Heart Failure

In 2016, results from the LEADER trial of liraglutide in patients with type 2 diabetes helped jump-start awareness of the potential role of this new class of drugs, the glucagonlike peptide–1 receptor agonists, for reducing cardiovascular events. The randomized, placebo-controlled trial enrolled more than 9000 patients at more than 400 sites in over 30 countries, and took nearly 6 years from the start of patient enrollment to publication of the landmark results.

In December 2020, an independent team of researchers published results from a study with a design identical to LEADER, but used data that came not from a massive, global, years-long trial but from already-existing numbers culled from three large U.S. insurance claim databases. The result of this emulation using real-world data was virtually identical to what the actual trial showed, replicating both the direction and statistical significance of the original finding of the randomized, controlled trial (RCT).

What if research proved that this sort of RCT emulation could reliably be done on a regular basis? What might it mean for regulatory decisions on drugs and devices that historically have been based entirely on efficacy evidence from RCTs?
 

Making the most of a sea of observational data

Medicine in the United States has become increasingly awash in a sea of observational data collected from sources that include electronic health records, insurance claims, and increasingly, personal-health monitoring devices.

The Food and Drug Administration is now in the process of trying to figure out how it can legitimately harness this tsunami of real-world data to make efficacy decisions, essentially creating a new category of evidence to complement traditional data from randomized trials. It’s an opportunity that agency staff and their outside advisors have been keen to seize, especially given the soaring cost of prospective, randomized trials.

Recognition of this untapped resource in part led to a key initiative, among many others, included in the 21st Century Cures Act, passed in December 2016. Among the Act’s mandates was that, by the end of 2021, the FDA would issue guidance on when drug sponsors could use real-world evidence (RWE) to either help support a new indication for an already approved drug or help satisfy postapproval study requirements.

The initiative recognizes that this approach is not appropriate for initial drug approvals, which remain exclusively reliant on evidence from RCTs. Instead, it seems best suited to support expanding indications for already approved drugs.

Although FDA staff have made progress in identifying the challenges and broadening their understanding of how to best handle real-world data that come from observing patients in routine practice, agency leaders stress that this complex issue will likely not be fully resolved by their guidance to be published later this year. The FDA released a draft of the guidance in May 2019.
 

Can RWE be ‘credible and reliable?’

“Whether observational, nonrandomized data can become credible enough to use is what we’re talking about. These are possibilities that need to be explained and better understood,” said Robert Temple, MD, deputy director for clinical science of the FDA Center for Drug Evaluation and Research.

“Since the 1970s, the FDA has recognized historical controls as legitimate, so it’s possible [for RWE] to be credible. The big test is when is it credible and reliable enough [to assess efficacy]?” wondered Dr. Temple during a 2-day workshop on the topic held mid-February and organized by Duke University’s Margolis Center for Health Policy.

“We’re approaching an inflection point regarding how observational studies are generated and used, but our evidentiary standards will not lower, and it will be a case-by-case decision” by the agency as they review future RWE submissions, said John Concato, MD, the FDA’s associate director for real-world evidence, during the workshop.

“We are working toward guidance development, but also looking down the road to what we need to do to enable this,” said Dr. Concato. “It’s a complicated issue. If it was easy, it would have already been fixed.” He added that the agency will likely release a “portfolio” of guidance for submitting real-world data and RWE. Real-world data are raw information that, when analyzed, become RWE.

In short, the FDA seems headed toward guidance that won’t spell out a pathway that guarantees success using RWE but will at least open the door to consideration of this unprecedented application.
 

Not like flipping a switch

The guidance will not activate acceptance of RWE all at once. “It’s not like a light switch,” cautioned Adam Kroetsch, MPP, research director for biomedical innovation and regulatory policy at Duke-Margolis in Washington, D.C. “It’s an evolutionary process,” and the upcoming guidance will provide “just a little more clarity” on what sorts of best practices using RWE the FDA will find persuasive. “It’s hard for the FDA to clearly say what it’s looking for until they see some good examples,” Dr. Kroetsch said in an interview.

What will change is that drug sponsors can submit using RWE, and the FDA “will have a more open-minded view,” predicted Sebastian Schneeweiss, MD, ScD, a workshop participant and chief of pharmacoepidemiology and pharmacoeconomics at Brigham and Women’s Hospital in Boston. “For the first time, a law required [the FDA] to take a serious look” at observational data for efficacy assessment.

“The FDA has had a bias against using RWE for evidence of efficacy but has long used it to understand drug safety. Now the FDA is trying to wrap its arms around how to best use RWE” for efficacy decisions, said Joseph S. Ross, MD, another workshop participant and professor of medicine and public health at Yale University, New Haven, Conn.

The agency’s cautious approach is reassuring, Dr. Ross noted in an interview. “There was worry that the 21st Century Cures Act would open the door to allowing real-world data to be used in ways that weren’t very reliable. Very quickly, the FDA started trying to figure out the best ways to use these data in reasonable ways.”
 

Duplicating RCTs with RWE

To help better understand the potential use of RWE, the FDA sponsored several demonstration projects. Researchers presented results from three of these projects during the workshop in February. All three examined whether RWE, plugged into the design of an actual RCT, can produce roughly similar results when similar patients are used.

A generally consistent finding from the three demonstration projects was that “when the data are fit for purpose” the emulated or duplicated analyses with RWE “can come to similar conclusions” as the actual RCTs, said Dr. Schneeweiss, who leads one of the demonstration projects, RCT DUPLICATE.

At the workshop he reported results from RWE duplications of 20 different RCTs using insurance claims data from U.S. patients. The findings came from 10 duplications already reported in Circulation in December 2020 (including a duplication of the LEADER trial), and an additional 10 as yet unpublished RCT duplications. In the next few months, the researchers intend to assess a final group of 10 more RCT duplications.

Workshop participants also presented results from two other FDA demonstration projects: the OPERAND program run by the Multi-Regional Clinical Trials Center of Brigham and Women’s Hospital and Harvard; and the CERSI program based at Yale and the Mayo Clinic in Rochester, Minn. Both are smaller in scale than RCT DUPLICATE, incorporate lab data in addition to claims data, and in some cases test how well RWE can emulate RCTs that are not yet completed.

Collectively, results from these demonstration projects suggest that RWE can successfully emulate the results of an RCT, said Dr. Ross, a coinvestigator on the CERSI study. But the CERSI findings also highlighted how an RCT can fall short of clinical relevance.

“One of our most important findings was that RCTs don’t always represent real-world practice,” he said. His group attempted to replicate the 5,000-patient GRADE trial of four different drug options added to metformin in patients with type 2 diabetes. One of the four options included insulin glargine (Lantus), and the attempt to emulate the study with RWE hit the bump that no relevant real-world patients in their US claims database actually received the formulation.

That means the GRADE trial “is almost meaningless. It doesn’t reflect real-world practice,” Dr. Ross noted.

Results from the three demonstration projects “highlight the gaps we still have,” summed up Dr. Kroetsch. “They show where we need better data” from observational sources that function as well as data from RCTs.

Still, the demonstration project results are “an important step forward in establishing the validity of real-world evidence,” commented David Kerr, MBChB, an endocrinologist and director of research and innovation at the Sansum Diabetes Research Institute in Santa Barbara, Calif.
 

‘Target trials’ tether RWE

The target trial approach to designing an observational study is a key tool for boosting reliability and applicability of the results. The idea is to create a well-designed trial that could be the basis for a conventional RCT, and then use observational data to flesh out the target trial instead of collecting data from prospectively enrolled patients.

Designing observational studies that emulate target trials allows causal inferences, said Miguel A. Hernán, MD, DrPH, a professor of biostatistics and epidemiology at the Harvard School of Public Health, Boston. Plugging real-world data into the framework of an appropriately designed target trial substantially cuts the risk of a biased analysis, he explained during the workshop.

However, the approach has limitations. The target trial must be a pragmatic trial, and the approach does not work for placebo-controlled trials, although it can accommodate a usual-care control arm. It also usually precludes patient blinding, testing treatments not used in routine practice, and close monitoring of patients in ways that are uncommon in usual care.

The target trial approach received broad endorsement during the workshop as the future for observational studies destined for efficacy consideration by the FDA.

“The idea of prespecifying a target trial is a really fantastic place to start,” commented Robert Ball, MD, deputy director of the FDA Office of Surveillance and Epidemiology. “There is still a whole set of questions once the trial is prespecified, but prespecification would be a fantastic step forward,” he said during the workshop.

Participants also endorsed other important steps to boost the value of observational studies for regulatory reviews, including preregistering the study on a site such as clinicaltrials.gov; being fully transparent about the origins of observational data; using data that match the needs of the target trial; not reviewing the data in advance to avoid cherry picking and gaming the analysis; and reporting neutral or negative results when they occur, something often not currently done for observational analyses.

But although there was clear progress and much agreement among thought leaders at the workshop, FDA representatives stressed caution in moving forward.
 

“No easy answer”

“With more experience, we can learn what works and what doesn’t work in generating valid results from observational studies,” said Dr. Concato. “Although the observational results have upside potential, we need to learn more. There is no easy answer, no checklist for fit-for-use data, no off-the-shelf study design, and no ideal analytic method.”

Dr. Concato acknowledged that the FDA’s goal is clear given the 2016 legislation. “The FDA is embracing our obligations under the 21st Century Cures Act to evaluate use of real-world data and real-world evidence.”

He also suggested that researchers “shy away from a false dichotomy of RCTs or observational studies and instead think about how and when RCTs and observational studies can be designed and conducted to yield trustworthy results.” Dr. Concato’s solution: “a taxonomy of interventional or noninterventional studies.”

“The FDA is under enormous pressure to embrace real-world evidence, both because of the economics of running RCTs and because of the availability of new observational data from electronic health records, wearable devices, claims, etc.,” said Dr. Kerr, who did not participate in the workshop but coauthored an editorial that calls for using real-world data in regulatory decisions for drugs and devices for diabetes. These factors create an “irresistible force” spurring the FDA to consider observational, noninterventional data.

“I think the FDA really wants this to go forward,” Dr. Kerr added in an interview. “The FDA keeps telling us that clinical trials do not have enough women or patients from minority groups. Real-world data is a way to address that. This will not be the death of RCTs, but this work shines a light on the deficiencies of RCTs and how the deficiencies can be dealt with.”

Dr. Kroetsch has reported no relevant financial relationships. Dr. Schneeweiss has reported being a consultant to and holding equity in Aetion and receiving research funding from the FDA. Dr. Ross has reported receiving research funding from the FDA, Johnson & Johnson, and Medtronic. Dr. Hernán has reported being a consultant for Cytel. Dr. Kerr has reported being a consultant for Ascensia, EOFlow, Lifecare, Merck, Novo Nordisk, Roche Diagnostics, and Voluntis. Dr. Temple, Dr. Concato, and Dr. Ball are FDA employees.

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

In 2016, results from the LEADER trial of liraglutide in patients with type 2 diabetes helped jump-start awareness of the potential role of this new class of drugs, the glucagonlike peptide–1 receptor agonists, for reducing cardiovascular events. The randomized, placebo-controlled trial enrolled more than 9000 patients at more than 400 sites in over 30 countries, and took nearly 6 years from the start of patient enrollment to publication of the landmark results.

In December 2020, an independent team of researchers published results from a study with a design identical to LEADER, but used data that came not from a massive, global, years-long trial but from already-existing numbers culled from three large U.S. insurance claim databases. The result of this emulation using real-world data was virtually identical to what the actual trial showed, replicating both the direction and statistical significance of the original finding of the randomized, controlled trial (RCT).

What if research proved that this sort of RCT emulation could reliably be done on a regular basis? What might it mean for regulatory decisions on drugs and devices that historically have been based entirely on efficacy evidence from RCTs?
 

Making the most of a sea of observational data

Medicine in the United States has become increasingly awash in a sea of observational data collected from sources that include electronic health records, insurance claims, and increasingly, personal-health monitoring devices.

The Food and Drug Administration is now in the process of trying to figure out how it can legitimately harness this tsunami of real-world data to make efficacy decisions, essentially creating a new category of evidence to complement traditional data from randomized trials. It’s an opportunity that agency staff and their outside advisors have been keen to seize, especially given the soaring cost of prospective, randomized trials.

Recognition of this untapped resource in part led to a key initiative, among many others, included in the 21st Century Cures Act, passed in December 2016. Among the Act’s mandates was that, by the end of 2021, the FDA would issue guidance on when drug sponsors could use real-world evidence (RWE) to either help support a new indication for an already approved drug or help satisfy postapproval study requirements.

The initiative recognizes that this approach is not appropriate for initial drug approvals, which remain exclusively reliant on evidence from RCTs. Instead, it seems best suited to support expanding indications for already approved drugs.

Although FDA staff have made progress in identifying the challenges and broadening their understanding of how to best handle real-world data that come from observing patients in routine practice, agency leaders stress that this complex issue will likely not be fully resolved by their guidance to be published later this year. The FDA released a draft of the guidance in May 2019.
 

Can RWE be ‘credible and reliable?’

“Whether observational, nonrandomized data can become credible enough to use is what we’re talking about. These are possibilities that need to be explained and better understood,” said Robert Temple, MD, deputy director for clinical science of the FDA Center for Drug Evaluation and Research.

“Since the 1970s, the FDA has recognized historical controls as legitimate, so it’s possible [for RWE] to be credible. The big test is when is it credible and reliable enough [to assess efficacy]?” wondered Dr. Temple during a 2-day workshop on the topic held mid-February and organized by Duke University’s Margolis Center for Health Policy.

“We’re approaching an inflection point regarding how observational studies are generated and used, but our evidentiary standards will not lower, and it will be a case-by-case decision” by the agency as they review future RWE submissions, said John Concato, MD, the FDA’s associate director for real-world evidence, during the workshop.

“We are working toward guidance development, but also looking down the road to what we need to do to enable this,” said Dr. Concato. “It’s a complicated issue. If it was easy, it would have already been fixed.” He added that the agency will likely release a “portfolio” of guidance for submitting real-world data and RWE. Real-world data are raw information that, when analyzed, become RWE.

In short, the FDA seems headed toward guidance that won’t spell out a pathway that guarantees success using RWE but will at least open the door to consideration of this unprecedented application.
 

Not like flipping a switch

The guidance will not activate acceptance of RWE all at once. “It’s not like a light switch,” cautioned Adam Kroetsch, MPP, research director for biomedical innovation and regulatory policy at Duke-Margolis in Washington, D.C. “It’s an evolutionary process,” and the upcoming guidance will provide “just a little more clarity” on what sorts of best practices using RWE the FDA will find persuasive. “It’s hard for the FDA to clearly say what it’s looking for until they see some good examples,” Dr. Kroetsch said in an interview.

What will change is that drug sponsors can submit using RWE, and the FDA “will have a more open-minded view,” predicted Sebastian Schneeweiss, MD, ScD, a workshop participant and chief of pharmacoepidemiology and pharmacoeconomics at Brigham and Women’s Hospital in Boston. “For the first time, a law required [the FDA] to take a serious look” at observational data for efficacy assessment.

“The FDA has had a bias against using RWE for evidence of efficacy but has long used it to understand drug safety. Now the FDA is trying to wrap its arms around how to best use RWE” for efficacy decisions, said Joseph S. Ross, MD, another workshop participant and professor of medicine and public health at Yale University, New Haven, Conn.

The agency’s cautious approach is reassuring, Dr. Ross noted in an interview. “There was worry that the 21st Century Cures Act would open the door to allowing real-world data to be used in ways that weren’t very reliable. Very quickly, the FDA started trying to figure out the best ways to use these data in reasonable ways.”
 

Duplicating RCTs with RWE

To help better understand the potential use of RWE, the FDA sponsored several demonstration projects. Researchers presented results from three of these projects during the workshop in February. All three examined whether RWE, plugged into the design of an actual RCT, can produce roughly similar results when similar patients are used.

A generally consistent finding from the three demonstration projects was that “when the data are fit for purpose” the emulated or duplicated analyses with RWE “can come to similar conclusions” as the actual RCTs, said Dr. Schneeweiss, who leads one of the demonstration projects, RCT DUPLICATE.

At the workshop he reported results from RWE duplications of 20 different RCTs using insurance claims data from U.S. patients. The findings came from 10 duplications already reported in Circulation in December 2020 (including a duplication of the LEADER trial), and an additional 10 as yet unpublished RCT duplications. In the next few months, the researchers intend to assess a final group of 10 more RCT duplications.

Workshop participants also presented results from two other FDA demonstration projects: the OPERAND program run by the Multi-Regional Clinical Trials Center of Brigham and Women’s Hospital and Harvard; and the CERSI program based at Yale and the Mayo Clinic in Rochester, Minn. Both are smaller in scale than RCT DUPLICATE, incorporate lab data in addition to claims data, and in some cases test how well RWE can emulate RCTs that are not yet completed.

Collectively, results from these demonstration projects suggest that RWE can successfully emulate the results of an RCT, said Dr. Ross, a coinvestigator on the CERSI study. But the CERSI findings also highlighted how an RCT can fall short of clinical relevance.

“One of our most important findings was that RCTs don’t always represent real-world practice,” he said. His group attempted to replicate the 5,000-patient GRADE trial of four different drug options added to metformin in patients with type 2 diabetes. One of the four options included insulin glargine (Lantus), and the attempt to emulate the study with RWE hit the bump that no relevant real-world patients in their US claims database actually received the formulation.

That means the GRADE trial “is almost meaningless. It doesn’t reflect real-world practice,” Dr. Ross noted.

Results from the three demonstration projects “highlight the gaps we still have,” summed up Dr. Kroetsch. “They show where we need better data” from observational sources that function as well as data from RCTs.

Still, the demonstration project results are “an important step forward in establishing the validity of real-world evidence,” commented David Kerr, MBChB, an endocrinologist and director of research and innovation at the Sansum Diabetes Research Institute in Santa Barbara, Calif.
 

‘Target trials’ tether RWE

The target trial approach to designing an observational study is a key tool for boosting reliability and applicability of the results. The idea is to create a well-designed trial that could be the basis for a conventional RCT, and then use observational data to flesh out the target trial instead of collecting data from prospectively enrolled patients.

Designing observational studies that emulate target trials allows causal inferences, said Miguel A. Hernán, MD, DrPH, a professor of biostatistics and epidemiology at the Harvard School of Public Health, Boston. Plugging real-world data into the framework of an appropriately designed target trial substantially cuts the risk of a biased analysis, he explained during the workshop.

