletes.”
FALSE. Not for PPCVS by history and physical examination alone, or with the addition of a screening 12-lead ECG. In Italy, where a cluster of high-profile sudden cardiac deaths led to passage of a 1982 national law mandating 12-lead ECG screening as part of the PPCVS, investigators presented studies purporting to demonstrate a subsequent reduction in the risk of SCD. But those studies were subsequently shown to be fraught with problems. And a high-quality study capable of convincingly demonstrating such a benefit would need to be prohibitively large and expensive. “Don’t hold your breath waiting for that to happen anytime soon,” advised Dr. Baggish, who is medical director for the Boston Marathon, as well as team cardiologist for Harvard University Athletics, the New England Patriots, the Boston Bruins, USRowing, and U.S. Soccer.
“Hypertrophic cardiomyopathy is the leading cause of sudden death among young competitive athletes.”
FALSE. A study of the National Collegiate Athletic Association (NCAA) comprehensive database, with 4.2 million athlete-years of follow-up, showed that the most common cause of SCD was autopsy-negative sudden unexplained death (SUD), accounting for 25% of cases. Hypertrophic cardiomyopathy was deemed the cause of 8% of the SCDs (Circulation. 2015 Jul 7;132[1]:10-9).
“The same thing has been shown in studies done in the United Kingdom and in Australia: . Over the next 10 years, I suspect that one of the most important areas that we’ll be looking into will be this SUD area, perhaps using molecular autopsy to make some headway there,” according to the cardiologist.
SCD is rare. In the NCAA study, the incidence was 1 in 53,703 athlete-years. In sobering contrast, accidents, suicide, and homicide accounted for 50% of all deaths in the collegiate athletes.
“When you think about what’s important in terms of educating young people to be safe, the history and physical exam and 12-lead ECG are nowhere near as important as talking with them about minimizing accident risk and staying away from guns,” Dr. Baggish commented.
“Contemporary ECG interpretation criteria designed specifically for use in young athletes have eliminated the problem of false-positive testing.”
FALSE. The story of adding ECG screening to the PPCVS is one of dramatically improved sensitivity over history and physical exam alone, but always at the cost of reduced specificity. In the Harvard Athlete Initiative Study, Dr. Baggish and coworkers reported that adding the 12-lead ECG resulted in a 17% false-positive rate (Ann Intern Med. 2010 Mar 2;152[5]:269-75). Similar findings were reported in independent studies at two other large universities.
“An ECG false-positive rate of 16%-20%? That’s big trouble. Remember, the conditions we’re looking for are uncommon, with a prevalence of maybe 1 in 500 at most. So if you’re flagging one-fifth or one-sixth of your athletes, the ECG is really not an appropriate tool for screening,” he commented.
Recognition of this limitation has led to development of refined, improved ECG criteria: most notably, the 2012 Seattle criteria, with an associated false-positive rate of 4%-8%, followed by the 2017 International Consensus Criteria (J Am Coll Cardiol. 2017 Feb 28;69[8]:1057-75), with a false-positive rate of 1%-2%. That’s a great improvement. Still, when Dr. Baggish, a marathoner himself, thinks about the roughly 32,000 Boston Marathon runners at the starting line each year, that false-positive rate would translate into 320-640 of those individuals being needlessly subjected to the not-insignificant time and expense of further testing, along with considerable anxiety for the runners and their families, and perhaps even inappropriate disqualification.
“Current ACC/AHA guidelines recommend against the use of the 12-lead ECG during the PPCVS.”
FALSE. Dr. Baggish was a coauthor of the current guidelines, which he described as “an open-door invitation to local decisions, with some important caveats” (Circulation. 2015 Dec 1;132[22]:e267-72).
The guidelines state that the minimum requirement and legal standard for PPCVS of young competitive athletes is a focused history and physical examination, such as the American College of Cardiology/American Heart Association 14-point screen, which consists of 10 elements addressing personal and family history and 4 focused on the physical examination, or the American Academy of Pediatrics Preparticipation Physical Evaluation. Further, while mandatory universal inclusion of the 12-lead ECG is not recommended – it’s rated Class III, meaning don’t do it – the guidelines state that screening programs are at liberty to choose the 12-lead ECG as an additional tool, “provided that close physician involvement and sufficient quality control can be achieved. If undertaken, such initiatives should recognize the known and anticipated limitations of the 12-lead ECG as a population screening test, including the expected frequency of false-positive and false-negative test results, as well as the cost required to support these initiatives over time.”
Dr. Baggish considers the ACC/AHA guidelines to be one of the two most important developments in the field of SCD during sports in recent years. The other is the NCAA-sponsored multidisciplinary Interassociation Consensus Statement on Cardiovascular Care of College Student-Athletes, which he also coauthored (J Am Coll Cardiol. 2016 Jun 28;67[25]:2981-95).
The report lays out the case for a much broader than traditional view of the PPCVS, with “goals that extend beyond detection of occult high-risk pathology.”
“The NCAA has done something very interesting,” Dr. Baggish explained. “It has said that, if we’re going to be screening, we should be thinking about screening with a much broader rationale. It’s not just about finding the needle-in-a-haystack hypertrophic cardiomyopathy or anomalous coronary arteries, it’s about engaging student-athletes at an early point in their collegiate career and trying to improve their health overall – and not just while they’re in college, but over their lifespan.”
He reported having no financial conflicts regarding his presentation.
SNOWMASS, COLO. – Myths and misconceptions abound regarding the merits of universal incorporation of the resting 12-lead ECG into preparticipation cardiovascular screening of young athletes, Aaron L. Baggish, MD, declared at the annual Cardiovascular Conference at Snowmass sponsored by the American College of Cardiology.
Dr. Baggish, director of the Cardiovascular Performance Program at Massachusetts General Hospital and a cardiologist at Harvard Medical School, Boston, set out to pop the balloons of a handful of these widely floating myths. These are commonly held fictions: In an electronic poll at the outset of his talk, only one in five members of his large audience recognized all of the following boldface statements as false.
“Preparticipation cardiovascular screening (PPCVS) has been shown to reduce the incidence of sudden cardiac death (SCD) among young competitive athletes.”
FALSE. Not for PPCVS by history and physical examination alone, or with the addition of a screening 12-lead ECG. In Italy, where a cluster of high-profile sudden cardiac deaths led to passage of a 1982 national law mandating 12-lead ECG screening as part of the PPCVS, investigators presented studies purporting to demonstrate a subsequent reduction in the risk of SCD. But those studies were subsequently shown to be fraught with problems. And a high-quality study capable of convincingly demonstrating such a benefit would need to be prohibitively large and expensive. “Don’t hold your breath waiting for that to happen anytime soon,” advised Dr. Baggish, who is medical director for the Boston Marathon, as well as team cardiologist for Harvard University Athletics, the New England Patriots, the Boston Bruins, USRowing, and U.S. Soccer.
“Hypertrophic cardiomyopathy is the leading cause of sudden death among young competitive athletes.”
FALSE. A study of the National Collegiate Athletic Association (NCAA) comprehensive database, with 4.2 million athlete-years of follow-up, showed that the most common cause of SCD was autopsy-negative sudden unexplained death (SUD), accounting for 25% of cases. Hypertrophic cardiomyopathy was deemed the cause of 8% of the SCDs (Circulation. 2015 Jul 7;132[1]:10-9).
“The same thing has been shown in studies done in the United Kingdom and in Australia: . Over the next 10 years, I suspect that one of the most important areas that we’ll be looking into will be this SUD area, perhaps using molecular autopsy to make some headway there,” according to the cardiologist.
SCD is rare. In the NCAA study, the incidence was 1 in 53,703 athlete-years. In sobering contrast, accidents, suicide, and homicide accounted for 50% of all deaths in the collegiate athletes.
“When you think about what’s important in terms of educating young people to be safe, the history and physical exam and 12-lead ECG are nowhere near as important as talking with them about minimizing accident risk and staying away from guns,” Dr. Baggish commented.
“Contemporary ECG interpretation criteria designed specifically for use in young athletes have eliminated the problem of false-positive testing.”
FALSE. The story of adding ECG screening to the PPCVS is one of dramatically improved sensitivity over history and physical exam alone, but always at the cost of reduced specificity. In the Harvard Athlete Initiative Study, Dr. Baggish and coworkers reported that adding the 12-lead ECG resulted in a 17% false-positive rate (Ann Intern Med. 2010 Mar 2;152[5]:269-75). Similar findings were reported in independent studies at two other large universities.
“An ECG false-positive rate of 16%-20%? That’s big trouble. Remember, the conditions we’re looking for are uncommon, with a prevalence of maybe 1 in 500 at most. So if you’re flagging one-fifth or one-sixth of your athletes, the ECG is really not an appropriate tool for screening,” he commented.
Recognition of this limitation has led to development of refined, improved ECG criteria: most notably, the 2012 Seattle criteria, with an associated false-positive rate of 4%-8%, followed by the 2017 International Consensus Criteria (J Am Coll Cardiol. 2017 Feb 28;69[8]:1057-75), with a false-positive rate of 1%-2%. That’s a great improvement. Still, when Dr. Baggish, a marathoner himself, thinks about the roughly 32,000 Boston Marathon runners at the starting line each year, that false-positive rate would translate into 320-640 of those individuals being needlessly subjected to the not-insignificant time and expense of further testing, along with considerable anxiety for the runners and their families, and perhaps even inappropriate disqualification.
“Current ACC/AHA guidelines recommend against the use of the 12-lead ECG during the PPCVS.”
FALSE. Dr. Baggish was a coauthor of the current guidelines, which he described as “an open-door invitation to local decisions, with some important caveats” (Circulation. 2015 Dec 1;132[22]:e267-72).
The guidelines state that the minimum requirement and legal standard for PPCVS of young competitive athletes is a focused history and physical examination, such as the American College of Cardiology/American Heart Association 14-point screen, which consists of 10 elements addressing personal and family history and 4 focused on the physical examination, or the American Academy of Pediatrics Preparticipation Physical Evaluation. Further, while mandatory universal inclusion of the 12-lead ECG is not recommended – it’s rated Class III, meaning don’t do it – the guidelines state that screening programs are at liberty to choose the 12-lead ECG as an additional tool, “provided that close physician involvement and sufficient quality control can be achieved. If undertaken, such initiatives should recognize the known and anticipated limitations of the 12-lead ECG as a population screening test, including the expected frequency of false-positive and false-negative test results, as well as the cost required to support these initiatives over time.”
Dr. Baggish considers the ACC/AHA guidelines to be one of the two most important developments in the field of SCD during sports in recent years. The other is the NCAA-sponsored multidisciplinary Interassociation Consensus Statement on Cardiovascular Care of College Student-Athletes, which he also coauthored (J Am Coll Cardiol. 2016 Jun 28;67[25]:2981-95).
The report lays out the case for a much broader than traditional view of the PPCVS, with “goals that extend beyond detection of occult high-risk pathology.”
“The NCAA has done something very interesting,” Dr. Baggish explained. “It has said that, if we’re going to be screening, we should be thinking about screening with a much broader rationale. It’s not just about finding the needle-in-a-haystack hypertrophic cardiomyopathy or anomalous coronary arteries, it’s about engaging student-athletes at an early point in their collegiate career and trying to improve their health overall – and not just while they’re in college, but over their lifespan.”
He reported having no financial conflicts regarding his presentation.
REPORTING FROM ACC SNOWMASS 2020
FDA issues public health warning recommending against cesium salt usage
The Food and Drug Administration has issued a public health alert warning consumers to avoid the use of dietary supplements that contain cesium chloride or any other cesium salt because of significant safety risks.
Cesium salts are sometimes advertised as an alternative treatment for cancer, the FDA said in the announcement, but these salts have never proved to be safe or effective at treating cancer or any other disease. Clinical case reports and nonclinical trials have shown that cesium salts are associated with a variety of adverse events, including cardiac arrhythmias, hypokalemia, seizures, syncope, and death.
The FDA warned health care providers that cesium salts presented a significant safety risk in compounding drugs in July 2018.
Health care providers should not recommend dietary supplements containing cesium salts to their patients, the FDA said, and if a patient experiences an adverse event while taking a supplement containing cesium salt, the event should be reported to the agency.
While there are few dietary supplements on the market that contain cesium salt, consumers should be aware of the risks and avoid these products. The FDA noted that “if claims sound too good to be true, they probably are.”
The Food and Drug Administration has issued a public health alert warning consumers to avoid the use of dietary supplements that contain cesium chloride or any other cesium salt because of significant safety risks.
Cesium salts are sometimes advertised as an alternative treatment for cancer, the FDA said in the announcement, but these salts have never proved to be safe or effective at treating cancer or any other disease. Clinical case reports and nonclinical trials have shown that cesium salts are associated with a variety of adverse events, including cardiac arrhythmias, hypokalemia, seizures, syncope, and death.
The FDA warned health care providers that cesium salts presented a significant safety risk in compounding drugs in July 2018.
Health care providers should not recommend dietary supplements containing cesium salts to their patients, the FDA said, and if a patient experiences an adverse event while taking a supplement containing cesium salt, the event should be reported to the agency.
While there are few dietary supplements on the market that contain cesium salt, consumers should be aware of the risks and avoid these products. The FDA noted that “if claims sound too good to be true, they probably are.”
The Food and Drug Administration has issued a public health alert warning consumers to avoid the use of dietary supplements that contain cesium chloride or any other cesium salt because of significant safety risks.
Cesium salts are sometimes advertised as an alternative treatment for cancer, the FDA said in the announcement, but these salts have never proved to be safe or effective at treating cancer or any other disease. Clinical case reports and nonclinical trials have shown that cesium salts are associated with a variety of adverse events, including cardiac arrhythmias, hypokalemia, seizures, syncope, and death.
The FDA warned health care providers that cesium salts presented a significant safety risk in compounding drugs in July 2018.
Health care providers should not recommend dietary supplements containing cesium salts to their patients, the FDA said, and if a patient experiences an adverse event while taking a supplement containing cesium salt, the event should be reported to the agency.
While there are few dietary supplements on the market that contain cesium salt, consumers should be aware of the risks and avoid these products. The FDA noted that “if claims sound too good to be true, they probably are.”
Heart rhythm data from wearables confounds EP practice
NATIONAL HARBOR, MD. – or other warnings that flagged a possible cardiac arrhythmia.
While the clinical community has yet to reach an evidence-based consensus on how to deal with this information, or even asymptomatic arrhythmias identified by more standard means, the American public is voting with their wrists. People seem to like collecting and reviewing readouts on their heart rhythm and other vital data, and then they often take their numbers to a physician, especially when their device suggests a possible problem.
“The whole paradigm of ordering a test only if you intend to act on the result has been flipped. People now get what they want directly, and our job is to guide them” after the fact. “You need to teach people what’s actionable and what’s not,” Mintu P. Turakhia, MD, said at the annual International AF Symposium.
“We’re in a situation where the ability of a sensor to detect things is separate from access to the health care system. They are no longer coupled; they are disjointed. People can create their own ICU in their house just by shopping online, but what do we do with this information, whether it’s an irregular heart rhythm or their whole genome?” asked Dr. Turakhia, executive director of the Center for Digital Health at Stanford (Calif.) University and director of cardiac electrophysiology at the VA Palo Alto (Calif.) Health Care System.
“The main challenge is people without a diagnosis who get a notification. How much monitoring should you do until you can say it was a false positive? We don’t know what to do, so we monitor them. People are trying to figure this out.” Dr. Turakhia said. Some people who seek out electrophysiologists this way “may not even have a primary care physician,” he noted.
