My Bing AI engine, when prompted, tells me that there are about 87 journals, 45 conferences, and 53 workshops presently dedicated exclusively to hypertension. All of that attention, and yet ...

What is going on?

The top killers of Americans remain coronary artery heart disease (26%), cancer (22%), and stroke (6%). The precursors and attributable risk factors for coronary artery heart disease include hypertension (40%), obesity (20%), diabetes (15%), and combustible tobacco use (15%). The key precursors and attributable risk factors for stroke are hypertension (53%), obesity (37%), diabetes (9%), and combustible tobacco use (11%). Obviously, these are estimates, with substantial overlap.

It’s pretty obvious that if the population and the health care systems of the United States were seriously interested in saving lives, they would strive diligently to control blood pressure, prevent obesity and diabetes, and eliminate combustible tobacco use.

We have addressed improving tobacco control and preventing obesity and diabetes on these pages many times, and lamented the medical, public health, and societal failings. Today we turn our attention to the control of hypertension. That is much easier and far less expensive.

All physicians and medical organizations know that hypertension is a major attributable cause of many serious, expensive, and fatal illnesses. As many as 119 million (48%) of American adults have hypertension. The American Heart Association (AHA), American Medical Association (AMA), American College of Cardiology (ACC), and hundreds of other organizations have set a new target of 130/80 (revised from 140/90) for blood pressure control and have launched a major initiative, Target: BP, to reach it.

That is just great. We all wish this massive effort to succeed where few others have. But do AHA, AMA, ACC, and others understand why most efforts to this point have failed? The blame is typically aimed at patients failing to adhere to their instructions. Maybe, but why? And how does Target: BP intend to convert chronic failure into success if it just continues to do everything they have been trying to do that doesn’t work?

At this point, the Centers for Disease Control and Prevention reports that fewer than 48% of American patients with hypertension meet even the less stringent historical 140/90 goal.

A group practice in Ohio, PriMed Physicians, has consistently exceeded 90% or even 95% blood pressure control for its patients with hypertension for more than 10 years. Exemplary. How do they do it? This video of the 13th annual Lundberg Institute lecture describes this unique and successful program.

PriMed’s clinicians use the MedsEngine AI tool from MediSync and the NICaS (noninvasive cardiac system with impedance cardiography) to determine each patient’s unique blood pressure pathophysiology. Clinicians and patients understand that the simplest explanation of this pathophysiology encompasses three factors: (1) the volume of “water” (blood) in the system; (2) the strength of the pumping (pulsatile) process; and (3) the tightness (resistance) of the tubes that carry the blood. Patients “get it” when it is explained this way, and they cooperate.

At the first patient encounter, the Food and Drug Administration–approved PhysioFlow is employed to assess those three vital hemodynamic factors. The individual patient’s data are loaded into a tightly programed EHR-based algorithm with 37 clinical factors and five classes of drugs, providing multiple ways to influence the three key pathophysiologic processes. In this way, they arrive at the precise drug(s) and dosages for that patient. During the second visit, most patients are already showing improvement. By the third visit, the blood pressures of most patients have reached target control. After that, it is maintenance and tweaking.

These factors summarize why it works:

• Senior management belief, commitment, and leadership
• Informed buy-in from clinicians and patients
• A test that determines root causes of too much fluid, too strong pump action, or too tight pipes, and their proportionality
• An AI tool that matches those three pathophysiologic factors and 35 other clinical factors with the best drug or drugs (of many, not just a few) and dosages
• Persistent clinician-patient follow-up
• Refusal to accept failure

Since this approach is so successful, why is its use not everywhere?

It is not as if nobody noticed, even if you and many organizations have not. The American Medical Group Association recognized the program’s success by giving its top award to PriMed in 2015.

Klepper and Rodis wrote about this approach for managing multiple chronic conditions in 2021. Here’s a background article and an explainer, Clinical use of impedance cardiography for hemodynamic assessment of early cardiovascular disease and management of hypertension.

I found one pragmatic controlled clinical trial of impedance cardiography with a decision-support system from Beijing that did demonstrate clinical and statistical significance.

Frankly, we do need more rigorous, unbiased, large, controlled clinical trials assessing the MedsEngine and NICaS approach to managing blood pressure to facilitate a massive switch from the old and established (but failing) approach to a starkly better way.

Almost no one ever “completes a database.” All decision makers must act based upon the best data to which they have access. Data are often incomplete. The difference between success and mediocrity is often the ability of an individual or system to decide when enough information is enough and act accordingly.

Cost-effectiveness studies in three countries (United Kingdom, United States, and China) confirm sharply lower lifelong costs when blood pressure is well controlled. Of course.

For the American medical-industrial complex, lowered costs for managing common serious diseases may be an undesired rather than a good thing. In money-driven medicine, lower costs to the payer and purchaser translate to less revenue for the providers. Imagine all of those invasive and noninvasive diagnostic and therapeutic procedures forgone by prevention of hypertension. Is it possible that such an underlying truth is the real reason why American medicine is habitually unsuccessful at controlling blood pressure?

Right now, if my blood pressure were not well controlled (it is), I would find my way to Cincinnati, to give PriMed physicians, MediSync, and MedsEngine a crack at prolonging my useful life.

Dr. Lundberg is editor in chief of Cancer Commons. He disclosed no relevant conflicts of interest.

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

My Bing AI engine, when prompted, tells me that there are about 87 journals, 45 conferences, and 53 workshops presently dedicated exclusively to hypertension. All of that attention, and yet ...

What is going on?

The top killers of Americans remain coronary artery heart disease (26%), cancer (22%), and stroke (6%). The precursors and attributable risk factors for coronary artery heart disease include hypertension (40%), obesity (20%), diabetes (15%), and combustible tobacco use (15%). The key precursors and attributable risk factors for stroke are hypertension (53%), obesity (37%), diabetes (9%), and combustible tobacco use (11%). Obviously, these are estimates, with substantial overlap.

It’s pretty obvious that if the population and the health care systems of the United States were seriously interested in saving lives, they would strive diligently to control blood pressure, prevent obesity and diabetes, and eliminate combustible tobacco use.

We have addressed improving tobacco control and preventing obesity and diabetes on these pages many times, and lamented the medical, public health, and societal failings. Today we turn our attention to the control of hypertension. That is much easier and far less expensive.

All physicians and medical organizations know that hypertension is a major attributable cause of many serious, expensive, and fatal illnesses. As many as 119 million (48%) of American adults have hypertension. The American Heart Association (AHA), American Medical Association (AMA), American College of Cardiology (ACC), and hundreds of other organizations have set a new target of 130/80 (revised from 140/90) for blood pressure control and have launched a major initiative, Target: BP, to reach it.

That is just great. We all wish this massive effort to succeed where few others have. But do AHA, AMA, ACC, and others understand why most efforts to this point have failed? The blame is typically aimed at patients failing to adhere to their instructions. Maybe, but why? And how does Target: BP intend to convert chronic failure into success if it just continues to do everything they have been trying to do that doesn’t work?

At this point, the Centers for Disease Control and Prevention reports that fewer than 48% of American patients with hypertension meet even the less stringent historical 140/90 goal.

A group practice in Ohio, PriMed Physicians, has consistently exceeded 90% or even 95% blood pressure control for its patients with hypertension for more than 10 years. Exemplary. How do they do it? This video of the 13th annual Lundberg Institute lecture describes this unique and successful program.

PriMed’s clinicians use the MedsEngine AI tool from MediSync and the NICaS (noninvasive cardiac system with impedance cardiography) to determine each patient’s unique blood pressure pathophysiology. Clinicians and patients understand that the simplest explanation of this pathophysiology encompasses three factors: (1) the volume of “water” (blood) in the system; (2) the strength of the pumping (pulsatile) process; and (3) the tightness (resistance) of the tubes that carry the blood. Patients “get it” when it is explained this way, and they cooperate.

At the first patient encounter, the Food and Drug Administration–approved PhysioFlow is employed to assess those three vital hemodynamic factors. The individual patient’s data are loaded into a tightly programed EHR-based algorithm with 37 clinical factors and five classes of drugs, providing multiple ways to influence the three key pathophysiologic processes. In this way, they arrive at the precise drug(s) and dosages for that patient. During the second visit, most patients are already showing improvement. By the third visit, the blood pressures of most patients have reached target control. After that, it is maintenance and tweaking.

These factors summarize why it works:

• Senior management belief, commitment, and leadership
• Informed buy-in from clinicians and patients
• A test that determines root causes of too much fluid, too strong pump action, or too tight pipes, and their proportionality
• An AI tool that matches those three pathophysiologic factors and 35 other clinical factors with the best drug or drugs (of many, not just a few) and dosages
• Persistent clinician-patient follow-up
• Refusal to accept failure

Since this approach is so successful, why is its use not everywhere?

It is not as if nobody noticed, even if you and many organizations have not. The American Medical Group Association recognized the program’s success by giving its top award to PriMed in 2015.

Klepper and Rodis wrote about this approach for managing multiple chronic conditions in 2021. Here’s a background article and an explainer, Clinical use of impedance cardiography for hemodynamic assessment of early cardiovascular disease and management of hypertension.

I found one pragmatic controlled clinical trial of impedance cardiography with a decision-support system from Beijing that did demonstrate clinical and statistical significance.

Frankly, we do need more rigorous, unbiased, large, controlled clinical trials assessing the MedsEngine and NICaS approach to managing blood pressure to facilitate a massive switch from the old and established (but failing) approach to a starkly better way.

Almost no one ever “completes a database.” All decision makers must act based upon the best data to which they have access. Data are often incomplete. The difference between success and mediocrity is often the ability of an individual or system to decide when enough information is enough and act accordingly.

Cost-effectiveness studies in three countries (United Kingdom, United States, and China) confirm sharply lower lifelong costs when blood pressure is well controlled. Of course.