However, the approach has limitations. The target trial must be a pragmatic trial, and the approach does not work for placebo-controlled trials, although it can accommodate a usual-care control arm. It also usually precludes patient blinding, testing treatments not used in routine practice, and close monitoring of patients in ways that are uncommon in usual care.

The target trial approach received broad endorsement during the workshop as the future for observational studies destined for efficacy consideration by the FDA.

“The idea of prespecifying a target trial is a really fantastic place to start,” commented Robert Ball, MD, deputy director of the FDA Office of Surveillance and Epidemiology. “There is still a whole set of questions once the trial is prespecified, but prespecification would be a fantastic step forward,” he said during the workshop.

Participants also endorsed other important steps to boost the value of observational studies for regulatory reviews, including preregistering the study on a site such as clinicaltrials.gov; being fully transparent about the origins of observational data; using data that match the needs of the target trial; not reviewing the data in advance to avoid cherry picking and gaming the analysis; and reporting neutral or negative results when they occur, something often not currently done for observational analyses.

But although there was clear progress and much agreement among thought leaders at the workshop, FDA representatives stressed caution in moving forward.
 

“No easy answer”

“With more experience, we can learn what works and what doesn’t work in generating valid results from observational studies,” said Dr. Concato. “Although the observational results have upside potential, we need to learn more. There is no easy answer, no checklist for fit-for-use data, no off-the-shelf study design, and no ideal analytic method.”

Dr. Concato acknowledged that the FDA’s goal is clear given the 2016 legislation. “The FDA is embracing our obligations under the 21st Century Cures Act to evaluate use of real-world data and real-world evidence.”

He also suggested that researchers “shy away from a false dichotomy of RCTs or observational studies and instead think about how and when RCTs and observational studies can be designed and conducted to yield trustworthy results.” Dr. Concato’s solution: “a taxonomy of interventional or noninterventional studies.”

“The FDA is under enormous pressure to embrace real-world evidence, both because of the economics of running RCTs and because of the availability of new observational data from electronic health records, wearable devices, claims, etc.,” said Dr. Kerr, who did not participate in the workshop but coauthored an editorial that calls for using real-world data in regulatory decisions for drugs and devices for diabetes. These factors create an “irresistible force” spurring the FDA to consider observational, noninterventional data.

“I think the FDA really wants this to go forward,” Dr. Kerr added in an interview. “The FDA keeps telling us that clinical trials do not have enough women or patients from minority groups. Real-world data is a way to address that. This will not be the death of RCTs, but this work shines a light on the deficiencies of RCTs and how the deficiencies can be dealt with.”

Dr. Kroetsch has reported no relevant financial relationships. Dr. Schneeweiss has reported being a consultant to and holding equity in Aetion and receiving research funding from the FDA. Dr. Ross has reported receiving research funding from the FDA, Johnson & Johnson, and Medtronic. Dr. Hernán has reported being a consultant for Cytel. Dr. Kerr has reported being a consultant for Ascensia, EOFlow, Lifecare, Merck, Novo Nordisk, Roche Diagnostics, and Voluntis. Dr. Temple, Dr. Concato, and Dr. Ball are FDA employees.

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

In 2016, results from the LEADER trial of liraglutide in patients with type 2 diabetes helped jump-start awareness of the potential role of this new class of drugs, the glucagonlike peptide–1 receptor agonists, for reducing cardiovascular events. The randomized, placebo-controlled trial enrolled more than 9000 patients at more than 400 sites in over 30 countries, and took nearly 6 years from the start of patient enrollment to publication of the landmark results.

In December 2020, an independent team of researchers published results from a study with a design identical to LEADER, but used data that came not from a massive, global, years-long trial but from already-existing numbers culled from three large U.S. insurance claim databases. The result of this emulation using real-world data was virtually identical to what the actual trial showed, replicating both the direction and statistical significance of the original finding of the randomized, controlled trial (RCT).

What if research proved that this sort of RCT emulation could reliably be done on a regular basis? What might it mean for regulatory decisions on drugs and devices that historically have been based entirely on efficacy evidence from RCTs?
 

Making the most of a sea of observational data

Medicine in the United States has become increasingly awash in a sea of observational data collected from sources that include electronic health records, insurance claims, and increasingly, personal-health monitoring devices.

The Food and Drug Administration is now in the process of trying to figure out how it can legitimately harness this tsunami of real-world data to make efficacy decisions, essentially creating a new category of evidence to complement traditional data from randomized trials. It’s an opportunity that agency staff and their outside advisors have been keen to seize, especially given the soaring cost of prospective, randomized trials.

Recognition of this untapped resource in part led to a key initiative, among many others, included in the 21st Century Cures Act, passed in December 2016. Among the Act’s mandates was that, by the end of 2021, the FDA would issue guidance on when drug sponsors could use real-world evidence (RWE) to either help support a new indication for an already approved drug or help satisfy postapproval study requirements.

The initiative recognizes that this approach is not appropriate for initial drug approvals, which remain exclusively reliant on evidence from RCTs. Instead, it seems best suited to support expanding indications for already approved drugs.

Although FDA staff have made progress in identifying the challenges and broadening their understanding of how to best handle real-world data that come from observing patients in routine practice, agency leaders stress that this complex issue will likely not be fully resolved by their guidance to be published later this year. The FDA released a draft of the guidance in May 2019.
 

Can RWE be ‘credible and reliable?’

“Whether observational, nonrandomized data can become credible enough to use is what we’re talking about. These are possibilities that need to be explained and better understood,” said Robert Temple, MD, deputy director for clinical science of the FDA Center for Drug Evaluation and Research.

“Since the 1970s, the FDA has recognized historical controls as legitimate, so it’s possible [for RWE] to be credible. The big test is when is it credible and reliable enough [to assess efficacy]?” wondered Dr. Temple during a 2-day workshop on the topic held mid-February and organized by Duke University’s Margolis Center for Health Policy.

“We’re approaching an inflection point regarding how observational studies are generated and used, but our evidentiary standards will not lower, and it will be a case-by-case decision” by the agency as they review future RWE submissions, said John Concato, MD, the FDA’s associate director for real-world evidence, during the workshop.

“We are working toward guidance development, but also looking down the road to what we need to do to enable this,” said Dr. Concato. “It’s a complicated issue. If it was easy, it would have already been fixed.” He added that the agency will likely release a “portfolio” of guidance for submitting real-world data and RWE. Real-world data are raw information that, when analyzed, become RWE.

In short, the FDA seems headed toward guidance that won’t spell out a pathway that guarantees success using RWE but will at least open the door to consideration of this unprecedented application.
 

Not like flipping a switch

The guidance will not activate acceptance of RWE all at once. “It’s not like a light switch,” cautioned Adam Kroetsch, MPP, research director for biomedical innovation and regulatory policy at Duke-Margolis in Washington, D.C. “It’s an evolutionary process,” and the upcoming guidance will provide “just a little more clarity” on what sorts of best practices using RWE the FDA will find persuasive. “It’s hard for the FDA to clearly say what it’s looking for until they see some good examples,” Dr. Kroetsch said in an interview.

What will change is that drug sponsors can submit using RWE, and the FDA “will have a more open-minded view,” predicted Sebastian Schneeweiss, MD, ScD, a workshop participant and chief of pharmacoepidemiology and pharmacoeconomics at Brigham and Women’s Hospital in Boston. “For the first time, a law required [the FDA] to take a serious look” at observational data for efficacy assessment.

“The FDA has had a bias against using RWE for evidence of efficacy but has long used it to understand drug safety. Now the FDA is trying to wrap its arms around how to best use RWE” for efficacy decisions, said Joseph S. Ross, MD, another workshop participant and professor of medicine and public health at Yale University, New Haven, Conn.

The agency’s cautious approach is reassuring, Dr. Ross noted in an interview. “There was worry that the 21st Century Cures Act would open the door to allowing real-world data to be used in ways that weren’t very reliable. Very quickly, the FDA started trying to figure out the best ways to use these data in reasonable ways.”
 

Duplicating RCTs with RWE

To help better understand the potential use of RWE, the FDA sponsored several demonstration projects. Researchers presented results from three of these projects during the workshop in February. All three examined whether RWE, plugged into the design of an actual RCT, can produce roughly similar results when similar patients are used.

A generally consistent finding from the three demonstration projects was that “when the data are fit for purpose” the emulated or duplicated analyses with RWE “can come to similar conclusions” as the actual RCTs, said Dr. Schneeweiss, who leads one of the demonstration projects, RCT DUPLICATE.

At the workshop he reported results from RWE duplications of 20 different RCTs using insurance claims data from U.S. patients. The findings came from 10 duplications already reported in Circulation in December 2020 (including a duplication of the LEADER trial), and an additional 10 as yet unpublished RCT duplications. In the next few months, the researchers intend to assess a final group of 10 more RCT duplications.

Workshop participants also presented results from two other FDA demonstration projects: the OPERAND program run by the Multi-Regional Clinical Trials Center of Brigham and Women’s Hospital and Harvard; and the CERSI program based at Yale and the Mayo Clinic in Rochester, Minn. Both are smaller in scale than RCT DUPLICATE, incorporate lab data in addition to claims data, and in some cases test how well RWE can emulate RCTs that are not yet completed.

Collectively, results from these demonstration projects suggest that RWE can successfully emulate the results of an RCT, said Dr. Ross, a coinvestigator on the CERSI study. But the CERSI findings also highlighted how an RCT can fall short of clinical relevance.

“One of our most important findings was that RCTs don’t always represent real-world practice,” he said. His group attempted to replicate the 5,000-patient GRADE trial of four different drug options added to metformin in patients with type 2 diabetes. One of the four options included insulin glargine (Lantus), and the attempt to emulate the study with RWE hit the bump that no relevant real-world patients in their US claims database actually received the formulation.

That means the GRADE trial “is almost meaningless. It doesn’t reflect real-world practice,” Dr. Ross noted.

Results from the three demonstration projects “highlight the gaps we still have,” summed up Dr. Kroetsch. “They show where we need better data” from observational sources that function as well as data from RCTs.

Still, the demonstration project results are “an important step forward in establishing the validity of real-world evidence,” commented David Kerr, MBChB, an endocrinologist and director of research and innovation at the Sansum Diabetes Research Institute in Santa Barbara, Calif.
 

‘Target trials’ tether RWE

The target trial approach to designing an observational study is a key tool for boosting reliability and applicability of the results. The idea is to create a well-designed trial that could be the basis for a conventional RCT, and then use observational data to flesh out the target trial instead of collecting data from prospectively enrolled patients.

Designing observational studies that emulate target trials allows causal inferences, said Miguel A. Hernán, MD, DrPH, a professor of biostatistics and epidemiology at the Harvard School of Public Health, Boston. Plugging real-world data into the framework of an appropriately designed target trial substantially cuts the risk of a biased analysis, he explained during the workshop.

However, the approach has limitations. The target trial must be a pragmatic trial, and the approach does not work for placebo-controlled trials, although it can accommodate a usual-care control arm. It also usually precludes patient blinding, testing treatments not used in routine practice, and close monitoring of patients in ways that are uncommon in usual care.

The target trial approach received broad endorsement during the workshop as the future for observational studies destined for efficacy consideration by the FDA.

“The idea of prespecifying a target trial is a really fantastic place to start,” commented Robert Ball, MD, deputy director of the FDA Office of Surveillance and Epidemiology. “There is still a whole set of questions once the trial is prespecified, but prespecification would be a fantastic step forward,” he said during the workshop.

Participants also endorsed other important steps to boost the value of observational studies for regulatory reviews, including preregistering the study on a site such as clinicaltrials.gov; being fully transparent about the origins of observational data; using data that match the needs of the target trial; not reviewing the data in advance to avoid cherry picking and gaming the analysis; and reporting neutral or negative results when they occur, something often not currently done for observational analyses.

But although there was clear progress and much agreement among thought leaders at the workshop, FDA representatives stressed caution in moving forward.
 

“No easy answer”

“With more experience, we can learn what works and what doesn’t work in generating valid results from observational studies,” said Dr. Concato. “Although the observational results have upside potential, we need to learn more. There is no easy answer, no checklist for fit-for-use data, no off-the-shelf study design, and no ideal analytic method.”

Dr. Concato acknowledged that the FDA’s goal is clear given the 2016 legislation. “The FDA is embracing our obligations under the 21st Century Cures Act to evaluate use of real-world data and real-world evidence.”

He also suggested that researchers “shy away from a false dichotomy of RCTs or observational studies and instead think about how and when RCTs and observational studies can be designed and conducted to yield trustworthy results.” Dr. Concato’s solution: “a taxonomy of interventional or noninterventional studies.”

“The FDA is under enormous pressure to embrace real-world evidence, both because of the economics of running RCTs and because of the availability of new observational data from electronic health records, wearable devices, claims, etc.,” said Dr. Kerr, who did not participate in the workshop but coauthored an editorial that calls for using real-world data in regulatory decisions for drugs and devices for diabetes. These factors create an “irresistible force” spurring the FDA to consider observational, noninterventional data.

“I think the FDA really wants this to go forward,” Dr. Kerr added in an interview. “The FDA keeps telling us that clinical trials do not have enough women or patients from minority groups. Real-world data is a way to address that. This will not be the death of RCTs, but this work shines a light on the deficiencies of RCTs and how the deficiencies can be dealt with.”

Dr. Kroetsch has reported no relevant financial relationships. Dr. Schneeweiss has reported being a consultant to and holding equity in Aetion and receiving research funding from the FDA. Dr. Ross has reported receiving research funding from the FDA, Johnson & Johnson, and Medtronic. Dr. Hernán has reported being a consultant for Cytel. Dr. Kerr has reported being a consultant for Ascensia, EOFlow, Lifecare, Merck, Novo Nordisk, Roche Diagnostics, and Voluntis. Dr. Temple, Dr. Concato, and Dr. Ball are FDA employees.

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

Personalized nutritional support for adults hospitalized with chronic heart failure and deemed to be at high nutritional risk reduced the risk of death or adverse cardiovascular events, compared with standard hospital food, new research indicates.
 

The Swiss EFFORT trial focused on patients with chronic heart failure and high risk of malnutrition defined by low body mass index, weight loss, and low food intake upon hospital admission.

“This high-risk group of chronic heart failure patients showed a significant improvement in mortality over 30 and 180 days, as well as other clinical outcomes, when individualized nutritional support interventions were offered to patients,” Philipp Schuetz, MD, MPH, Kantonsspital Aarau, Switzerland, said in an interview.

“While monitoring the nutritional status should be done also in outpatient settings by [general practitioners], malnutrition screening upon hospital admission may help to identify high-risk patients with high risk for nutritional status deterioration during the hospital stay who will benefit from nutritional assessment and treatment,” said Dr. Schuetz.

The study was published online May 3 in the Journal of the American College of Cardiology.
 

It’s not all about salt

The findings are based on a prespecified secondary analysis of outcomes in 645 patients (median age, 78.8 years, 52% men) hospitalized with chronic heart failure who participated in the open-label EFFORT study.  

One-third of patients were hospitalized for acute decompensated heart failure and two-thirds had chronic heart failure and other acute medical illnesses requiring hospitalization.

All patients were at risk of malnutrition based on a Nutritional Risk Screening (NRS) score of 3 points or higher. They were randomly allocated 1:1 to individualized nutritional support to reach energy, protein, and micronutrient goals or usual hospital food (control group). 

By 30 days, 27 of 321 patients (8.4%) receiving nutritional support had died compared with 48 of 324 patients (14.8%) in the control group (adjusted odds ratio [OR]: 0.44; 95% confidence interval, 0.26-0.75; P = .002)

Patients with high nutritional risk (NRS >4 points) showed the most benefit from nutritional support.

Compared with patients with moderate nutritional risk scores (NRS score 3-4), those with high nutritional risk (NRS >4) had a highly significant 65% increased mortality risk over 180 days.

The individual component of the NRS with the strongest association with mortality was low food intake in the week before hospitalization.

Patients who received nutritional support in the hospital also had a lower risk for major cardiovascular events at 30 days (17.4% vs. 26.9%; OR, 0.50; 95% CI, 0.34-0.75; P = .001).

“Historically, cardiologists and internists caring for patients with heart failure have mainly focused on salt-restrictive diets to reduce blood volume and thus optimize heart function. Yet, reduction of salt intake has not been shown to effectively improve clinical outcome but may, on the contrary, increase the risk of malnutrition as low-salt diets are often not tasty,” Dr. Schuetz said.

“Our data suggest that we should move our focus away from salt-restrictive diets to high-protein diets to cover individual nutritional goals in this high-risk group of patients, which includes screening, assessment, and nutritional support by dietitians,” Dr. Schuetz said.

In a linked editorial, Sheldon Gottlieb, MD, Johns Hopkins University, Baltimore, said there has been “relatively little attention” paid to the role of diet in heart failure other than recommending reduced salt intake. 

In fact, in the 2021 American College of Cardiology expert consensus recommendations for optimizing heart failure treatment, roughly five words are devoted to diet and exercise and there is no mention of nutrition assessment by a dietitian, he points out.

“This study adds another tile to the still-fragmentary mosaic picture of the patient with heart failure at nutritional risk who might benefit from nutritional support,” Dr. Dr. Gottlieb wrote.

“ ‘Good medical care’ dictates that all hospitalized patients deserve to have a standardized nutritional assessment; the challenge remains: how to determine which patient with heart failure at nutritional risk will benefit by medical nutrition therapy,” Dr. Gottlieb said.

The Swiss National Science Foundation and the Research Council of the Kantonsspital Aarau provided funding for the trial. Dr. Schuetz’s institution has previously received unrestricted grant money unrelated to this project from Nestle Health Science and Abbott Nutrition. Dr. Gottlieb owns a federal trademark for the “Greens, Beans, and Leans” diet, and has a pending federal trademark for “FLOATS”: flax + oats cereal.

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

Personalized nutritional support for adults hospitalized with chronic heart failure and deemed to be at high nutritional risk reduced the risk of death or adverse cardiovascular events, compared with standard hospital food, new research indicates.
 

The Swiss EFFORT trial focused on patients with chronic heart failure and high risk of malnutrition defined by low body mass index, weight loss, and low food intake upon hospital admission.