The potential implications of widespread monitoring for heartbeat irregularities in the general public began to surface in a study that Dr. Turakhia helped run that collected wearable data from nearly 420,000 Americans. Results from the Apple Heart Study showed that, during a median 117 days of monitoring with a smart watch, 2,161 people (0.5%) received a report of an irregular pulse, which led to further investigations that eventually diagnosed atrial fibrillation (AFib) in 153 people of the 450 who underwent follow-up assessment (N Engl J Med. 2019 Nov 14;381[20]:1909-17). These results “raise questions” about the large number of people who underwent follow-up testing who did not have arrhythmia, Dr. Turakhia noted.
“The dissemination of wearables has been quite dramatic, and electrophysiologists end up owning this,” commented Jeremy N. Ruskin, MD, professor of medicine at Harvard Medical School and director emeritus of the cardiac arrhythmia service at Massachusetts General Hospital, both in Boston. “I get a ton of calls from people whom I wish never bought a smart watch, and they say ‘I have atrial fibrillation. What do I do?’ ”
To document the growth of this trend, Dr. Turakhia cited results from a survey he collaborated on, run by Stanford and Rock Health, that found a 33% ownership rate among American adults of a wearable device capable of collecting health data, and a 42% rate of people who tracked their health data with a device, app, journal, or log. Both of these rates more than doubled what a similar survey found in 2015.
The cardiac electrophysiology community took a first step toward addressing one aspect of this evolving situation. In early 2020, the Heart Rhythm Society and the Consumer Technology Association jointly issued a guidance document targeted at consumers that walks them through the kinds of information their wearable devices might collect and how to approach this information. The main message: If you have questions or concerns about your data, consult a clinician. What remains in short supply is guidance to clinicians on what to do when they see these patients.
“Until recently, device-detected AFib was the sole purview of electrophysiologists using implanted rhythm-monitoring devices. Now mobile and other devices raise issues [of asymptomatic AFib] for a much broader population,” noted Daniel E. Singer, MD, professor of medicine and epidemiology at Harvard and Massachusetts General Hospital. “The world of device-detected AFib now includes watches.”
Researchers have tried for years to better understand the stroke risk faced by patients with asymptomatic or subclinical AFib that’s detected by an implanted device, as in the ASSERT study of nearly 2,600 patients followed for a median of 2.5 years that found an increased stroke risk when the duration of individual, subclinical AFib episodes surpassed 24 hours (Eur Heart J. 2017 May 1;38[17]:1339-44). More recently, a study of AFib duration collected by implanted cardiac devices in nearly 22,000 Americans showed a relationship between stroke risk and both the duration of AFib episodes and the underlying risk of a person for stroke as measured by their CHA2DS2-VAScscore (Circulation. 2019 Nov 12;140[20]:1639-46). Just under 30% of patients in the study were diagnosed with AFib at entry.
The implications of asymptomatic episodes of AFib have so far been largely studied in people with an implanted cardiac device, which may have limited applicability to wearable users. In addition, the field has not yet fully sorted out the relationships between the duration of individual AFib episodes and overall AFib burden, and a person’s stroke risk and the window of time when the potential stroke-preventing benefits of anticoagulation outweigh its bleeding risk.
The results of trials now in progress that are examining the safety and efficacy of medical interventions designed to avert strokes in patients with asymptomatic AFib “will bear on the use of anticoagulants in a large group of patients,” including people with AFib detected by a wearable, Dr. Singer predicted.
The Apple Heart Study was sponsored Apple. Dr. Turakhia has received funding from Apple, and he has received honoraria or research funding from several other companies. Dr. Ruskin has been a consultant or adviser to several companies, is a steering committee member for Pfizer, and holds equity or options in Portola, Element Science, NewPace, Gilead, and InfoBionic. Dr. Singer has been a consultant and adviser to Boehringer Ingelheim, Bristol-Myers Squibb, Johnson & Johnson, Merck, and Pfizer, and he has received research grants from Bristol-Myers Squibb.
NATIONAL HARBOR, MD. – or other warnings that flagged a possible cardiac arrhythmia.
While the clinical community has yet to reach an evidence-based consensus on how to deal with this information, or even asymptomatic arrhythmias identified by more standard means, the American public is voting with their wrists. People seem to like collecting and reviewing readouts on their heart rhythm and other vital data, and then they often take their numbers to a physician, especially when their device suggests a possible problem.
“The whole paradigm of ordering a test only if you intend to act on the result has been flipped. People now get what they want directly, and our job is to guide them” after the fact. “You need to teach people what’s actionable and what’s not,” Mintu P. Turakhia, MD, said at the annual International AF Symposium.
“We’re in a situation where the ability of a sensor to detect things is separate from access to the health care system. They are no longer coupled; they are disjointed. People can create their own ICU in their house just by shopping online, but what do we do with this information, whether it’s an irregular heart rhythm or their whole genome?” asked Dr. Turakhia, executive director of the Center for Digital Health at Stanford (Calif.) University and director of cardiac electrophysiology at the VA Palo Alto (Calif.) Health Care System.
“The main challenge is people without a diagnosis who get a notification. How much monitoring should you do until you can say it was a false positive? We don’t know what to do, so we monitor them. People are trying to figure this out.” Dr. Turakhia said. Some people who seek out electrophysiologists this way “may not even have a primary care physician,” he noted.
The potential implications of widespread monitoring for heartbeat irregularities in the general public began to surface in a study that Dr. Turakhia helped run that collected wearable data from nearly 420,000 Americans. Results from the Apple Heart Study showed that, during a median 117 days of monitoring with a smart watch, 2,161 people (0.5%) received a report of an irregular pulse, which led to further investigations that eventually diagnosed atrial fibrillation (AFib) in 153 people of the 450 who underwent follow-up assessment (N Engl J Med. 2019 Nov 14;381[20]:1909-17). These results “raise questions” about the large number of people who underwent follow-up testing who did not have arrhythmia, Dr. Turakhia noted.
“The dissemination of wearables has been quite dramatic, and electrophysiologists end up owning this,” commented Jeremy N. Ruskin, MD, professor of medicine at Harvard Medical School and director emeritus of the cardiac arrhythmia service at Massachusetts General Hospital, both in Boston. “I get a ton of calls from people whom I wish never bought a smart watch, and they say ‘I have atrial fibrillation. What do I do?’ ”
To document the growth of this trend, Dr. Turakhia cited results from a survey he collaborated on, run by Stanford and Rock Health, that found a 33% ownership rate among American adults of a wearable device capable of collecting health data, and a 42% rate of people who tracked their health data with a device, app, journal, or log. Both of these rates more than doubled what a similar survey found in 2015.
The cardiac electrophysiology community took a first step toward addressing one aspect of this evolving situation. In early 2020, the Heart Rhythm Society and the Consumer Technology Association jointly issued a guidance document targeted at consumers that walks them through the kinds of information their wearable devices might collect and how to approach this information. The main message: If you have questions or concerns about your data, consult a clinician. What remains in short supply is guidance to clinicians on what to do when they see these patients.
“Until recently, device-detected AFib was the sole purview of electrophysiologists using implanted rhythm-monitoring devices. Now mobile and other devices raise issues [of asymptomatic AFib] for a much broader population,” noted Daniel E. Singer, MD, professor of medicine and epidemiology at Harvard and Massachusetts General Hospital. “The world of device-detected AFib now includes watches.”
Researchers have tried for years to better understand the stroke risk faced by patients with asymptomatic or subclinical AFib that’s detected by an implanted device, as in the ASSERT study of nearly 2,600 patients followed for a median of 2.5 years that found an increased stroke risk when the duration of individual, subclinical AFib episodes surpassed 24 hours (Eur Heart J. 2017 May 1;38[17]:1339-44). More recently, a study of AFib duration collected by implanted cardiac devices in nearly 22,000 Americans showed a relationship between stroke risk and both the duration of AFib episodes and the underlying risk of a person for stroke as measured by their CHA2DS2-VAScscore (Circulation. 2019 Nov 12;140[20]:1639-46). Just under 30% of patients in the study were diagnosed with AFib at entry.
The implications of asymptomatic episodes of AFib have so far been largely studied in people with an implanted cardiac device, which may have limited applicability to wearable users. In addition, the field has not yet fully sorted out the relationships between the duration of individual AFib episodes and overall AFib burden, and a person’s stroke risk and the window of time when the potential stroke-preventing benefits of anticoagulation outweigh its bleeding risk.
The results of trials now in progress that are examining the safety and efficacy of medical interventions designed to avert strokes in patients with asymptomatic AFib “will bear on the use of anticoagulants in a large group of patients,” including people with AFib detected by a wearable, Dr. Singer predicted.
The Apple Heart Study was sponsored Apple. Dr. Turakhia has received funding from Apple, and he has received honoraria or research funding from several other companies. Dr. Ruskin has been a consultant or adviser to several companies, is a steering committee member for Pfizer, and holds equity or options in Portola, Element Science, NewPace, Gilead, and InfoBionic. Dr. Singer has been a consultant and adviser to Boehringer Ingelheim, Bristol-Myers Squibb, Johnson & Johnson, Merck, and Pfizer, and he has received research grants from Bristol-Myers Squibb.
NATIONAL HARBOR, MD. – or other warnings that flagged a possible cardiac arrhythmia.
While the clinical community has yet to reach an evidence-based consensus on how to deal with this information, or even asymptomatic arrhythmias identified by more standard means, the American public is voting with their wrists. People seem to like collecting and reviewing readouts on their heart rhythm and other vital data, and then they often take their numbers to a physician, especially when their device suggests a possible problem.
“The whole paradigm of ordering a test only if you intend to act on the result has been flipped. People now get what they want directly, and our job is to guide them” after the fact. “You need to teach people what’s actionable and what’s not,” Mintu P. Turakhia, MD, said at the annual International AF Symposium.
“We’re in a situation where the ability of a sensor to detect things is separate from access to the health care system. They are no longer coupled; they are disjointed. People can create their own ICU in their house just by shopping online, but what do we do with this information, whether it’s an irregular heart rhythm or their whole genome?” asked Dr. Turakhia, executive director of the Center for Digital Health at Stanford (Calif.) University and director of cardiac electrophysiology at the VA Palo Alto (Calif.) Health Care System.
“The main challenge is people without a diagnosis who get a notification. How much monitoring should you do until you can say it was a false positive? We don’t know what to do, so we monitor them. People are trying to figure this out.” Dr. Turakhia said. Some people who seek out electrophysiologists this way “may not even have a primary care physician,” he noted.
The potential implications of widespread monitoring for heartbeat irregularities in the general public began to surface in a study that Dr. Turakhia helped run that collected wearable data from nearly 420,000 Americans. Results from the Apple Heart Study showed that, during a median 117 days of monitoring with a smart watch, 2,161 people (0.5%) received a report of an irregular pulse, which led to further investigations that eventually diagnosed atrial fibrillation (AFib) in 153 people of the 450 who underwent follow-up assessment (N Engl J Med. 2019 Nov 14;381[20]:1909-17). These results “raise questions” about the large number of people who underwent follow-up testing who did not have arrhythmia, Dr. Turakhia noted.
“The dissemination of wearables has been quite dramatic, and electrophysiologists end up owning this,” commented Jeremy N. Ruskin, MD, professor of medicine at Harvard Medical School and director emeritus of the cardiac arrhythmia service at Massachusetts General Hospital, both in Boston. “I get a ton of calls from people whom I wish never bought a smart watch, and they say ‘I have atrial fibrillation. What do I do?’ ”
To document the growth of this trend, Dr. Turakhia cited results from a survey he collaborated on, run by Stanford and Rock Health, that found a 33% ownership rate among American adults of a wearable device capable of collecting health data, and a 42% rate of people who tracked their health data with a device, app, journal, or log. Both of these rates more than doubled what a similar survey found in 2015.
The cardiac electrophysiology community took a first step toward addressing one aspect of this evolving situation. In early 2020, the Heart Rhythm Society and the Consumer Technology Association jointly issued a guidance document targeted at consumers that walks them through the kinds of information their wearable devices might collect and how to approach this information. The main message: If you have questions or concerns about your data, consult a clinician. What remains in short supply is guidance to clinicians on what to do when they see these patients.
“Until recently, device-detected AFib was the sole purview of electrophysiologists using implanted rhythm-monitoring devices. Now mobile and other devices raise issues [of asymptomatic AFib] for a much broader population,” noted Daniel E. Singer, MD, professor of medicine and epidemiology at Harvard and Massachusetts General Hospital. “The world of device-detected AFib now includes watches.”
Researchers have tried for years to better understand the stroke risk faced by patients with asymptomatic or subclinical AFib that’s detected by an implanted device, as in the ASSERT study of nearly 2,600 patients followed for a median of 2.5 years that found an increased stroke risk when the duration of individual, subclinical AFib episodes surpassed 24 hours (Eur Heart J. 2017 May 1;38[17]:1339-44). More recently, a study of AFib duration collected by implanted cardiac devices in nearly 22,000 Americans showed a relationship between stroke risk and both the duration of AFib episodes and the underlying risk of a person for stroke as measured by their CHA2DS2-VAScscore (Circulation. 2019 Nov 12;140[20]:1639-46). Just under 30% of patients in the study were diagnosed with AFib at entry.
The implications of asymptomatic episodes of AFib have so far been largely studied in people with an implanted cardiac device, which may have limited applicability to wearable users. In addition, the field has not yet fully sorted out the relationships between the duration of individual AFib episodes and overall AFib burden, and a person’s stroke risk and the window of time when the potential stroke-preventing benefits of anticoagulation outweigh its bleeding risk.
The results of trials now in progress that are examining the safety and efficacy of medical interventions designed to avert strokes in patients with asymptomatic AFib “will bear on the use of anticoagulants in a large group of patients,” including people with AFib detected by a wearable, Dr. Singer predicted.
The Apple Heart Study was sponsored Apple. Dr. Turakhia has received funding from Apple, and he has received honoraria or research funding from several other companies. Dr. Ruskin has been a consultant or adviser to several companies, is a steering committee member for Pfizer, and holds equity or options in Portola, Element Science, NewPace, Gilead, and InfoBionic. Dr. Singer has been a consultant and adviser to Boehringer Ingelheim, Bristol-Myers Squibb, Johnson & Johnson, Merck, and Pfizer, and he has received research grants from Bristol-Myers Squibb.
REPORTING FROM THE AF SYMPOSIUM 2020
Expanded indication for leadless pacemaker triples eligible patients
The U.S. Food and Drug Administration’s approval of an expanded indication for a leadless pacemaker for patients “who may benefit from maintenance of atrioventricular synchrony” will make this technology potentially available to nearly half of the Americans who need a pacemaker, roughly triple the number of patients who have been candidates for a leadless pacemaker up to now.
“This approval was huge. The complication rate with leadless pacemakers has been 63% less than the rate using pacemakers with transvenous leads,” said Larry A. Chinitz, MD, a cardiac electrophysiologist and a coinvestigator on some of the studies that led to the new indication. By expanding the types of patients suitable for leadless pacing “we’ll achieve AV [atrioventricular] synchrony in more patients with fewer complications,” said Dr. Chinitz, professor of medicine and director of the Cardiac Electrophysiology and Heart Rhythm Center at NYU Langone Health in New York.
Because the device is both leadless and requires no pocket owing to its small size and placement in a patient’s right ventricle, it has implications for potentially broadening the population that could benefit from the device, he said in an interview. “When we started with this pacemaker, it was limited to elderly patients with persistent atrial fibrillation who needed only ventricular pacing, a very small group,” just under 15% of the universe of patients who need pacemakers. The broadened indication, for patients with high-grade AV block who also have atrial function, makes it possible to think of using this safer and easier-to-place device in patients who need infrequent pacing, and in patients with multiple comorbidities that give them an increased complication risk, he said. The new indication means “you’re treating a much broader patient population, doing it more safely, and creating the foundation for expanding this technology.”