For the American medical-industrial complex, lowered costs for managing common serious diseases may be an undesired rather than a good thing. In money-driven medicine, lower costs to the payer and purchaser translate to less revenue for the providers. Imagine all of those invasive and noninvasive diagnostic and therapeutic procedures forgone by prevention of hypertension. Is it possible that such an underlying truth is the real reason why American medicine is habitually unsuccessful at controlling blood pressure?

Right now, if my blood pressure were not well controlled (it is), I would find my way to Cincinnati, to give PriMed physicians, MediSync, and MedsEngine a crack at prolonging my useful life.

Dr. Lundberg is editor in chief of Cancer Commons. He disclosed no relevant conflicts of interest.

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

My Bing AI engine, when prompted, tells me that there are about 87 journals, 45 conferences, and 53 workshops presently dedicated exclusively to hypertension. All of that attention, and yet ...

What is going on?

The top killers of Americans remain coronary artery heart disease (26%), cancer (22%), and stroke (6%). The precursors and attributable risk factors for coronary artery heart disease include hypertension (40%), obesity (20%), diabetes (15%), and combustible tobacco use (15%). The key precursors and attributable risk factors for stroke are hypertension (53%), obesity (37%), diabetes (9%), and combustible tobacco use (11%). Obviously, these are estimates, with substantial overlap.

It’s pretty obvious that if the population and the health care systems of the United States were seriously interested in saving lives, they would strive diligently to control blood pressure, prevent obesity and diabetes, and eliminate combustible tobacco use.

We have addressed improving tobacco control and preventing obesity and diabetes on these pages many times, and lamented the medical, public health, and societal failings. Today we turn our attention to the control of hypertension. That is much easier and far less expensive.

All physicians and medical organizations know that hypertension is a major attributable cause of many serious, expensive, and fatal illnesses. As many as 119 million (48%) of American adults have hypertension. The American Heart Association (AHA), American Medical Association (AMA), American College of Cardiology (ACC), and hundreds of other organizations have set a new target of 130/80 (revised from 140/90) for blood pressure control and have launched a major initiative, Target: BP, to reach it.

That is just great. We all wish this massive effort to succeed where few others have. But do AHA, AMA, ACC, and others understand why most efforts to this point have failed? The blame is typically aimed at patients failing to adhere to their instructions. Maybe, but why? And how does Target: BP intend to convert chronic failure into success if it just continues to do everything they have been trying to do that doesn’t work?

At this point, the Centers for Disease Control and Prevention reports that fewer than 48% of American patients with hypertension meet even the less stringent historical 140/90 goal.

A group practice in Ohio, PriMed Physicians, has consistently exceeded 90% or even 95% blood pressure control for its patients with hypertension for more than 10 years. Exemplary. How do they do it? This video of the 13th annual Lundberg Institute lecture describes this unique and successful program.

PriMed’s clinicians use the MedsEngine AI tool from MediSync and the NICaS (noninvasive cardiac system with impedance cardiography) to determine each patient’s unique blood pressure pathophysiology. Clinicians and patients understand that the simplest explanation of this pathophysiology encompasses three factors: (1) the volume of “water” (blood) in the system; (2) the strength of the pumping (pulsatile) process; and (3) the tightness (resistance) of the tubes that carry the blood. Patients “get it” when it is explained this way, and they cooperate.

At the first patient encounter, the Food and Drug Administration–approved PhysioFlow is employed to assess those three vital hemodynamic factors. The individual patient’s data are loaded into a tightly programed EHR-based algorithm with 37 clinical factors and five classes of drugs, providing multiple ways to influence the three key pathophysiologic processes. In this way, they arrive at the precise drug(s) and dosages for that patient. During the second visit, most patients are already showing improvement. By the third visit, the blood pressures of most patients have reached target control. After that, it is maintenance and tweaking.

These factors summarize why it works:

• Senior management belief, commitment, and leadership
• Informed buy-in from clinicians and patients
• A test that determines root causes of too much fluid, too strong pump action, or too tight pipes, and their proportionality
• An AI tool that matches those three pathophysiologic factors and 35 other clinical factors with the best drug or drugs (of many, not just a few) and dosages
• Persistent clinician-patient follow-up
• Refusal to accept failure

Since this approach is so successful, why is its use not everywhere?

It is not as if nobody noticed, even if you and many organizations have not. The American Medical Group Association recognized the program’s success by giving its top award to PriMed in 2015.

Klepper and Rodis wrote about this approach for managing multiple chronic conditions in 2021. Here’s a background article and an explainer, Clinical use of impedance cardiography for hemodynamic assessment of early cardiovascular disease and management of hypertension.

I found one pragmatic controlled clinical trial of impedance cardiography with a decision-support system from Beijing that did demonstrate clinical and statistical significance.

Frankly, we do need more rigorous, unbiased, large, controlled clinical trials assessing the MedsEngine and NICaS approach to managing blood pressure to facilitate a massive switch from the old and established (but failing) approach to a starkly better way.

Almost no one ever “completes a database.” All decision makers must act based upon the best data to which they have access. Data are often incomplete. The difference between success and mediocrity is often the ability of an individual or system to decide when enough information is enough and act accordingly.

Cost-effectiveness studies in three countries (United Kingdom, United States, and China) confirm sharply lower lifelong costs when blood pressure is well controlled. Of course.

For the American medical-industrial complex, lowered costs for managing common serious diseases may be an undesired rather than a good thing. In money-driven medicine, lower costs to the payer and purchaser translate to less revenue for the providers. Imagine all of those invasive and noninvasive diagnostic and therapeutic procedures forgone by prevention of hypertension. Is it possible that such an underlying truth is the real reason why American medicine is habitually unsuccessful at controlling blood pressure?

Right now, if my blood pressure were not well controlled (it is), I would find my way to Cincinnati, to give PriMed physicians, MediSync, and MedsEngine a crack at prolonging my useful life.

Dr. Lundberg is editor in chief of Cancer Commons. He disclosed no relevant conflicts of interest.

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

Adam Boggon, MBChB, was working at the Royal Free Hospital in North London during the city’s second wave of COVID-19. “I was effectively living in the hospital,” he recalled. “It felt like I was going 10,000 miles per hour, trying to corral hundreds of medical students and doctors.”

During a national lockdown, there were few places Dr. Boggon could escape to, but the Hampstead Heath swimming ponds mostly remained open. He swam there regularly to exercise and recharge even in winter.

“Swimming in cold water takes you out of yourself,” Dr. Boggon said. “It was such a release for someone who grew up in a rural place and had access to green space, even though the water is murky.” It also hovers around 50 °F (10 °C).

Jumping into cold water, well, kind of stinks. So why do it? It’s not only for bragging rights. A growing number of studies suggest significant mental and physical health benefits to swimming in cold water, specifically to improve depression symptoms and even ease inflammatory conditions.

And a lot of that research is driven by medical pros who love to do it themselves.

For Dr. Boggon, swimming in frigid water is uncomfortable, but he feels that a sensation of calmness follows that makes the plunge more than worth it. Now a Fulbright Scholar at Harvard, where he studies public health and health management, Dr. Boggon is able to frequent the fabled Walden Pond just outside of Boston.

As Thoreau himself said, “You can never have enough of nature.”

Yes, even if it’s really, really cold.
 

Taking a deeper dive

Heather Massey, PhD, a senior lecturer in Sport, Health, and Exercise Science at University of Portsmouth, blames her father, a dinghy sailor, for her affinity for cold-water swimming.

And she’s done more than most, including an epic 16-hour crossing of the English Channel. The water temperature was in the upper-50s °F, and she swam without a wetsuit. “Time just seemed to collapse,” she has shared about the experience.

While working on her PhD and studying the effects of environmental physiology, in particular what happens to the body when it gets hot or cold, Dr. Massey’s hobby and studies seemed to coalesce.

Her research initially focused on the hazards around being in cold open water. But she also noticed a growing trend of people claiming health benefits from the practice. “People started to talk about experiencing improved symptoms of depression or improved mental health from their activities in the water,” she said.

She partnered with another outdoor swimming enthusiast, Hannah Denton, a counseling psychologist working for the National Health Service in the United Kingdom. Ms. Denton was publishing papers on the potential impact that outdoor swimming may have on people with depression and how it could improve mental health in general. She also regularly engages in cold-water swims to boost feelings of mindfulness and peace.

“Having the experience of being so close to nature, as well as the strong sensory experience of being in cold water, does really encourage you to be in the moment,” Ms. Denton wrote in an article for the Sussex Mindfulness Centre. “My experiences of sea swimming and mindfulness support each other. Both have made me feel more comfortable with my body, to have more of a present moment focus, to pay attention to my breathing, and to gain distance from difficult thoughts.”

Over the past few years, Dr. Massey and Ms. Denton have moved from fairly small-scale studies with no real controls to today, completing a randomized controlled trial and looking at the impact that outdoor swimming may have on people living with mild to moderate depression.

“At first, people sort of thought our idea was a bit wacky,” said Dr. Massey. “Now, the popularity of open-water swimming has really blossomed, and so has this area of research. We’re starting to build more rigor into the work.”

Like all the researchers and physicians interviewed for this article, Dr. Massey hesitates to claim that cold-water swimming is a “cure” that should be medicalized.

“It’s not about prescribing it or forcing people to do it,” said Dr. Massey. “This is not something that a doctor should write on a prescription and say you should go and have eight 1-hour sessions of swimming.”
 

(Not yet) a common cure

Enter into the conversation Mark Harper, MD, PhD, consultant anesthetist at Sussex University Hospitals in the United Kingdom and Kristiansand, Norway. Dr. Harper is the author of the 2022 book, Chill: The Cold Water Swim Cure – A Transformative Guide to Renew Your Body and Mind.