“This high-risk group of chronic heart failure patients showed a significant improvement in mortality over 30 and 180 days, as well as other clinical outcomes, when individualized nutritional support interventions were offered to patients,” Philipp Schuetz, MD, MPH, Kantonsspital Aarau, Switzerland, said in an interview.

“While monitoring the nutritional status should be done also in outpatient settings by [general practitioners], malnutrition screening upon hospital admission may help to identify high-risk patients with high risk for nutritional status deterioration during the hospital stay who will benefit from nutritional assessment and treatment,” said Dr. Schuetz.

The study was published online May 3 in the Journal of the American College of Cardiology.
 

It’s not all about salt

The findings are based on a prespecified secondary analysis of outcomes in 645 patients (median age, 78.8 years, 52% men) hospitalized with chronic heart failure who participated in the open-label EFFORT study.  

One-third of patients were hospitalized for acute decompensated heart failure and two-thirds had chronic heart failure and other acute medical illnesses requiring hospitalization.

All patients were at risk of malnutrition based on a Nutritional Risk Screening (NRS) score of 3 points or higher. They were randomly allocated 1:1 to individualized nutritional support to reach energy, protein, and micronutrient goals or usual hospital food (control group). 

By 30 days, 27 of 321 patients (8.4%) receiving nutritional support had died compared with 48 of 324 patients (14.8%) in the control group (adjusted odds ratio [OR]: 0.44; 95% confidence interval, 0.26-0.75; P = .002)

Patients with high nutritional risk (NRS >4 points) showed the most benefit from nutritional support.

Compared with patients with moderate nutritional risk scores (NRS score 3-4), those with high nutritional risk (NRS >4) had a highly significant 65% increased mortality risk over 180 days.

The individual component of the NRS with the strongest association with mortality was low food intake in the week before hospitalization.

Patients who received nutritional support in the hospital also had a lower risk for major cardiovascular events at 30 days (17.4% vs. 26.9%; OR, 0.50; 95% CI, 0.34-0.75; P = .001).

“Historically, cardiologists and internists caring for patients with heart failure have mainly focused on salt-restrictive diets to reduce blood volume and thus optimize heart function. Yet, reduction of salt intake has not been shown to effectively improve clinical outcome but may, on the contrary, increase the risk of malnutrition as low-salt diets are often not tasty,” Dr. Schuetz said.

“Our data suggest that we should move our focus away from salt-restrictive diets to high-protein diets to cover individual nutritional goals in this high-risk group of patients, which includes screening, assessment, and nutritional support by dietitians,” Dr. Schuetz said.

In a linked editorial, Sheldon Gottlieb, MD, Johns Hopkins University, Baltimore, said there has been “relatively little attention” paid to the role of diet in heart failure other than recommending reduced salt intake. 

In fact, in the 2021 American College of Cardiology expert consensus recommendations for optimizing heart failure treatment, roughly five words are devoted to diet and exercise and there is no mention of nutrition assessment by a dietitian, he points out.

“This study adds another tile to the still-fragmentary mosaic picture of the patient with heart failure at nutritional risk who might benefit from nutritional support,” Dr. Dr. Gottlieb wrote.

“ ‘Good medical care’ dictates that all hospitalized patients deserve to have a standardized nutritional assessment; the challenge remains: how to determine which patient with heart failure at nutritional risk will benefit by medical nutrition therapy,” Dr. Gottlieb said.

The Swiss National Science Foundation and the Research Council of the Kantonsspital Aarau provided funding for the trial. Dr. Schuetz’s institution has previously received unrestricted grant money unrelated to this project from Nestle Health Science and Abbott Nutrition. Dr. Gottlieb owns a federal trademark for the “Greens, Beans, and Leans” diet, and has a pending federal trademark for “FLOATS”: flax + oats cereal.

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

Personalized nutritional support for adults hospitalized with chronic heart failure and deemed to be at high nutritional risk reduced the risk of death or adverse cardiovascular events, compared with standard hospital food, new research indicates.
 

The Swiss EFFORT trial focused on patients with chronic heart failure and high risk of malnutrition defined by low body mass index, weight loss, and low food intake upon hospital admission.

“This high-risk group of chronic heart failure patients showed a significant improvement in mortality over 30 and 180 days, as well as other clinical outcomes, when individualized nutritional support interventions were offered to patients,” Philipp Schuetz, MD, MPH, Kantonsspital Aarau, Switzerland, said in an interview.

“While monitoring the nutritional status should be done also in outpatient settings by [general practitioners], malnutrition screening upon hospital admission may help to identify high-risk patients with high risk for nutritional status deterioration during the hospital stay who will benefit from nutritional assessment and treatment,” said Dr. Schuetz.

The study was published online May 3 in the Journal of the American College of Cardiology.
 

It’s not all about salt

The findings are based on a prespecified secondary analysis of outcomes in 645 patients (median age, 78.8 years, 52% men) hospitalized with chronic heart failure who participated in the open-label EFFORT study.  

One-third of patients were hospitalized for acute decompensated heart failure and two-thirds had chronic heart failure and other acute medical illnesses requiring hospitalization.

All patients were at risk of malnutrition based on a Nutritional Risk Screening (NRS) score of 3 points or higher. They were randomly allocated 1:1 to individualized nutritional support to reach energy, protein, and micronutrient goals or usual hospital food (control group). 

By 30 days, 27 of 321 patients (8.4%) receiving nutritional support had died compared with 48 of 324 patients (14.8%) in the control group (adjusted odds ratio [OR]: 0.44; 95% confidence interval, 0.26-0.75; P = .002)

Patients with high nutritional risk (NRS >4 points) showed the most benefit from nutritional support.

Compared with patients with moderate nutritional risk scores (NRS score 3-4), those with high nutritional risk (NRS >4) had a highly significant 65% increased mortality risk over 180 days.

The individual component of the NRS with the strongest association with mortality was low food intake in the week before hospitalization.

Patients who received nutritional support in the hospital also had a lower risk for major cardiovascular events at 30 days (17.4% vs. 26.9%; OR, 0.50; 95% CI, 0.34-0.75; P = .001).

“Historically, cardiologists and internists caring for patients with heart failure have mainly focused on salt-restrictive diets to reduce blood volume and thus optimize heart function. Yet, reduction of salt intake has not been shown to effectively improve clinical outcome but may, on the contrary, increase the risk of malnutrition as low-salt diets are often not tasty,” Dr. Schuetz said.

“Our data suggest that we should move our focus away from salt-restrictive diets to high-protein diets to cover individual nutritional goals in this high-risk group of patients, which includes screening, assessment, and nutritional support by dietitians,” Dr. Schuetz said.

In a linked editorial, Sheldon Gottlieb, MD, Johns Hopkins University, Baltimore, said there has been “relatively little attention” paid to the role of diet in heart failure other than recommending reduced salt intake. 

In fact, in the 2021 American College of Cardiology expert consensus recommendations for optimizing heart failure treatment, roughly five words are devoted to diet and exercise and there is no mention of nutrition assessment by a dietitian, he points out.

“This study adds another tile to the still-fragmentary mosaic picture of the patient with heart failure at nutritional risk who might benefit from nutritional support,” Dr. Dr. Gottlieb wrote.

“ ‘Good medical care’ dictates that all hospitalized patients deserve to have a standardized nutritional assessment; the challenge remains: how to determine which patient with heart failure at nutritional risk will benefit by medical nutrition therapy,” Dr. Gottlieb said.

The Swiss National Science Foundation and the Research Council of the Kantonsspital Aarau provided funding for the trial. Dr. Schuetz’s institution has previously received unrestricted grant money unrelated to this project from Nestle Health Science and Abbott Nutrition. Dr. Gottlieb owns a federal trademark for the “Greens, Beans, and Leans” diet, and has a pending federal trademark for “FLOATS”: flax + oats cereal.

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

When starting a new loop diuretic for a patient with heart failure, strongly consider torsemide over furosemide, Anthony C. Breu, MD, advised at SHM Converge, the annual conference of the Society of Hospital Medicine.

“Whether or not you take a patient who’s already on furosemide and you make the switch to torsemide is a little bit tougher for me to advocate, though that has happened in clinical trials,” said Dr. Breu, assistant professor of medicine at Harvard Medical School, Boston, who spoke May 5 at the Converge session “Things We Do for No Reason.” He co-presented the session with Leonard Feldman, MD, SFHM, director of the Osler Medical Residency Urban Health Track and associate professor at Johns Hopkins Medicine, Baltimore.

“If you consider doing this it would make sense to do so concert with the outpatient primary doctor and the outpatient cardiologist,” Dr. Breu said. “But in my review of the literature, it’s at least worth having these discussions, particularly for a patient who has multiple readmissions for heart failure. That may be a time to pause and ask: ‘Could torsemide be of benefit here?’ ”

In Dr. Breu’s opinion, there are at least three reasons why consider torsemide should be considered a first-line treatment for heart failure. For one thing, the current evidence says so. In a trial published in 2001, researchers randomized 234 patients with heart failure to receive torsemide or furosemide for 1 year. The percentage of patients who had one or more hospital readmissions was lower among those who received torsemide, compared with those who received furosemide in the torsemide group for heart failure (17% vs. 32%, respectively; P < .01) and for other cardiovascular causes (44% vs. 59%; P = .03). In addition, the number of total admissions was numerically lower for patients in the torsemide group, compared with the furosemide group for heart failure (23 vs. 61; P < .01) and for cardiovascular causes (78 vs. 130; P = .02).

In a separate study, researchers conducted an open-label trial of 237 patients with New York Heart Association (NYHA) class II-IV heart failure who were randomized to torsemide or furosemide. They found that a significantly higher percentage of patients in the torsemide group improved by one or more NYHA heart failure class, compared with those in the furosemide group (40%; P = .001 vs. 31%; P = .3). Moreover, patients treated with furosemide had more restrictions of daily life at 9 months, compared with those treated with torsemide (P < .001).

A separate, open-label, nonrandomized, postmarketing surveillance trial also found benefits of torsemide over furosemide or other agents used for patients with NYHA class III and IV heart failure. Patients treated with torsemide had a lower total mortality, compared with those treated with furosemide or other agents (2.2% vs. 4.5%, respectively; P < .05) as well as a lower cardiac mortality (1.4% vs. 3.5%; P < .05). They were also more likely to improve by one or more heart failure class (46% vs. 37%; P < .01) and less likely to have potassium levels less than 3.5 mEq/L or greater than 5.0 mEq/L (13% vs. 18%; P = .01).

According to Dr. Breu, meta-analyses of this topic consistently show that the NYHA class improved more with torsemide than with furosemide. “Some meta-analyses find a mortality benefit, while others find a readmissions benefit,” he said. “None of them show a benefit of furosemide over torsemide.”

A second reason to use torsemide as a first-line treatment for heart failure is that it has superior pharmacokinetics/dynamics, compared with furosemide. “We’ve all heard that furosemide has variable bioavailability,” said Dr. Breu, who also deputy editor of the Journal of Hospital Medicine’s “Things We Do For No Reason” article series. “Torsemide and bumetanide are much more reliably absorbed, partially because they are not affected by food, whereas furosemide is. That could be potentially problematic for patients who take their diuretic with meals. The fact that torsemide has less renal clearance is a benefit, because patients with heart failure have changing renal function.” In addition, the half-life of torsemide is 3-4 hours and the duration of action is 12 hours, “which are both longer than those for furosemide or bumetanide,” he added.

He also pointed out that torsemide has been shown to block the aldosterone receptor in vitro and in rat models – an effect that has not been observed with other loop diuretics. A randomized trial of patients with chronic heart failure found that levels of renin and aldosterone increased more with torsemide, compared with furosemide, supporting the hypothesis of aldosterone receptor blockade.

A third main reason to use torsemide as your go-to for heart failure has to do with its purported antifibrotic effects, “so that it could be more than a diuretic,” Dr. Breu said. “In heart failure, myocardial fibrosis occurs from increased collagen synthesis and turnover. Aldosterone has been shown to play a role in this myocardial fibrosis. Spironolactone has been shown to mitigate this to some extent. If torsemide acts a little like spironolactone, maybe that could explain some of the long-term effects that we see in these studies.”

A study supporting this notion found that torsemide but not furosemide reduced levels of serum carboxyl-terminal peptide of procollagen type I, which is associated with exaggerated myocardial deposition of collagen type I fibers in cardiac diseases.

Going forward, a study known as TRANSFORM-HF, which is currently recruiting about 6,000 patients, should bring more clarity to the topic. The primary objective is to compare the treatment strategy of torsemide versus furosemide on clinical outcomes over 12 months in patients with heart failure who are hospitalized. The estimated completion is mid-2022.

Dr. Breu and Dr. Feldman reported having no relevant financial disclosures.

When starting a new loop diuretic for a patient with heart failure, strongly consider torsemide over furosemide, Anthony C. Breu, MD, advised at SHM Converge, the annual conference of the Society of Hospital Medicine.

“Whether or not you take a patient who’s already on furosemide and you make the switch to torsemide is a little bit tougher for me to advocate, though that has happened in clinical trials,” said Dr. Breu, assistant professor of medicine at Harvard Medical School, Boston, who spoke May 5 at the Converge session “Things We Do for No Reason.” He co-presented the session with Leonard Feldman, MD, SFHM, director of the Osler Medical Residency Urban Health Track and associate professor at Johns Hopkins Medicine, Baltimore.

“If you consider doing this it would make sense to do so concert with the outpatient primary doctor and the outpatient cardiologist,” Dr. Breu said. “But in my review of the literature, it’s at least worth having these discussions, particularly for a patient who has multiple readmissions for heart failure. That may be a time to pause and ask: ‘Could torsemide be of benefit here?’ ”

In Dr. Breu’s opinion, there are at least three reasons why consider torsemide should be considered a first-line treatment for heart failure. For one thing, the current evidence says so. In a trial published in 2001, researchers randomized 234 patients with heart failure to receive torsemide or furosemide for 1 year. The percentage of patients who had one or more hospital readmissions was lower among those who received torsemide, compared with those who received furosemide in the torsemide group for heart failure (17% vs. 32%, respectively; P < .01) and for other cardiovascular causes (44% vs. 59%; P = .03). In addition, the number of total admissions was numerically lower for patients in the torsemide group, compared with the furosemide group for heart failure (23 vs. 61; P < .01) and for cardiovascular causes (78 vs. 130; P = .02).

In a separate study, researchers conducted an open-label trial of 237 patients with New York Heart Association (NYHA) class II-IV heart failure who were randomized to torsemide or furosemide. They found that a significantly higher percentage of patients in the torsemide group improved by one or more NYHA heart failure class, compared with those in the furosemide group (40%; P = .001 vs. 31%; P = .3). Moreover, patients treated with furosemide had more restrictions of daily life at 9 months, compared with those treated with torsemide (P < .001).

A separate, open-label, nonrandomized, postmarketing surveillance trial also found benefits of torsemide over furosemide or other agents used for patients with NYHA class III and IV heart failure. Patients treated with torsemide had a lower total mortality, compared with those treated with furosemide or other agents (2.2% vs. 4.5%, respectively; P < .05) as well as a lower cardiac mortality (1.4% vs. 3.5%; P < .05). They were also more likely to improve by one or more heart failure class (46% vs. 37%; P < .01) and less likely to have potassium levels less than 3.5 mEq/L or greater than 5.0 mEq/L (13% vs. 18%; P = .01).

According to Dr. Breu, meta-analyses of this topic consistently show that the NYHA class improved more with torsemide than with furosemide. “Some meta-analyses find a mortality benefit, while others find a readmissions benefit,” he said. “None of them show a benefit of furosemide over torsemide.”

A second reason to use torsemide as a first-line treatment for heart failure is that it has superior pharmacokinetics/dynamics, compared with furosemide. “We’ve all heard that furosemide has variable bioavailability,” said Dr. Breu, who also deputy editor of the Journal of Hospital Medicine’s “Things We Do For No Reason” article series. “Torsemide and bumetanide are much more reliably absorbed, partially because they are not affected by food, whereas furosemide is. That could be potentially problematic for patients who take their diuretic with meals. The fact that torsemide has less renal clearance is a benefit, because patients with heart failure have changing renal function.” In addition, the half-life of torsemide is 3-4 hours and the duration of action is 12 hours, “which are both longer than those for furosemide or bumetanide,” he added.

He also pointed out that torsemide has been shown to block the aldosterone receptor in vitro and in rat models – an effect that has not been observed with other loop diuretics. A randomized trial of patients with chronic heart failure found that levels of renin and aldosterone increased more with torsemide, compared with furosemide, supporting the hypothesis of aldosterone receptor blockade.

A third main reason to use torsemide as your go-to for heart failure has to do with its purported antifibrotic effects, “so that it could be more than a diuretic,” Dr. Breu said. “In heart failure, myocardial fibrosis occurs from increased collagen synthesis and turnover. Aldosterone has been shown to play a role in this myocardial fibrosis. Spironolactone has been shown to mitigate this to some extent. If torsemide acts a little like spironolactone, maybe that could explain some of the long-term effects that we see in these studies.”

A study supporting this notion found that torsemide but not furosemide reduced levels of serum carboxyl-terminal peptide of procollagen type I, which is associated with exaggerated myocardial deposition of collagen type I fibers in cardiac diseases.

Going forward, a study known as TRANSFORM-HF, which is currently recruiting about 6,000 patients, should bring more clarity to the topic. The primary objective is to compare the treatment strategy of torsemide versus furosemide on clinical outcomes over 12 months in patients with heart failure who are hospitalized. The estimated completion is mid-2022.

Dr. Breu and Dr. Feldman reported having no relevant financial disclosures.

When starting a new loop diuretic for a patient with heart failure, strongly consider torsemide over furosemide, Anthony C. Breu, MD, advised at SHM Converge, the annual conference of the Society of Hospital Medicine.

“Whether or not you take a patient who’s already on furosemide and you make the switch to torsemide is a little bit tougher for me to advocate, though that has happened in clinical trials,” said Dr. Breu, assistant professor of medicine at Harvard Medical School, Boston, who spoke May 5 at the Converge session “Things We Do for No Reason.” He co-presented the session with Leonard Feldman, MD, SFHM, director of the Osler Medical Residency Urban Health Track and associate professor at Johns Hopkins Medicine, Baltimore.