The Micra AV pacemaker uses the same basic design as the previously approved Micra Transcatheter Pacing System, which came onto the U.S. market in 2016 and provides single-chamber pacing. An accelerometer on the device allows it to detect atrial motion and thereby synchronize ventricular and atrial contractions, which led to the new indication. Although the Micra AV device looks similar to the original single-chamber model, it has an entirely new circuitry that prolongs battery life during dual-chamber pacing as well as new software that incorporates the accelerometer data, explained Robert Kowal, MD, a cardiac electrophysiologist, and vice president of medical affairs and chief medical officer of cardiac rhythm and heart failure at Medtronic in Minneapolis. The battery of the Micra AV is designed to last about 15 years, Dr. Chinitz noted.
Results from two studies that Dr. Chinitz helped run established the safety and efficacy of the device for dual-chamber pacing. The MARVEL (Micra Atrial Tracking Using a Ventricular Accelerometer) study included 64 patients who completed the study at 12 worldwide centers, which produced an average 80% AV synchrony in 33 patients with high-degree AV block (The other patients in the study had predominantly intrinsic AV conduction; Heart Rhythm. 2018 Sep;15[9]:1363-71). The MARVEL 2 study included 75 patients with either second- or third-degree AV block at 12 worldwide centers and showed that AV synchrony increased from an average of 27% without two-chamber pacing to 89% with the dual-chamber function turned on, and with 95% of patients achieving at least 70% AV synchrony (JACC Clin Electrophysiol. 2020 Jan;6[1]:94-106).
The 2016 indication for single-chamber pacing included patients with “high-grade” AV bloc with or without atrial fibrillation, typically patients for whom dual-chamber pacemaker was not a great option because of the risks for complication but with the downside of limited AV synchrony, a limitation now mitigated by the option of mechanical synchronization, Dr. Kowal said. The AV device remains intended for patients with high-grade AV node block, which means patients with second- or third-degree block, he added in an interview. The estimated prevalence of third-degree AV block among U.S. adults is about 0.02%, which translates into about 50,000 people; the estimated prevalence of second-degree AV block is much less, about 10% of the third-degree prevalence.
Despite the substantial cut in complications by a leadless and pocketless pacemaker, “some patients may still benefit from a traditional dual-chamber pacemaker,” specifically active patients who might sometimes get their heart rates up with exercise to levels of about 150 beats/min or higher, Dr. Kowal said. That’s because currently the programing algorithms used to synchronize the ventricle and atrium become less reliable at heart rates above 105 beats/min, he explained. However, the ability for mechanical synchronization to keep up at higher heart rates should improve as additional data are collected that can refine the algorithms. It’s also unusual for most patients who are pacemaker candidates to reach heart rates this high, he said.
The MARVEL and MARVEL 2 studies were sponsored by Medtronic, the company that markets Micra pacemakers. Dr. Chinitz has received fees and fellowship support from Medtronic, and has also received fees from Abbott, Biosense Webster, Biotronik, and Pfizer, and he has also received fellowship support from Biotronik and Boston Scientific. Dr. Kowal is a Medtronic employee.
The U.S. Food and Drug Administration’s approval of an expanded indication for a leadless pacemaker for patients “who may benefit from maintenance of atrioventricular synchrony” will make this technology potentially available to nearly half of the Americans who need a pacemaker, roughly triple the number of patients who have been candidates for a leadless pacemaker up to now.
“This approval was huge. The complication rate with leadless pacemakers has been 63% less than the rate using pacemakers with transvenous leads,” said Larry A. Chinitz, MD, a cardiac electrophysiologist and a coinvestigator on some of the studies that led to the new indication. By expanding the types of patients suitable for leadless pacing “we’ll achieve AV [atrioventricular] synchrony in more patients with fewer complications,” said Dr. Chinitz, professor of medicine and director of the Cardiac Electrophysiology and Heart Rhythm Center at NYU Langone Health in New York.
Because the device is both leadless and requires no pocket owing to its small size and placement in a patient’s right ventricle, it has implications for potentially broadening the population that could benefit from the device, he said in an interview. “When we started with this pacemaker, it was limited to elderly patients with persistent atrial fibrillation who needed only ventricular pacing, a very small group,” just under 15% of the universe of patients who need pacemakers. The broadened indication, for patients with high-grade AV block who also have atrial function, makes it possible to think of using this safer and easier-to-place device in patients who need infrequent pacing, and in patients with multiple comorbidities that give them an increased complication risk, he said. The new indication means “you’re treating a much broader patient population, doing it more safely, and creating the foundation for expanding this technology.”
The Micra AV pacemaker uses the same basic design as the previously approved Micra Transcatheter Pacing System, which came onto the U.S. market in 2016 and provides single-chamber pacing. An accelerometer on the device allows it to detect atrial motion and thereby synchronize ventricular and atrial contractions, which led to the new indication. Although the Micra AV device looks similar to the original single-chamber model, it has an entirely new circuitry that prolongs battery life during dual-chamber pacing as well as new software that incorporates the accelerometer data, explained Robert Kowal, MD, a cardiac electrophysiologist, and vice president of medical affairs and chief medical officer of cardiac rhythm and heart failure at Medtronic in Minneapolis. The battery of the Micra AV is designed to last about 15 years, Dr. Chinitz noted.
Results from two studies that Dr. Chinitz helped run established the safety and efficacy of the device for dual-chamber pacing. The MARVEL (Micra Atrial Tracking Using a Ventricular Accelerometer) study included 64 patients who completed the study at 12 worldwide centers, which produced an average 80% AV synchrony in 33 patients with high-degree AV block (The other patients in the study had predominantly intrinsic AV conduction; Heart Rhythm. 2018 Sep;15[9]:1363-71). The MARVEL 2 study included 75 patients with either second- or third-degree AV block at 12 worldwide centers and showed that AV synchrony increased from an average of 27% without two-chamber pacing to 89% with the dual-chamber function turned on, and with 95% of patients achieving at least 70% AV synchrony (JACC Clin Electrophysiol. 2020 Jan;6[1]:94-106).
The 2016 indication for single-chamber pacing included patients with “high-grade” AV bloc with or without atrial fibrillation, typically patients for whom dual-chamber pacemaker was not a great option because of the risks for complication but with the downside of limited AV synchrony, a limitation now mitigated by the option of mechanical synchronization, Dr. Kowal said. The AV device remains intended for patients with high-grade AV node block, which means patients with second- or third-degree block, he added in an interview. The estimated prevalence of third-degree AV block among U.S. adults is about 0.02%, which translates into about 50,000 people; the estimated prevalence of second-degree AV block is much less, about 10% of the third-degree prevalence.
Despite the substantial cut in complications by a leadless and pocketless pacemaker, “some patients may still benefit from a traditional dual-chamber pacemaker,” specifically active patients who might sometimes get their heart rates up with exercise to levels of about 150 beats/min or higher, Dr. Kowal said. That’s because currently the programing algorithms used to synchronize the ventricle and atrium become less reliable at heart rates above 105 beats/min, he explained. However, the ability for mechanical synchronization to keep up at higher heart rates should improve as additional data are collected that can refine the algorithms. It’s also unusual for most patients who are pacemaker candidates to reach heart rates this high, he said.
The MARVEL and MARVEL 2 studies were sponsored by Medtronic, the company that markets Micra pacemakers. Dr. Chinitz has received fees and fellowship support from Medtronic, and has also received fees from Abbott, Biosense Webster, Biotronik, and Pfizer, and he has also received fellowship support from Biotronik and Boston Scientific. Dr. Kowal is a Medtronic employee.
The U.S. Food and Drug Administration’s approval of an expanded indication for a leadless pacemaker for patients “who may benefit from maintenance of atrioventricular synchrony” will make this technology potentially available to nearly half of the Americans who need a pacemaker, roughly triple the number of patients who have been candidates for a leadless pacemaker up to now.
“This approval was huge. The complication rate with leadless pacemakers has been 63% less than the rate using pacemakers with transvenous leads,” said Larry A. Chinitz, MD, a cardiac electrophysiologist and a coinvestigator on some of the studies that led to the new indication. By expanding the types of patients suitable for leadless pacing “we’ll achieve AV [atrioventricular] synchrony in more patients with fewer complications,” said Dr. Chinitz, professor of medicine and director of the Cardiac Electrophysiology and Heart Rhythm Center at NYU Langone Health in New York.
Because the device is both leadless and requires no pocket owing to its small size and placement in a patient’s right ventricle, it has implications for potentially broadening the population that could benefit from the device, he said in an interview. “When we started with this pacemaker, it was limited to elderly patients with persistent atrial fibrillation who needed only ventricular pacing, a very small group,” just under 15% of the universe of patients who need pacemakers. The broadened indication, for patients with high-grade AV block who also have atrial function, makes it possible to think of using this safer and easier-to-place device in patients who need infrequent pacing, and in patients with multiple comorbidities that give them an increased complication risk, he said. The new indication means “you’re treating a much broader patient population, doing it more safely, and creating the foundation for expanding this technology.”
The Micra AV pacemaker uses the same basic design as the previously approved Micra Transcatheter Pacing System, which came onto the U.S. market in 2016 and provides single-chamber pacing. An accelerometer on the device allows it to detect atrial motion and thereby synchronize ventricular and atrial contractions, which led to the new indication. Although the Micra AV device looks similar to the original single-chamber model, it has an entirely new circuitry that prolongs battery life during dual-chamber pacing as well as new software that incorporates the accelerometer data, explained Robert Kowal, MD, a cardiac electrophysiologist, and vice president of medical affairs and chief medical officer of cardiac rhythm and heart failure at Medtronic in Minneapolis. The battery of the Micra AV is designed to last about 15 years, Dr. Chinitz noted.
Results from two studies that Dr. Chinitz helped run established the safety and efficacy of the device for dual-chamber pacing. The MARVEL (Micra Atrial Tracking Using a Ventricular Accelerometer) study included 64 patients who completed the study at 12 worldwide centers, which produced an average 80% AV synchrony in 33 patients with high-degree AV block (The other patients in the study had predominantly intrinsic AV conduction; Heart Rhythm. 2018 Sep;15[9]:1363-71). The MARVEL 2 study included 75 patients with either second- or third-degree AV block at 12 worldwide centers and showed that AV synchrony increased from an average of 27% without two-chamber pacing to 89% with the dual-chamber function turned on, and with 95% of patients achieving at least 70% AV synchrony (JACC Clin Electrophysiol. 2020 Jan;6[1]:94-106).
The 2016 indication for single-chamber pacing included patients with “high-grade” AV bloc with or without atrial fibrillation, typically patients for whom dual-chamber pacemaker was not a great option because of the risks for complication but with the downside of limited AV synchrony, a limitation now mitigated by the option of mechanical synchronization, Dr. Kowal said. The AV device remains intended for patients with high-grade AV node block, which means patients with second- or third-degree block, he added in an interview. The estimated prevalence of third-degree AV block among U.S. adults is about 0.02%, which translates into about 50,000 people; the estimated prevalence of second-degree AV block is much less, about 10% of the third-degree prevalence.
Despite the substantial cut in complications by a leadless and pocketless pacemaker, “some patients may still benefit from a traditional dual-chamber pacemaker,” specifically active patients who might sometimes get their heart rates up with exercise to levels of about 150 beats/min or higher, Dr. Kowal said. That’s because currently the programing algorithms used to synchronize the ventricle and atrium become less reliable at heart rates above 105 beats/min, he explained. However, the ability for mechanical synchronization to keep up at higher heart rates should improve as additional data are collected that can refine the algorithms. It’s also unusual for most patients who are pacemaker candidates to reach heart rates this high, he said.
The MARVEL and MARVEL 2 studies were sponsored by Medtronic, the company that markets Micra pacemakers. Dr. Chinitz has received fees and fellowship support from Medtronic, and has also received fees from Abbott, Biosense Webster, Biotronik, and Pfizer, and he has also received fellowship support from Biotronik and Boston Scientific. Dr. Kowal is a Medtronic employee.
Vigilance safely keeps AFib patients off anticoagulants post ablation
NATIONAL HARBOR, MD. – A pilot program of daily arrhythmia self-vigilance has allowed selected patients with no atrial fibrillation following a catheter ablation procedure to safely come off a regimen of daily oral anticoagulation despite having residual risk factors for ischemic stroke.
This program, which started several years ago at the University of Pennsylvania in Philadelphia, has now managed 190 patients and followed them for a median of just over 3 years, and during 576 patient-years of follow-up, just a single patient had an ischemic cerebrovascular event that occurred with no atrial fibrillation (AFib) recurrence and appeared to be caused by an atherosclerotic embolism, Francis E. Marchlinski, MD, said at the annual International AF Symposium.
Although this strategy has not yet been tested in a prospective, randomized trial, this anecdotal, single-center experience suggests that the approach is “safe and effective” for selected patients who are eager to come off of their anticoagulation regimen when they remain arrhythmia free following catheter ablation of their AFib, said Dr. Marchlinski, professor of medicine and director of electrophysiology at the University of Pennsylvania. He and his associates developed this strategy as a way to more safely allow these patients to stop taking a daily oral anticoagulant because he found that many patients were stopping on their own, with no safety strategy in place.
“Patients tell me they don’t want to be on an oral anticoagulant because a parent had a hemorrhagic stroke, and they say they’re willing to accept the risk” of having an ischemic stroke by coming off anticoagulation. “This is a way for them to do it safely,” Dr. Marchlinski said in an interview. He stressed that he only allows his patients to go this route if they understand the risk and accept their shared responsibility for vigilant, twice-daily pulse monitoring to detect resumption of an irregular heart beat.
Since 2011, Dr. Marchlinski’s program ablated 1,216 patients with AFib who then remained arrhythmia free during 3 weeks of continuous ECG monitoring following their procedure. Among these patients, 443 had a CHA2DS2-VAScscore of either 0 (men) or 1 (women) that indicated no ongoing need for oral anticoagulation according to current guidelines. Of the remaining 773 patients with a CHA2DS2-VASc score of at least 1 in men and 2 in women, the clinicians determined 583 to be ineligible for the program because of their unwillingness to accept the risk, unwillingness to comply with daily pulse checks, a history of asymptomatic AFib, a CHA2DS2-VASc score greater than 4, or a resting pulse above 90 beats per minute, leaving 190 patients eligible to participate. Among these patients, 105 (55%) had a CHA2DS2-VASc score of 2-4, which should prompt anticoagulation according to current guidelines.Participating patients committed to check their resting pulse by palpation at least twice daily and to contacting the program immediately if their resting rate spiked by more than 20 beats per minutes or in another way seemed irregular. Patients were also instructed to restart their oral anticoagulation immediately if they experienced AFib symptoms that persisted for more than 5 minutes. Many patients in the program also use a wearable device (usually a watch) to monitor their resting pulse and to generate a 30-second ECG recording that they can send as an electronic file to the University of Pennsylvania staff. “We embrace wearables,” Dr. Marchlinski said. Those without a wearable can undergo transtelephonic EEG monitoring to document a suspected arrhythmia recurrence, and all patients undergo annual monitoring by continuous ECG for at least 2 weeks.During follow-up, in addition to the 1 patient free from recurrent AFib who had an atherosclerotic embolism, 34 patients resumed anticoagulant treatment because of AFib recurrence; 12 withdrew from the program because of noncompliance or preference, or because an exclusion appeared; 29 resumed oral anticoagulation transiently but then discontinued the drug a second time when their AFib recurrence resolved; and 114 patients (60% of the starting cohort of 190) remained completely off anticoagulation during a median of 37 months. These data updated a published report from Dr. Marchlinski and his associates on their first 99 patients followed for a median of 30 months (J Cardiovasc Electrophysiol. 2019 May;30[5]:631-8).