Dr. Harper grew up swimming in pools, and it wasn’t until his pool closed for 2 weeks that he ventured into the sea. He recalled walking up the beach afterward, thinking, God, this feels good, and from that moment on, he became hooked on outdoor swimming and curious about its therapeutic potential.

The “cure” in the book’s title, Dr. Harper explained, is being used in the historical sense of “treatment,” as in the first medical book about sea-bathing written over 250 years ago. Dr. Harper acknowledged that the connection to health is still speculative. “However, the circumstantial evidence, the feedback from participants and early study data for its benefits are now very strong,” he said.

In a small study published in 2022, Dr. Harper and colleagues took 59 people with anxiety and depression and put them through a sea-swimming course. Afterward, 80% showed a clinically significant improvement in their mental health.

More recently, Dr. Harper and his team of researchers released a survey to determine how many people were using cold-water swimming as a treatment for a mental or physical ailment. “We thought 30 or 40 people would respond, but we ended up with over 700,” he said. “The majority were using it for mental health but also included inflammation-related conditions.”

Over 2 decades, Dr. Harper has seen dramatic success stories. In his book, he recalled a good friend who, in his early 20s, suffered from Crohn’s disease so badly he couldn’t walk up the steps to his parents’ house. The friend turned to outdoor cold swimming as a low-impact workout and began noticing the symptoms of his disease were improving. Within months, he was able to go off his medications. In 2022, he completed 52 triathlons: one per week for the entire year.
 

How cold exposure may play with your brain

Vaibhav Diwadkar, PhD, professor of psychiatry and behavioral neurosciences at Wayne State University, in Detroit, is studying how human brain networks respond to cold exposure. Dr. Diwadkar and his colleague, Otto Muzik, PhD, began by putting volunteers in a rubber suit with thin tubing and infusing the tubing with temperature-controlled water. Meanwhile, they collected functional brain imaging data to analyze which parts of the brain were responding as body temperature changed.

The data showed that the cold exposure made certain areas of the brain very active, including some that have been associated with the regulation of mood.

Dr. Diwadkar posits that controlled exposure to cold serves as a low-level stressor that knocks different systems within the brain and body out of homeostasis. Once the stress is removed, the brain responds by releasing neurotransmitters that enhance mood, frequently leading to feelings of euphoria in participants.

“We don’t have direct evidence of such a mechanism, but it’s a reasonable speculation,” said Dr. Diwadkar.

However, he pointed out that science writers in the media often portray topics such as this one in black and white, which is “oversimplifying the scientific complexity of biology.”

Clearly, more research needs to be done on the potential therapeutic benefits of cold-water swimming. But for those suffering from anxiety, depression, or chronic illness, if taking a cold dip makes you feel better, the why and how might be beside the point.

Plus, as Dr. Harper pointed out, it’s an easy and accessible therapy.

“All you need is some water – enough to submerge your entire body in – that’s less than 68 °F (20 °C),” he said. “If you stay long enough to get over that initial shock, which is just 2 or 3 minutes, then you’ve got the effect. If you get out and want to go back in again, then you’ve done it right.”
 

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

Adam Boggon, MBChB, was working at the Royal Free Hospital in North London during the city’s second wave of COVID-19. “I was effectively living in the hospital,” he recalled. “It felt like I was going 10,000 miles per hour, trying to corral hundreds of medical students and doctors.”

During a national lockdown, there were few places Dr. Boggon could escape to, but the Hampstead Heath swimming ponds mostly remained open. He swam there regularly to exercise and recharge even in winter.

“Swimming in cold water takes you out of yourself,” Dr. Boggon said. “It was such a release for someone who grew up in a rural place and had access to green space, even though the water is murky.” It also hovers around 50 °F (10 °C).

Jumping into cold water, well, kind of stinks. So why do it? It’s not only for bragging rights. A growing number of studies suggest significant mental and physical health benefits to swimming in cold water, specifically to improve depression symptoms and even ease inflammatory conditions.

And a lot of that research is driven by medical pros who love to do it themselves.

For Dr. Boggon, swimming in frigid water is uncomfortable, but he feels that a sensation of calmness follows that makes the plunge more than worth it. Now a Fulbright Scholar at Harvard, where he studies public health and health management, Dr. Boggon is able to frequent the fabled Walden Pond just outside of Boston.

As Thoreau himself said, “You can never have enough of nature.”

Yes, even if it’s really, really cold.
 

Taking a deeper dive

Heather Massey, PhD, a senior lecturer in Sport, Health, and Exercise Science at University of Portsmouth, blames her father, a dinghy sailor, for her affinity for cold-water swimming.

And she’s done more than most, including an epic 16-hour crossing of the English Channel. The water temperature was in the upper-50s °F, and she swam without a wetsuit. “Time just seemed to collapse,” she has shared about the experience.

While working on her PhD and studying the effects of environmental physiology, in particular what happens to the body when it gets hot or cold, Dr. Massey’s hobby and studies seemed to coalesce.

Her research initially focused on the hazards around being in cold open water. But she also noticed a growing trend of people claiming health benefits from the practice. “People started to talk about experiencing improved symptoms of depression or improved mental health from their activities in the water,” she said.

She partnered with another outdoor swimming enthusiast, Hannah Denton, a counseling psychologist working for the National Health Service in the United Kingdom. Ms. Denton was publishing papers on the potential impact that outdoor swimming may have on people with depression and how it could improve mental health in general. She also regularly engages in cold-water swims to boost feelings of mindfulness and peace.

“Having the experience of being so close to nature, as well as the strong sensory experience of being in cold water, does really encourage you to be in the moment,” Ms. Denton wrote in an article for the Sussex Mindfulness Centre. “My experiences of sea swimming and mindfulness support each other. Both have made me feel more comfortable with my body, to have more of a present moment focus, to pay attention to my breathing, and to gain distance from difficult thoughts.”

Over the past few years, Dr. Massey and Ms. Denton have moved from fairly small-scale studies with no real controls to today, completing a randomized controlled trial and looking at the impact that outdoor swimming may have on people living with mild to moderate depression.

“At first, people sort of thought our idea was a bit wacky,” said Dr. Massey. “Now, the popularity of open-water swimming has really blossomed, and so has this area of research. We’re starting to build more rigor into the work.”

Like all the researchers and physicians interviewed for this article, Dr. Massey hesitates to claim that cold-water swimming is a “cure” that should be medicalized.

“It’s not about prescribing it or forcing people to do it,” said Dr. Massey. “This is not something that a doctor should write on a prescription and say you should go and have eight 1-hour sessions of swimming.”
 

(Not yet) a common cure

Enter into the conversation Mark Harper, MD, PhD, consultant anesthetist at Sussex University Hospitals in the United Kingdom and Kristiansand, Norway. Dr. Harper is the author of the 2022 book, Chill: The Cold Water Swim Cure – A Transformative Guide to Renew Your Body and Mind.

Dr. Harper grew up swimming in pools, and it wasn’t until his pool closed for 2 weeks that he ventured into the sea. He recalled walking up the beach afterward, thinking, God, this feels good, and from that moment on, he became hooked on outdoor swimming and curious about its therapeutic potential.

The “cure” in the book’s title, Dr. Harper explained, is being used in the historical sense of “treatment,” as in the first medical book about sea-bathing written over 250 years ago. Dr. Harper acknowledged that the connection to health is still speculative. “However, the circumstantial evidence, the feedback from participants and early study data for its benefits are now very strong,” he said.

In a small study published in 2022, Dr. Harper and colleagues took 59 people with anxiety and depression and put them through a sea-swimming course. Afterward, 80% showed a clinically significant improvement in their mental health.

More recently, Dr. Harper and his team of researchers released a survey to determine how many people were using cold-water swimming as a treatment for a mental or physical ailment. “We thought 30 or 40 people would respond, but we ended up with over 700,” he said. “The majority were using it for mental health but also included inflammation-related conditions.”

Over 2 decades, Dr. Harper has seen dramatic success stories. In his book, he recalled a good friend who, in his early 20s, suffered from Crohn’s disease so badly he couldn’t walk up the steps to his parents’ house. The friend turned to outdoor cold swimming as a low-impact workout and began noticing the symptoms of his disease were improving. Within months, he was able to go off his medications. In 2022, he completed 52 triathlons: one per week for the entire year.
 

How cold exposure may play with your brain

Vaibhav Diwadkar, PhD, professor of psychiatry and behavioral neurosciences at Wayne State University, in Detroit, is studying how human brain networks respond to cold exposure. Dr. Diwadkar and his colleague, Otto Muzik, PhD, began by putting volunteers in a rubber suit with thin tubing and infusing the tubing with temperature-controlled water. Meanwhile, they collected functional brain imaging data to analyze which parts of the brain were responding as body temperature changed.

The data showed that the cold exposure made certain areas of the brain very active, including some that have been associated with the regulation of mood.

Dr. Diwadkar posits that controlled exposure to cold serves as a low-level stressor that knocks different systems within the brain and body out of homeostasis. Once the stress is removed, the brain responds by releasing neurotransmitters that enhance mood, frequently leading to feelings of euphoria in participants.

“We don’t have direct evidence of such a mechanism, but it’s a reasonable speculation,” said Dr. Diwadkar.

However, he pointed out that science writers in the media often portray topics such as this one in black and white, which is “oversimplifying the scientific complexity of biology.”

Clearly, more research needs to be done on the potential therapeutic benefits of cold-water swimming. But for those suffering from anxiety, depression, or chronic illness, if taking a cold dip makes you feel better, the why and how might be beside the point.

Plus, as Dr. Harper pointed out, it’s an easy and accessible therapy.

“All you need is some water – enough to submerge your entire body in – that’s less than 68 °F (20 °C),” he said. “If you stay long enough to get over that initial shock, which is just 2 or 3 minutes, then you’ve got the effect. If you get out and want to go back in again, then you’ve done it right.”
 