“If you consider doing this it would make sense to do so concert with the outpatient primary doctor and the outpatient cardiologist,” Dr. Breu said. “But in my review of the literature, it’s at least worth having these discussions, particularly for a patient who has multiple readmissions for heart failure. That may be a time to pause and ask: ‘Could torsemide be of benefit here?’ ”

In Dr. Breu’s opinion, there are at least three reasons why consider torsemide should be considered a first-line treatment for heart failure. For one thing, the current evidence says so. In a trial published in 2001, researchers randomized 234 patients with heart failure to receive torsemide or furosemide for 1 year. The percentage of patients who had one or more hospital readmissions was lower among those who received torsemide, compared with those who received furosemide in the torsemide group for heart failure (17% vs. 32%, respectively; P < .01) and for other cardiovascular causes (44% vs. 59%; P = .03). In addition, the number of total admissions was numerically lower for patients in the torsemide group, compared with the furosemide group for heart failure (23 vs. 61; P < .01) and for cardiovascular causes (78 vs. 130; P = .02).

In a separate study, researchers conducted an open-label trial of 237 patients with New York Heart Association (NYHA) class II-IV heart failure who were randomized to torsemide or furosemide. They found that a significantly higher percentage of patients in the torsemide group improved by one or more NYHA heart failure class, compared with those in the furosemide group (40%; P = .001 vs. 31%; P = .3). Moreover, patients treated with furosemide had more restrictions of daily life at 9 months, compared with those treated with torsemide (P < .001).

A separate, open-label, nonrandomized, postmarketing surveillance trial also found benefits of torsemide over furosemide or other agents used for patients with NYHA class III and IV heart failure. Patients treated with torsemide had a lower total mortality, compared with those treated with furosemide or other agents (2.2% vs. 4.5%, respectively; P < .05) as well as a lower cardiac mortality (1.4% vs. 3.5%; P < .05). They were also more likely to improve by one or more heart failure class (46% vs. 37%; P < .01) and less likely to have potassium levels less than 3.5 mEq/L or greater than 5.0 mEq/L (13% vs. 18%; P = .01).

According to Dr. Breu, meta-analyses of this topic consistently show that the NYHA class improved more with torsemide than with furosemide. “Some meta-analyses find a mortality benefit, while others find a readmissions benefit,” he said. “None of them show a benefit of furosemide over torsemide.”

A second reason to use torsemide as a first-line treatment for heart failure is that it has superior pharmacokinetics/dynamics, compared with furosemide. “We’ve all heard that furosemide has variable bioavailability,” said Dr. Breu, who also deputy editor of the Journal of Hospital Medicine’s “Things We Do For No Reason” article series. “Torsemide and bumetanide are much more reliably absorbed, partially because they are not affected by food, whereas furosemide is. That could be potentially problematic for patients who take their diuretic with meals. The fact that torsemide has less renal clearance is a benefit, because patients with heart failure have changing renal function.” In addition, the half-life of torsemide is 3-4 hours and the duration of action is 12 hours, “which are both longer than those for furosemide or bumetanide,” he added.

He also pointed out that torsemide has been shown to block the aldosterone receptor in vitro and in rat models – an effect that has not been observed with other loop diuretics. A randomized trial of patients with chronic heart failure found that levels of renin and aldosterone increased more with torsemide, compared with furosemide, supporting the hypothesis of aldosterone receptor blockade.

A third main reason to use torsemide as your go-to for heart failure has to do with its purported antifibrotic effects, “so that it could be more than a diuretic,” Dr. Breu said. “In heart failure, myocardial fibrosis occurs from increased collagen synthesis and turnover. Aldosterone has been shown to play a role in this myocardial fibrosis. Spironolactone has been shown to mitigate this to some extent. If torsemide acts a little like spironolactone, maybe that could explain some of the long-term effects that we see in these studies.”

A study supporting this notion found that torsemide but not furosemide reduced levels of serum carboxyl-terminal peptide of procollagen type I, which is associated with exaggerated myocardial deposition of collagen type I fibers in cardiac diseases.

Going forward, a study known as TRANSFORM-HF, which is currently recruiting about 6,000 patients, should bring more clarity to the topic. The primary objective is to compare the treatment strategy of torsemide versus furosemide on clinical outcomes over 12 months in patients with heart failure who are hospitalized. The estimated completion is mid-2022.

Dr. Breu and Dr. Feldman reported having no relevant financial disclosures.

Inequities in the initial growth of transcatheter aortic valve replacement (TAVR) programs in American hospitals has led to less use of the transformative procedure in poorer communities, a new cross-sectional study suggests.

Using Medicare claims data, investigators identified 554 new TAVR programs created between January 2012 and December 2018.

Of these, 98% were established in metropolitan areas (>50,000 residents) and 53% were started in areas with preexisting TAVR programs, “thereby increasing the number of programs but not necessarily increasing the geographic availability of the procedure,” said study author Ashwin Nathan, MD, Hospital of the University of Pennsylvania, Philadelphia.

Only 11 programs were started in nonmetropolitan areas over the study period, he noted during the featured clinical research presentation at the Society for Cardiovascular Angiography and Interventions (SCAI) 2021 annual scientific sessions, held virtually this year.

Hospitals that established TAVR programs, compared with those that did not, cared for patients with higher median household incomes (difference, $1,305; P = .03) and from areas with better economic well-being based on the Distressed Communities Index (difference, –3.15 units; P < .01), and cared for fewer patients with dual eligibility for Medicaid (difference, –3.15%; P < .01).

When the investigators looked at rates of TAVR between the core-based statistical areas, there were fewer TAVR procedures per 100,000 Medicare beneficiaries in areas with more Medicaid dual-eligible patients (difference, –1.19% per 1% increase), lower average median household incomes (difference, –0.62% per $1,000 decrease), and more average community distress (difference, –0.35% per 1 unit increase; P < .01 for all).

“What we can conclude is that the increased number of TAVR programs that we found during the study period did not necessarily translate to increased access to TAVR ... Wealthy, more privileged patients had more access to TAVR by virtue of the hospitals that serve them,” Dr. Nathan said.

Future steps, he said, are to identify the role of race and ethnicity in inequitable access to TAVR, identify system- and patient-level barriers to access, and to develop and test solutions to address inequitable care.

Elaborating on the latter point during a discussion of the results, study coauthor Jay S. Giri, MD, MPH, also from the Hospital of the University of Pennsylvania, observed that although the data showed rural areas are left behind, not every part of an urban area acts like the area more generally.

As a result, they’re delving into the 25 largest urban areas and trying to disaggregate, based on both socioeconomic status and race within the area, whether inequities exist, he said. “Believe it or not, in some urban areas where there clearly is access – there might even be a dozen TAVR programs within a 25 mile radius – do some of those areas still act like rural areas that don’t have access? So more to come on that.”

Session comoderator Steven Yakubov, MD, MidWest Cardiology Research Foundation in Columbus, Ohio, said the results show TAVR programs tend to be developed in well-served areas but asked whether some of the responsibility falls on patients to seek medical attention. “Do we just not give enough education to patients on how to access care?”

Dr. Giri responded by highlighting the complexity of navigating from even being diagnosed with aortic stenosis to making it through a multidisciplinary TAVR evaluation.

“Individuals with increased health literacy and more means are more likely to make it through that gauntlet. But from a public health perspective, obviously, I’d argue that the onus is probably more on the medical community at large to figure out how to roll these programs out more widespread,” he said.

“It looked to us like market forces overwhelmingly seemed to drive the development of new TAVR programs over access to care considerations,” Dr. Giri added. “And just to point out, those market forces aren’t at the level of the device manufacturers, who are often maligned for cost. This is really about the market forces at the level of hospitals and health systems.”

Session comoderator Megan Coylewright, MD, MPH, Erlanger Heart and Lung Institute, Chattanooga, Tenn., said, “I think that’s really well stated,” and noted that physicians may bear some responsibility as well.

“From a physician responsibility, especially for structural heart, we tended to all aggregate together, all of us that have structural heart training or that have trained in certain institutions,” she said. “It’s certainly on us to continue to spread out and go to the communities in need to ensure access. I think, as Dr. Giri said, there are a lot of solutions and that needs to be the focus for the next couple of years.”

Dr. Nathan reported having no relevant disclosures. Dr. Giri reported serving as a principal investigator for a research study for Boston Scientific, Inari Medical, Abbott, and Recor Medical; consulting for Boston Scientific; and serving on an advisory board for Inari Medical.

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

Inequities in the initial growth of transcatheter aortic valve replacement (TAVR) programs in American hospitals has led to less use of the transformative procedure in poorer communities, a new cross-sectional study suggests.

Using Medicare claims data, investigators identified 554 new TAVR programs created between January 2012 and December 2018.

Of these, 98% were established in metropolitan areas (>50,000 residents) and 53% were started in areas with preexisting TAVR programs, “thereby increasing the number of programs but not necessarily increasing the geographic availability of the procedure,” said study author Ashwin Nathan, MD, Hospital of the University of Pennsylvania, Philadelphia.

Only 11 programs were started in nonmetropolitan areas over the study period, he noted during the featured clinical research presentation at the Society for Cardiovascular Angiography and Interventions (SCAI) 2021 annual scientific sessions, held virtually this year.

Hospitals that established TAVR programs, compared with those that did not, cared for patients with higher median household incomes (difference, $1,305; P = .03) and from areas with better economic well-being based on the Distressed Communities Index (difference, –3.15 units; P < .01), and cared for fewer patients with dual eligibility for Medicaid (difference, –3.15%; P < .01).

When the investigators looked at rates of TAVR between the core-based statistical areas, there were fewer TAVR procedures per 100,000 Medicare beneficiaries in areas with more Medicaid dual-eligible patients (difference, –1.19% per 1% increase), lower average median household incomes (difference, –0.62% per $1,000 decrease), and more average community distress (difference, –0.35% per 1 unit increase; P < .01 for all).

“What we can conclude is that the increased number of TAVR programs that we found during the study period did not necessarily translate to increased access to TAVR ... Wealthy, more privileged patients had more access to TAVR by virtue of the hospitals that serve them,” Dr. Nathan said.

Future steps, he said, are to identify the role of race and ethnicity in inequitable access to TAVR, identify system- and patient-level barriers to access, and to develop and test solutions to address inequitable care.

Elaborating on the latter point during a discussion of the results, study coauthor Jay S. Giri, MD, MPH, also from the Hospital of the University of Pennsylvania, observed that although the data showed rural areas are left behind, not every part of an urban area acts like the area more generally.

As a result, they’re delving into the 25 largest urban areas and trying to disaggregate, based on both socioeconomic status and race within the area, whether inequities exist, he said. “Believe it or not, in some urban areas where there clearly is access – there might even be a dozen TAVR programs within a 25 mile radius – do some of those areas still act like rural areas that don’t have access? So more to come on that.”

Session comoderator Steven Yakubov, MD, MidWest Cardiology Research Foundation in Columbus, Ohio, said the results show TAVR programs tend to be developed in well-served areas but asked whether some of the responsibility falls on patients to seek medical attention. “Do we just not give enough education to patients on how to access care?”

Dr. Giri responded by highlighting the complexity of navigating from even being diagnosed with aortic stenosis to making it through a multidisciplinary TAVR evaluation.

“Individuals with increased health literacy and more means are more likely to make it through that gauntlet. But from a public health perspective, obviously, I’d argue that the onus is probably more on the medical community at large to figure out how to roll these programs out more widespread,” he said.

“It looked to us like market forces overwhelmingly seemed to drive the development of new TAVR programs over access to care considerations,” Dr. Giri added. “And just to point out, those market forces aren’t at the level of the device manufacturers, who are often maligned for cost. This is really about the market forces at the level of hospitals and health systems.”

Session comoderator Megan Coylewright, MD, MPH, Erlanger Heart and Lung Institute, Chattanooga, Tenn., said, “I think that’s really well stated,” and noted that physicians may bear some responsibility as well.

“From a physician responsibility, especially for structural heart, we tended to all aggregate together, all of us that have structural heart training or that have trained in certain institutions,” she said. “It’s certainly on us to continue to spread out and go to the communities in need to ensure access. I think, as Dr. Giri said, there are a lot of solutions and that needs to be the focus for the next couple of years.”

Dr. Nathan reported having no relevant disclosures. Dr. Giri reported serving as a principal investigator for a research study for Boston Scientific, Inari Medical, Abbott, and Recor Medical; consulting for Boston Scientific; and serving on an advisory board for Inari Medical.

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

Inequities in the initial growth of transcatheter aortic valve replacement (TAVR) programs in American hospitals has led to less use of the transformative procedure in poorer communities, a new cross-sectional study suggests.

Using Medicare claims data, investigators identified 554 new TAVR programs created between January 2012 and December 2018.

Of these, 98% were established in metropolitan areas (>50,000 residents) and 53% were started in areas with preexisting TAVR programs, “thereby increasing the number of programs but not necessarily increasing the geographic availability of the procedure,” said study author Ashwin Nathan, MD, Hospital of the University of Pennsylvania, Philadelphia.

Only 11 programs were started in nonmetropolitan areas over the study period, he noted during the featured clinical research presentation at the Society for Cardiovascular Angiography and Interventions (SCAI) 2021 annual scientific sessions, held virtually this year.

Hospitals that established TAVR programs, compared with those that did not, cared for patients with higher median household incomes (difference, $1,305; P = .03) and from areas with better economic well-being based on the Distressed Communities Index (difference, –3.15 units; P < .01), and cared for fewer patients with dual eligibility for Medicaid (difference, –3.15%; P < .01).

When the investigators looked at rates of TAVR between the core-based statistical areas, there were fewer TAVR procedures per 100,000 Medicare beneficiaries in areas with more Medicaid dual-eligible patients (difference, –1.19% per 1% increase), lower average median household incomes (difference, –0.62% per $1,000 decrease), and more average community distress (difference, –0.35% per 1 unit increase; P < .01 for all).

“What we can conclude is that the increased number of TAVR programs that we found during the study period did not necessarily translate to increased access to TAVR ... Wealthy, more privileged patients had more access to TAVR by virtue of the hospitals that serve them,” Dr. Nathan said.

Future steps, he said, are to identify the role of race and ethnicity in inequitable access to TAVR, identify system- and patient-level barriers to access, and to develop and test solutions to address inequitable care.

Elaborating on the latter point during a discussion of the results, study coauthor Jay S. Giri, MD, MPH, also from the Hospital of the University of Pennsylvania, observed that although the data showed rural areas are left behind, not every part of an urban area acts like the area more generally.

As a result, they’re delving into the 25 largest urban areas and trying to disaggregate, based on both socioeconomic status and race within the area, whether inequities exist, he said. “Believe it or not, in some urban areas where there clearly is access – there might even be a dozen TAVR programs within a 25 mile radius – do some of those areas still act like rural areas that don’t have access? So more to come on that.”

Session comoderator Steven Yakubov, MD, MidWest Cardiology Research Foundation in Columbus, Ohio, said the results show TAVR programs tend to be developed in well-served areas but asked whether some of the responsibility falls on patients to seek medical attention. “Do we just not give enough education to patients on how to access care?”

Dr. Giri responded by highlighting the complexity of navigating from even being diagnosed with aortic stenosis to making it through a multidisciplinary TAVR evaluation.

“Individuals with increased health literacy and more means are more likely to make it through that gauntlet. But from a public health perspective, obviously, I’d argue that the onus is probably more on the medical community at large to figure out how to roll these programs out more widespread,” he said.

“It looked to us like market forces overwhelmingly seemed to drive the development of new TAVR programs over access to care considerations,” Dr. Giri added. “And just to point out, those market forces aren’t at the level of the device manufacturers, who are often maligned for cost. This is really about the market forces at the level of hospitals and health systems.”

Session comoderator Megan Coylewright, MD, MPH, Erlanger Heart and Lung Institute, Chattanooga, Tenn., said, “I think that’s really well stated,” and noted that physicians may bear some responsibility as well.

“From a physician responsibility, especially for structural heart, we tended to all aggregate together, all of us that have structural heart training or that have trained in certain institutions,” she said. “It’s certainly on us to continue to spread out and go to the communities in need to ensure access. I think, as Dr. Giri said, there are a lot of solutions and that needs to be the focus for the next couple of years.”

Dr. Nathan reported having no relevant disclosures. Dr. Giri reported serving as a principal investigator for a research study for Boston Scientific, Inari Medical, Abbott, and Recor Medical; consulting for Boston Scientific; and serving on an advisory board for Inari Medical.

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

The Food and Drug Administration has approved dapagliflozin (Farxiga, AstraZeneca) to reduce the risk for kidney function decline, kidney failure, cardiovascular death, and hospitalization for heart failure in adult patients with chronic kidney disease (CKD) at risk for disease progression.

“Chronic kidney disease is an important public health issue, and there is a significant unmet need for therapies that slow disease progression and improve outcomes,” said Aliza Thompson, MD, deputy director of the division of cardiology and nephrology at the FDA’s Center for Drug Evaluation and Research. “Today’s approval of Farxiga for the treatment of chronic kidney disease is an important step forward in helping people living with kidney disease.”

Dapagliflozin was approved in 2014 to improve glycemic control in patients with diabetes mellitus, and approval was expanded in 2020 to include treatment of patients with heart failure and reduced ejection fraction, based on results of the DAPA-HF trial.

This new approval in chronic kidney disease was based on results of the DAPA-CKD trial that was stopped early in March 2020 because of efficacy of the treatment.

DAPA-CKD randomly assigned 4,304 patients with CKD but without diabetes to receive either dapagliflozin or placebo. The full study results, reported at the 2020 annual congress of the European Society of Cardiology and simultaneously published in the New England Journal of Medicine, showed that, during a median of 2.4 years, treatment with dapagliflozin led to a significant 31% relative reduction, compared with placebo in the study’s primary outcome, a composite that included at least a 50% drop in estimated glomerular filtration rate, compared with baseline, end-stage kidney disease, kidney transplant, renal death, or cardiovascular death.

Dapagliflozin treatment also cut all-cause mortality by a statistically significant relative reduction of 31%, and another secondary-endpoint analysis showed a statistically significant 29% relative reduction in the rate of cardiovascular death or heart failure hospitalization.

“Farxiga was not studied, nor is expected to be effective, in treating chronic kidney disease among patients with autosomal dominant or recessive polycystic (characterized by multiple cysts) kidney disease or among patients who require or have recently used immunosuppressive therapy to treat kidney disease,” the FDA statement noted.

Dapagliflozin should not be used by patients with a history of serious hypersensitivity reactions to this medication, or who are on dialysis, the agency added. “Serious, life-threatening cases of Fournier’s Gangrene have occurred in patients with diabetes taking Farxiga.”