This experience underscored the need for ongoing rhythm monitoring even in the absence of AFib symptoms, as six patients developed asymptomatic AFib detected by monitoring, including one patient whose recurrence occurred 30 months after the ablation procedure.
Dr. Marchlinski stressed the stringent selection process he applies to limit this approach to patients who are willing to faithfully monitor their pulse and symptoms daily, and who accept the risk that this approach may pose and their responsibility to stay in contact with the clinical team. The program calls patients at the 6-month mark between annual monitoring to remind them of their need for daily attention.
“Being off anticoagulants is very important to these patients,” he explained, and he highlighted the added workload this strategy places on his staff. “I think this has legs” for adoption by other cardiac arrhythmia programs, “but it depends on the time the staff is willing to spend” monitoring and following these patients, some of whom regularly send in ECG traces from their wearable devices for assessment. “It takes a village” to make this program work, he said.
Dr. Marchlinski has been a consultant to or has received honoraria from Abbott EP/St. Jude, Biosense Webster, Biotronik, Boston Scientific, and Medtronic.
NATIONAL HARBOR, MD. – A pilot program of daily arrhythmia self-vigilance has allowed selected patients with no atrial fibrillation following a catheter ablation procedure to safely come off a regimen of daily oral anticoagulation despite having residual risk factors for ischemic stroke.
This program, which started several years ago at the University of Pennsylvania in Philadelphia, has now managed 190 patients and followed them for a median of just over 3 years, and during 576 patient-years of follow-up, just a single patient had an ischemic cerebrovascular event that occurred with no atrial fibrillation (AFib) recurrence and appeared to be caused by an atherosclerotic embolism, Francis E. Marchlinski, MD, said at the annual International AF Symposium.
Although this strategy has not yet been tested in a prospective, randomized trial, this anecdotal, single-center experience suggests that the approach is “safe and effective” for selected patients who are eager to come off of their anticoagulation regimen when they remain arrhythmia free following catheter ablation of their AFib, said Dr. Marchlinski, professor of medicine and director of electrophysiology at the University of Pennsylvania. He and his associates developed this strategy as a way to more safely allow these patients to stop taking a daily oral anticoagulant because he found that many patients were stopping on their own, with no safety strategy in place.
“Patients tell me they don’t want to be on an oral anticoagulant because a parent had a hemorrhagic stroke, and they say they’re willing to accept the risk” of having an ischemic stroke by coming off anticoagulation. “This is a way for them to do it safely,” Dr. Marchlinski said in an interview. He stressed that he only allows his patients to go this route if they understand the risk and accept their shared responsibility for vigilant, twice-daily pulse monitoring to detect resumption of an irregular heart beat.
Since 2011, Dr. Marchlinski’s program ablated 1,216 patients with AFib who then remained arrhythmia free during 3 weeks of continuous ECG monitoring following their procedure. Among these patients, 443 had a CHA2DS2-VAScscore of either 0 (men) or 1 (women) that indicated no ongoing need for oral anticoagulation according to current guidelines. Of the remaining 773 patients with a CHA2DS2-VASc score of at least 1 in men and 2 in women, the clinicians determined 583 to be ineligible for the program because of their unwillingness to accept the risk, unwillingness to comply with daily pulse checks, a history of asymptomatic AFib, a CHA2DS2-VASc score greater than 4, or a resting pulse above 90 beats per minute, leaving 190 patients eligible to participate. Among these patients, 105 (55%) had a CHA2DS2-VASc score of 2-4, which should prompt anticoagulation according to current guidelines.Participating patients committed to check their resting pulse by palpation at least twice daily and to contacting the program immediately if their resting rate spiked by more than 20 beats per minutes or in another way seemed irregular. Patients were also instructed to restart their oral anticoagulation immediately if they experienced AFib symptoms that persisted for more than 5 minutes. Many patients in the program also use a wearable device (usually a watch) to monitor their resting pulse and to generate a 30-second ECG recording that they can send as an electronic file to the University of Pennsylvania staff. “We embrace wearables,” Dr. Marchlinski said. Those without a wearable can undergo transtelephonic EEG monitoring to document a suspected arrhythmia recurrence, and all patients undergo annual monitoring by continuous ECG for at least 2 weeks.During follow-up, in addition to the 1 patient free from recurrent AFib who had an atherosclerotic embolism, 34 patients resumed anticoagulant treatment because of AFib recurrence; 12 withdrew from the program because of noncompliance or preference, or because an exclusion appeared; 29 resumed oral anticoagulation transiently but then discontinued the drug a second time when their AFib recurrence resolved; and 114 patients (60% of the starting cohort of 190) remained completely off anticoagulation during a median of 37 months. These data updated a published report from Dr. Marchlinski and his associates on their first 99 patients followed for a median of 30 months (J Cardiovasc Electrophysiol. 2019 May;30[5]:631-8).
This experience underscored the need for ongoing rhythm monitoring even in the absence of AFib symptoms, as six patients developed asymptomatic AFib detected by monitoring, including one patient whose recurrence occurred 30 months after the ablation procedure.
Dr. Marchlinski stressed the stringent selection process he applies to limit this approach to patients who are willing to faithfully monitor their pulse and symptoms daily, and who accept the risk that this approach may pose and their responsibility to stay in contact with the clinical team. The program calls patients at the 6-month mark between annual monitoring to remind them of their need for daily attention.
“Being off anticoagulants is very important to these patients,” he explained, and he highlighted the added workload this strategy places on his staff. “I think this has legs” for adoption by other cardiac arrhythmia programs, “but it depends on the time the staff is willing to spend” monitoring and following these patients, some of whom regularly send in ECG traces from their wearable devices for assessment. “It takes a village” to make this program work, he said.
Dr. Marchlinski has been a consultant to or has received honoraria from Abbott EP/St. Jude, Biosense Webster, Biotronik, Boston Scientific, and Medtronic.
NATIONAL HARBOR, MD. – A pilot program of daily arrhythmia self-vigilance has allowed selected patients with no atrial fibrillation following a catheter ablation procedure to safely come off a regimen of daily oral anticoagulation despite having residual risk factors for ischemic stroke.
This program, which started several years ago at the University of Pennsylvania in Philadelphia, has now managed 190 patients and followed them for a median of just over 3 years, and during 576 patient-years of follow-up, just a single patient had an ischemic cerebrovascular event that occurred with no atrial fibrillation (AFib) recurrence and appeared to be caused by an atherosclerotic embolism, Francis E. Marchlinski, MD, said at the annual International AF Symposium.
Although this strategy has not yet been tested in a prospective, randomized trial, this anecdotal, single-center experience suggests that the approach is “safe and effective” for selected patients who are eager to come off of their anticoagulation regimen when they remain arrhythmia free following catheter ablation of their AFib, said Dr. Marchlinski, professor of medicine and director of electrophysiology at the University of Pennsylvania. He and his associates developed this strategy as a way to more safely allow these patients to stop taking a daily oral anticoagulant because he found that many patients were stopping on their own, with no safety strategy in place.
“Patients tell me they don’t want to be on an oral anticoagulant because a parent had a hemorrhagic stroke, and they say they’re willing to accept the risk” of having an ischemic stroke by coming off anticoagulation. “This is a way for them to do it safely,” Dr. Marchlinski said in an interview. He stressed that he only allows his patients to go this route if they understand the risk and accept their shared responsibility for vigilant, twice-daily pulse monitoring to detect resumption of an irregular heart beat.
Since 2011, Dr. Marchlinski’s program ablated 1,216 patients with AFib who then remained arrhythmia free during 3 weeks of continuous ECG monitoring following their procedure. Among these patients, 443 had a CHA2DS2-VAScscore of either 0 (men) or 1 (women) that indicated no ongoing need for oral anticoagulation according to current guidelines. Of the remaining 773 patients with a CHA2DS2-VASc score of at least 1 in men and 2 in women, the clinicians determined 583 to be ineligible for the program because of their unwillingness to accept the risk, unwillingness to comply with daily pulse checks, a history of asymptomatic AFib, a CHA2DS2-VASc score greater than 4, or a resting pulse above 90 beats per minute, leaving 190 patients eligible to participate. Among these patients, 105 (55%) had a CHA2DS2-VASc score of 2-4, which should prompt anticoagulation according to current guidelines.Participating patients committed to check their resting pulse by palpation at least twice daily and to contacting the program immediately if their resting rate spiked by more than 20 beats per minutes or in another way seemed irregular. Patients were also instructed to restart their oral anticoagulation immediately if they experienced AFib symptoms that persisted for more than 5 minutes. Many patients in the program also use a wearable device (usually a watch) to monitor their resting pulse and to generate a 30-second ECG recording that they can send as an electronic file to the University of Pennsylvania staff. “We embrace wearables,” Dr. Marchlinski said. Those without a wearable can undergo transtelephonic EEG monitoring to document a suspected arrhythmia recurrence, and all patients undergo annual monitoring by continuous ECG for at least 2 weeks.During follow-up, in addition to the 1 patient free from recurrent AFib who had an atherosclerotic embolism, 34 patients resumed anticoagulant treatment because of AFib recurrence; 12 withdrew from the program because of noncompliance or preference, or because an exclusion appeared; 29 resumed oral anticoagulation transiently but then discontinued the drug a second time when their AFib recurrence resolved; and 114 patients (60% of the starting cohort of 190) remained completely off anticoagulation during a median of 37 months. These data updated a published report from Dr. Marchlinski and his associates on their first 99 patients followed for a median of 30 months (J Cardiovasc Electrophysiol. 2019 May;30[5]:631-8).
This experience underscored the need for ongoing rhythm monitoring even in the absence of AFib symptoms, as six patients developed asymptomatic AFib detected by monitoring, including one patient whose recurrence occurred 30 months after the ablation procedure.
Dr. Marchlinski stressed the stringent selection process he applies to limit this approach to patients who are willing to faithfully monitor their pulse and symptoms daily, and who accept the risk that this approach may pose and their responsibility to stay in contact with the clinical team. The program calls patients at the 6-month mark between annual monitoring to remind them of their need for daily attention.
“Being off anticoagulants is very important to these patients,” he explained, and he highlighted the added workload this strategy places on his staff. “I think this has legs” for adoption by other cardiac arrhythmia programs, “but it depends on the time the staff is willing to spend” monitoring and following these patients, some of whom regularly send in ECG traces from their wearable devices for assessment. “It takes a village” to make this program work, he said.
Dr. Marchlinski has been a consultant to or has received honoraria from Abbott EP/St. Jude, Biosense Webster, Biotronik, Boston Scientific, and Medtronic.
REPORTING FROM THE AF SYMPOSIUM 2020
AFib link with titin mutations warrants selected genetic testing
NATIONAL HARBOR, MD. – Testing to identify mutations in the gene that codes for the muscle protein titin is now a reasonable step in routine clinical practice for selected people with either early-onset atrial fibrillation (AFib) or a family history of atrial fibrillation, or other cardiac disorders that have been strongly linked with titin-gene mutations, Patrick T. Ellinor, MD, said at the annual International AF Symposium.
About one out of every 250 people carries a loss of function (LOF) mutation in one of their TTN genes that codes for the titin protein, making these mutations about as common as mutations for familial hypercholesterolemia, noted Dr. Ellinor, professor of medicine at Harvard Medical School in Boston and director of the Cardiovascular Disease Initiative at the Broad Institute in Cambridge, Mass. TTN LOF mutations are “bad and very frequent,” he said in an interview. “This is evolving quickly as we start to appreciate how frequent these mutations are.”
Several commercial genetic testing companies now offer testing of blood specimens for TTN LOF mutations, often as part of an “arrhythmia test” panel, with a turnaround time of about 4 weeks at a cost to the patient of about $100, noted Dr. Ellinor, who said that he has begun to discuss such testing with a small number of patients in his practice. “It’s reasonable for selected people; the jury is still out on which ones,” a subject that guideline writers will soon need to address, he said.
Patients already diagnosed with early-onset atrial fibrillation (AFib) could benefit from knowing if they had a TTN LOF mutation because that diagnosis would warrant a magnetic resonance scan to look for “subtle myopathies” not detectable with echocardiography, Dr. Ellinor explained. Identification of a TTN LOF would also be a reason to then test the patient’s children. “Perhaps we should offer testing to everyone 40 years old or younger with AFib,” Dr. Ellinor suggested. Many of these patients are now getting genetic testing for TTN on their own “whether or not their physician wants it done,” he noted.
The most recent, and perhaps most persuasive evidence for the link between TTN LOF mutations and AFib came from a recent report from Dr. Ellinor and associates that examined genome-wide associations in 1,546 people with AFib and 41,593 controls using information contained in the UK Biobank, which holds complete gene sequencing data for about half a million U.K. residents (Circ Res. 2020 Jan 17;126[2]: 200-9). The results showed that just under 0.5% of the entire population carried a TTN LOF mutation, and among patients with AFib the prevalence of a TTN LOF mutation was about 2%, but among people who carry this type of mutation 14% were diagnosed with AFib. This penetrance of 14% for AFib among people with a TTN LOF mutation makes AFib the most frequent clinical consequence identified so far for people with this type of mutation. Other cardiac disorders linked with TTN LOF mutations include heart failure and nonischemic cardiomyopathy. The Biobank study findings showed a penetrance for heart failure of about 7% among those with a TTN LOF mutation, and a penetrance of these mutations for nonischemic cardiomyopathy of about 3%.
Dr. Ellinor cited three other recently published studies with consistent results documenting a strong link between TTN LOF mutations and AFib: a study he worked on with lead author Seung H. Choi, Ph.D., and associates that ran an analysis on 2,781 AFib patients and 4,959 controls in a U.S. database of people who underwent whole-genome sequencing (JAMA. 2018 Dec 11; 320[22]:2354-64); a study of 24 Danish families with clusters of three or more affected members with AFib as well as 399 Danish residents with lone, early-onset AFib (Nat Commun. 2018 Oct 17;9[1]:4316); and a study of 25 patients with “very early onset” (less than 45 years old) AFib, which identified four of the 25 patients with a TTN LOF mutation (Circ Genom Precis Med. 2019 Nov 12[11]; 526-8).
Titin is the largest protein in humans and is critical for normal myocardial function. Titin acts as a molecular scaffold for sarcomere assembly and signaling, providing passive stiffness to the sarcomere. Mutations in TTN have been associated with tibial muscular dystrophy, hypertrophic cardiomyopathy, and dilated cardiomyopathy. The relationship now established between TTN mutations and AFib, cardiomyopathy, and heart failure may in the future help explain the tight clinical association of AFib and heart failure, Dr. Ellinor noted. The TTN gene is also notable as the largest gene in the human genome.
Dr. Ellinor has received research funding from Bayer, and he has served as an adviser or consultant to Bayer, Quest Diagnostics, and Novartis.
SOURCE: Choi SH et al. Circ Res. 2020 Jan 17;126[2]: 200-9.
NATIONAL HARBOR, MD. – Testing to identify mutations in the gene that codes for the muscle protein titin is now a reasonable step in routine clinical practice for selected people with either early-onset atrial fibrillation (AFib) or a family history of atrial fibrillation, or other cardiac disorders that have been strongly linked with titin-gene mutations, Patrick T. Ellinor, MD, said at the annual International AF Symposium.
About one out of every 250 people carries a loss of function (LOF) mutation in one of their TTN genes that codes for the titin protein, making these mutations about as common as mutations for familial hypercholesterolemia, noted Dr. Ellinor, professor of medicine at Harvard Medical School in Boston and director of the Cardiovascular Disease Initiative at the Broad Institute in Cambridge, Mass. TTN LOF mutations are “bad and very frequent,” he said in an interview. “This is evolving quickly as we start to appreciate how frequent these mutations are.”