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

Adam Boggon, MBChB, was working at the Royal Free Hospital in North London during the city’s second wave of COVID-19. “I was effectively living in the hospital,” he recalled. “It felt like I was going 10,000 miles per hour, trying to corral hundreds of medical students and doctors.”

During a national lockdown, there were few places Dr. Boggon could escape to, but the Hampstead Heath swimming ponds mostly remained open. He swam there regularly to exercise and recharge even in winter.

“Swimming in cold water takes you out of yourself,” Dr. Boggon said. “It was such a release for someone who grew up in a rural place and had access to green space, even though the water is murky.” It also hovers around 50 °F (10 °C).

Jumping into cold water, well, kind of stinks. So why do it? It’s not only for bragging rights. A growing number of studies suggest significant mental and physical health benefits to swimming in cold water, specifically to improve depression symptoms and even ease inflammatory conditions.

And a lot of that research is driven by medical pros who love to do it themselves.

For Dr. Boggon, swimming in frigid water is uncomfortable, but he feels that a sensation of calmness follows that makes the plunge more than worth it. Now a Fulbright Scholar at Harvard, where he studies public health and health management, Dr. Boggon is able to frequent the fabled Walden Pond just outside of Boston.

As Thoreau himself said, “You can never have enough of nature.”

Yes, even if it’s really, really cold.
 

Taking a deeper dive

Heather Massey, PhD, a senior lecturer in Sport, Health, and Exercise Science at University of Portsmouth, blames her father, a dinghy sailor, for her affinity for cold-water swimming.

And she’s done more than most, including an epic 16-hour crossing of the English Channel. The water temperature was in the upper-50s °F, and she swam without a wetsuit. “Time just seemed to collapse,” she has shared about the experience.

While working on her PhD and studying the effects of environmental physiology, in particular what happens to the body when it gets hot or cold, Dr. Massey’s hobby and studies seemed to coalesce.

Her research initially focused on the hazards around being in cold open water. But she also noticed a growing trend of people claiming health benefits from the practice. “People started to talk about experiencing improved symptoms of depression or improved mental health from their activities in the water,” she said.

She partnered with another outdoor swimming enthusiast, Hannah Denton, a counseling psychologist working for the National Health Service in the United Kingdom. Ms. Denton was publishing papers on the potential impact that outdoor swimming may have on people with depression and how it could improve mental health in general. She also regularly engages in cold-water swims to boost feelings of mindfulness and peace.

“Having the experience of being so close to nature, as well as the strong sensory experience of being in cold water, does really encourage you to be in the moment,” Ms. Denton wrote in an article for the Sussex Mindfulness Centre. “My experiences of sea swimming and mindfulness support each other. Both have made me feel more comfortable with my body, to have more of a present moment focus, to pay attention to my breathing, and to gain distance from difficult thoughts.”

Over the past few years, Dr. Massey and Ms. Denton have moved from fairly small-scale studies with no real controls to today, completing a randomized controlled trial and looking at the impact that outdoor swimming may have on people living with mild to moderate depression.

“At first, people sort of thought our idea was a bit wacky,” said Dr. Massey. “Now, the popularity of open-water swimming has really blossomed, and so has this area of research. We’re starting to build more rigor into the work.”

Like all the researchers and physicians interviewed for this article, Dr. Massey hesitates to claim that cold-water swimming is a “cure” that should be medicalized.

“It’s not about prescribing it or forcing people to do it,” said Dr. Massey. “This is not something that a doctor should write on a prescription and say you should go and have eight 1-hour sessions of swimming.”
 

(Not yet) a common cure

Enter into the conversation Mark Harper, MD, PhD, consultant anesthetist at Sussex University Hospitals in the United Kingdom and Kristiansand, Norway. Dr. Harper is the author of the 2022 book, Chill: The Cold Water Swim Cure – A Transformative Guide to Renew Your Body and Mind.

Dr. Harper grew up swimming in pools, and it wasn’t until his pool closed for 2 weeks that he ventured into the sea. He recalled walking up the beach afterward, thinking, God, this feels good, and from that moment on, he became hooked on outdoor swimming and curious about its therapeutic potential.

The “cure” in the book’s title, Dr. Harper explained, is being used in the historical sense of “treatment,” as in the first medical book about sea-bathing written over 250 years ago. Dr. Harper acknowledged that the connection to health is still speculative. “However, the circumstantial evidence, the feedback from participants and early study data for its benefits are now very strong,” he said.

In a small study published in 2022, Dr. Harper and colleagues took 59 people with anxiety and depression and put them through a sea-swimming course. Afterward, 80% showed a clinically significant improvement in their mental health.

More recently, Dr. Harper and his team of researchers released a survey to determine how many people were using cold-water swimming as a treatment for a mental or physical ailment. “We thought 30 or 40 people would respond, but we ended up with over 700,” he said. “The majority were using it for mental health but also included inflammation-related conditions.”

Over 2 decades, Dr. Harper has seen dramatic success stories. In his book, he recalled a good friend who, in his early 20s, suffered from Crohn’s disease so badly he couldn’t walk up the steps to his parents’ house. The friend turned to outdoor cold swimming as a low-impact workout and began noticing the symptoms of his disease were improving. Within months, he was able to go off his medications. In 2022, he completed 52 triathlons: one per week for the entire year.
 

How cold exposure may play with your brain

Vaibhav Diwadkar, PhD, professor of psychiatry and behavioral neurosciences at Wayne State University, in Detroit, is studying how human brain networks respond to cold exposure. Dr. Diwadkar and his colleague, Otto Muzik, PhD, began by putting volunteers in a rubber suit with thin tubing and infusing the tubing with temperature-controlled water. Meanwhile, they collected functional brain imaging data to analyze which parts of the brain were responding as body temperature changed.

The data showed that the cold exposure made certain areas of the brain very active, including some that have been associated with the regulation of mood.

Dr. Diwadkar posits that controlled exposure to cold serves as a low-level stressor that knocks different systems within the brain and body out of homeostasis. Once the stress is removed, the brain responds by releasing neurotransmitters that enhance mood, frequently leading to feelings of euphoria in participants.

“We don’t have direct evidence of such a mechanism, but it’s a reasonable speculation,” said Dr. Diwadkar.

However, he pointed out that science writers in the media often portray topics such as this one in black and white, which is “oversimplifying the scientific complexity of biology.”

Clearly, more research needs to be done on the potential therapeutic benefits of cold-water swimming. But for those suffering from anxiety, depression, or chronic illness, if taking a cold dip makes you feel better, the why and how might be beside the point.

Plus, as Dr. Harper pointed out, it’s an easy and accessible therapy.

“All you need is some water – enough to submerge your entire body in – that’s less than 68 °F (20 °C),” he said. “If you stay long enough to get over that initial shock, which is just 2 or 3 minutes, then you’ve got the effect. If you get out and want to go back in again, then you’ve done it right.”
 

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

I was running my 25th New York City Marathon. It was 2018, and I almost pulled out of running that year. I wasn’t myself, and maybe that’s an understatement.

A month earlier, I had been involved in a malpractice case. I was found liable for $10 million. My colleagues didn’t think I had done anything wrong, but the jury did. And the local newspapers made me look like a villain.

I was devastated. But my priest, my friends, and my family all told me, “You can’t quit.” So, I decided to run for them.

I started on the Verrazzano-Narrows Bridge that morning with some friends from work. I usually listen to music as I’m running, but I didn’t that year. I was just in my zone, enjoying the crowds. They’re huge. Millions of people on the streets.

I was running well. I did half the race in an hour and 57 minutes. My family always meets me at mile 17, and I was almost there. I had reached 59th Street and was about to make the turn onto First Avenue.

That’s one of the noisiest places in the marathon. There’s a kind of tunnel, and with the crowd and the throng of runners, it’s incredibly loud. But somehow, I heard somebody yell, “Help!”

Now, how I heard that, I don’t know. And if I’d been listening to music like I always do, no way I would’ve heard it. I could swear it was an angel on my shoulder that said, “Turn around, dummy. You’ve got a person that needs your help to your left.”

I turned around and about 30 feet behind me, I saw a woman waving her hands and a runner on the ground. I thought, Somebody fainted. I pushed through the crowd to get to them. The woman was crying, saying, “My friend went down to tie her shoe and she fell back. I think she’s seizing or something.”

I got down and tried to wake the other woman up. I lifted her legs up. But I quickly realized there was more to the story. I felt for pulses and couldn’t feel them. I screamed for a defibrillator and started to do CPR.

Some volunteers and police started coming toward us. The police officers looked at me like, What’s this guy doing? I explained that I was a physician, and one of them began helping me with the CPR. As we did that, someone brought a defibrillator.

Meanwhile, runners were going past, almost over us. The police officers were trying to create a barrier.

The machine gave the woman a shock, but we didn’t get a response, so we resumed CPR. At that point, my legs began to cramp so badly I couldn’t go on. So the police officer took over, and I yelled, “I need an ambu bag!” Somebody brought one, and I started giving her oxygen.

At that point, a paramedic team arrived with a bigger defibrillator. We shocked her again. And again. That time we got results, but she quickly went out again. The fourth time, we got her heart back and she started breathing on her own.

We finally got her into an ambulance. I wanted to go with them, but the woman’s friend needed to get in, so there wasn’t enough room.

And then they were gone, and I was just standing there.

A police officer put his arm around me. He said, “Doc, you’re amazing. What do you need? Where can I take you?”

I said, “Take me? My wife is waiting for me at mile 17.”

I took off and ran. When I got to my wife and kids, they were so worried. We all wear tracking devices, and they could see that I had stopped for more than 20 minutes.

I fell into my wife’s arms and told her what had happened. I was crying. “I don’t know what to do. I need to get to the hospital.”