Patients should consider taking a lower dose of insulin or insulin secretagogue to reduce hypoglycemic risk if they are also taking dapagliflozin. Treatment can also cause dehydration, serious urinary tract infections, genital yeast infections, and metabolic acidosis, the announcement said. “Patients should be assessed for their volume status and kidney function before starting Farxiga.”

Dapagliflozin previously received Fast Track, Breakthrough Therapy, and Priority Review designations for this new indication.

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

The Food and Drug Administration has approved dapagliflozin (Farxiga, AstraZeneca) to reduce the risk for kidney function decline, kidney failure, cardiovascular death, and hospitalization for heart failure in adult patients with chronic kidney disease (CKD) at risk for disease progression.

“Chronic kidney disease is an important public health issue, and there is a significant unmet need for therapies that slow disease progression and improve outcomes,” said Aliza Thompson, MD, deputy director of the division of cardiology and nephrology at the FDA’s Center for Drug Evaluation and Research. “Today’s approval of Farxiga for the treatment of chronic kidney disease is an important step forward in helping people living with kidney disease.”

Dapagliflozin was approved in 2014 to improve glycemic control in patients with diabetes mellitus, and approval was expanded in 2020 to include treatment of patients with heart failure and reduced ejection fraction, based on results of the DAPA-HF trial.

This new approval in chronic kidney disease was based on results of the DAPA-CKD trial that was stopped early in March 2020 because of efficacy of the treatment.

DAPA-CKD randomly assigned 4,304 patients with CKD but without diabetes to receive either dapagliflozin or placebo. The full study results, reported at the 2020 annual congress of the European Society of Cardiology and simultaneously published in the New England Journal of Medicine, showed that, during a median of 2.4 years, treatment with dapagliflozin led to a significant 31% relative reduction, compared with placebo in the study’s primary outcome, a composite that included at least a 50% drop in estimated glomerular filtration rate, compared with baseline, end-stage kidney disease, kidney transplant, renal death, or cardiovascular death.

Dapagliflozin treatment also cut all-cause mortality by a statistically significant relative reduction of 31%, and another secondary-endpoint analysis showed a statistically significant 29% relative reduction in the rate of cardiovascular death or heart failure hospitalization.

“Farxiga was not studied, nor is expected to be effective, in treating chronic kidney disease among patients with autosomal dominant or recessive polycystic (characterized by multiple cysts) kidney disease or among patients who require or have recently used immunosuppressive therapy to treat kidney disease,” the FDA statement noted.

Dapagliflozin should not be used by patients with a history of serious hypersensitivity reactions to this medication, or who are on dialysis, the agency added. “Serious, life-threatening cases of Fournier’s Gangrene have occurred in patients with diabetes taking Farxiga.”

Patients should consider taking a lower dose of insulin or insulin secretagogue to reduce hypoglycemic risk if they are also taking dapagliflozin. Treatment can also cause dehydration, serious urinary tract infections, genital yeast infections, and metabolic acidosis, the announcement said. “Patients should be assessed for their volume status and kidney function before starting Farxiga.”

Dapagliflozin previously received Fast Track, Breakthrough Therapy, and Priority Review designations for this new indication.

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

The Food and Drug Administration has approved dapagliflozin (Farxiga, AstraZeneca) to reduce the risk for kidney function decline, kidney failure, cardiovascular death, and hospitalization for heart failure in adult patients with chronic kidney disease (CKD) at risk for disease progression.

“Chronic kidney disease is an important public health issue, and there is a significant unmet need for therapies that slow disease progression and improve outcomes,” said Aliza Thompson, MD, deputy director of the division of cardiology and nephrology at the FDA’s Center for Drug Evaluation and Research. “Today’s approval of Farxiga for the treatment of chronic kidney disease is an important step forward in helping people living with kidney disease.”

Dapagliflozin was approved in 2014 to improve glycemic control in patients with diabetes mellitus, and approval was expanded in 2020 to include treatment of patients with heart failure and reduced ejection fraction, based on results of the DAPA-HF trial.

This new approval in chronic kidney disease was based on results of the DAPA-CKD trial that was stopped early in March 2020 because of efficacy of the treatment.

DAPA-CKD randomly assigned 4,304 patients with CKD but without diabetes to receive either dapagliflozin or placebo. The full study results, reported at the 2020 annual congress of the European Society of Cardiology and simultaneously published in the New England Journal of Medicine, showed that, during a median of 2.4 years, treatment with dapagliflozin led to a significant 31% relative reduction, compared with placebo in the study’s primary outcome, a composite that included at least a 50% drop in estimated glomerular filtration rate, compared with baseline, end-stage kidney disease, kidney transplant, renal death, or cardiovascular death.

Dapagliflozin treatment also cut all-cause mortality by a statistically significant relative reduction of 31%, and another secondary-endpoint analysis showed a statistically significant 29% relative reduction in the rate of cardiovascular death or heart failure hospitalization.

“Farxiga was not studied, nor is expected to be effective, in treating chronic kidney disease among patients with autosomal dominant or recessive polycystic (characterized by multiple cysts) kidney disease or among patients who require or have recently used immunosuppressive therapy to treat kidney disease,” the FDA statement noted.

Dapagliflozin should not be used by patients with a history of serious hypersensitivity reactions to this medication, or who are on dialysis, the agency added. “Serious, life-threatening cases of Fournier’s Gangrene have occurred in patients with diabetes taking Farxiga.”

Patients should consider taking a lower dose of insulin or insulin secretagogue to reduce hypoglycemic risk if they are also taking dapagliflozin. Treatment can also cause dehydration, serious urinary tract infections, genital yeast infections, and metabolic acidosis, the announcement said. “Patients should be assessed for their volume status and kidney function before starting Farxiga.”

Dapagliflozin previously received Fast Track, Breakthrough Therapy, and Priority Review designations for this new indication.

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

What started as an attempt to standardize care for acute myocardial infarction with cardiogenic shock at a handful of Detroit-area hospitals has led to markedly better survival rates than the traditional flip of a coin, in a nationwide analysis.

Final results from the National Cardiogenic Shock Initiative (NCSI) show 71% of patients survived to discharge and 68% were alive at 30 days.

Patients presenting in stage C or D shock, who comprised the bulk of patients in previous trials, had survival rates of 79% and 77%, respectively.

Among stage E patients, who are in extremis and have typical survival rates of less than 20%, survival was 54% at discharge and 49% at 30 days, co–principal investigator Babar Basir, DO, Henry Ford Hospital, Detroit, reported at the Society for Cardiovascular Angiography and Interventions (SCAI) annual scientific sessions, held virtually.

“This is the first push to really be able to consistently get survival rates over 50%, particularly in those patients who presented in stage C and D shock,” he said. “Really, it’s important to emphasize here the hard work it’s taken to get to this point and all the research that’s been done.”

The NCSI protocol emphasizes rapid identification and support of cardiogenic shock (door to support time <90 minutes), early placement of the Impella (Abiomed) ventricular assist device prior to percutaneous coronary intervention (PCI), and right heart monitoring to reduce the use of inotropes and vasopressors.

Co–principal investigator William O’Neill, MD, also from Henry Ford, previously reported results from the pilot study showing 84% of 30 patients survived to discharge.

The present analysis was based on outcomes of 406 consecutive acute MI patients (mean age, 63.7 years; 24% female) who presented with cardiogenic shock at 32 academic and 48 community hospitals in 29 states and the District of Columbia.

Dr. Basir emphasized that this is the largest prospective North American acute MI cardiogenic shock study in 20 years and recruited “one of the sickest cohorts ever studied.” The average blood pressure among the patients was 77/50 mm Hg; 77% had a lactate of at least 2 mmol/L (mean, 4.8 mmol/L), and 25% were in stage E shock.

One-quarter of patients were transferred from other institutions, 82% presented with ST-segment elevation MI, two-thirds had multivessel disease, and 13% had a left main culprit lesion.

Right heart catheterization was used in 90% of patients, an Impella CP device in 92%, an Impella 2.5 device in 5%, femoral access PCI in 78%, and aspiration thrombectomy in a full 27%.

Despite this sick cohort, survival at 30 days was better than in any previous study of cardiogenic shock, Dr. Basir said. In comparison, 30-day survival rates were 53%, 60%, and 49% in the SHOCK, IABP SHOCK, and CULPRIT SHOCK trials, respectively.

That said, survival over the course of the first year fell to 53% in the entire cohort, 62% in patients with stage C or D shock, and 31% in those in stage E shock.

“One-year mortality continues to be a problem for these patients and emphasizes the need for goal-directed medical therapy, early advanced heart failure follow-up, and novel therapies such as what we are planning with the evaluation of [supersaturated oxygen] SSO₂ to reduce infarct sizes in the ISO-SHOCK trial,” set to begin later this year, Dr. Basir said.

Given the promising results in the NCSI, the randomized controlled RECOVER IV trial is planned to begin in 2022, he noted. It will assess whether Impella pre-PCI is superior to PCI without Impella in patients with inclusion criteria similar to that of the NCSI. The DanGer Shock randomized trial is ongoing in Denmark and Germany and assessing all-cause mortality at 6 months with the Impella CP device compared with standard of care.

“We hypothesize that greater utilization of this protocol, and refinement of the escalation strategies will consistently lead to a survival rate greater than 80%,” Dr. Basir concluded.

Past SCAI president Kirk Garratt, MD, Christiana Care, Newark, Del., who moderated a press conference where the data were highlighted, noted that late complications led to a roughly 20% absolute mortality increase from discharge to 1 year, and questioned what percentage could be attributed to the mechanical support offered.

Dr. Basir said that information was not specifically tracked but that many patients presented with multiorgan failure and, irrespective of that, the majority died from ongoing heart failure.

During the formal presentation, panelist Ron Waksman, MD, MedStar Heart Institute, Washington, questioned whether results were different between academic and community centers, but also pointed to the lack of a comparator in the single-arm study.

“It’s very hard to do any comparison historically; we do need to have a control group,” he said. “If you would have opened it to any treatment at the time of the initiative, which is great, but not just limit it to use of the Impella devices, we would have better understanding if there is really a differentiation between one device versus the other devices.”

Dr. Basir replied, “I think that is a very reasonable comment and, in regard to your question, it is always difficult to differentiate between academic and community centers, but these were large community programs that have all of the technologies available in an academic center.”

NCIS is funded in part by unrestricted grants from Abiomed and Chiesi. Dr. Basir reported consulting for Abbott Vascular, Abiomed, Cardiovascular Systems, Chiesi, Procyrion, and Zoll.

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

What started as an attempt to standardize care for acute myocardial infarction with cardiogenic shock at a handful of Detroit-area hospitals has led to markedly better survival rates than the traditional flip of a coin, in a nationwide analysis.

Final results from the National Cardiogenic Shock Initiative (NCSI) show 71% of patients survived to discharge and 68% were alive at 30 days.

Patients presenting in stage C or D shock, who comprised the bulk of patients in previous trials, had survival rates of 79% and 77%, respectively.

Among stage E patients, who are in extremis and have typical survival rates of less than 20%, survival was 54% at discharge and 49% at 30 days, co–principal investigator Babar Basir, DO, Henry Ford Hospital, Detroit, reported at the Society for Cardiovascular Angiography and Interventions (SCAI) annual scientific sessions, held virtually.

“This is the first push to really be able to consistently get survival rates over 50%, particularly in those patients who presented in stage C and D shock,” he said. “Really, it’s important to emphasize here the hard work it’s taken to get to this point and all the research that’s been done.”

The NCSI protocol emphasizes rapid identification and support of cardiogenic shock (door to support time <90 minutes), early placement of the Impella (Abiomed) ventricular assist device prior to percutaneous coronary intervention (PCI), and right heart monitoring to reduce the use of inotropes and vasopressors.

Co–principal investigator William O’Neill, MD, also from Henry Ford, previously reported results from the pilot study showing 84% of 30 patients survived to discharge.

The present analysis was based on outcomes of 406 consecutive acute MI patients (mean age, 63.7 years; 24% female) who presented with cardiogenic shock at 32 academic and 48 community hospitals in 29 states and the District of Columbia.

Dr. Basir emphasized that this is the largest prospective North American acute MI cardiogenic shock study in 20 years and recruited “one of the sickest cohorts ever studied.” The average blood pressure among the patients was 77/50 mm Hg; 77% had a lactate of at least 2 mmol/L (mean, 4.8 mmol/L), and 25% were in stage E shock.

One-quarter of patients were transferred from other institutions, 82% presented with ST-segment elevation MI, two-thirds had multivessel disease, and 13% had a left main culprit lesion.

Right heart catheterization was used in 90% of patients, an Impella CP device in 92%, an Impella 2.5 device in 5%, femoral access PCI in 78%, and aspiration thrombectomy in a full 27%.

Despite this sick cohort, survival at 30 days was better than in any previous study of cardiogenic shock, Dr. Basir said. In comparison, 30-day survival rates were 53%, 60%, and 49% in the SHOCK, IABP SHOCK, and CULPRIT SHOCK trials, respectively.

That said, survival over the course of the first year fell to 53% in the entire cohort, 62% in patients with stage C or D shock, and 31% in those in stage E shock.

“One-year mortality continues to be a problem for these patients and emphasizes the need for goal-directed medical therapy, early advanced heart failure follow-up, and novel therapies such as what we are planning with the evaluation of [supersaturated oxygen] SSO₂ to reduce infarct sizes in the ISO-SHOCK trial,” set to begin later this year, Dr. Basir said.

Given the promising results in the NCSI, the randomized controlled RECOVER IV trial is planned to begin in 2022, he noted. It will assess whether Impella pre-PCI is superior to PCI without Impella in patients with inclusion criteria similar to that of the NCSI. The DanGer Shock randomized trial is ongoing in Denmark and Germany and assessing all-cause mortality at 6 months with the Impella CP device compared with standard of care.

“We hypothesize that greater utilization of this protocol, and refinement of the escalation strategies will consistently lead to a survival rate greater than 80%,” Dr. Basir concluded.

Past SCAI president Kirk Garratt, MD, Christiana Care, Newark, Del., who moderated a press conference where the data were highlighted, noted that late complications led to a roughly 20% absolute mortality increase from discharge to 1 year, and questioned what percentage could be attributed to the mechanical support offered.

Dr. Basir said that information was not specifically tracked but that many patients presented with multiorgan failure and, irrespective of that, the majority died from ongoing heart failure.

During the formal presentation, panelist Ron Waksman, MD, MedStar Heart Institute, Washington, questioned whether results were different between academic and community centers, but also pointed to the lack of a comparator in the single-arm study.

“It’s very hard to do any comparison historically; we do need to have a control group,” he said. “If you would have opened it to any treatment at the time of the initiative, which is great, but not just limit it to use of the Impella devices, we would have better understanding if there is really a differentiation between one device versus the other devices.”

Dr. Basir replied, “I think that is a very reasonable comment and, in regard to your question, it is always difficult to differentiate between academic and community centers, but these were large community programs that have all of the technologies available in an academic center.”

NCIS is funded in part by unrestricted grants from Abiomed and Chiesi. Dr. Basir reported consulting for Abbott Vascular, Abiomed, Cardiovascular Systems, Chiesi, Procyrion, and Zoll.

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

What started as an attempt to standardize care for acute myocardial infarction with cardiogenic shock at a handful of Detroit-area hospitals has led to markedly better survival rates than the traditional flip of a coin, in a nationwide analysis.

Final results from the National Cardiogenic Shock Initiative (NCSI) show 71% of patients survived to discharge and 68% were alive at 30 days.

Patients presenting in stage C or D shock, who comprised the bulk of patients in previous trials, had survival rates of 79% and 77%, respectively.

Among stage E patients, who are in extremis and have typical survival rates of less than 20%, survival was 54% at discharge and 49% at 30 days, co–principal investigator Babar Basir, DO, Henry Ford Hospital, Detroit, reported at the Society for Cardiovascular Angiography and Interventions (SCAI) annual scientific sessions, held virtually.

“This is the first push to really be able to consistently get survival rates over 50%, particularly in those patients who presented in stage C and D shock,” he said. “Really, it’s important to emphasize here the hard work it’s taken to get to this point and all the research that’s been done.”

The NCSI protocol emphasizes rapid identification and support of cardiogenic shock (door to support time <90 minutes), early placement of the Impella (Abiomed) ventricular assist device prior to percutaneous coronary intervention (PCI), and right heart monitoring to reduce the use of inotropes and vasopressors.

Co–principal investigator William O’Neill, MD, also from Henry Ford, previously reported results from the pilot study showing 84% of 30 patients survived to discharge.

The present analysis was based on outcomes of 406 consecutive acute MI patients (mean age, 63.7 years; 24% female) who presented with cardiogenic shock at 32 academic and 48 community hospitals in 29 states and the District of Columbia.

Dr. Basir emphasized that this is the largest prospective North American acute MI cardiogenic shock study in 20 years and recruited “one of the sickest cohorts ever studied.” The average blood pressure among the patients was 77/50 mm Hg; 77% had a lactate of at least 2 mmol/L (mean, 4.8 mmol/L), and 25% were in stage E shock.

One-quarter of patients were transferred from other institutions, 82% presented with ST-segment elevation MI, two-thirds had multivessel disease, and 13% had a left main culprit lesion.

Right heart catheterization was used in 90% of patients, an Impella CP device in 92%, an Impella 2.5 device in 5%, femoral access PCI in 78%, and aspiration thrombectomy in a full 27%.

Despite this sick cohort, survival at 30 days was better than in any previous study of cardiogenic shock, Dr. Basir said. In comparison, 30-day survival rates were 53%, 60%, and 49% in the SHOCK, IABP SHOCK, and CULPRIT SHOCK trials, respectively.

That said, survival over the course of the first year fell to 53% in the entire cohort, 62% in patients with stage C or D shock, and 31% in those in stage E shock.

“One-year mortality continues to be a problem for these patients and emphasizes the need for goal-directed medical therapy, early advanced heart failure follow-up, and novel therapies such as what we are planning with the evaluation of [supersaturated oxygen] SSO₂ to reduce infarct sizes in the ISO-SHOCK trial,” set to begin later this year, Dr. Basir said.

Given the promising results in the NCSI, the randomized controlled RECOVER IV trial is planned to begin in 2022, he noted. It will assess whether Impella pre-PCI is superior to PCI without Impella in patients with inclusion criteria similar to that of the NCSI. The DanGer Shock randomized trial is ongoing in Denmark and Germany and assessing all-cause mortality at 6 months with the Impella CP device compared with standard of care.