Several commercial genetic testing companies now offer testing of blood specimens for TTN LOF mutations, often as part of an “arrhythmia test” panel, with a turnaround time of about 4 weeks at a cost to the patient of about $100, noted Dr. Ellinor, who said that he has begun to discuss such testing with a small number of patients in his practice. “It’s reasonable for selected people; the jury is still out on which ones,” a subject that guideline writers will soon need to address, he said.
Patients already diagnosed with early-onset atrial fibrillation (AFib) could benefit from knowing if they had a TTN LOF mutation because that diagnosis would warrant a magnetic resonance scan to look for “subtle myopathies” not detectable with echocardiography, Dr. Ellinor explained. Identification of a TTN LOF would also be a reason to then test the patient’s children. “Perhaps we should offer testing to everyone 40 years old or younger with AFib,” Dr. Ellinor suggested. Many of these patients are now getting genetic testing for TTN on their own “whether or not their physician wants it done,” he noted.
The most recent, and perhaps most persuasive evidence for the link between TTN LOF mutations and AFib came from a recent report from Dr. Ellinor and associates that examined genome-wide associations in 1,546 people with AFib and 41,593 controls using information contained in the UK Biobank, which holds complete gene sequencing data for about half a million U.K. residents (Circ Res. 2020 Jan 17;126[2]: 200-9). The results showed that just under 0.5% of the entire population carried a TTN LOF mutation, and among patients with AFib the prevalence of a TTN LOF mutation was about 2%, but among people who carry this type of mutation 14% were diagnosed with AFib. This penetrance of 14% for AFib among people with a TTN LOF mutation makes AFib the most frequent clinical consequence identified so far for people with this type of mutation. Other cardiac disorders linked with TTN LOF mutations include heart failure and nonischemic cardiomyopathy. The Biobank study findings showed a penetrance for heart failure of about 7% among those with a TTN LOF mutation, and a penetrance of these mutations for nonischemic cardiomyopathy of about 3%.
Dr. Ellinor cited three other recently published studies with consistent results documenting a strong link between TTN LOF mutations and AFib: a study he worked on with lead author Seung H. Choi, Ph.D., and associates that ran an analysis on 2,781 AFib patients and 4,959 controls in a U.S. database of people who underwent whole-genome sequencing (JAMA. 2018 Dec 11; 320[22]:2354-64); a study of 24 Danish families with clusters of three or more affected members with AFib as well as 399 Danish residents with lone, early-onset AFib (Nat Commun. 2018 Oct 17;9[1]:4316); and a study of 25 patients with “very early onset” (less than 45 years old) AFib, which identified four of the 25 patients with a TTN LOF mutation (Circ Genom Precis Med. 2019 Nov 12[11]; 526-8).
Titin is the largest protein in humans and is critical for normal myocardial function. Titin acts as a molecular scaffold for sarcomere assembly and signaling, providing passive stiffness to the sarcomere. Mutations in TTN have been associated with tibial muscular dystrophy, hypertrophic cardiomyopathy, and dilated cardiomyopathy. The relationship now established between TTN mutations and AFib, cardiomyopathy, and heart failure may in the future help explain the tight clinical association of AFib and heart failure, Dr. Ellinor noted. The TTN gene is also notable as the largest gene in the human genome.
Dr. Ellinor has received research funding from Bayer, and he has served as an adviser or consultant to Bayer, Quest Diagnostics, and Novartis.
SOURCE: Choi SH et al. Circ Res. 2020 Jan 17;126[2]: 200-9.
NATIONAL HARBOR, MD. – Testing to identify mutations in the gene that codes for the muscle protein titin is now a reasonable step in routine clinical practice for selected people with either early-onset atrial fibrillation (AFib) or a family history of atrial fibrillation, or other cardiac disorders that have been strongly linked with titin-gene mutations, Patrick T. Ellinor, MD, said at the annual International AF Symposium.
About one out of every 250 people carries a loss of function (LOF) mutation in one of their TTN genes that codes for the titin protein, making these mutations about as common as mutations for familial hypercholesterolemia, noted Dr. Ellinor, professor of medicine at Harvard Medical School in Boston and director of the Cardiovascular Disease Initiative at the Broad Institute in Cambridge, Mass. TTN LOF mutations are “bad and very frequent,” he said in an interview. “This is evolving quickly as we start to appreciate how frequent these mutations are.”
Several commercial genetic testing companies now offer testing of blood specimens for TTN LOF mutations, often as part of an “arrhythmia test” panel, with a turnaround time of about 4 weeks at a cost to the patient of about $100, noted Dr. Ellinor, who said that he has begun to discuss such testing with a small number of patients in his practice. “It’s reasonable for selected people; the jury is still out on which ones,” a subject that guideline writers will soon need to address, he said.
Patients already diagnosed with early-onset atrial fibrillation (AFib) could benefit from knowing if they had a TTN LOF mutation because that diagnosis would warrant a magnetic resonance scan to look for “subtle myopathies” not detectable with echocardiography, Dr. Ellinor explained. Identification of a TTN LOF would also be a reason to then test the patient’s children. “Perhaps we should offer testing to everyone 40 years old or younger with AFib,” Dr. Ellinor suggested. Many of these patients are now getting genetic testing for TTN on their own “whether or not their physician wants it done,” he noted.
The most recent, and perhaps most persuasive evidence for the link between TTN LOF mutations and AFib came from a recent report from Dr. Ellinor and associates that examined genome-wide associations in 1,546 people with AFib and 41,593 controls using information contained in the UK Biobank, which holds complete gene sequencing data for about half a million U.K. residents (Circ Res. 2020 Jan 17;126[2]: 200-9). The results showed that just under 0.5% of the entire population carried a TTN LOF mutation, and among patients with AFib the prevalence of a TTN LOF mutation was about 2%, but among people who carry this type of mutation 14% were diagnosed with AFib. This penetrance of 14% for AFib among people with a TTN LOF mutation makes AFib the most frequent clinical consequence identified so far for people with this type of mutation. Other cardiac disorders linked with TTN LOF mutations include heart failure and nonischemic cardiomyopathy. The Biobank study findings showed a penetrance for heart failure of about 7% among those with a TTN LOF mutation, and a penetrance of these mutations for nonischemic cardiomyopathy of about 3%.
Dr. Ellinor cited three other recently published studies with consistent results documenting a strong link between TTN LOF mutations and AFib: a study he worked on with lead author Seung H. Choi, Ph.D., and associates that ran an analysis on 2,781 AFib patients and 4,959 controls in a U.S. database of people who underwent whole-genome sequencing (JAMA. 2018 Dec 11; 320[22]:2354-64); a study of 24 Danish families with clusters of three or more affected members with AFib as well as 399 Danish residents with lone, early-onset AFib (Nat Commun. 2018 Oct 17;9[1]:4316); and a study of 25 patients with “very early onset” (less than 45 years old) AFib, which identified four of the 25 patients with a TTN LOF mutation (Circ Genom Precis Med. 2019 Nov 12[11]; 526-8).
Titin is the largest protein in humans and is critical for normal myocardial function. Titin acts as a molecular scaffold for sarcomere assembly and signaling, providing passive stiffness to the sarcomere. Mutations in TTN have been associated with tibial muscular dystrophy, hypertrophic cardiomyopathy, and dilated cardiomyopathy. The relationship now established between TTN mutations and AFib, cardiomyopathy, and heart failure may in the future help explain the tight clinical association of AFib and heart failure, Dr. Ellinor noted. The TTN gene is also notable as the largest gene in the human genome.
Dr. Ellinor has received research funding from Bayer, and he has served as an adviser or consultant to Bayer, Quest Diagnostics, and Novartis.
SOURCE: Choi SH et al. Circ Res. 2020 Jan 17;126[2]: 200-9.
REPORTING FROM THE AF SYMPOSIUM 2020
Cardiovascular risks associated with cannabis use
Researchers are recommending routine screening of marijuana use in cardiovascular care settings.
A review of current evidence suggests an association between marijuana use and adverse cardiovascular effects, as well as interactions between marijuana and cardiovascular medications.
Although more research is needed, the review authors suggested patients may benefit from marijuana screening and testing as well as discussions about the potential risks of marijuana use in the setting of cardiovascular disease.
Ersilia M. DeFilippis, MD, of Columbia University Irving Medical Center in New York and colleagues conducted this review, which was published in the Journal of the American College of Cardiology.
The authors noted that research on marijuana use and cardiovascular disease is limited. The different forms of cannabis and various routes of administration have made it difficult to draw concrete conclusions about marijuana products. Additionally, there have been no randomized, controlled trials of marijuana products in the United States because such trials are illegal; however, there are observational studies linking marijuana use and adverse cardiovascular effects.
Snapshot of available evidence
One study showed that smoking marijuana produces many of the same cardiotoxic chemicals produced by smoking tobacco (BMJ. 2003 May 3;326[7396]:942-3). Another study suggested marijuana smokers may have greater exposure to harmful chemicals (J Psychoactive Drugs. 1988 Jan-Mar;20[1]:43-6).
More specifically, a meta-analysis suggested that smoking marijuana was one of the top three triggers of myocardial infarction (Lancet. 2011 Feb 26;377[9767]:732-40). And in a systematic analysis, 28 of 33 studies linked marijuana use to an increased risk of acute coronary syndromes (Clin Toxicol [Phila]. 2019 Oct;57[10]:831-41).
Furthermore, a study of 2.5 million marijuana users showed that 3% experienced arrhythmias (Int J Cardiol. 2018 Aug 1;264:91-2). A population survey showed that people who smoked marijuana in the past year experienced a 3.3-fold higher rate of cerebrovascular events (Aust N Z J Public Health. 2016 Jun;40[3]:226-30).
Studies have also indicated that cannabinoids can affect cardiovascular medications, including antiarrhythmics, calcium-channel blockers, isosorbide dinitrate/mononitrate, statins, beta-blockers, warfarin, theophylline, and nonsteroidal anti-inflammatory drugs (Medicines [Basel]. 2018 Dec 23;6[1] pii: E3; Curr Top Behav Neurosci. 2017;32:249-62; Pharmacogenet Genomics. 2009 Jul;19[7]:559-62; Ann Pharmacother. 2009 Jul;43[7]:1347-53; Pharmacol Ther. 2019 Sep;201:25-38).
Reviewer recommendations
Cardiovascular specialists should be informed about regulations governing marijuana products, as well as “potential health consequences of marijuana and its derivatives,” according to Dr. DeFilippis and colleagues.
The authors recommend routinely screening patients for marijuana use, perhaps using the Daily Sessions, Frequency, Age of Onset, and Quantity of Cannabis Use Inventory (PLoS One. 2017 May 26;12[5]:e0178194) or the Cannabis Abuse Screening Test (Int J Methods Psychiatr Res. 2018 Jun;27[2]:e1597).
The authors say urine toxicology “may be reasonable” for patients with myocardial infarction or new-onset heart failure. Such testing is required for patients undergoing a heart transplant because marijuana use may affect their candidacy.
Dr. DeFilippis and colleagues say cardiovascular specialists should inform patients about the risks associated with marijuana use. The authors recommend shared decision making for patients who use marijuana for symptom management or palliative purposes.
Three review authors disclosed relationships with many different pharmaceutical companies. One author disclosed relationships with Medscape Cardiology and WebMD, which are owned by the same parent company as MDedge.
SOURCE: J Am Coll Cardiol. 2020 Jan 20. doi: 10.1016/j.jacc.2019.11.025.
Researchers are recommending routine screening of marijuana use in cardiovascular care settings.
A review of current evidence suggests an association between marijuana use and adverse cardiovascular effects, as well as interactions between marijuana and cardiovascular medications.
Although more research is needed, the review authors suggested patients may benefit from marijuana screening and testing as well as discussions about the potential risks of marijuana use in the setting of cardiovascular disease.
Ersilia M. DeFilippis, MD, of Columbia University Irving Medical Center in New York and colleagues conducted this review, which was published in the Journal of the American College of Cardiology.
The authors noted that research on marijuana use and cardiovascular disease is limited. The different forms of cannabis and various routes of administration have made it difficult to draw concrete conclusions about marijuana products. Additionally, there have been no randomized, controlled trials of marijuana products in the United States because such trials are illegal; however, there are observational studies linking marijuana use and adverse cardiovascular effects.
Snapshot of available evidence
One study showed that smoking marijuana produces many of the same cardiotoxic chemicals produced by smoking tobacco (BMJ. 2003 May 3;326[7396]:942-3). Another study suggested marijuana smokers may have greater exposure to harmful chemicals (J Psychoactive Drugs. 1988 Jan-Mar;20[1]:43-6).
More specifically, a meta-analysis suggested that smoking marijuana was one of the top three triggers of myocardial infarction (Lancet. 2011 Feb 26;377[9767]:732-40). And in a systematic analysis, 28 of 33 studies linked marijuana use to an increased risk of acute coronary syndromes (Clin Toxicol [Phila]. 2019 Oct;57[10]:831-41).
Furthermore, a study of 2.5 million marijuana users showed that 3% experienced arrhythmias (Int J Cardiol. 2018 Aug 1;264:91-2). A population survey showed that people who smoked marijuana in the past year experienced a 3.3-fold higher rate of cerebrovascular events (Aust N Z J Public Health. 2016 Jun;40[3]:226-30).
Studies have also indicated that cannabinoids can affect cardiovascular medications, including antiarrhythmics, calcium-channel blockers, isosorbide dinitrate/mononitrate, statins, beta-blockers, warfarin, theophylline, and nonsteroidal anti-inflammatory drugs (Medicines [Basel]. 2018 Dec 23;6[1] pii: E3; Curr Top Behav Neurosci. 2017;32:249-62; Pharmacogenet Genomics. 2009 Jul;19[7]:559-62; Ann Pharmacother. 2009 Jul;43[7]:1347-53; Pharmacol Ther. 2019 Sep;201:25-38).
Reviewer recommendations
Cardiovascular specialists should be informed about regulations governing marijuana products, as well as “potential health consequences of marijuana and its derivatives,” according to Dr. DeFilippis and colleagues.
The authors recommend routinely screening patients for marijuana use, perhaps using the Daily Sessions, Frequency, Age of Onset, and Quantity of Cannabis Use Inventory (PLoS One. 2017 May 26;12[5]:e0178194) or the Cannabis Abuse Screening Test (Int J Methods Psychiatr Res. 2018 Jun;27[2]:e1597).
The authors say urine toxicology “may be reasonable” for patients with myocardial infarction or new-onset heart failure. Such testing is required for patients undergoing a heart transplant because marijuana use may affect their candidacy.
Dr. DeFilippis and colleagues say cardiovascular specialists should inform patients about the risks associated with marijuana use. The authors recommend shared decision making for patients who use marijuana for symptom management or palliative purposes.
Three review authors disclosed relationships with many different pharmaceutical companies. One author disclosed relationships with Medscape Cardiology and WebMD, which are owned by the same parent company as MDedge.
SOURCE: J Am Coll Cardiol. 2020 Jan 20. doi: 10.1016/j.jacc.2019.11.025.
Researchers are recommending routine screening of marijuana use in cardiovascular care settings.
A review of current evidence suggests an association between marijuana use and adverse cardiovascular effects, as well as interactions between marijuana and cardiovascular medications.
Although more research is needed, the review authors suggested patients may benefit from marijuana screening and testing as well as discussions about the potential risks of marijuana use in the setting of cardiovascular disease.
Ersilia M. DeFilippis, MD, of Columbia University Irving Medical Center in New York and colleagues conducted this review, which was published in the Journal of the American College of Cardiology.