And she said, “No, you need to go finish the race.”

So, I did. It was painful because of the cramps, but I was numb at that point. I was thinking about the woman the whole way. My time was 5 hours and 20 minutes.

As soon as I finished, I went to every police officer I could find, but nobody knew anything. Suddenly, I remembered my cousin. He had previously been the head of EMS for New York City. I called him. “Abdo, it’s Ted, you’ve got to do me a favor.”

“What?” he said. “Are you delirious from running the marathon?”

I told him what I needed. He called me back 5 minutes later and said, “Ted, what’d you do? Everybody wants to know who you are and where you are! The woman just went out again at New York Cornell. But they got her back, and they’re bringing her up to the cath lab.”

After every marathon that I run, we host a big party at our house. My family and friends and neighbors all celebrate while I’m dying on the couch. That night, my daughter told everyone the story of what happened.

But I was still not right. Still thinking about the malpractice suit.

Yes, I just did something great. But I’d recently been called the worst physician in the world. The distraction of the marathon was gone, and I was back to thinking, What am I going to do with my life? Who’s ever going to want to see me again? I’m a pariah.

Everybody said, “Ted, what happened a month ago isn’t you. What happened today was you.”

I told them to leave it alone, but my daughter and my neighbor started calling people anyway. The next day I got a call from the local newspaper. It was the same journalist who had written about me from the trial. I told him I didn’t want to talk. I was actually pretty nasty.

But my wife said, “Ted, what are you doing? That guy was trying to help you.” So, I called back and apologized.

“Dr. Strange, we knew that story wasn’t right,” he said. “We have to write this story.”

After the article came out, I started getting more calls from the media. Channel 7 News and CBS News did segments. The New York Knicks invited us to a game and presented me with a watch. It was incredible. But I was also really embarrassed by it.

People started calling me a hero. I’m not a hero. I just did what I’m supposed to do, what I’m trained to do. Shame on me if I don’t do that. Good guy and hopefully good physician, sure, but not a hero.

I also give credit to the City of New York Police Department, the FDNY, and the volunteers. Without them, I couldn’t have done what I did. It was a true team effort.

A few weeks later, the woman went home to Minnesota. She’ll never run a marathon again, but she’s still alive to this day. It turned out she had a single lesion called the “widow-maker” lesion. She was in perfect health and had just completed an ultramarathon a few months before; but she had a genetic predisposition. She still calls me every December to thank me for another Christmas.

There’s more.

One year after this whole thing, almost to the date, I got a call from my attorney. “The court just threw out the malpractice verdict,” he said. “You didn’t do anything wrong.”

I’m a man of faith. And I believe all this happened for a reason. Maybe God was sending me a message, and that’s why I heard a call for help on 59th Street in my 25th marathon among millions of people in a crowd.

I ran the marathon the next year. And when I got to that spot, I stopped and reflected. Nobody knew why I was standing there, but I knew. To this day, I could take you to that spot.

I turn 65 next July, and I plan to keep on running the race.
 

Dr. Strange is chair of medicine at Staten Island University Hospital, associate ambulatory physician executive of the Staten Island Region, and an internal medicine and geriatric medicine physician with Northwell Health.

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

I was running my 25th New York City Marathon. It was 2018, and I almost pulled out of running that year. I wasn’t myself, and maybe that’s an understatement.

A month earlier, I had been involved in a malpractice case. I was found liable for $10 million. My colleagues didn’t think I had done anything wrong, but the jury did. And the local newspapers made me look like a villain.

I was devastated. But my priest, my friends, and my family all told me, “You can’t quit.” So, I decided to run for them.

I started on the Verrazzano-Narrows Bridge that morning with some friends from work. I usually listen to music as I’m running, but I didn’t that year. I was just in my zone, enjoying the crowds. They’re huge. Millions of people on the streets.

I was running well. I did half the race in an hour and 57 minutes. My family always meets me at mile 17, and I was almost there. I had reached 59th Street and was about to make the turn onto First Avenue.

That’s one of the noisiest places in the marathon. There’s a kind of tunnel, and with the crowd and the throng of runners, it’s incredibly loud. But somehow, I heard somebody yell, “Help!”

Now, how I heard that, I don’t know. And if I’d been listening to music like I always do, no way I would’ve heard it. I could swear it was an angel on my shoulder that said, “Turn around, dummy. You’ve got a person that needs your help to your left.”

I turned around and about 30 feet behind me, I saw a woman waving her hands and a runner on the ground. I thought, Somebody fainted. I pushed through the crowd to get to them. The woman was crying, saying, “My friend went down to tie her shoe and she fell back. I think she’s seizing or something.”

I got down and tried to wake the other woman up. I lifted her legs up. But I quickly realized there was more to the story. I felt for pulses and couldn’t feel them. I screamed for a defibrillator and started to do CPR.

Some volunteers and police started coming toward us. The police officers looked at me like, What’s this guy doing? I explained that I was a physician, and one of them began helping me with the CPR. As we did that, someone brought a defibrillator.

Meanwhile, runners were going past, almost over us. The police officers were trying to create a barrier.

The machine gave the woman a shock, but we didn’t get a response, so we resumed CPR. At that point, my legs began to cramp so badly I couldn’t go on. So the police officer took over, and I yelled, “I need an ambu bag!” Somebody brought one, and I started giving her oxygen.

At that point, a paramedic team arrived with a bigger defibrillator. We shocked her again. And again. That time we got results, but she quickly went out again. The fourth time, we got her heart back and she started breathing on her own.

We finally got her into an ambulance. I wanted to go with them, but the woman’s friend needed to get in, so there wasn’t enough room.

And then they were gone, and I was just standing there.

A police officer put his arm around me. He said, “Doc, you’re amazing. What do you need? Where can I take you?”

I said, “Take me? My wife is waiting for me at mile 17.”

I took off and ran. When I got to my wife and kids, they were so worried. We all wear tracking devices, and they could see that I had stopped for more than 20 minutes.

I fell into my wife’s arms and told her what had happened. I was crying. “I don’t know what to do. I need to get to the hospital.”

And she said, “No, you need to go finish the race.”

So, I did. It was painful because of the cramps, but I was numb at that point. I was thinking about the woman the whole way. My time was 5 hours and 20 minutes.

As soon as I finished, I went to every police officer I could find, but nobody knew anything. Suddenly, I remembered my cousin. He had previously been the head of EMS for New York City. I called him. “Abdo, it’s Ted, you’ve got to do me a favor.”

“What?” he said. “Are you delirious from running the marathon?”

I told him what I needed. He called me back 5 minutes later and said, “Ted, what’d you do? Everybody wants to know who you are and where you are! The woman just went out again at New York Cornell. But they got her back, and they’re bringing her up to the cath lab.”

After every marathon that I run, we host a big party at our house. My family and friends and neighbors all celebrate while I’m dying on the couch. That night, my daughter told everyone the story of what happened.

But I was still not right. Still thinking about the malpractice suit.

Yes, I just did something great. But I’d recently been called the worst physician in the world. The distraction of the marathon was gone, and I was back to thinking, What am I going to do with my life? Who’s ever going to want to see me again? I’m a pariah.

Everybody said, “Ted, what happened a month ago isn’t you. What happened today was you.”

I told them to leave it alone, but my daughter and my neighbor started calling people anyway. The next day I got a call from the local newspaper. It was the same journalist who had written about me from the trial. I told him I didn’t want to talk. I was actually pretty nasty.

But my wife said, “Ted, what are you doing? That guy was trying to help you.” So, I called back and apologized.

“Dr. Strange, we knew that story wasn’t right,” he said. “We have to write this story.”

After the article came out, I started getting more calls from the media. Channel 7 News and CBS News did segments. The New York Knicks invited us to a game and presented me with a watch. It was incredible. But I was also really embarrassed by it.

People started calling me a hero. I’m not a hero. I just did what I’m supposed to do, what I’m trained to do. Shame on me if I don’t do that. Good guy and hopefully good physician, sure, but not a hero.

I also give credit to the City of New York Police Department, the FDNY, and the volunteers. Without them, I couldn’t have done what I did. It was a true team effort.

A few weeks later, the woman went home to Minnesota. She’ll never run a marathon again, but she’s still alive to this day. It turned out she had a single lesion called the “widow-maker” lesion. She was in perfect health and had just completed an ultramarathon a few months before; but she had a genetic predisposition. She still calls me every December to thank me for another Christmas.

There’s more.

One year after this whole thing, almost to the date, I got a call from my attorney. “The court just threw out the malpractice verdict,” he said. “You didn’t do anything wrong.”

I’m a man of faith. And I believe all this happened for a reason. Maybe God was sending me a message, and that’s why I heard a call for help on 59th Street in my 25th marathon among millions of people in a crowd.

I ran the marathon the next year. And when I got to that spot, I stopped and reflected. Nobody knew why I was standing there, but I knew. To this day, I could take you to that spot.

I turn 65 next July, and I plan to keep on running the race.
 

Dr. Strange is chair of medicine at Staten Island University Hospital, associate ambulatory physician executive of the Staten Island Region, and an internal medicine and geriatric medicine physician with Northwell Health.

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

I was running my 25th New York City Marathon. It was 2018, and I almost pulled out of running that year. I wasn’t myself, and maybe that’s an understatement.

A month earlier, I had been involved in a malpractice case. I was found liable for $10 million. My colleagues didn’t think I had done anything wrong, but the jury did. And the local newspapers made me look like a villain.

I was devastated. But my priest, my friends, and my family all told me, “You can’t quit.” So, I decided to run for them.

I started on the Verrazzano-Narrows Bridge that morning with some friends from work. I usually listen to music as I’m running, but I didn’t that year. I was just in my zone, enjoying the crowds. They’re huge. Millions of people on the streets.