“We hypothesize that greater utilization of this protocol, and refinement of the escalation strategies will consistently lead to a survival rate greater than 80%,” Dr. Basir concluded.

Past SCAI president Kirk Garratt, MD, Christiana Care, Newark, Del., who moderated a press conference where the data were highlighted, noted that late complications led to a roughly 20% absolute mortality increase from discharge to 1 year, and questioned what percentage could be attributed to the mechanical support offered.

Dr. Basir said that information was not specifically tracked but that many patients presented with multiorgan failure and, irrespective of that, the majority died from ongoing heart failure.

During the formal presentation, panelist Ron Waksman, MD, MedStar Heart Institute, Washington, questioned whether results were different between academic and community centers, but also pointed to the lack of a comparator in the single-arm study.

“It’s very hard to do any comparison historically; we do need to have a control group,” he said. “If you would have opened it to any treatment at the time of the initiative, which is great, but not just limit it to use of the Impella devices, we would have better understanding if there is really a differentiation between one device versus the other devices.”

Dr. Basir replied, “I think that is a very reasonable comment and, in regard to your question, it is always difficult to differentiate between academic and community centers, but these were large community programs that have all of the technologies available in an academic center.”

NCIS is funded in part by unrestricted grants from Abiomed and Chiesi. Dr. Basir reported consulting for Abbott Vascular, Abiomed, Cardiovascular Systems, Chiesi, Procyrion, and Zoll.

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

Hormonal therapies for the treatment of hormone-dependent breast and prostate cancer could raise the risk for myocardial infarction and stroke, and patients need to be closely monitored to allow early detection and treatment of cardiovascular disease (CVD), the American Heart Association says in a new scientific statement.
 

“The statement provides data on the risks of each type of hormonal therapy so clinicians can use it as a guide to help manage cardiovascular risks during cancer treatment,” Tochi Okwuosa, DO, chair of the writing group, said in a news release.

“A team-based approach to patient care that includes the oncology team, cardiologist, primary care clinician, dietitian, endocrinologist, and other health care professionals as appropriate is needed to work with each patient to manage and reduce the increased risk of heart disease and strokes associated with hormonal therapy in breast and prostate cancer treatment,” said Dr. Okwuosa, director of cardio-oncology services, Rush University Medical Center, Chicago.

The scientific statement was published online April 26 in Circulation: Genomic and Precision Medicine.

Hormone-dependent cancers, such as prostate and breast cancer, are the most common noncutaneous cancers in the United States and around the world. As hormonal therapies have markedly improved survival in these patients, CVD has emerged as a leading cause illness and death.

The increased CVD burden might be explained by the increasing average age of cancer survivors, leading to higher rates of age-related CV risk factors and coronary artery disease.

The writing group reviewed existing evidence from observational studies and randomized controlled trials on the cardiovascular impact of anticancer hormonal therapies.



Among the key findings:

• In patients with breast cancer,  has been shown to increase the risk for venous thromboembolic events, but to have somewhat protective to neutral effects on CVD risk burden and CVD events. Conversely, aromatase inhibitors have been shown to increase the risk for CVD risk factors and events, including MI and stroke.
• Androgen-deprivation therapy for prostate cancer appears to increase the risk for CV events, although gonadotrophin-releasing hormone (GnRH) antagonists are associated with a lower risk for CV events than are GnRH agonists. The oral antiandrogens appear to be associated with increased CVD risk as well, particularly when used for complete androgen blockade as combination GnRH/anti-androgen therapy.
• The duration of hormonal therapies has a significant impact on CVD risk; the longer patients receive hormonal therapy, the greater the risk. More research is needed to better define the risks associated with duration of treatment.
• The data are mixed on the impact of preexisting CV risk factors and CVD on CV events associated with hormonal therapy. Although the presence of baseline CV risk factors and CVD can increase CV events associated with aromatase inhibitors, it is not clear that tamoxifen does.
• Studies suggest that patients with prostate cancer and baseline CVD and CV risk factors have increased rates of CV events when treated with androgen-deprivation therapy.
• Although the prolonged use of some hormonal therapies worsens CV risk factors and , the effects of the duration of therapy on CV events are less clear.

The writing group noted that there are no definitive guidelines for the monitoring and management of hormonal therapy-related CVD risks.

The authors encourage clinicians to be alert for worsening CV problems in those with preexisting heart disease or risk factors, and to recognize that even patients without preexisting CV problems are at higher risk because of their exposure to hormonal therapies.

“For patients who have two or more cardiovascular risk factors, it is likely that referral to a cardiologist would be appropriate prior to beginning hormone treatment. For patients already receiving hormonal therapies, a discussion with the oncology team can help to determine if a cardiology referral is recommended,” Dr. Okwuosa said in the news release.

This scientific statement was prepared by the volunteer writing group on behalf of the AHA Cardio-Oncology Subcommittee of the Council on Clinical Cardiology and the Council on Genomic and Precision Medicine; the Council on Arteriosclerosis, Thrombosis, and Vascular Biology; and the Council on Cardiovascular Radiology and Intervention.

The research had no commercial funding. Dr. Okwuosa has disclosed no relevant financial relationships.

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

Hormonal therapies for the treatment of hormone-dependent breast and prostate cancer could raise the risk for myocardial infarction and stroke, and patients need to be closely monitored to allow early detection and treatment of cardiovascular disease (CVD), the American Heart Association says in a new scientific statement.
 

“The statement provides data on the risks of each type of hormonal therapy so clinicians can use it as a guide to help manage cardiovascular risks during cancer treatment,” Tochi Okwuosa, DO, chair of the writing group, said in a news release.

“A team-based approach to patient care that includes the oncology team, cardiologist, primary care clinician, dietitian, endocrinologist, and other health care professionals as appropriate is needed to work with each patient to manage and reduce the increased risk of heart disease and strokes associated with hormonal therapy in breast and prostate cancer treatment,” said Dr. Okwuosa, director of cardio-oncology services, Rush University Medical Center, Chicago.

The scientific statement was published online April 26 in Circulation: Genomic and Precision Medicine.

Hormone-dependent cancers, such as prostate and breast cancer, are the most common noncutaneous cancers in the United States and around the world. As hormonal therapies have markedly improved survival in these patients, CVD has emerged as a leading cause illness and death.

The increased CVD burden might be explained by the increasing average age of cancer survivors, leading to higher rates of age-related CV risk factors and coronary artery disease.

The writing group reviewed existing evidence from observational studies and randomized controlled trials on the cardiovascular impact of anticancer hormonal therapies.



Among the key findings:

• In patients with breast cancer,  has been shown to increase the risk for venous thromboembolic events, but to have somewhat protective to neutral effects on CVD risk burden and CVD events. Conversely, aromatase inhibitors have been shown to increase the risk for CVD risk factors and events, including MI and stroke.
• Androgen-deprivation therapy for prostate cancer appears to increase the risk for CV events, although gonadotrophin-releasing hormone (GnRH) antagonists are associated with a lower risk for CV events than are GnRH agonists. The oral antiandrogens appear to be associated with increased CVD risk as well, particularly when used for complete androgen blockade as combination GnRH/anti-androgen therapy.
• The duration of hormonal therapies has a significant impact on CVD risk; the longer patients receive hormonal therapy, the greater the risk. More research is needed to better define the risks associated with duration of treatment.
• The data are mixed on the impact of preexisting CV risk factors and CVD on CV events associated with hormonal therapy. Although the presence of baseline CV risk factors and CVD can increase CV events associated with aromatase inhibitors, it is not clear that tamoxifen does.
• Studies suggest that patients with prostate cancer and baseline CVD and CV risk factors have increased rates of CV events when treated with androgen-deprivation therapy.
• Although the prolonged use of some hormonal therapies worsens CV risk factors and , the effects of the duration of therapy on CV events are less clear.

The writing group noted that there are no definitive guidelines for the monitoring and management of hormonal therapy-related CVD risks.

The authors encourage clinicians to be alert for worsening CV problems in those with preexisting heart disease or risk factors, and to recognize that even patients without preexisting CV problems are at higher risk because of their exposure to hormonal therapies.

“For patients who have two or more cardiovascular risk factors, it is likely that referral to a cardiologist would be appropriate prior to beginning hormone treatment. For patients already receiving hormonal therapies, a discussion with the oncology team can help to determine if a cardiology referral is recommended,” Dr. Okwuosa said in the news release.

This scientific statement was prepared by the volunteer writing group on behalf of the AHA Cardio-Oncology Subcommittee of the Council on Clinical Cardiology and the Council on Genomic and Precision Medicine; the Council on Arteriosclerosis, Thrombosis, and Vascular Biology; and the Council on Cardiovascular Radiology and Intervention.

The research had no commercial funding. Dr. Okwuosa has disclosed no relevant financial relationships.

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

Hormonal therapies for the treatment of hormone-dependent breast and prostate cancer could raise the risk for myocardial infarction and stroke, and patients need to be closely monitored to allow early detection and treatment of cardiovascular disease (CVD), the American Heart Association says in a new scientific statement.
 

“The statement provides data on the risks of each type of hormonal therapy so clinicians can use it as a guide to help manage cardiovascular risks during cancer treatment,” Tochi Okwuosa, DO, chair of the writing group, said in a news release.

“A team-based approach to patient care that includes the oncology team, cardiologist, primary care clinician, dietitian, endocrinologist, and other health care professionals as appropriate is needed to work with each patient to manage and reduce the increased risk of heart disease and strokes associated with hormonal therapy in breast and prostate cancer treatment,” said Dr. Okwuosa, director of cardio-oncology services, Rush University Medical Center, Chicago.

The scientific statement was published online April 26 in Circulation: Genomic and Precision Medicine.

Hormone-dependent cancers, such as prostate and breast cancer, are the most common noncutaneous cancers in the United States and around the world. As hormonal therapies have markedly improved survival in these patients, CVD has emerged as a leading cause illness and death.

The increased CVD burden might be explained by the increasing average age of cancer survivors, leading to higher rates of age-related CV risk factors and coronary artery disease.

The writing group reviewed existing evidence from observational studies and randomized controlled trials on the cardiovascular impact of anticancer hormonal therapies.



Among the key findings:

• In patients with breast cancer,  has been shown to increase the risk for venous thromboembolic events, but to have somewhat protective to neutral effects on CVD risk burden and CVD events. Conversely, aromatase inhibitors have been shown to increase the risk for CVD risk factors and events, including MI and stroke.
• Androgen-deprivation therapy for prostate cancer appears to increase the risk for CV events, although gonadotrophin-releasing hormone (GnRH) antagonists are associated with a lower risk for CV events than are GnRH agonists. The oral antiandrogens appear to be associated with increased CVD risk as well, particularly when used for complete androgen blockade as combination GnRH/anti-androgen therapy.
• The duration of hormonal therapies has a significant impact on CVD risk; the longer patients receive hormonal therapy, the greater the risk. More research is needed to better define the risks associated with duration of treatment.
• The data are mixed on the impact of preexisting CV risk factors and CVD on CV events associated with hormonal therapy. Although the presence of baseline CV risk factors and CVD can increase CV events associated with aromatase inhibitors, it is not clear that tamoxifen does.
• Studies suggest that patients with prostate cancer and baseline CVD and CV risk factors have increased rates of CV events when treated with androgen-deprivation therapy.
• Although the prolonged use of some hormonal therapies worsens CV risk factors and , the effects of the duration of therapy on CV events are less clear.

The writing group noted that there are no definitive guidelines for the monitoring and management of hormonal therapy-related CVD risks.

The authors encourage clinicians to be alert for worsening CV problems in those with preexisting heart disease or risk factors, and to recognize that even patients without preexisting CV problems are at higher risk because of their exposure to hormonal therapies.

“For patients who have two or more cardiovascular risk factors, it is likely that referral to a cardiologist would be appropriate prior to beginning hormone treatment. For patients already receiving hormonal therapies, a discussion with the oncology team can help to determine if a cardiology referral is recommended,” Dr. Okwuosa said in the news release.

This scientific statement was prepared by the volunteer writing group on behalf of the AHA Cardio-Oncology Subcommittee of the Council on Clinical Cardiology and the Council on Genomic and Precision Medicine; the Council on Arteriosclerosis, Thrombosis, and Vascular Biology; and the Council on Cardiovascular Radiology and Intervention.

The research had no commercial funding. Dr. Okwuosa has disclosed no relevant financial relationships.

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

Young athletes are unlikely to experience ongoing heart problems post–COVID-19 infection.

In a multicenter study conducted during September-December 2020, only 0.7% of 3,018 collegiate athletes who tested positive for SARS-CoV-2 infection were found to have definite, probable, or possible infection-related cardiac involvement.

None experienced an adverse cardiac event and only five (0.2%) required hospitalization for noncardiac complications of COVID-19.

“The take-home message is that cardiac involvement does not happen as much as we had initially feared. It’s in the range of 0.5% to 3%, depending on how you define cardiac involvement, which is not nothing, but it’s not the 30% or 50% that some early studies hinted at,” said Kimberly G. Harmon, MD, of the University of Washington, Seattle.

Nearly 20,000 athletes tested

The researchers prospectively tested 19,378 athletes for SARS-CoV-2 infection from 42 U.S. colleges and universities during the study period. A total of 3,018 (16%; mean age, 20 years; 32% female) tested positive and underwent cardiac evaluation.

“We didn’t prescribe what the schools had to do in terms of cardiac evaluation, but most of these colleges are well resourced, and about 74% of athletes were evaluated using the triad testing strategy of 12-lead electrocardiography, cardiac troponin, and transthoracic echocardiography [TEE], with cardiac magnetic resonance [CMR ]when indicated,” explained Dr. Harmon. Only 198 athletes underwent primary screening with CMR.

Athletes were often tested multiple times for SARS-CoV-2 infection by participating institutions and were included in this study if they had any positive test and underwent postinfection cardiac screening.

The cohort includes athletes representing 26 distinct sporting disciplines, including American-style football (36%), basketball (9%), and cross country/track and field (8%). Most were asymptomatic or had only mild COVID-19 symptoms (33% and 29%, respectively).
 

‘Exercise appears to be protective’

Abnormal findings suggestive of SARS-CoV-2 cardiac involvement were detected by ECG in 0.7% of athletes (21 of 2,999), cardiac troponin elevation in 0.9% (24/2,719), and abnormal TTE findings in 0.9% (24/2,556).

The odds of having cardiac involvement was 3.1 times higher in athletes with cardiopulmonary symptoms.

“One thing we’ve seen in the literature and in this cohort, is that exercise appears to be protective to some extent from COVID-19. We had a lot of cases, but in the whole cohort, only five athletes were hospitalized with COVID and those were for noncardiac reasons,” said Dr. Harmon.

During a median clinical surveillance of 113 days, there was one (0.03%) adverse cardiac event likely unrelated to SARS-CoV-2 infection.

The diagnostic yield for probable or definite cardiac involvement was 6.7 times higher for a CMR obtained for clinical reasons (10.1%) versus a primary screening CMR (1.5%).

“This is data we desperately needed. Small, single-center studies early in the pandemic had indicated a higher prevalence of cardiac involvement, which led us to be very conservative about return-to-play in the early days,” said Jeffrey Lander, MD, who was not involved in the study.

Limit CMR to symptomatic athletes

“I think this data can be extended beyond the college athlete. And it’s fair to say to high school athletes and young recreational athletes who have had asymptomatic or mild infection, you probably don’t need further workup if you’re feeling fine,” suggested Dr. Harmon.

“For those with moderate or severe illness, then the triple screen protocol is a good idea, particularly if they are having any symptoms,” she added.

Dr. Lander agrees that athletes should be screened by appropriate providers before returning to sports, but that CMR should not be used routinely for return-to-play screening.

“We’ve never taken a group of, say, 1,000 college athletes who just recovered from the flu and done cardiac MRIs on them, so it’s a bit like opening Pandora’s box when it’s used too liberally. It’s difficult to assess if the findings are secondary to COVID infection or from something entirely unrelated,” he noted.

ORCCA is a collaboration of the American Heart Association and the American Medical Society for Sports Medicine to track COVID-19 cases among National Collegiate Athletic Association (NCAA) athletes. The current study was supported by a grant from the American Medical Society for Sports Medicine.

Young athletes are unlikely to experience ongoing heart problems post–COVID-19 infection.

In a multicenter study conducted during September-December 2020, only 0.7% of 3,018 collegiate athletes who tested positive for SARS-CoV-2 infection were found to have definite, probable, or possible infection-related cardiac involvement.

None experienced an adverse cardiac event and only five (0.2%) required hospitalization for noncardiac complications of COVID-19.

“The take-home message is that cardiac involvement does not happen as much as we had initially feared. It’s in the range of 0.5% to 3%, depending on how you define cardiac involvement, which is not nothing, but it’s not the 30% or 50% that some early studies hinted at,” said Kimberly G. Harmon, MD, of the University of Washington, Seattle.

Nearly 20,000 athletes tested

The researchers prospectively tested 19,378 athletes for SARS-CoV-2 infection from 42 U.S. colleges and universities during the study period. A total of 3,018 (16%; mean age, 20 years; 32% female) tested positive and underwent cardiac evaluation.

“We didn’t prescribe what the schools had to do in terms of cardiac evaluation, but most of these colleges are well resourced, and about 74% of athletes were evaluated using the triad testing strategy of 12-lead electrocardiography, cardiac troponin, and transthoracic echocardiography [TEE], with cardiac magnetic resonance [CMR ]when indicated,” explained Dr. Harmon. Only 198 athletes underwent primary screening with CMR.

Athletes were often tested multiple times for SARS-CoV-2 infection by participating institutions and were included in this study if they had any positive test and underwent postinfection cardiac screening.

The cohort includes athletes representing 26 distinct sporting disciplines, including American-style football (36%), basketball (9%), and cross country/track and field (8%). Most were asymptomatic or had only mild COVID-19 symptoms (33% and 29%, respectively).
 

‘Exercise appears to be protective’

Abnormal findings suggestive of SARS-CoV-2 cardiac involvement were detected by ECG in 0.7% of athletes (21 of 2,999), cardiac troponin elevation in 0.9% (24/2,719), and abnormal TTE findings in 0.9% (24/2,556).

The odds of having cardiac involvement was 3.1 times higher in athletes with cardiopulmonary symptoms.