The authors noted that research on marijuana use and cardiovascular disease is limited. The different forms of cannabis and various routes of administration have made it difficult to draw concrete conclusions about marijuana products. Additionally, there have been no randomized, controlled trials of marijuana products in the United States because such trials are illegal; however, there are observational studies linking marijuana use and adverse cardiovascular effects.
Snapshot of available evidence
One study showed that smoking marijuana produces many of the same cardiotoxic chemicals produced by smoking tobacco (BMJ. 2003 May 3;326[7396]:942-3). Another study suggested marijuana smokers may have greater exposure to harmful chemicals (J Psychoactive Drugs. 1988 Jan-Mar;20[1]:43-6).
More specifically, a meta-analysis suggested that smoking marijuana was one of the top three triggers of myocardial infarction (Lancet. 2011 Feb 26;377[9767]:732-40). And in a systematic analysis, 28 of 33 studies linked marijuana use to an increased risk of acute coronary syndromes (Clin Toxicol [Phila]. 2019 Oct;57[10]:831-41).
Furthermore, a study of 2.5 million marijuana users showed that 3% experienced arrhythmias (Int J Cardiol. 2018 Aug 1;264:91-2). A population survey showed that people who smoked marijuana in the past year experienced a 3.3-fold higher rate of cerebrovascular events (Aust N Z J Public Health. 2016 Jun;40[3]:226-30).
Studies have also indicated that cannabinoids can affect cardiovascular medications, including antiarrhythmics, calcium-channel blockers, isosorbide dinitrate/mononitrate, statins, beta-blockers, warfarin, theophylline, and nonsteroidal anti-inflammatory drugs (Medicines [Basel]. 2018 Dec 23;6[1] pii: E3; Curr Top Behav Neurosci. 2017;32:249-62; Pharmacogenet Genomics. 2009 Jul;19[7]:559-62; Ann Pharmacother. 2009 Jul;43[7]:1347-53; Pharmacol Ther. 2019 Sep;201:25-38).
Reviewer recommendations
Cardiovascular specialists should be informed about regulations governing marijuana products, as well as “potential health consequences of marijuana and its derivatives,” according to Dr. DeFilippis and colleagues.
The authors recommend routinely screening patients for marijuana use, perhaps using the Daily Sessions, Frequency, Age of Onset, and Quantity of Cannabis Use Inventory (PLoS One. 2017 May 26;12[5]:e0178194) or the Cannabis Abuse Screening Test (Int J Methods Psychiatr Res. 2018 Jun;27[2]:e1597).
The authors say urine toxicology “may be reasonable” for patients with myocardial infarction or new-onset heart failure. Such testing is required for patients undergoing a heart transplant because marijuana use may affect their candidacy.
Dr. DeFilippis and colleagues say cardiovascular specialists should inform patients about the risks associated with marijuana use. The authors recommend shared decision making for patients who use marijuana for symptom management or palliative purposes.
Three review authors disclosed relationships with many different pharmaceutical companies. One author disclosed relationships with Medscape Cardiology and WebMD, which are owned by the same parent company as MDedge.
SOURCE: J Am Coll Cardiol. 2020 Jan 20. doi: 10.1016/j.jacc.2019.11.025.
FROM JOURNAL OF THE AMERICAN COLLEGE OF CARDIOLOGY
HRS urges consumers to direct questions about wearables’ data to clinicians
With much of the public now wearing devices on their wrists or elsewhere capable of recording a range of vital signs, including heart rate abnormalities, the Heart Rhythm Society launched a guide for American consumers about wearables and the data they collect during a session on Jan. 9 at CES 2020 in Las Vegas.
While providing a succinct but comprehensive overview of the types of wearables and the health metrics they can record, the main and recurring message of the 10-page e-pamphlet is that, when a layperson has a question or concern about their data, the best course is to consult a clinician.
The “Guidance for Wearable Health Solutions,” produced by the Heart Rhythm Society (HRS) along with the Consumer Technology Association (CTA, which presents the annual CES exhibition), cautions that “most wearables are primarily suited for fitness and wellness,” and stresses that wearables “are not a substitute for medical devices prescribed by a clinician.” And in all cases, the document advises, when questions arise about the data – including an apparently high heart rate; a reading the device identifies as abnormal; and when symptoms appear such as a rapid heart rate, dizziness, or fluttering or flopping of the heart – the response that the guidance advocates is consistent: Talk with your clinician.
“Heart Rhythm Society members are seeing more and more patients with their own data collected by wearables,” said Nassir F. Marrouche, MD, professor of medicine and director of electrophysiology at Tulane University, New Orleans, and a member of the panel that wrote the guidance document for the HRS and CTA. “Every provider is dealing with consumer wearable data. The need is important for consumers to be supported. Consumers and patients are buying over-the-counter devices and using them for diagnosis and management, with little to no guidance, and we want to help them feel supported in managing their data and understand what to do with it,” Dr. Marrouche said in an interview.
“This is a new reality in medicine; the direction of information is changing. Consumers are collecting data themselves and coming to physicians already informed. There is a new shift in how information is collected, shared, and used.” Dr. Marrouche was 1 of 5 cardiac electrophysiologists who served on the 11-member writing group.
The new document for consumers “addresses an unmet need,” and the HRS collaboration with the CTA was “a unique opportunity to develop useful guidance that supports education and empowers consumers,” said Christina Wurster, chief strategy officer for the HRS in Washington and a member of the writing panel. “The questions outlined in the document are questions our members receive daily. The document is a resource they can direct people to.”
The HRS and CTA will “partner with consumer advocacy groups and professional societies to further disseminate the document,” added Ms. Wurster. “We’ll also have a strong push on social media to reach consumer audiences and drive awareness of this new resource,” she said in an interview. In addition, HRS “has strategic partnerships with other societies and will aim to work with them for dissemination, including societies related to internal medicine, emergency medicine, cardiology, and nursing, as well as also working with patient and consumer advocacy groups to reach the public.” The CTA will also actively publicize and disseminate the guidance document through their members.
Clinical guidelines play catch-up
Ironically, the HRS has issued this guidance to the public and has told people to take their wearable-collected heart data to clinicians before the HRS or any other medical group has advised clinicians on how they should handle, interpret, and use heart rhythm data collected this way.
Presumably, many if not most of the people with questions about their heart data from wearables are asymptomatic, because symptoms are what usually drive patients with a cardiac arrhythmia to consult a physician – they don’t wait to see what their device tells them. But the best way to manage asymptomatic arrhythmias like atrial fibrillation (AFib) remains a big clinical uncertainty today, with no evidence base as a guide, although several studies exploring this question are in progress.
“There are no clear and definitive data showing that treating subclinical atrial fibrillation improves outcomes. That’s what we need, and until we get these data you won’t see strong recommendations in guidelines” to screen patients for asymptomatic AFib or other arrhythmias, said Sana M. Al-Khatib, MD, a cardiac electrophysiologist and professor of medicine at Duke University, Durham, N.C., during the 2019 American Heart Association scientific sessions in Philadelphia in a talk about wearables and guidelines.
“If you intervene with silent AFib, do you improve outcomes? That evidence is lacking,” she said. Another shortcoming of current evidence is a clear understanding of what AFib burden warrants intervention, added Dr. Al-Khatib. “We see high-rate AFib episodes recorded in patients with implanted cardiac devices [and no symptoms], and we don’t know what to do with that either.”
The closest any existing guideline from a medical society comes to currently endorsing screening for AFib by a wearable is the 2016 European Society of Cardiology’s AFib management guidelines, which give “opportunistic screening” among people aged older than 65 years a IB recommendation, but specifically for screening by taking a patient’s pulse or with a ECG recording, with no mention of the screening role for wearables (Eur Heart J. 2016 Oct 7;37[38]:2893-967), Dr. Al-Khatib noted.
The most extensive data on screening for asymptomatic AFib in an unselected population came in the recently reported results from the Apple Heart Study, which enrolled more than 419,000 people monitored by a smart watch for a median of 117 days. During this screening, 2,161 people (0.52%) received a notification of having an irregular pulse (including 3.1% of those who were aged at least 65 years), which triggered more intensive assessment with an ECG patch for a median of 13 days in 450 of the 2,161 screening positives (21%) who agreed to participate in this follow-up. Among those 450 people, the patch test identified 34% as having actual AFib (N Engl J Med. 2019 Nov 14;381[20]:1909-17). But while this study provided evidence that screening for an irregular heartbeat with a wearable can identify AFib with some level of success, the results did not address whether this approach improved short- or long-term patient outcomes.
In addition, what the Apple Heart Study results showed was that this sort of screening results in a relatively large volume of follow-up testing. Of the 2,161 participants who received an irregular pulse notification, 1,376 (64%) returned a 90-day survey. Of these, 787 (57%) reported contact with a health care provider outside the study, 28% were prescribed a new medication, 33% were recommended to see a specialist (such as a cardiologist), and 36% were recommended to have additional testing.
“The results raise the question that a lot of resources were used,” to assess patients with a positive screening result, noted Paul A. Heidenreich, MD, a cardiologist and professor of medicine at Stanford (Calif.) University who studies quality of care for patients with heart disease. He estimated that, in the Apple Heart Study, each of the more than 2,000 patients who screening positive for an irregular heartbeat and underwent subsequent assessment ran up about $700 worth of follow-up testing. But he added that, in the case of AFib, the primary intervention that many previously undiagnosed AFib patients receive is some sort of anticoagulation for stroke prevention. Moreover, because this intervention is so effective there is a lot of money to play with to make AFib screening cost effective, as judged by typical, contemporary metrics of cost efficacy that value a quality-adjusted life-year (QALY) gain as reasonable for society to pay if the cost of an incremental QALY is $50,000-$150,000.
If the benchmark is a cost that’s within $50,000/QALY, then an average follow-up cost of $116/person to assess screened positives can fall within this cost ceiling. If the benchmark is $150,000/QALY, then follow-up costs can run as high as $491/person screened, said Dr. Heidenreich during the same AHA session where Dr. Al-Khatib spoke last November.
Despite this good news for screening for AFib with a wearable from a cost-effectiveness perspective, “there is so much uncertainty regarding the benefit and the consequences of incidental findings that we need an outcomes study before widespread implementation” of this type of screening, Dr. Heidenreich concluded. “We need an outcomes study to feel comfortable” with screening. “There is a huge potential for extra care that we don’t understand.”
Dr. Marrouche agreed that collecting adequate evidence to drive changes in clinical guidelines on how to use data from wearables has lagged behind the rapid spread of wearables and the information they can produce among the American public. “Outcomes and evidence will support guidelines development, but in the meantime, we’re offering education to clinicians, patients, and consumers. Consumers own their data, and they can share them with whomever they choose.”
The document notes that people who use wearables are, in general, “enthusiastic about tracking their data, not only for their own use, but also to share” with others, often on social media websites.
“We cannot control that, but our goal in the document is focused on the clinical relevance [of the data] and to help people better understand their data and use it in a meaningful and safe way,” Dr. Marrouche said.
Dr. Marrouche has been a consultant to, advisor to, or received research support from Abbott, Biosense Webster, Biotronik, GE Healthcare, Medtronic, Preventice, Sanofi-Aventis, Siemens, and Vytronus. Ms. Wurster is an employee of the Heart Rhythm Society. Dr. Al-Khatib has been a consultant to Milestone Pharmaceuticals and Medtronic, and she has also received other financial benefits from Medtronic. Dr. Heidenreich had no disclosures,
With much of the public now wearing devices on their wrists or elsewhere capable of recording a range of vital signs, including heart rate abnormalities, the Heart Rhythm Society launched a guide for American consumers about wearables and the data they collect during a session on Jan. 9 at CES 2020 in Las Vegas.
While providing a succinct but comprehensive overview of the types of wearables and the health metrics they can record, the main and recurring message of the 10-page e-pamphlet is that, when a layperson has a question or concern about their data, the best course is to consult a clinician.
The “Guidance for Wearable Health Solutions,” produced by the Heart Rhythm Society (HRS) along with the Consumer Technology Association (CTA, which presents the annual CES exhibition), cautions that “most wearables are primarily suited for fitness and wellness,” and stresses that wearables “are not a substitute for medical devices prescribed by a clinician.” And in all cases, the document advises, when questions arise about the data – including an apparently high heart rate; a reading the device identifies as abnormal; and when symptoms appear such as a rapid heart rate, dizziness, or fluttering or flopping of the heart – the response that the guidance advocates is consistent: Talk with your clinician.
“Heart Rhythm Society members are seeing more and more patients with their own data collected by wearables,” said Nassir F. Marrouche, MD, professor of medicine and director of electrophysiology at Tulane University, New Orleans, and a member of the panel that wrote the guidance document for the HRS and CTA. “Every provider is dealing with consumer wearable data. The need is important for consumers to be supported. Consumers and patients are buying over-the-counter devices and using them for diagnosis and management, with little to no guidance, and we want to help them feel supported in managing their data and understand what to do with it,” Dr. Marrouche said in an interview.
“This is a new reality in medicine; the direction of information is changing. Consumers are collecting data themselves and coming to physicians already informed. There is a new shift in how information is collected, shared, and used.” Dr. Marrouche was 1 of 5 cardiac electrophysiologists who served on the 11-member writing group.
The new document for consumers “addresses an unmet need,” and the HRS collaboration with the CTA was “a unique opportunity to develop useful guidance that supports education and empowers consumers,” said Christina Wurster, chief strategy officer for the HRS in Washington and a member of the writing panel. “The questions outlined in the document are questions our members receive daily. The document is a resource they can direct people to.”
The HRS and CTA will “partner with consumer advocacy groups and professional societies to further disseminate the document,” added Ms. Wurster. “We’ll also have a strong push on social media to reach consumer audiences and drive awareness of this new resource,” she said in an interview. In addition, HRS “has strategic partnerships with other societies and will aim to work with them for dissemination, including societies related to internal medicine, emergency medicine, cardiology, and nursing, as well as also working with patient and consumer advocacy groups to reach the public.” The CTA will also actively publicize and disseminate the guidance document through their members.
Clinical guidelines play catch-up
Ironically, the HRS has issued this guidance to the public and has told people to take their wearable-collected heart data to clinicians before the HRS or any other medical group has advised clinicians on how they should handle, interpret, and use heart rhythm data collected this way.
Presumably, many if not most of the people with questions about their heart data from wearables are asymptomatic, because symptoms are what usually drive patients with a cardiac arrhythmia to consult a physician – they don’t wait to see what their device tells them. But the best way to manage asymptomatic arrhythmias like atrial fibrillation (AFib) remains a big clinical uncertainty today, with no evidence base as a guide, although several studies exploring this question are in progress.
“There are no clear and definitive data showing that treating subclinical atrial fibrillation improves outcomes. That’s what we need, and until we get these data you won’t see strong recommendations in guidelines” to screen patients for asymptomatic AFib or other arrhythmias, said Sana M. Al-Khatib, MD, a cardiac electrophysiologist and professor of medicine at Duke University, Durham, N.C., during the 2019 American Heart Association scientific sessions in Philadelphia in a talk about wearables and guidelines.
“If you intervene with silent AFib, do you improve outcomes? That evidence is lacking,” she said. Another shortcoming of current evidence is a clear understanding of what AFib burden warrants intervention, added Dr. Al-Khatib. “We see high-rate AFib episodes recorded in patients with implanted cardiac devices [and no symptoms], and we don’t know what to do with that either.”
The closest any existing guideline from a medical society comes to currently endorsing screening for AFib by a wearable is the 2016 European Society of Cardiology’s AFib management guidelines, which give “opportunistic screening” among people aged older than 65 years a IB recommendation, but specifically for screening by taking a patient’s pulse or with a ECG recording, with no mention of the screening role for wearables (Eur Heart J. 2016 Oct 7;37[38]:2893-967), Dr. Al-Khatib noted.