I was running well. I did half the race in an hour and 57 minutes. My family always meets me at mile 17, and I was almost there. I had reached 59th Street and was about to make the turn onto First Avenue.

That’s one of the noisiest places in the marathon. There’s a kind of tunnel, and with the crowd and the throng of runners, it’s incredibly loud. But somehow, I heard somebody yell, “Help!”

Now, how I heard that, I don’t know. And if I’d been listening to music like I always do, no way I would’ve heard it. I could swear it was an angel on my shoulder that said, “Turn around, dummy. You’ve got a person that needs your help to your left.”

I turned around and about 30 feet behind me, I saw a woman waving her hands and a runner on the ground. I thought, Somebody fainted. I pushed through the crowd to get to them. The woman was crying, saying, “My friend went down to tie her shoe and she fell back. I think she’s seizing or something.”

I got down and tried to wake the other woman up. I lifted her legs up. But I quickly realized there was more to the story. I felt for pulses and couldn’t feel them. I screamed for a defibrillator and started to do CPR.

Some volunteers and police started coming toward us. The police officers looked at me like, What’s this guy doing? I explained that I was a physician, and one of them began helping me with the CPR. As we did that, someone brought a defibrillator.

Meanwhile, runners were going past, almost over us. The police officers were trying to create a barrier.

The machine gave the woman a shock, but we didn’t get a response, so we resumed CPR. At that point, my legs began to cramp so badly I couldn’t go on. So the police officer took over, and I yelled, “I need an ambu bag!” Somebody brought one, and I started giving her oxygen.

At that point, a paramedic team arrived with a bigger defibrillator. We shocked her again. And again. That time we got results, but she quickly went out again. The fourth time, we got her heart back and she started breathing on her own.

We finally got her into an ambulance. I wanted to go with them, but the woman’s friend needed to get in, so there wasn’t enough room.

And then they were gone, and I was just standing there.

A police officer put his arm around me. He said, “Doc, you’re amazing. What do you need? Where can I take you?”

I said, “Take me? My wife is waiting for me at mile 17.”

I took off and ran. When I got to my wife and kids, they were so worried. We all wear tracking devices, and they could see that I had stopped for more than 20 minutes.

I fell into my wife’s arms and told her what had happened. I was crying. “I don’t know what to do. I need to get to the hospital.”

And she said, “No, you need to go finish the race.”

So, I did. It was painful because of the cramps, but I was numb at that point. I was thinking about the woman the whole way. My time was 5 hours and 20 minutes.

As soon as I finished, I went to every police officer I could find, but nobody knew anything. Suddenly, I remembered my cousin. He had previously been the head of EMS for New York City. I called him. “Abdo, it’s Ted, you’ve got to do me a favor.”

“What?” he said. “Are you delirious from running the marathon?”

I told him what I needed. He called me back 5 minutes later and said, “Ted, what’d you do? Everybody wants to know who you are and where you are! The woman just went out again at New York Cornell. But they got her back, and they’re bringing her up to the cath lab.”

After every marathon that I run, we host a big party at our house. My family and friends and neighbors all celebrate while I’m dying on the couch. That night, my daughter told everyone the story of what happened.

But I was still not right. Still thinking about the malpractice suit.

Yes, I just did something great. But I’d recently been called the worst physician in the world. The distraction of the marathon was gone, and I was back to thinking, What am I going to do with my life? Who’s ever going to want to see me again? I’m a pariah.

Everybody said, “Ted, what happened a month ago isn’t you. What happened today was you.”

I told them to leave it alone, but my daughter and my neighbor started calling people anyway. The next day I got a call from the local newspaper. It was the same journalist who had written about me from the trial. I told him I didn’t want to talk. I was actually pretty nasty.

But my wife said, “Ted, what are you doing? That guy was trying to help you.” So, I called back and apologized.

“Dr. Strange, we knew that story wasn’t right,” he said. “We have to write this story.”

After the article came out, I started getting more calls from the media. Channel 7 News and CBS News did segments. The New York Knicks invited us to a game and presented me with a watch. It was incredible. But I was also really embarrassed by it.

People started calling me a hero. I’m not a hero. I just did what I’m supposed to do, what I’m trained to do. Shame on me if I don’t do that. Good guy and hopefully good physician, sure, but not a hero.

I also give credit to the City of New York Police Department, the FDNY, and the volunteers. Without them, I couldn’t have done what I did. It was a true team effort.

A few weeks later, the woman went home to Minnesota. She’ll never run a marathon again, but she’s still alive to this day. It turned out she had a single lesion called the “widow-maker” lesion. She was in perfect health and had just completed an ultramarathon a few months before; but she had a genetic predisposition. She still calls me every December to thank me for another Christmas.

There’s more.

One year after this whole thing, almost to the date, I got a call from my attorney. “The court just threw out the malpractice verdict,” he said. “You didn’t do anything wrong.”

I’m a man of faith. And I believe all this happened for a reason. Maybe God was sending me a message, and that’s why I heard a call for help on 59th Street in my 25th marathon among millions of people in a crowd.

I ran the marathon the next year. And when I got to that spot, I stopped and reflected. Nobody knew why I was standing there, but I knew. To this day, I could take you to that spot.

I turn 65 next July, and I plan to keep on running the race.
 

Dr. Strange is chair of medicine at Staten Island University Hospital, associate ambulatory physician executive of the Staten Island Region, and an internal medicine and geriatric medicine physician with Northwell Health.

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

Pharmacogenomic testing for antidepressants could help reduce the time and cost it takes to find the most effective medication for a patient, according to a new study.

Scientists developed a microsimulation model to evaluate the effectiveness of pharmacogenomic testing for adult patients in British Columbia, with newly diagnosed moderate to severe major depressive disorder (MDD). The model predicted that testing could result in 37% fewer patients developing refractory depression, 15% more time of patients feeling well, and a health system cost-savings of $956 million CAD over 20 years.

“Our study shows that, if pharmacogenomic testing guides the prescription of an effective antidepressant, it can reduce the lengthy trial-and-error process many patients experience and dramatically reduce the financial burden on the health care system,” Shahzad Ghanbarian, PhD, the lead author and a research analyst at the University of British Columbia’s Centre for Clinical Epidemiology and Evaluation, Vancouver, said in an interview.

“The next step should be developing implementation strategies and identifying the most suitable health care professionals to provide pharmacogenomic-guided care,” she said.

The study was published online on in the Canadian Medical Association Journal.
 

Developing a model

The World Health Organization has predicted that depression will be the leading cause of disability worldwide by 2030. However, about half of patients don’t respond to the antidepressant that they are initially prescribed, and more than one-quarter report adverse effects. Previous studies have found that up to 42% of the lack in response stems from genetic factors that affect medication metabolism.

Pharmacogenomic testing, which uses a blood, saliva, or buccal swab sample, could help identify genetic variants involved in drug metabolism and response as well as guide prescribing and reduce adverse effects, the authors wrote.

Dr. Ghanbarian and colleagues developed a microsimulation model in collaboration with patient partners, clinicians, and the health system to evaluate the effectiveness and cost-effectiveness of pharmacogenomic testing for adult patients with MDD in British Columbia. The model included unique patient characteristics, such as metabolizer phenotypes, and followed the experience of patients through diagnosis, treatment, and recurrence.

According to British Columbia administrative data from 2015 to 2020, the model simulated a population of 194,149 adults and incorporated 40 different antidepressants and other treatments, including electroconvulsive therapy (ECT) and psychotherapy. The research team compared treatment pathways for patients with and without pharmacogenomic testing over 20 years.

Overall, the model showed that pharmacogenomic-guided treatment resulted in higher remission rates and lower discontinuation rates, with 23,216 (37%) fewer patients developing refractory depression and decreased use of resource-intensive treatment options such as ECT and psychotherapy (by 28% and 22%, respectively). According to the model, these reductions would save the British Columbia health system $4,926 CAD per patient, or about $56 million CAD over 20 years.

These findings provide a solid economic justification for clinical implementation of pharmacogenomic-guided depression treatment in Canada.

In addition, the model found that patients who underwent pharmacogenomic testing spent 15% more time in the “well” state without depression symptoms and 18% less time in the MDD state with recurrent episodes or refractory depression. In turn, this would mean 1,869 fewer deaths and 21,346 fewer all-cause hospital admissions over 20 years.

Pharmacogenomic testing also led to gains of 0.064 life-years and 0.381 quality-adjusted life-years per patient, or 12,436 life-years and 74,023 QALYs for all of British Columbia over 20 years.

From a cost perspective, the $121 million CAD cost of pharmacogenomic testing and $524 million CAD increase in episodic care were offset by a decrease in the cost of refractory MDD care. In sensitivity analyses, up-front investment in pharmacogenomic testing was typically offset after 2 years through lower direct medical costs, and it was also considered a cost-saving measure from that point forward.

“By incorporating the perspectives of patients with lived and living experience into this model, alongside robust data sets, we were able to carefully simulate the treatment journey of people with major depression,” Dr. Ghanbarian said. “The simulation model is designed to be flexible and could be applied to other jurisdictions beyond British Columbia, where we might expect to see similar benefits, particularly within a comparable Canadian context.”
 

Implementing the model

Now, Dr. Ghanbarian and colleagues are interested in potential implementation strategies at a system-wide level. For now, pharmacogenomic tests aren’t offered through the public health systems across Canada, but patients can pay for them through private companies.

“These findings provide a solid economic justification for clinical implementation of pharmacogenomic-guided depression treatment in Canada,” Chad Bousman, PhD, associate professor of physiology and pharmacology at the University of Calgary (Alta.), said in an interview.

Dr. Bousman, who was not involved with this study, coauthored the Clinical Pharmacogenetics Implementation Consortium guideline for several genotypes and serotonin reuptake inhibitor antidepressants. He and colleagues have also developed and evaluated web-based tools that translate pharmacogenetic data into evidence-based prescribing recommendations.