“One thing we’ve seen in the literature and in this cohort, is that exercise appears to be protective to some extent from COVID-19. We had a lot of cases, but in the whole cohort, only five athletes were hospitalized with COVID and those were for noncardiac reasons,” said Dr. Harmon.

During a median clinical surveillance of 113 days, there was one (0.03%) adverse cardiac event likely unrelated to SARS-CoV-2 infection.

The diagnostic yield for probable or definite cardiac involvement was 6.7 times higher for a CMR obtained for clinical reasons (10.1%) versus a primary screening CMR (1.5%).

“This is data we desperately needed. Small, single-center studies early in the pandemic had indicated a higher prevalence of cardiac involvement, which led us to be very conservative about return-to-play in the early days,” said Jeffrey Lander, MD, who was not involved in the study.

Limit CMR to symptomatic athletes

“I think this data can be extended beyond the college athlete. And it’s fair to say to high school athletes and young recreational athletes who have had asymptomatic or mild infection, you probably don’t need further workup if you’re feeling fine,” suggested Dr. Harmon.

“For those with moderate or severe illness, then the triple screen protocol is a good idea, particularly if they are having any symptoms,” she added.

Dr. Lander agrees that athletes should be screened by appropriate providers before returning to sports, but that CMR should not be used routinely for return-to-play screening.

“We’ve never taken a group of, say, 1,000 college athletes who just recovered from the flu and done cardiac MRIs on them, so it’s a bit like opening Pandora’s box when it’s used too liberally. It’s difficult to assess if the findings are secondary to COVID infection or from something entirely unrelated,” he noted.

ORCCA is a collaboration of the American Heart Association and the American Medical Society for Sports Medicine to track COVID-19 cases among National Collegiate Athletic Association (NCAA) athletes. The current study was supported by a grant from the American Medical Society for Sports Medicine.

Young athletes are unlikely to experience ongoing heart problems post–COVID-19 infection.

In a multicenter study conducted during September-December 2020, only 0.7% of 3,018 collegiate athletes who tested positive for SARS-CoV-2 infection were found to have definite, probable, or possible infection-related cardiac involvement.

None experienced an adverse cardiac event and only five (0.2%) required hospitalization for noncardiac complications of COVID-19.

“The take-home message is that cardiac involvement does not happen as much as we had initially feared. It’s in the range of 0.5% to 3%, depending on how you define cardiac involvement, which is not nothing, but it’s not the 30% or 50% that some early studies hinted at,” said Kimberly G. Harmon, MD, of the University of Washington, Seattle.

Nearly 20,000 athletes tested

The researchers prospectively tested 19,378 athletes for SARS-CoV-2 infection from 42 U.S. colleges and universities during the study period. A total of 3,018 (16%; mean age, 20 years; 32% female) tested positive and underwent cardiac evaluation.

“We didn’t prescribe what the schools had to do in terms of cardiac evaluation, but most of these colleges are well resourced, and about 74% of athletes were evaluated using the triad testing strategy of 12-lead electrocardiography, cardiac troponin, and transthoracic echocardiography [TEE], with cardiac magnetic resonance [CMR ]when indicated,” explained Dr. Harmon. Only 198 athletes underwent primary screening with CMR.

Athletes were often tested multiple times for SARS-CoV-2 infection by participating institutions and were included in this study if they had any positive test and underwent postinfection cardiac screening.

The cohort includes athletes representing 26 distinct sporting disciplines, including American-style football (36%), basketball (9%), and cross country/track and field (8%). Most were asymptomatic or had only mild COVID-19 symptoms (33% and 29%, respectively).
 

‘Exercise appears to be protective’

Abnormal findings suggestive of SARS-CoV-2 cardiac involvement were detected by ECG in 0.7% of athletes (21 of 2,999), cardiac troponin elevation in 0.9% (24/2,719), and abnormal TTE findings in 0.9% (24/2,556).

The odds of having cardiac involvement was 3.1 times higher in athletes with cardiopulmonary symptoms.

“One thing we’ve seen in the literature and in this cohort, is that exercise appears to be protective to some extent from COVID-19. We had a lot of cases, but in the whole cohort, only five athletes were hospitalized with COVID and those were for noncardiac reasons,” said Dr. Harmon.

During a median clinical surveillance of 113 days, there was one (0.03%) adverse cardiac event likely unrelated to SARS-CoV-2 infection.

The diagnostic yield for probable or definite cardiac involvement was 6.7 times higher for a CMR obtained for clinical reasons (10.1%) versus a primary screening CMR (1.5%).

“This is data we desperately needed. Small, single-center studies early in the pandemic had indicated a higher prevalence of cardiac involvement, which led us to be very conservative about return-to-play in the early days,” said Jeffrey Lander, MD, who was not involved in the study.

Limit CMR to symptomatic athletes

“I think this data can be extended beyond the college athlete. And it’s fair to say to high school athletes and young recreational athletes who have had asymptomatic or mild infection, you probably don’t need further workup if you’re feeling fine,” suggested Dr. Harmon.

“For those with moderate or severe illness, then the triple screen protocol is a good idea, particularly if they are having any symptoms,” she added.

Dr. Lander agrees that athletes should be screened by appropriate providers before returning to sports, but that CMR should not be used routinely for return-to-play screening.

“We’ve never taken a group of, say, 1,000 college athletes who just recovered from the flu and done cardiac MRIs on them, so it’s a bit like opening Pandora’s box when it’s used too liberally. It’s difficult to assess if the findings are secondary to COVID infection or from something entirely unrelated,” he noted.

ORCCA is a collaboration of the American Heart Association and the American Medical Society for Sports Medicine to track COVID-19 cases among National Collegiate Athletic Association (NCAA) athletes. The current study was supported by a grant from the American Medical Society for Sports Medicine.

An updated American Heart Association scientific statement on the role of obesity in cardiovascular disease provides the first new guidance in 15 years, drawing on evidence that’s emerged in that time to clarify the potential of newer drug therapies and interventions like bariatric surgery and lifestyle modifications to curtail cardiovascular disease risks.

“The timing of this information is important because the obesity epidemic contributes significantly to the global burden of cardiovascular disease and numerous chronic health conditions that also impact heart disease,” said Tiffany Powell-Wiley, MD, MPH, chair of the volunteer statement writing group.

“One of the big takeaways that I hope people get from the statement is really making it clear that obesity is a complex disease, and that it is multifactorial,” Dr. Powell-Wiley said in an interview. “There are not just biological reasons why individuals have obesity, but there are environmental, psychosocial, and really multilevel factors that contribute to the development and course of obesity.”

Most significantly, Dr. Powell-Wiley said, “we want to emphasize that we really want to have cardiologists think about and focus on abdominal obesity in particular.”

A metric for cardiovascular risk that seems to gain credibility in the statement is the relationship of waist circumference to height regardless of overall weight. “That is a very important finding that we can now really think of waist circumference as an important measure in our clinical practice,” said Dr. Powell-Wiley, chief of the Social Determinants of Obesity and Cardiovascular Risk Laboratory in the division of intramural research at the National Heart, Lung, and Blood Institute. “We want to get across to providers that this is something that should be measured and should be followed over time, based on data from the last 15 years that waist circumference and abdominal obesity are associated with higher cardiovascular risk regardless of body mass index.”

The statement provides potentially groundbreaking advice on atrial fibrillation as a consequence of weight, noted Dr. Powell-Wiley. “Up until recently, we haven’t really thought about weight management as a part of managing Afib [atrial fibrillation],” she said. “This statement highlights the need to think about weight management in addition to anticoagulation as part of the pieces for managing Afib.”
 

Evidence on interventions

The statement, published in Circulation, also dives into the evidence surrounding the varied interventions for managing weight.

American Heart Association

“The biggest area where there’s much more data is bariatric surgery,” said Dr. Powell-Wiley. “There’s clear evidence that bariatric surgery lowers cardio mortality and all-cause mortality for patients, but we’ve also seen data around lifestyle interventions, with the Look AHEAD trial, which showed that while there were improvements in CV [cardiovascular] risk factors, we didn’t see the reduction in CV mortality that we wanted to see.”

The statement noted that the Look AHEAD trial (for Action for Health in Diabetes) of people with type 2 diabetes failed to show a significant reduction in major adverse cardiac events or CV mortality after almost 10 years of an intensive weight-loss intervention. Dr. Powell-Wiley added that the result seemed to be related more to the lack of weight loss with lifestyle interventions when compared with bariatric surgery.

The statement also addressed the effectiveness of drug treatments for weight control in managing CV risk, and while the evidence supporting pharmacotherapy specifically for weight loss has been mixed, emerging treatments have shown promise, Dr. Powell-Wiley said. “I think we now have some bright spots with new therapies that have been developed for diabetes and heart failure, such as the SGLT2 inhibitors as well as the GLP-1 agonists, and how they can also appear to improve weight and likely will improve CV mortality in patients with obesity.”

The “obesity paradox,” which Dr. Powell-Wiley noted is “definitely a controversial topic,” is also addressed in the statement. “We try to explain what it is and what we know about it right now,” she said. “We know for instance that patients with obesity, particularly those who have class 1 obesity or patients who are overweight, seem to do better in the short term in relation to coronary artery disease and heart failure, but the reasons for that are not necessarily clear.”

The statement also provides evidence-based insights on the use of diagnostic tools, including stress echocardiography and cardiac MRI as well as coronary angiography, and the clinical significance of specific echocardiographic changes in obese patients.

The writing committee also identified areas that need future research. “It’s really important to emphasize what we learned about the complexity of obesity over this time period,” Dr. Powell-Wiley said. “But again, we don’t have all the answers; there’s a lot more work to be done to understand what type of lifestyle intervention might be most beneficial, especially with addressing abdominal obesity, and how these new therapeutics around heart failure and diabetes may be useful in patients with obesity.

Obesity in adolescents is another area that needs further research, Dr. Powell-Wiley said. “How do we prevent obesity in those populations when we know they’re at risk for so much as they get older? Once you have obesity it’s hard to change that trajectory.”

The scientific statement was prepared by the volunteer writing group on behalf of the AHA’s Council on Lifestyle and Cardiometabolic Health, the Council on Cardiovascular and Stroke Nursing, the Council on Clinical Cardiology, the Council on Epidemiology and Prevention, and the Stroke Council. Committee vice chair Paul Poirier, MD, PhD, reported financial relationships with Abbott, Amgen, AstraZeneca, Bausch Health, Bayer, Boehringer Ingelheim, Eli Lilly, Janssen, Novartis, Novo Nordisk, Sanofi, Servier, and HLS Therapeutics. One committee member disclosed a financial relationship with AstraZeneca. Dr. Powell-Wiley and the other committee members have no relationships to disclose.

An updated American Heart Association scientific statement on the role of obesity in cardiovascular disease provides the first new guidance in 15 years, drawing on evidence that’s emerged in that time to clarify the potential of newer drug therapies and interventions like bariatric surgery and lifestyle modifications to curtail cardiovascular disease risks.

“The timing of this information is important because the obesity epidemic contributes significantly to the global burden of cardiovascular disease and numerous chronic health conditions that also impact heart disease,” said Tiffany Powell-Wiley, MD, MPH, chair of the volunteer statement writing group.

“One of the big takeaways that I hope people get from the statement is really making it clear that obesity is a complex disease, and that it is multifactorial,” Dr. Powell-Wiley said in an interview. “There are not just biological reasons why individuals have obesity, but there are environmental, psychosocial, and really multilevel factors that contribute to the development and course of obesity.”

Most significantly, Dr. Powell-Wiley said, “we want to emphasize that we really want to have cardiologists think about and focus on abdominal obesity in particular.”

A metric for cardiovascular risk that seems to gain credibility in the statement is the relationship of waist circumference to height regardless of overall weight. “That is a very important finding that we can now really think of waist circumference as an important measure in our clinical practice,” said Dr. Powell-Wiley, chief of the Social Determinants of Obesity and Cardiovascular Risk Laboratory in the division of intramural research at the National Heart, Lung, and Blood Institute. “We want to get across to providers that this is something that should be measured and should be followed over time, based on data from the last 15 years that waist circumference and abdominal obesity are associated with higher cardiovascular risk regardless of body mass index.”

The statement provides potentially groundbreaking advice on atrial fibrillation as a consequence of weight, noted Dr. Powell-Wiley. “Up until recently, we haven’t really thought about weight management as a part of managing Afib [atrial fibrillation],” she said. “This statement highlights the need to think about weight management in addition to anticoagulation as part of the pieces for managing Afib.”
 

Evidence on interventions

The statement, published in Circulation, also dives into the evidence surrounding the varied interventions for managing weight.

American Heart Association

“The biggest area where there’s much more data is bariatric surgery,” said Dr. Powell-Wiley. “There’s clear evidence that bariatric surgery lowers cardio mortality and all-cause mortality for patients, but we’ve also seen data around lifestyle interventions, with the Look AHEAD trial, which showed that while there were improvements in CV [cardiovascular] risk factors, we didn’t see the reduction in CV mortality that we wanted to see.”

The statement noted that the Look AHEAD trial (for Action for Health in Diabetes) of people with type 2 diabetes failed to show a significant reduction in major adverse cardiac events or CV mortality after almost 10 years of an intensive weight-loss intervention. Dr. Powell-Wiley added that the result seemed to be related more to the lack of weight loss with lifestyle interventions when compared with bariatric surgery.

The statement also addressed the effectiveness of drug treatments for weight control in managing CV risk, and while the evidence supporting pharmacotherapy specifically for weight loss has been mixed, emerging treatments have shown promise, Dr. Powell-Wiley said. “I think we now have some bright spots with new therapies that have been developed for diabetes and heart failure, such as the SGLT2 inhibitors as well as the GLP-1 agonists, and how they can also appear to improve weight and likely will improve CV mortality in patients with obesity.”

The “obesity paradox,” which Dr. Powell-Wiley noted is “definitely a controversial topic,” is also addressed in the statement. “We try to explain what it is and what we know about it right now,” she said. “We know for instance that patients with obesity, particularly those who have class 1 obesity or patients who are overweight, seem to do better in the short term in relation to coronary artery disease and heart failure, but the reasons for that are not necessarily clear.”

The statement also provides evidence-based insights on the use of diagnostic tools, including stress echocardiography and cardiac MRI as well as coronary angiography, and the clinical significance of specific echocardiographic changes in obese patients.

The writing committee also identified areas that need future research. “It’s really important to emphasize what we learned about the complexity of obesity over this time period,” Dr. Powell-Wiley said. “But again, we don’t have all the answers; there’s a lot more work to be done to understand what type of lifestyle intervention might be most beneficial, especially with addressing abdominal obesity, and how these new therapeutics around heart failure and diabetes may be useful in patients with obesity.

Obesity in adolescents is another area that needs further research, Dr. Powell-Wiley said. “How do we prevent obesity in those populations when we know they’re at risk for so much as they get older? Once you have obesity it’s hard to change that trajectory.”

The scientific statement was prepared by the volunteer writing group on behalf of the AHA’s Council on Lifestyle and Cardiometabolic Health, the Council on Cardiovascular and Stroke Nursing, the Council on Clinical Cardiology, the Council on Epidemiology and Prevention, and the Stroke Council. Committee vice chair Paul Poirier, MD, PhD, reported financial relationships with Abbott, Amgen, AstraZeneca, Bausch Health, Bayer, Boehringer Ingelheim, Eli Lilly, Janssen, Novartis, Novo Nordisk, Sanofi, Servier, and HLS Therapeutics. One committee member disclosed a financial relationship with AstraZeneca. Dr. Powell-Wiley and the other committee members have no relationships to disclose.

An updated American Heart Association scientific statement on the role of obesity in cardiovascular disease provides the first new guidance in 15 years, drawing on evidence that’s emerged in that time to clarify the potential of newer drug therapies and interventions like bariatric surgery and lifestyle modifications to curtail cardiovascular disease risks.

“The timing of this information is important because the obesity epidemic contributes significantly to the global burden of cardiovascular disease and numerous chronic health conditions that also impact heart disease,” said Tiffany Powell-Wiley, MD, MPH, chair of the volunteer statement writing group.

“One of the big takeaways that I hope people get from the statement is really making it clear that obesity is a complex disease, and that it is multifactorial,” Dr. Powell-Wiley said in an interview. “There are not just biological reasons why individuals have obesity, but there are environmental, psychosocial, and really multilevel factors that contribute to the development and course of obesity.”

Most significantly, Dr. Powell-Wiley said, “we want to emphasize that we really want to have cardiologists think about and focus on abdominal obesity in particular.”

A metric for cardiovascular risk that seems to gain credibility in the statement is the relationship of waist circumference to height regardless of overall weight. “That is a very important finding that we can now really think of waist circumference as an important measure in our clinical practice,” said Dr. Powell-Wiley, chief of the Social Determinants of Obesity and Cardiovascular Risk Laboratory in the division of intramural research at the National Heart, Lung, and Blood Institute. “We want to get across to providers that this is something that should be measured and should be followed over time, based on data from the last 15 years that waist circumference and abdominal obesity are associated with higher cardiovascular risk regardless of body mass index.”

The statement provides potentially groundbreaking advice on atrial fibrillation as a consequence of weight, noted Dr. Powell-Wiley. “Up until recently, we haven’t really thought about weight management as a part of managing Afib [atrial fibrillation],” she said. “This statement highlights the need to think about weight management in addition to anticoagulation as part of the pieces for managing Afib.”
 

Evidence on interventions

The statement, published in Circulation, also dives into the evidence surrounding the varied interventions for managing weight.

American Heart Association

“The biggest area where there’s much more data is bariatric surgery,” said Dr. Powell-Wiley. “There’s clear evidence that bariatric surgery lowers cardio mortality and all-cause mortality for patients, but we’ve also seen data around lifestyle interventions, with the Look AHEAD trial, which showed that while there were improvements in CV [cardiovascular] risk factors, we didn’t see the reduction in CV mortality that we wanted to see.”

The statement noted that the Look AHEAD trial (for Action for Health in Diabetes) of people with type 2 diabetes failed to show a significant reduction in major adverse cardiac events or CV mortality after almost 10 years of an intensive weight-loss intervention. Dr. Powell-Wiley added that the result seemed to be related more to the lack of weight loss with lifestyle interventions when compared with bariatric surgery.