The most extensive data on screening for asymptomatic AFib in an unselected population came in the recently reported results from the Apple Heart Study, which enrolled more than 419,000 people monitored by a smart watch for a median of 117 days. During this screening, 2,161 people (0.52%) received a notification of having an irregular pulse (including 3.1% of those who were aged at least 65 years), which triggered more intensive assessment with an ECG patch for a median of 13 days in 450 of the 2,161 screening positives (21%) who agreed to participate in this follow-up. Among those 450 people, the patch test identified 34% as having actual AFib (N Engl J Med. 2019 Nov 14;381[20]:1909-17). But while this study provided evidence that screening for an irregular heartbeat with a wearable can identify AFib with some level of success, the results did not address whether this approach improved short- or long-term patient outcomes.
In addition, what the Apple Heart Study results showed was that this sort of screening results in a relatively large volume of follow-up testing. Of the 2,161 participants who received an irregular pulse notification, 1,376 (64%) returned a 90-day survey. Of these, 787 (57%) reported contact with a health care provider outside the study, 28% were prescribed a new medication, 33% were recommended to see a specialist (such as a cardiologist), and 36% were recommended to have additional testing.
“The results raise the question that a lot of resources were used,” to assess patients with a positive screening result, noted Paul A. Heidenreich, MD, a cardiologist and professor of medicine at Stanford (Calif.) University who studies quality of care for patients with heart disease. He estimated that, in the Apple Heart Study, each of the more than 2,000 patients who screening positive for an irregular heartbeat and underwent subsequent assessment ran up about $700 worth of follow-up testing. But he added that, in the case of AFib, the primary intervention that many previously undiagnosed AFib patients receive is some sort of anticoagulation for stroke prevention. Moreover, because this intervention is so effective there is a lot of money to play with to make AFib screening cost effective, as judged by typical, contemporary metrics of cost efficacy that value a quality-adjusted life-year (QALY) gain as reasonable for society to pay if the cost of an incremental QALY is $50,000-$150,000.
If the benchmark is a cost that’s within $50,000/QALY, then an average follow-up cost of $116/person to assess screened positives can fall within this cost ceiling. If the benchmark is $150,000/QALY, then follow-up costs can run as high as $491/person screened, said Dr. Heidenreich during the same AHA session where Dr. Al-Khatib spoke last November.
Despite this good news for screening for AFib with a wearable from a cost-effectiveness perspective, “there is so much uncertainty regarding the benefit and the consequences of incidental findings that we need an outcomes study before widespread implementation” of this type of screening, Dr. Heidenreich concluded. “We need an outcomes study to feel comfortable” with screening. “There is a huge potential for extra care that we don’t understand.”
Dr. Marrouche agreed that collecting adequate evidence to drive changes in clinical guidelines on how to use data from wearables has lagged behind the rapid spread of wearables and the information they can produce among the American public. “Outcomes and evidence will support guidelines development, but in the meantime, we’re offering education to clinicians, patients, and consumers. Consumers own their data, and they can share them with whomever they choose.”
The document notes that people who use wearables are, in general, “enthusiastic about tracking their data, not only for their own use, but also to share” with others, often on social media websites.
“We cannot control that, but our goal in the document is focused on the clinical relevance [of the data] and to help people better understand their data and use it in a meaningful and safe way,” Dr. Marrouche said.
Dr. Marrouche has been a consultant to, advisor to, or received research support from Abbott, Biosense Webster, Biotronik, GE Healthcare, Medtronic, Preventice, Sanofi-Aventis, Siemens, and Vytronus. Ms. Wurster is an employee of the Heart Rhythm Society. Dr. Al-Khatib has been a consultant to Milestone Pharmaceuticals and Medtronic, and she has also received other financial benefits from Medtronic. Dr. Heidenreich had no disclosures,
With much of the public now wearing devices on their wrists or elsewhere capable of recording a range of vital signs, including heart rate abnormalities, the Heart Rhythm Society launched a guide for American consumers about wearables and the data they collect during a session on Jan. 9 at CES 2020 in Las Vegas.
While providing a succinct but comprehensive overview of the types of wearables and the health metrics they can record, the main and recurring message of the 10-page e-pamphlet is that, when a layperson has a question or concern about their data, the best course is to consult a clinician.
The “Guidance for Wearable Health Solutions,” produced by the Heart Rhythm Society (HRS) along with the Consumer Technology Association (CTA, which presents the annual CES exhibition), cautions that “most wearables are primarily suited for fitness and wellness,” and stresses that wearables “are not a substitute for medical devices prescribed by a clinician.” And in all cases, the document advises, when questions arise about the data – including an apparently high heart rate; a reading the device identifies as abnormal; and when symptoms appear such as a rapid heart rate, dizziness, or fluttering or flopping of the heart – the response that the guidance advocates is consistent: Talk with your clinician.
“Heart Rhythm Society members are seeing more and more patients with their own data collected by wearables,” said Nassir F. Marrouche, MD, professor of medicine and director of electrophysiology at Tulane University, New Orleans, and a member of the panel that wrote the guidance document for the HRS and CTA. “Every provider is dealing with consumer wearable data. The need is important for consumers to be supported. Consumers and patients are buying over-the-counter devices and using them for diagnosis and management, with little to no guidance, and we want to help them feel supported in managing their data and understand what to do with it,” Dr. Marrouche said in an interview.
“This is a new reality in medicine; the direction of information is changing. Consumers are collecting data themselves and coming to physicians already informed. There is a new shift in how information is collected, shared, and used.” Dr. Marrouche was 1 of 5 cardiac electrophysiologists who served on the 11-member writing group.
The new document for consumers “addresses an unmet need,” and the HRS collaboration with the CTA was “a unique opportunity to develop useful guidance that supports education and empowers consumers,” said Christina Wurster, chief strategy officer for the HRS in Washington and a member of the writing panel. “The questions outlined in the document are questions our members receive daily. The document is a resource they can direct people to.”
The HRS and CTA will “partner with consumer advocacy groups and professional societies to further disseminate the document,” added Ms. Wurster. “We’ll also have a strong push on social media to reach consumer audiences and drive awareness of this new resource,” she said in an interview. In addition, HRS “has strategic partnerships with other societies and will aim to work with them for dissemination, including societies related to internal medicine, emergency medicine, cardiology, and nursing, as well as also working with patient and consumer advocacy groups to reach the public.” The CTA will also actively publicize and disseminate the guidance document through their members.
Clinical guidelines play catch-up
Ironically, the HRS has issued this guidance to the public and has told people to take their wearable-collected heart data to clinicians before the HRS or any other medical group has advised clinicians on how they should handle, interpret, and use heart rhythm data collected this way.
Presumably, many if not most of the people with questions about their heart data from wearables are asymptomatic, because symptoms are what usually drive patients with a cardiac arrhythmia to consult a physician – they don’t wait to see what their device tells them. But the best way to manage asymptomatic arrhythmias like atrial fibrillation (AFib) remains a big clinical uncertainty today, with no evidence base as a guide, although several studies exploring this question are in progress.
“There are no clear and definitive data showing that treating subclinical atrial fibrillation improves outcomes. That’s what we need, and until we get these data you won’t see strong recommendations in guidelines” to screen patients for asymptomatic AFib or other arrhythmias, said Sana M. Al-Khatib, MD, a cardiac electrophysiologist and professor of medicine at Duke University, Durham, N.C., during the 2019 American Heart Association scientific sessions in Philadelphia in a talk about wearables and guidelines.
“If you intervene with silent AFib, do you improve outcomes? That evidence is lacking,” she said. Another shortcoming of current evidence is a clear understanding of what AFib burden warrants intervention, added Dr. Al-Khatib. “We see high-rate AFib episodes recorded in patients with implanted cardiac devices [and no symptoms], and we don’t know what to do with that either.”
The closest any existing guideline from a medical society comes to currently endorsing screening for AFib by a wearable is the 2016 European Society of Cardiology’s AFib management guidelines, which give “opportunistic screening” among people aged older than 65 years a IB recommendation, but specifically for screening by taking a patient’s pulse or with a ECG recording, with no mention of the screening role for wearables (Eur Heart J. 2016 Oct 7;37[38]:2893-967), Dr. Al-Khatib noted.
The most extensive data on screening for asymptomatic AFib in an unselected population came in the recently reported results from the Apple Heart Study, which enrolled more than 419,000 people monitored by a smart watch for a median of 117 days. During this screening, 2,161 people (0.52%) received a notification of having an irregular pulse (including 3.1% of those who were aged at least 65 years), which triggered more intensive assessment with an ECG patch for a median of 13 days in 450 of the 2,161 screening positives (21%) who agreed to participate in this follow-up. Among those 450 people, the patch test identified 34% as having actual AFib (N Engl J Med. 2019 Nov 14;381[20]:1909-17). But while this study provided evidence that screening for an irregular heartbeat with a wearable can identify AFib with some level of success, the results did not address whether this approach improved short- or long-term patient outcomes.
In addition, what the Apple Heart Study results showed was that this sort of screening results in a relatively large volume of follow-up testing. Of the 2,161 participants who received an irregular pulse notification, 1,376 (64%) returned a 90-day survey. Of these, 787 (57%) reported contact with a health care provider outside the study, 28% were prescribed a new medication, 33% were recommended to see a specialist (such as a cardiologist), and 36% were recommended to have additional testing.
“The results raise the question that a lot of resources were used,” to assess patients with a positive screening result, noted Paul A. Heidenreich, MD, a cardiologist and professor of medicine at Stanford (Calif.) University who studies quality of care for patients with heart disease. He estimated that, in the Apple Heart Study, each of the more than 2,000 patients who screening positive for an irregular heartbeat and underwent subsequent assessment ran up about $700 worth of follow-up testing. But he added that, in the case of AFib, the primary intervention that many previously undiagnosed AFib patients receive is some sort of anticoagulation for stroke prevention. Moreover, because this intervention is so effective there is a lot of money to play with to make AFib screening cost effective, as judged by typical, contemporary metrics of cost efficacy that value a quality-adjusted life-year (QALY) gain as reasonable for society to pay if the cost of an incremental QALY is $50,000-$150,000.
If the benchmark is a cost that’s within $50,000/QALY, then an average follow-up cost of $116/person to assess screened positives can fall within this cost ceiling. If the benchmark is $150,000/QALY, then follow-up costs can run as high as $491/person screened, said Dr. Heidenreich during the same AHA session where Dr. Al-Khatib spoke last November.
Despite this good news for screening for AFib with a wearable from a cost-effectiveness perspective, “there is so much uncertainty regarding the benefit and the consequences of incidental findings that we need an outcomes study before widespread implementation” of this type of screening, Dr. Heidenreich concluded. “We need an outcomes study to feel comfortable” with screening. “There is a huge potential for extra care that we don’t understand.”
Dr. Marrouche agreed that collecting adequate evidence to drive changes in clinical guidelines on how to use data from wearables has lagged behind the rapid spread of wearables and the information they can produce among the American public. “Outcomes and evidence will support guidelines development, but in the meantime, we’re offering education to clinicians, patients, and consumers. Consumers own their data, and they can share them with whomever they choose.”
The document notes that people who use wearables are, in general, “enthusiastic about tracking their data, not only for their own use, but also to share” with others, often on social media websites.
“We cannot control that, but our goal in the document is focused on the clinical relevance [of the data] and to help people better understand their data and use it in a meaningful and safe way,” Dr. Marrouche said.
Dr. Marrouche has been a consultant to, advisor to, or received research support from Abbott, Biosense Webster, Biotronik, GE Healthcare, Medtronic, Preventice, Sanofi-Aventis, Siemens, and Vytronus. Ms. Wurster is an employee of the Heart Rhythm Society. Dr. Al-Khatib has been a consultant to Milestone Pharmaceuticals and Medtronic, and she has also received other financial benefits from Medtronic. Dr. Heidenreich had no disclosures,
FDA okays first generics for Eliquis
The Food and Drug Administration has approved two applications for first generic versions of apixaban (Eliquis, Bristol-Myers Squibb/Pfizer) tablets to reduce the risk for stroke and systemic embolism in patients with nonvalvular atrial fibrillation.
The FDA gave the go-ahead to market generic versions of apixaban to Micro Labs Limited and Mylan Pharmaceuticals.
“Today’s approvals of the first generics of apixaban are an example of how the FDA’s generic drug program improves access to lower-cost, safe, and high-quality medicines,” Janet Woodcock, MD, director of the FDA’s Center for Drug Evaluation and Research, said in a statement today. “These approvals mark the first generic approvals of a direct oral anticoagulant.”
It is estimated that between 2.7 and 6.1 million people in the United States have atrial fibrillation. Many of these individuals use anticoagulants or anticlotting drugs to reduce that risk. Direct oral anticoagulants, however, do not require repeated blood testing.
Apixaban was approved by the FDA in December 2012 for the prevention of stroke and systemic embolism in patients with nonvalvular atrial fibrillation. Additional indications in the United States are to treat and prevent the recurrence of deep vein thrombosis (DVT) and pulmonary embolism (PE) and as DVT/PE prophylaxis in adults who have undergone hip or knee replacement surgery.
The FDA reminds providers that, as with brand name apixaban, generic versions must be dispensed with a medication guide that provides important instructions on the drug’s uses and risks. Healthcare professionals should counsel patients on signs and symptoms of possible bleeding.
As with other FDA-approved anticlotting drugs, bleeding, including life-threatening and fatal bleeding, is the most serious risk with apixaban.
Full prescribing information for the drug also warns about the increased risk for stroke in patients who discontinue use of the drug without taking some other form of anticoagulation. Epidural or spinal hematoma, which may cause long-term or permanent paralysis, may occur in patients treated with apixaban who are undergoing spinal epidural anesthesia or spinal puncture.
This story first appeared on Medscape.com.
The Food and Drug Administration has approved two applications for first generic versions of apixaban (Eliquis, Bristol-Myers Squibb/Pfizer) tablets to reduce the risk for stroke and systemic embolism in patients with nonvalvular atrial fibrillation.
The FDA gave the go-ahead to market generic versions of apixaban to Micro Labs Limited and Mylan Pharmaceuticals.
“Today’s approvals of the first generics of apixaban are an example of how the FDA’s generic drug program improves access to lower-cost, safe, and high-quality medicines,” Janet Woodcock, MD, director of the FDA’s Center for Drug Evaluation and Research, said in a statement today. “These approvals mark the first generic approvals of a direct oral anticoagulant.”
It is estimated that between 2.7 and 6.1 million people in the United States have atrial fibrillation. Many of these individuals use anticoagulants or anticlotting drugs to reduce that risk. Direct oral anticoagulants, however, do not require repeated blood testing.
Apixaban was approved by the FDA in December 2012 for the prevention of stroke and systemic embolism in patients with nonvalvular atrial fibrillation. Additional indications in the United States are to treat and prevent the recurrence of deep vein thrombosis (DVT) and pulmonary embolism (PE) and as DVT/PE prophylaxis in adults who have undergone hip or knee replacement surgery.
The FDA reminds providers that, as with brand name apixaban, generic versions must be dispensed with a medication guide that provides important instructions on the drug’s uses and risks. Healthcare professionals should counsel patients on signs and symptoms of possible bleeding.
As with other FDA-approved anticlotting drugs, bleeding, including life-threatening and fatal bleeding, is the most serious risk with apixaban.
Full prescribing information for the drug also warns about the increased risk for stroke in patients who discontinue use of the drug without taking some other form of anticoagulation. Epidural or spinal hematoma, which may cause long-term or permanent paralysis, may occur in patients treated with apixaban who are undergoing spinal epidural anesthesia or spinal puncture.