“The hope is that this work will facilitate investment in the establishment of the necessary infrastructure to ensure Canadians have equitable access to pharmacogenomic testing and ultimately improve mental health outcomes,” he said.

The study was funded by Genome BC, Genome Canada, and Michael Smith Health Research British Columbia. Dr. Ghanbarian and Dr. Bousman reported no relevant financial relationships.

A version of this article appeared on Medscape.com.

Pharmacogenomic testing for antidepressants could help reduce the time and cost it takes to find the most effective medication for a patient, according to a new study.

Scientists developed a microsimulation model to evaluate the effectiveness of pharmacogenomic testing for adult patients in British Columbia, with newly diagnosed moderate to severe major depressive disorder (MDD). The model predicted that testing could result in 37% fewer patients developing refractory depression, 15% more time of patients feeling well, and a health system cost-savings of $956 million CAD over 20 years.

“Our study shows that, if pharmacogenomic testing guides the prescription of an effective antidepressant, it can reduce the lengthy trial-and-error process many patients experience and dramatically reduce the financial burden on the health care system,” Shahzad Ghanbarian, PhD, the lead author and a research analyst at the University of British Columbia’s Centre for Clinical Epidemiology and Evaluation, Vancouver, said in an interview.

“The next step should be developing implementation strategies and identifying the most suitable health care professionals to provide pharmacogenomic-guided care,” she said.

The study was published online on in the Canadian Medical Association Journal.
 

Developing a model

The World Health Organization has predicted that depression will be the leading cause of disability worldwide by 2030. However, about half of patients don’t respond to the antidepressant that they are initially prescribed, and more than one-quarter report adverse effects. Previous studies have found that up to 42% of the lack in response stems from genetic factors that affect medication metabolism.

Pharmacogenomic testing, which uses a blood, saliva, or buccal swab sample, could help identify genetic variants involved in drug metabolism and response as well as guide prescribing and reduce adverse effects, the authors wrote.

Dr. Ghanbarian and colleagues developed a microsimulation model in collaboration with patient partners, clinicians, and the health system to evaluate the effectiveness and cost-effectiveness of pharmacogenomic testing for adult patients with MDD in British Columbia. The model included unique patient characteristics, such as metabolizer phenotypes, and followed the experience of patients through diagnosis, treatment, and recurrence.

According to British Columbia administrative data from 2015 to 2020, the model simulated a population of 194,149 adults and incorporated 40 different antidepressants and other treatments, including electroconvulsive therapy (ECT) and psychotherapy. The research team compared treatment pathways for patients with and without pharmacogenomic testing over 20 years.

Overall, the model showed that pharmacogenomic-guided treatment resulted in higher remission rates and lower discontinuation rates, with 23,216 (37%) fewer patients developing refractory depression and decreased use of resource-intensive treatment options such as ECT and psychotherapy (by 28% and 22%, respectively). According to the model, these reductions would save the British Columbia health system $4,926 CAD per patient, or about $56 million CAD over 20 years.

These findings provide a solid economic justification for clinical implementation of pharmacogenomic-guided depression treatment in Canada.

In addition, the model found that patients who underwent pharmacogenomic testing spent 15% more time in the “well” state without depression symptoms and 18% less time in the MDD state with recurrent episodes or refractory depression. In turn, this would mean 1,869 fewer deaths and 21,346 fewer all-cause hospital admissions over 20 years.

Pharmacogenomic testing also led to gains of 0.064 life-years and 0.381 quality-adjusted life-years per patient, or 12,436 life-years and 74,023 QALYs for all of British Columbia over 20 years.

From a cost perspective, the $121 million CAD cost of pharmacogenomic testing and $524 million CAD increase in episodic care were offset by a decrease in the cost of refractory MDD care. In sensitivity analyses, up-front investment in pharmacogenomic testing was typically offset after 2 years through lower direct medical costs, and it was also considered a cost-saving measure from that point forward.

“By incorporating the perspectives of patients with lived and living experience into this model, alongside robust data sets, we were able to carefully simulate the treatment journey of people with major depression,” Dr. Ghanbarian said. “The simulation model is designed to be flexible and could be applied to other jurisdictions beyond British Columbia, where we might expect to see similar benefits, particularly within a comparable Canadian context.”
 

Implementing the model

Now, Dr. Ghanbarian and colleagues are interested in potential implementation strategies at a system-wide level. For now, pharmacogenomic tests aren’t offered through the public health systems across Canada, but patients can pay for them through private companies.

“These findings provide a solid economic justification for clinical implementation of pharmacogenomic-guided depression treatment in Canada,” Chad Bousman, PhD, associate professor of physiology and pharmacology at the University of Calgary (Alta.), said in an interview.

Dr. Bousman, who was not involved with this study, coauthored the Clinical Pharmacogenetics Implementation Consortium guideline for several genotypes and serotonin reuptake inhibitor antidepressants. He and colleagues have also developed and evaluated web-based tools that translate pharmacogenetic data into evidence-based prescribing recommendations.

“The hope is that this work will facilitate investment in the establishment of the necessary infrastructure to ensure Canadians have equitable access to pharmacogenomic testing and ultimately improve mental health outcomes,” he said.

The study was funded by Genome BC, Genome Canada, and Michael Smith Health Research British Columbia. Dr. Ghanbarian and Dr. Bousman reported no relevant financial relationships.

A version of this article appeared on Medscape.com.

Pharmacogenomic testing for antidepressants could help reduce the time and cost it takes to find the most effective medication for a patient, according to a new study.

Scientists developed a microsimulation model to evaluate the effectiveness of pharmacogenomic testing for adult patients in British Columbia, with newly diagnosed moderate to severe major depressive disorder (MDD). The model predicted that testing could result in 37% fewer patients developing refractory depression, 15% more time of patients feeling well, and a health system cost-savings of $956 million CAD over 20 years.

“Our study shows that, if pharmacogenomic testing guides the prescription of an effective antidepressant, it can reduce the lengthy trial-and-error process many patients experience and dramatically reduce the financial burden on the health care system,” Shahzad Ghanbarian, PhD, the lead author and a research analyst at the University of British Columbia’s Centre for Clinical Epidemiology and Evaluation, Vancouver, said in an interview.

“The next step should be developing implementation strategies and identifying the most suitable health care professionals to provide pharmacogenomic-guided care,” she said.

The study was published online on in the Canadian Medical Association Journal.
 

Developing a model

The World Health Organization has predicted that depression will be the leading cause of disability worldwide by 2030. However, about half of patients don’t respond to the antidepressant that they are initially prescribed, and more than one-quarter report adverse effects. Previous studies have found that up to 42% of the lack in response stems from genetic factors that affect medication metabolism.

Pharmacogenomic testing, which uses a blood, saliva, or buccal swab sample, could help identify genetic variants involved in drug metabolism and response as well as guide prescribing and reduce adverse effects, the authors wrote.

Dr. Ghanbarian and colleagues developed a microsimulation model in collaboration with patient partners, clinicians, and the health system to evaluate the effectiveness and cost-effectiveness of pharmacogenomic testing for adult patients with MDD in British Columbia. The model included unique patient characteristics, such as metabolizer phenotypes, and followed the experience of patients through diagnosis, treatment, and recurrence.

According to British Columbia administrative data from 2015 to 2020, the model simulated a population of 194,149 adults and incorporated 40 different antidepressants and other treatments, including electroconvulsive therapy (ECT) and psychotherapy. The research team compared treatment pathways for patients with and without pharmacogenomic testing over 20 years.

Overall, the model showed that pharmacogenomic-guided treatment resulted in higher remission rates and lower discontinuation rates, with 23,216 (37%) fewer patients developing refractory depression and decreased use of resource-intensive treatment options such as ECT and psychotherapy (by 28% and 22%, respectively). According to the model, these reductions would save the British Columbia health system $4,926 CAD per patient, or about $56 million CAD over 20 years.

These findings provide a solid economic justification for clinical implementation of pharmacogenomic-guided depression treatment in Canada.

In addition, the model found that patients who underwent pharmacogenomic testing spent 15% more time in the “well” state without depression symptoms and 18% less time in the MDD state with recurrent episodes or refractory depression. In turn, this would mean 1,869 fewer deaths and 21,346 fewer all-cause hospital admissions over 20 years.

Pharmacogenomic testing also led to gains of 0.064 life-years and 0.381 quality-adjusted life-years per patient, or 12,436 life-years and 74,023 QALYs for all of British Columbia over 20 years.

From a cost perspective, the $121 million CAD cost of pharmacogenomic testing and $524 million CAD increase in episodic care were offset by a decrease in the cost of refractory MDD care. In sensitivity analyses, up-front investment in pharmacogenomic testing was typically offset after 2 years through lower direct medical costs, and it was also considered a cost-saving measure from that point forward.

“By incorporating the perspectives of patients with lived and living experience into this model, alongside robust data sets, we were able to carefully simulate the treatment journey of people with major depression,” Dr. Ghanbarian said. “The simulation model is designed to be flexible and could be applied to other jurisdictions beyond British Columbia, where we might expect to see similar benefits, particularly within a comparable Canadian context.”
 

Implementing the model

Now, Dr. Ghanbarian and colleagues are interested in potential implementation strategies at a system-wide level. For now, pharmacogenomic tests aren’t offered through the public health systems across Canada, but patients can pay for them through private companies.

“These findings provide a solid economic justification for clinical implementation of pharmacogenomic-guided depression treatment in Canada,” Chad Bousman, PhD, associate professor of physiology and pharmacology at the University of Calgary (Alta.), said in an interview.