The statement also addressed the effectiveness of drug treatments for weight control in managing CV risk, and while the evidence supporting pharmacotherapy specifically for weight loss has been mixed, emerging treatments have shown promise, Dr. Powell-Wiley said. “I think we now have some bright spots with new therapies that have been developed for diabetes and heart failure, such as the SGLT2 inhibitors as well as the GLP-1 agonists, and how they can also appear to improve weight and likely will improve CV mortality in patients with obesity.”

The “obesity paradox,” which Dr. Powell-Wiley noted is “definitely a controversial topic,” is also addressed in the statement. “We try to explain what it is and what we know about it right now,” she said. “We know for instance that patients with obesity, particularly those who have class 1 obesity or patients who are overweight, seem to do better in the short term in relation to coronary artery disease and heart failure, but the reasons for that are not necessarily clear.”

The statement also provides evidence-based insights on the use of diagnostic tools, including stress echocardiography and cardiac MRI as well as coronary angiography, and the clinical significance of specific echocardiographic changes in obese patients.

The writing committee also identified areas that need future research. “It’s really important to emphasize what we learned about the complexity of obesity over this time period,” Dr. Powell-Wiley said. “But again, we don’t have all the answers; there’s a lot more work to be done to understand what type of lifestyle intervention might be most beneficial, especially with addressing abdominal obesity, and how these new therapeutics around heart failure and diabetes may be useful in patients with obesity.

Obesity in adolescents is another area that needs further research, Dr. Powell-Wiley said. “How do we prevent obesity in those populations when we know they’re at risk for so much as they get older? Once you have obesity it’s hard to change that trajectory.”

The scientific statement was prepared by the volunteer writing group on behalf of the AHA’s Council on Lifestyle and Cardiometabolic Health, the Council on Cardiovascular and Stroke Nursing, the Council on Clinical Cardiology, the Council on Epidemiology and Prevention, and the Stroke Council. Committee vice chair Paul Poirier, MD, PhD, reported financial relationships with Abbott, Amgen, AstraZeneca, Bausch Health, Bayer, Boehringer Ingelheim, Eli Lilly, Janssen, Novartis, Novo Nordisk, Sanofi, Servier, and HLS Therapeutics. One committee member disclosed a financial relationship with AstraZeneca. Dr. Powell-Wiley and the other committee members have no relationships to disclose.

In a U.K. cohort of more than 260,000 mostly middle-aged adults in primary care with overweight or obesity, body mass index remained relatively stable over a decade.

However, compared to overweight individuals, those with severe (class 3) obesity were more socioeconomically disadvantaged and had triple the risk for incident heart failure or all-cause or cardiovascular disease (CVD)–related mortality in a study published online April 15 in BMC Public Health.

“This is the first study to evaluate the long-term impact of overweight and obese individuals’ BMI trajectory on cardiovascular endpoints, heart failure, and mortality outcomes,” wrote Barbara Iyen, PhD, University of Nottingham, England, and colleagues.

The findings emphasize “the high cardiovascular toll exacted by continuing failure to tackle obesity, particularly among more socioeconomically deprived populations,” they warned.

“We have found that despite widespread efforts to prevent and manage obesity, the majority of adults who are overweight or obese in the general population continue to remain so in the long term,” Dr. Iyen said in a statement from her university.

“More effective policies and weight-management interventions are needed urgently to address this increasing burden and associated adverse health outcomes,” she stressed.

Invited to comment, Sadiya S. Khan, MD, Northwestern University, Chicago, said in an interview: “This research adds to the growing body of evidence [that] earlier and more intensive interventions for weight loss are necessary to promote cardiovascular health and reduce morbidity and mortality.

“Adjunctive pharmacotherapy and bariatric surgery are both options that should be considered in addition to intensive lifestyle interventions in overweight and obesity groups,” she added.

“I would always advocate for earlier prevention efforts focused on weight loss, because years lived with obesity are associated with future CVD, so every year counts,” Dr. Khan said.
 

Does BMI remain elevated, predict worse heart health?

Although obesity is a well-recognized risk factor for CVD, long-term changes in BMI and the impact of BMI on the risk for heart failure, CVD, and mortality have not been quantified among adults with overweight and obesity, Dr. Iyen and colleagues explained.

The researchers examined data from the UK Clinical Practice Research Datalink and secondary care and mortality records to determine BMI trajectories among adults with overweight or obesity and to quantify the risk for heart failure, CVD (defined as coronary heart disease, stroke, transient ischemic attack, or peripheral vascular disease, CVD-related mortality, and all-cause mortality.

They identified 264,230 adults with overweight or obesity who were seen in 790 primary care practices in the United Kingdom from 1999 to 2018 and who did not initially have heart failure or CVD and for whom baseline BMI measurements and at least one other BMI measurement 2, 5, 8, and 10 years later was available.

The researchers divided the cohort into four groups on the basis of initial BMI: overweight (36% of patients; mean BMI, 28.7 kg/m²); class 1 obesity (40%; mean BMI, 33.7 kg/m²); class 2 obesity (19%; mean BMI, 39.9 kg/m²), and class 3 obesity (5%; mean BMI, 49.1 kg/m²).

The mean age of the individuals was 50 years, and 64% were White. Race/ethnicity data were unavailable for 31%. Asian Indian, Asian, and Black patients comprised 5% of the cohort.
 

“Strong significant gradient in heart failure risk”

Compared to the overweight (reference) group, the severe-obesity group comprised a higher percentage of women (74% vs. 70%), and the prevalence of comorbidities and socioeconomic deprivation was higher.

BMI remained relatively stable in each BMI group. The mean BMI increase was 1.06 kg/m² during a median follow-up of 10.9 years.

There were 30,400 incident cases of CVD, 7,662 incident cases of heart failure, and 24,022 deaths, of which 2,827 (11.8%) were from CVD.

The risk for heart failure and CVD-related or all-cause mortality increased with increasing obesity severity.

Compared with overweight individuals, those with class 3 obesity were at significantly increased risk for heart failure (hazard ratio [HR], 3.26), all-cause mortality (HR, 2.72), and CVD-related mortality (HR, 3.31) after adjustment for age, sex, and comorbidities (hypertension, type 2 diabetes, atrial fibrillation, and chronic kidney disease).

The risk for stroke/TIA or coronary heart disease was similar among those with severe obesity and the other individuals. The risk for PVD was significantly lower (HR, 0.73).

The reduced risk for PVD in the most severely obese group is similar to findings in the Framingham heart study, the authors noted, and may be due to underdiagnosis or differences in the underlying mechanism.
 

Compelling evidence of poor health outcomes associated with obesity

Study limitations include the fact that the findings may not be generalizable to other race/ethnicity groups, the lack of information on diet and exercise, and the fact that BMI was used as a surrogate of adiposity. As such, it does not account for an age-related decrease in heavier-than-fat muscle mass and differences between sexes and ethnic groups.

The finding of stable obesity over time accords with two smaller studies that included Canadian and American adults.

The current study did not uncover an obesity paradox, unlike some studies that included patients with preexisting CVD or a history of acute coronary events. Those studies reported better clinical outcomes among patients with overweight or obesity.

The current study included individuals who did not initially have CVD. Those with more severe obesity were younger than individuals with overweight at the time of the occurrence of incident CVD (age 64 vs. 66) and at the age of death (age 67 vs. age 75), which “provides compelling evidence of poor health outcomes associated with obesity,” the authors emphasized.

“Further research is ... needed to explore whether interventions to change BMI trajectories would have an impact on future CVD outcomes,” they concluded.

Dr. Iyen’s clinical academic lectureship is fully funded by the National Institute for Health Research (NIHR). The views expressed are those of the authors and are not necessarily those of the National Health Service, the NIHR, or the Department of Health and Social Care. Dr. Khan has disclosed no relevant financial relationships.

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

In a U.K. cohort of more than 260,000 mostly middle-aged adults in primary care with overweight or obesity, body mass index remained relatively stable over a decade.

However, compared to overweight individuals, those with severe (class 3) obesity were more socioeconomically disadvantaged and had triple the risk for incident heart failure or all-cause or cardiovascular disease (CVD)–related mortality in a study published online April 15 in BMC Public Health.

“This is the first study to evaluate the long-term impact of overweight and obese individuals’ BMI trajectory on cardiovascular endpoints, heart failure, and mortality outcomes,” wrote Barbara Iyen, PhD, University of Nottingham, England, and colleagues.

The findings emphasize “the high cardiovascular toll exacted by continuing failure to tackle obesity, particularly among more socioeconomically deprived populations,” they warned.

“We have found that despite widespread efforts to prevent and manage obesity, the majority of adults who are overweight or obese in the general population continue to remain so in the long term,” Dr. Iyen said in a statement from her university.

“More effective policies and weight-management interventions are needed urgently to address this increasing burden and associated adverse health outcomes,” she stressed.

Invited to comment, Sadiya S. Khan, MD, Northwestern University, Chicago, said in an interview: “This research adds to the growing body of evidence [that] earlier and more intensive interventions for weight loss are necessary to promote cardiovascular health and reduce morbidity and mortality.

“Adjunctive pharmacotherapy and bariatric surgery are both options that should be considered in addition to intensive lifestyle interventions in overweight and obesity groups,” she added.

“I would always advocate for earlier prevention efforts focused on weight loss, because years lived with obesity are associated with future CVD, so every year counts,” Dr. Khan said.
 

Does BMI remain elevated, predict worse heart health?

Although obesity is a well-recognized risk factor for CVD, long-term changes in BMI and the impact of BMI on the risk for heart failure, CVD, and mortality have not been quantified among adults with overweight and obesity, Dr. Iyen and colleagues explained.

The researchers examined data from the UK Clinical Practice Research Datalink and secondary care and mortality records to determine BMI trajectories among adults with overweight or obesity and to quantify the risk for heart failure, CVD (defined as coronary heart disease, stroke, transient ischemic attack, or peripheral vascular disease, CVD-related mortality, and all-cause mortality.

They identified 264,230 adults with overweight or obesity who were seen in 790 primary care practices in the United Kingdom from 1999 to 2018 and who did not initially have heart failure or CVD and for whom baseline BMI measurements and at least one other BMI measurement 2, 5, 8, and 10 years later was available.

The researchers divided the cohort into four groups on the basis of initial BMI: overweight (36% of patients; mean BMI, 28.7 kg/m²); class 1 obesity (40%; mean BMI, 33.7 kg/m²); class 2 obesity (19%; mean BMI, 39.9 kg/m²), and class 3 obesity (5%; mean BMI, 49.1 kg/m²).

The mean age of the individuals was 50 years, and 64% were White. Race/ethnicity data were unavailable for 31%. Asian Indian, Asian, and Black patients comprised 5% of the cohort.
 

“Strong significant gradient in heart failure risk”

Compared to the overweight (reference) group, the severe-obesity group comprised a higher percentage of women (74% vs. 70%), and the prevalence of comorbidities and socioeconomic deprivation was higher.

BMI remained relatively stable in each BMI group. The mean BMI increase was 1.06 kg/m² during a median follow-up of 10.9 years.

There were 30,400 incident cases of CVD, 7,662 incident cases of heart failure, and 24,022 deaths, of which 2,827 (11.8%) were from CVD.

The risk for heart failure and CVD-related or all-cause mortality increased with increasing obesity severity.

Compared with overweight individuals, those with class 3 obesity were at significantly increased risk for heart failure (hazard ratio [HR], 3.26), all-cause mortality (HR, 2.72), and CVD-related mortality (HR, 3.31) after adjustment for age, sex, and comorbidities (hypertension, type 2 diabetes, atrial fibrillation, and chronic kidney disease).

The risk for stroke/TIA or coronary heart disease was similar among those with severe obesity and the other individuals. The risk for PVD was significantly lower (HR, 0.73).

The reduced risk for PVD in the most severely obese group is similar to findings in the Framingham heart study, the authors noted, and may be due to underdiagnosis or differences in the underlying mechanism.
 

Compelling evidence of poor health outcomes associated with obesity

Study limitations include the fact that the findings may not be generalizable to other race/ethnicity groups, the lack of information on diet and exercise, and the fact that BMI was used as a surrogate of adiposity. As such, it does not account for an age-related decrease in heavier-than-fat muscle mass and differences between sexes and ethnic groups.

The finding of stable obesity over time accords with two smaller studies that included Canadian and American adults.

The current study did not uncover an obesity paradox, unlike some studies that included patients with preexisting CVD or a history of acute coronary events. Those studies reported better clinical outcomes among patients with overweight or obesity.

The current study included individuals who did not initially have CVD. Those with more severe obesity were younger than individuals with overweight at the time of the occurrence of incident CVD (age 64 vs. 66) and at the age of death (age 67 vs. age 75), which “provides compelling evidence of poor health outcomes associated with obesity,” the authors emphasized.

“Further research is ... needed to explore whether interventions to change BMI trajectories would have an impact on future CVD outcomes,” they concluded.

Dr. Iyen’s clinical academic lectureship is fully funded by the National Institute for Health Research (NIHR). The views expressed are those of the authors and are not necessarily those of the National Health Service, the NIHR, or the Department of Health and Social Care. Dr. Khan has disclosed no relevant financial relationships.

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

In a U.K. cohort of more than 260,000 mostly middle-aged adults in primary care with overweight or obesity, body mass index remained relatively stable over a decade.

However, compared to overweight individuals, those with severe (class 3) obesity were more socioeconomically disadvantaged and had triple the risk for incident heart failure or all-cause or cardiovascular disease (CVD)–related mortality in a study published online April 15 in BMC Public Health.

“This is the first study to evaluate the long-term impact of overweight and obese individuals’ BMI trajectory on cardiovascular endpoints, heart failure, and mortality outcomes,” wrote Barbara Iyen, PhD, University of Nottingham, England, and colleagues.

The findings emphasize “the high cardiovascular toll exacted by continuing failure to tackle obesity, particularly among more socioeconomically deprived populations,” they warned.

“We have found that despite widespread efforts to prevent and manage obesity, the majority of adults who are overweight or obese in the general population continue to remain so in the long term,” Dr. Iyen said in a statement from her university.

“More effective policies and weight-management interventions are needed urgently to address this increasing burden and associated adverse health outcomes,” she stressed.

Invited to comment, Sadiya S. Khan, MD, Northwestern University, Chicago, said in an interview: “This research adds to the growing body of evidence [that] earlier and more intensive interventions for weight loss are necessary to promote cardiovascular health and reduce morbidity and mortality.

“Adjunctive pharmacotherapy and bariatric surgery are both options that should be considered in addition to intensive lifestyle interventions in overweight and obesity groups,” she added.

“I would always advocate for earlier prevention efforts focused on weight loss, because years lived with obesity are associated with future CVD, so every year counts,” Dr. Khan said.
 

Does BMI remain elevated, predict worse heart health?

Although obesity is a well-recognized risk factor for CVD, long-term changes in BMI and the impact of BMI on the risk for heart failure, CVD, and mortality have not been quantified among adults with overweight and obesity, Dr. Iyen and colleagues explained.

The researchers examined data from the UK Clinical Practice Research Datalink and secondary care and mortality records to determine BMI trajectories among adults with overweight or obesity and to quantify the risk for heart failure, CVD (defined as coronary heart disease, stroke, transient ischemic attack, or peripheral vascular disease, CVD-related mortality, and all-cause mortality.

They identified 264,230 adults with overweight or obesity who were seen in 790 primary care practices in the United Kingdom from 1999 to 2018 and who did not initially have heart failure or CVD and for whom baseline BMI measurements and at least one other BMI measurement 2, 5, 8, and 10 years later was available.

The researchers divided the cohort into four groups on the basis of initial BMI: overweight (36% of patients; mean BMI, 28.7 kg/m²); class 1 obesity (40%; mean BMI, 33.7 kg/m²); class 2 obesity (19%; mean BMI, 39.9 kg/m²), and class 3 obesity (5%; mean BMI, 49.1 kg/m²).

The mean age of the individuals was 50 years, and 64% were White. Race/ethnicity data were unavailable for 31%. Asian Indian, Asian, and Black patients comprised 5% of the cohort.
 

“Strong significant gradient in heart failure risk”

Compared to the overweight (reference) group, the severe-obesity group comprised a higher percentage of women (74% vs. 70%), and the prevalence of comorbidities and socioeconomic deprivation was higher.

BMI remained relatively stable in each BMI group. The mean BMI increase was 1.06 kg/m² during a median follow-up of 10.9 years.

There were 30,400 incident cases of CVD, 7,662 incident cases of heart failure, and 24,022 deaths, of which 2,827 (11.8%) were from CVD.

The risk for heart failure and CVD-related or all-cause mortality increased with increasing obesity severity.

Compared with overweight individuals, those with class 3 obesity were at significantly increased risk for heart failure (hazard ratio [HR], 3.26), all-cause mortality (HR, 2.72), and CVD-related mortality (HR, 3.31) after adjustment for age, sex, and comorbidities (hypertension, type 2 diabetes, atrial fibrillation, and chronic kidney disease).

The risk for stroke/TIA or coronary heart disease was similar among those with severe obesity and the other individuals. The risk for PVD was significantly lower (HR, 0.73).

The reduced risk for PVD in the most severely obese group is similar to findings in the Framingham heart study, the authors noted, and may be due to underdiagnosis or differences in the underlying mechanism.
 

Compelling evidence of poor health outcomes associated with obesity

Study limitations include the fact that the findings may not be generalizable to other race/ethnicity groups, the lack of information on diet and exercise, and the fact that BMI was used as a surrogate of adiposity. As such, it does not account for an age-related decrease in heavier-than-fat muscle mass and differences between sexes and ethnic groups.

The finding of stable obesity over time accords with two smaller studies that included Canadian and American adults.

The current study did not uncover an obesity paradox, unlike some studies that included patients with preexisting CVD or a history of acute coronary events. Those studies reported better clinical outcomes among patients with overweight or obesity.

The current study included individuals who did not initially have CVD. Those with more severe obesity were younger than individuals with overweight at the time of the occurrence of incident CVD (age 64 vs. 66) and at the age of death (age 67 vs. age 75), which “provides compelling evidence of poor health outcomes associated with obesity,” the authors emphasized.

“Further research is ... needed to explore whether interventions to change BMI trajectories would have an impact on future CVD outcomes,” they concluded.

Dr. Iyen’s clinical academic lectureship is fully funded by the National Institute for Health Research (NIHR). The views expressed are those of the authors and are not necessarily those of the National Health Service, the NIHR, or the Department of Health and Social Care. Dr. Khan has disclosed no relevant financial relationships.

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