This story first appeared on Medscape.com.
The Food and Drug Administration has approved two applications for first generic versions of apixaban (Eliquis, Bristol-Myers Squibb/Pfizer) tablets to reduce the risk for stroke and systemic embolism in patients with nonvalvular atrial fibrillation.
The FDA gave the go-ahead to market generic versions of apixaban to Micro Labs Limited and Mylan Pharmaceuticals.
“Today’s approvals of the first generics of apixaban are an example of how the FDA’s generic drug program improves access to lower-cost, safe, and high-quality medicines,” Janet Woodcock, MD, director of the FDA’s Center for Drug Evaluation and Research, said in a statement today. “These approvals mark the first generic approvals of a direct oral anticoagulant.”
It is estimated that between 2.7 and 6.1 million people in the United States have atrial fibrillation. Many of these individuals use anticoagulants or anticlotting drugs to reduce that risk. Direct oral anticoagulants, however, do not require repeated blood testing.
Apixaban was approved by the FDA in December 2012 for the prevention of stroke and systemic embolism in patients with nonvalvular atrial fibrillation. Additional indications in the United States are to treat and prevent the recurrence of deep vein thrombosis (DVT) and pulmonary embolism (PE) and as DVT/PE prophylaxis in adults who have undergone hip or knee replacement surgery.
The FDA reminds providers that, as with brand name apixaban, generic versions must be dispensed with a medication guide that provides important instructions on the drug’s uses and risks. Healthcare professionals should counsel patients on signs and symptoms of possible bleeding.
As with other FDA-approved anticlotting drugs, bleeding, including life-threatening and fatal bleeding, is the most serious risk with apixaban.
Full prescribing information for the drug also warns about the increased risk for stroke in patients who discontinue use of the drug without taking some other form of anticoagulation. Epidural or spinal hematoma, which may cause long-term or permanent paralysis, may occur in patients treated with apixaban who are undergoing spinal epidural anesthesia or spinal puncture.
This story first appeared on Medscape.com.
Hydroxychloroquine prevents congenital heart block recurrence in anti-Ro pregnancies
ATLANTA – Hydroxychloroquine (Plaquenil) 400 mg/day starting by pregnancy week 10 reduces recurrence of congenital heart block in infants born to women with anti-Ro antibodies, according to an open-label, prospective study presented at the annual meeting of the American College of Rheumatology.
Among antibody-positive women who had a previous pregnancy complicated by congenital heart block (CHB), the regimen reduced recurrence in a subsequent pregnancy from the expected historical rate of 18% to 7.4%, a more than 50% drop. “Given the potential benefit of hydroxychloroquine” (HCQ) and its relative safety during pregnancy, “testing all pregnancies for anti-Ro antibodies, regardless of maternal health, should be considered,” concluded investigators led by rheumatologist Peter Izmirly, MD, associate professor of medicine at New York (N.Y.) University.
About 40% of women with systemic lupus erythematosus and nearly 100% of women with Sjögren’s syndrome, as well as about 1% of women in the general population, have anti-Ro antibodies. They can be present in completely asymptomatic women, which is why the authors called for general screening. Indeed, half of the women in the trial had no or only mild, undifferentiated rheumatic symptoms. Often, “women who carry anti-Ro antibodies have no idea they have them” until they have a child with CHB and are tested, Dr. Izmirly said.
The antibodies cross the placenta and interfere with the normal development of the AV node; about 18% of infants die and most of the rest require lifelong pacing. The risk of CHB in antibody-positive women is about 2%, but once a child is born with the condition, the risk climbs to about 18% in subsequent pregnancies.
Years ago, Dr. Izmirly and his colleagues had a hunch that HCQ might help because it disrupts the toll-like receptor signaling involved in the disease process. A database review he led added weight to the idea, finding that among 257 anti-Ro positive pregnancies, the rate of CHB was 7.5% among the 40 women who happened to take HCQ, versus 21.2% among the 217 who did not. “We wanted to see if we could replicate that prospectively,” he said.
The Preventive Approach to Congenital Heart Block with Hydroxychloroquine (PATCH) trial enrolled 54 antibody positive women with a previous CHB pregnancy. They were started on 400 mg/day HCQ by gestation week 10.
There were four cases of second- or third-degree CHB among the women (7.4%, P = 0.02), all detected by fetal echocardiogram around week 20.
Nine of the women were treated with IVIG and/or dexamethasone for lupus flares or fetal heart issues other than advanced block, which confounded the results. To analyze the effect in a purely HCQ cohort, the team recruited an additional nine women not treated with any other medication during pregnancy, one of whose fetus developed third-degree heart block.
In total, 5 of 63 pregnancies (7.9%) resulted in advanced block. Among the 54 women exposed only to HCQ, the rate of second- or third-degree block was again 7.4% (4 of 54, P = .02). HCQ compliance, assessed by maternal blood levels above 200 ng/mL at least once, was 98%, and cord blood confirmed fetal exposure to HCQ.
Once detected, CHB was treated with dexamethasone or IVIG. One case progressed to cardiomyopathy, and the pregnancy was terminated. Another child required pacing after birth. Other children reverted to normal sinus rhythm but had intermittent second-degree block at age 2.
Overall, “the safety in this study was excellent,” said rheumatologist and senior investigator Jill Buyon, MD, director of the division of rheumatology at New York University.
The complications – nine births before 37 weeks, one infant small for gestational age – were not unexpected in a rheumatic population. “We were very nervous about Plaquenil cardiomyopathy” in the pregnancy that was terminated, but there was no evidence of it on histology.
The children will have ocular optical coherence tomography at age 5 to check for retinal toxicity; the 12 who have been tested so far show no obvious signs. Dr. Izmirly said he doesn’t expect to see any problems. “We are just being super cautious.”
The audience had questions about why the trial didn’t have a placebo arm. He explained that CHB is a rare event – one in 15,000 pregnancies – and it took 8 years just to adequately power the single-arm study; recruiting more than 100 additional women for a placebo-controlled trial wasn’t practical.
Also, “there was no way” women were going to be randomized to placebo when HCQ seemed so promising; 35% of the enrollees had already lost a child to CHB. “Everyone wanted the drug,” Dr. Izmirly said.
The majority of women were white, and about half met criteria for lupus and/or Sjögren’s. Anti-Ro levels remained above 1,000 EU throughout pregnancy. Women were excluded if they were taking high-dose prednisone or any dose of fluorinated corticosteroids at baseline.
The National Institutes of Health funded the work. The investigators had no relevant disclosures.
SOURCE: Izmirly P et al. Arthritis Rheumatol. 2019;71(suppl 10). Abstract 1761.
ATLANTA – Hydroxychloroquine (Plaquenil) 400 mg/day starting by pregnancy week 10 reduces recurrence of congenital heart block in infants born to women with anti-Ro antibodies, according to an open-label, prospective study presented at the annual meeting of the American College of Rheumatology.
Among antibody-positive women who had a previous pregnancy complicated by congenital heart block (CHB), the regimen reduced recurrence in a subsequent pregnancy from the expected historical rate of 18% to 7.4%, a more than 50% drop. “Given the potential benefit of hydroxychloroquine” (HCQ) and its relative safety during pregnancy, “testing all pregnancies for anti-Ro antibodies, regardless of maternal health, should be considered,” concluded investigators led by rheumatologist Peter Izmirly, MD, associate professor of medicine at New York (N.Y.) University.
About 40% of women with systemic lupus erythematosus and nearly 100% of women with Sjögren’s syndrome, as well as about 1% of women in the general population, have anti-Ro antibodies. They can be present in completely asymptomatic women, which is why the authors called for general screening. Indeed, half of the women in the trial had no or only mild, undifferentiated rheumatic symptoms. Often, “women who carry anti-Ro antibodies have no idea they have them” until they have a child with CHB and are tested, Dr. Izmirly said.
The antibodies cross the placenta and interfere with the normal development of the AV node; about 18% of infants die and most of the rest require lifelong pacing. The risk of CHB in antibody-positive women is about 2%, but once a child is born with the condition, the risk climbs to about 18% in subsequent pregnancies.
Years ago, Dr. Izmirly and his colleagues had a hunch that HCQ might help because it disrupts the toll-like receptor signaling involved in the disease process. A database review he led added weight to the idea, finding that among 257 anti-Ro positive pregnancies, the rate of CHB was 7.5% among the 40 women who happened to take HCQ, versus 21.2% among the 217 who did not. “We wanted to see if we could replicate that prospectively,” he said.
The Preventive Approach to Congenital Heart Block with Hydroxychloroquine (PATCH) trial enrolled 54 antibody positive women with a previous CHB pregnancy. They were started on 400 mg/day HCQ by gestation week 10.
There were four cases of second- or third-degree CHB among the women (7.4%, P = 0.02), all detected by fetal echocardiogram around week 20.
Nine of the women were treated with IVIG and/or dexamethasone for lupus flares or fetal heart issues other than advanced block, which confounded the results. To analyze the effect in a purely HCQ cohort, the team recruited an additional nine women not treated with any other medication during pregnancy, one of whose fetus developed third-degree heart block.
In total, 5 of 63 pregnancies (7.9%) resulted in advanced block. Among the 54 women exposed only to HCQ, the rate of second- or third-degree block was again 7.4% (4 of 54, P = .02). HCQ compliance, assessed by maternal blood levels above 200 ng/mL at least once, was 98%, and cord blood confirmed fetal exposure to HCQ.
Once detected, CHB was treated with dexamethasone or IVIG. One case progressed to cardiomyopathy, and the pregnancy was terminated. Another child required pacing after birth. Other children reverted to normal sinus rhythm but had intermittent second-degree block at age 2.
Overall, “the safety in this study was excellent,” said rheumatologist and senior investigator Jill Buyon, MD, director of the division of rheumatology at New York University.
The complications – nine births before 37 weeks, one infant small for gestational age – were not unexpected in a rheumatic population. “We were very nervous about Plaquenil cardiomyopathy” in the pregnancy that was terminated, but there was no evidence of it on histology.
The children will have ocular optical coherence tomography at age 5 to check for retinal toxicity; the 12 who have been tested so far show no obvious signs. Dr. Izmirly said he doesn’t expect to see any problems. “We are just being super cautious.”
The audience had questions about why the trial didn’t have a placebo arm. He explained that CHB is a rare event – one in 15,000 pregnancies – and it took 8 years just to adequately power the single-arm study; recruiting more than 100 additional women for a placebo-controlled trial wasn’t practical.
Also, “there was no way” women were going to be randomized to placebo when HCQ seemed so promising; 35% of the enrollees had already lost a child to CHB. “Everyone wanted the drug,” Dr. Izmirly said.
The majority of women were white, and about half met criteria for lupus and/or Sjögren’s. Anti-Ro levels remained above 1,000 EU throughout pregnancy. Women were excluded if they were taking high-dose prednisone or any dose of fluorinated corticosteroids at baseline.
The National Institutes of Health funded the work. The investigators had no relevant disclosures.
SOURCE: Izmirly P et al. Arthritis Rheumatol. 2019;71(suppl 10). Abstract 1761.
ATLANTA – Hydroxychloroquine (Plaquenil) 400 mg/day starting by pregnancy week 10 reduces recurrence of congenital heart block in infants born to women with anti-Ro antibodies, according to an open-label, prospective study presented at the annual meeting of the American College of Rheumatology.
Among antibody-positive women who had a previous pregnancy complicated by congenital heart block (CHB), the regimen reduced recurrence in a subsequent pregnancy from the expected historical rate of 18% to 7.4%, a more than 50% drop. “Given the potential benefit of hydroxychloroquine” (HCQ) and its relative safety during pregnancy, “testing all pregnancies for anti-Ro antibodies, regardless of maternal health, should be considered,” concluded investigators led by rheumatologist Peter Izmirly, MD, associate professor of medicine at New York (N.Y.) University.
About 40% of women with systemic lupus erythematosus and nearly 100% of women with Sjögren’s syndrome, as well as about 1% of women in the general population, have anti-Ro antibodies. They can be present in completely asymptomatic women, which is why the authors called for general screening. Indeed, half of the women in the trial had no or only mild, undifferentiated rheumatic symptoms. Often, “women who carry anti-Ro antibodies have no idea they have them” until they have a child with CHB and are tested, Dr. Izmirly said.
The antibodies cross the placenta and interfere with the normal development of the AV node; about 18% of infants die and most of the rest require lifelong pacing. The risk of CHB in antibody-positive women is about 2%, but once a child is born with the condition, the risk climbs to about 18% in subsequent pregnancies.
Years ago, Dr. Izmirly and his colleagues had a hunch that HCQ might help because it disrupts the toll-like receptor signaling involved in the disease process. A database review he led added weight to the idea, finding that among 257 anti-Ro positive pregnancies, the rate of CHB was 7.5% among the 40 women who happened to take HCQ, versus 21.2% among the 217 who did not. “We wanted to see if we could replicate that prospectively,” he said.
The Preventive Approach to Congenital Heart Block with Hydroxychloroquine (PATCH) trial enrolled 54 antibody positive women with a previous CHB pregnancy. They were started on 400 mg/day HCQ by gestation week 10.
There were four cases of second- or third-degree CHB among the women (7.4%, P = 0.02), all detected by fetal echocardiogram around week 20.
Nine of the women were treated with IVIG and/or dexamethasone for lupus flares or fetal heart issues other than advanced block, which confounded the results. To analyze the effect in a purely HCQ cohort, the team recruited an additional nine women not treated with any other medication during pregnancy, one of whose fetus developed third-degree heart block.
In total, 5 of 63 pregnancies (7.9%) resulted in advanced block. Among the 54 women exposed only to HCQ, the rate of second- or third-degree block was again 7.4% (4 of 54, P = .02). HCQ compliance, assessed by maternal blood levels above 200 ng/mL at least once, was 98%, and cord blood confirmed fetal exposure to HCQ.
Once detected, CHB was treated with dexamethasone or IVIG. One case progressed to cardiomyopathy, and the pregnancy was terminated. Another child required pacing after birth. Other children reverted to normal sinus rhythm but had intermittent second-degree block at age 2.
Overall, “the safety in this study was excellent,” said rheumatologist and senior investigator Jill Buyon, MD, director of the division of rheumatology at New York University.
The complications – nine births before 37 weeks, one infant small for gestational age – were not unexpected in a rheumatic population. “We were very nervous about Plaquenil cardiomyopathy” in the pregnancy that was terminated, but there was no evidence of it on histology.
The children will have ocular optical coherence tomography at age 5 to check for retinal toxicity; the 12 who have been tested so far show no obvious signs. Dr. Izmirly said he doesn’t expect to see any problems. “We are just being super cautious.”
The audience had questions about why the trial didn’t have a placebo arm. He explained that CHB is a rare event – one in 15,000 pregnancies – and it took 8 years just to adequately power the single-arm study; recruiting more than 100 additional women for a placebo-controlled trial wasn’t practical.
Also, “there was no way” women were going to be randomized to placebo when HCQ seemed so promising; 35% of the enrollees had already lost a child to CHB. “Everyone wanted the drug,” Dr. Izmirly said.
The majority of women were white, and about half met criteria for lupus and/or Sjögren’s. Anti-Ro levels remained above 1,000 EU throughout pregnancy. Women were excluded if they were taking high-dose prednisone or any dose of fluorinated corticosteroids at baseline.
The National Institutes of Health funded the work. The investigators had no relevant disclosures.
SOURCE: Izmirly P et al. Arthritis Rheumatol. 2019;71(suppl 10). Abstract 1761.
REPORTING FROM ACR 2019