Dr. Bousman, who was not involved with this study, coauthored the Clinical Pharmacogenetics Implementation Consortium guideline for several genotypes and serotonin reuptake inhibitor antidepressants. He and colleagues have also developed and evaluated web-based tools that translate pharmacogenetic data into evidence-based prescribing recommendations.

“The hope is that this work will facilitate investment in the establishment of the necessary infrastructure to ensure Canadians have equitable access to pharmacogenomic testing and ultimately improve mental health outcomes,” he said.

The study was funded by Genome BC, Genome Canada, and Michael Smith Health Research British Columbia. Dr. Ghanbarian and Dr. Bousman reported no relevant financial relationships.

A version of this article appeared on Medscape.com.

Maternal depressive symptoms probably start at or before pregnancy, with trajectories that remain stable across the perinatal into the postnatal period, new research suggests.

The analysis of more than 11,000 pregnant women with depressive symptoms from seven prospective cohorts in Canada, the United Kingdom, and Singapore suggests that depressive symptoms (low, mild, or high levels) start sooner and last longer than is commonly thought.

The term “postnatal depression” is “at odds with existing scientific literature and the experience of clinicians who treat mental disorders in the context of obstetric practice,” said Michael J. Meaney, PhD, professor at McGill University, Montreal, and director of the Translational Neuroscience Program at the Agency for Science, Technology and Research (A*STAR), Singapore. 

“Although we anticipated that the prenatal period would be the primary time of onset and that symptom levels would be largely stable, I was nevertheless surprised at how this pattern was so universal across so many studies,” he said in an interview. “In truth, we saw very little evidence for a postnatal onset.”

This suggests that depressive symptoms start earlier than previously thought, and “that the relevant clinical settings for prevention are those treating women in routine health care, including family medicine,” he added.
 

Start screening sooner 

The investigators examined the course and stability of self-reported depressive symptoms at multiple time points across the perinatal period among 11,563 pregnant women in seven cohorts from the United Kingdom, Canada, and Singapore. Participants’ mean age was 29 years; 87.6% were White, 4.9% were East Asian, and 2.6% were Southeast Asian. 

The analysis tracked depressive symptoms from preconception through pregnancy to 2 years after childbirth. Three groups of mothers were identified in each cohort on the basis of their level of depressive symptoms (low, mild, or high) as assessed by the Edinburgh Postnatal Depression Scale (EPDS) or the Center for Epidemiological Studies Depression (CES-D).

The team found that all mothers within and across all cohorts had stable trajectories of maternal depressive symptoms from pregnancy onward. Trajectories for mothers who passed clinically validated cutoffs for “probable” depression also showed stable trajectories from pregnancy into the postnatal period.

“Taken together, these findings suggest that maternal depressive symptom levels in community-based cohort studies are apparent during pregnancy and remain stable into the postnatal period,” the authors write. “The results point to the early antenatal period as a timepoint for the identification of stable trajectories of maternal depressive symptoms. Public health policies should emphasize the early antenatal period as the optimal timing for interventions targeting maternal depressive symptoms.”

The findings, they note, “underscore the American Psychiatric Association’s recent approach in renaming postpartum depression as peripartum depression.”

Furthermore, a recent paper of the group’s findings details that depressive symptoms may often predate conception. 

“Our findings should serve to universally align practice to prenatal screening,” even though depression screening often takes place in a mid-gestational visit during the second trimester, Dr. Meaney said. “Our findings and those on the effects on child development strongly suggest the timing of the screening must be advanced into the first confirmation of pregnancy.” 
 

Depression is likely worse in the United States

Catherine Monk, PhD, chief of the Division of Women’s Mental Health and professor of medical psychology at Columbia University, Vagelos College of Physicians and Surgeons, New York, said in an interview that the results of the study “amplify similar research findings and the experience of most perinatal clinicians: Depression is stable from pregnancy onwards.”

John Abbott/Columbia University

Dr. Monk, who was not involved in the research, said that “as the authors note, the common focus on postpartum depression misses the months of prior suffering and an opportunity for earlier intervention.” Dr. Monk said she would have liked the results to have been examined further by race and ethnicity and socioeconomic factors. “Also, the combined sample does not include a U.S. cohort. This is significant as the U.S. has the highest maternal morbidity and mortality rate of developed nations, and some reports identify mental health factors as the number-one cause of maternal mortality.”

“Given the tremendous economic, racial, and ethnic inequities in health care – the lack of any kind of health justice – it is quite possible that in the U.S., depression that starts in pregnancy worsens over time, at least for some demographic groups,” Dr. Monk said. “Rates of depression, levels of depression, and the course of it during the peripartum period may be even more dire [in the U.S.] than what is represented in this article.” “What should be practice-changing about this article, and so many others demonstrating the persistent and often high levels of life-threatening depression during pregnancy, is the need for mental health providers to advocate for changes to the low rates of insurance reimbursement that push providers away from accepting insurance and into private practice, making access to affordable mental care nearly impossible for most,” she concluded. 

This study was supported by the Singapore Institute for Clinical Sciences, Agency for Science, Technology, and Research; the Toxic Stress Network of the JPB Foundation; the Hope for Depression Research Foundation; and the Jacob’s Foundation. Dr. Meaney and Dr. Monk report no conflicts of interest.

A version of this article appeared on Medscape.com.

Maternal depressive symptoms probably start at or before pregnancy, with trajectories that remain stable across the perinatal into the postnatal period, new research suggests.

The analysis of more than 11,000 pregnant women with depressive symptoms from seven prospective cohorts in Canada, the United Kingdom, and Singapore suggests that depressive symptoms (low, mild, or high levels) start sooner and last longer than is commonly thought.

The term “postnatal depression” is “at odds with existing scientific literature and the experience of clinicians who treat mental disorders in the context of obstetric practice,” said Michael J. Meaney, PhD, professor at McGill University, Montreal, and director of the Translational Neuroscience Program at the Agency for Science, Technology and Research (A*STAR), Singapore. 

“Although we anticipated that the prenatal period would be the primary time of onset and that symptom levels would be largely stable, I was nevertheless surprised at how this pattern was so universal across so many studies,” he said in an interview. “In truth, we saw very little evidence for a postnatal onset.”

This suggests that depressive symptoms start earlier than previously thought, and “that the relevant clinical settings for prevention are those treating women in routine health care, including family medicine,” he added.
 

Start screening sooner 

The investigators examined the course and stability of self-reported depressive symptoms at multiple time points across the perinatal period among 11,563 pregnant women in seven cohorts from the United Kingdom, Canada, and Singapore. Participants’ mean age was 29 years; 87.6% were White, 4.9% were East Asian, and 2.6% were Southeast Asian. 

The analysis tracked depressive symptoms from preconception through pregnancy to 2 years after childbirth. Three groups of mothers were identified in each cohort on the basis of their level of depressive symptoms (low, mild, or high) as assessed by the Edinburgh Postnatal Depression Scale (EPDS) or the Center for Epidemiological Studies Depression (CES-D).

The team found that all mothers within and across all cohorts had stable trajectories of maternal depressive symptoms from pregnancy onward. Trajectories for mothers who passed clinically validated cutoffs for “probable” depression also showed stable trajectories from pregnancy into the postnatal period.

“Taken together, these findings suggest that maternal depressive symptom levels in community-based cohort studies are apparent during pregnancy and remain stable into the postnatal period,” the authors write. “The results point to the early antenatal period as a timepoint for the identification of stable trajectories of maternal depressive symptoms. Public health policies should emphasize the early antenatal period as the optimal timing for interventions targeting maternal depressive symptoms.”

The findings, they note, “underscore the American Psychiatric Association’s recent approach in renaming postpartum depression as peripartum depression.”

Furthermore, a recent paper of the group’s findings details that depressive symptoms may often predate conception. 

“Our findings should serve to universally align practice to prenatal screening,” even though depression screening often takes place in a mid-gestational visit during the second trimester, Dr. Meaney said. “Our findings and those on the effects on child development strongly suggest the timing of the screening must be advanced into the first confirmation of pregnancy.” 
 

Depression is likely worse in the United States

Catherine Monk, PhD, chief of the Division of Women’s Mental Health and professor of medical psychology at Columbia University, Vagelos College of Physicians and Surgeons, New York, said in an interview that the results of the study “amplify similar research findings and the experience of most perinatal clinicians: Depression is stable from pregnancy onwards.”

John Abbott/Columbia University

Dr. Monk, who was not involved in the research, said that “as the authors note, the common focus on postpartum depression misses the months of prior suffering and an opportunity for earlier intervention.” Dr. Monk said she would have liked the results to have been examined further by race and ethnicity and socioeconomic factors. “Also, the combined sample does not include a U.S. cohort. This is significant as the U.S. has the highest maternal morbidity and mortality rate of developed nations, and some reports identify mental health factors as the number-one cause of maternal mortality.”

“Given the tremendous economic, racial, and ethnic inequities in health care – the lack of any kind of health justice – it is quite possible that in the U.S., depression that starts in pregnancy worsens over time, at least for some demographic groups,” Dr. Monk said. “Rates of depression, levels of depression, and the course of it during the peripartum period may be even more dire [in the U.S.] than what is represented in this article.” “What should be practice-changing about this article, and so many others demonstrating the persistent and often high levels of life-threatening depression during pregnancy, is the need for mental health providers to advocate for changes to the low rates of insurance reimbursement that push providers away from accepting insurance and into private practice, making access to affordable mental care nearly impossible for most,” she concluded. 

This study was supported by the Singapore Institute for Clinical Sciences, Agency for Science, Technology, and Research; the Toxic Stress Network of the JPB Foundation; the Hope for Depression Research Foundation; and the Jacob’s Foundation. Dr. Meaney and Dr. Monk report no conflicts of interest.

A version of this article appeared on Medscape.com.

Maternal depressive symptoms probably start at or before pregnancy, with trajectories that remain stable across the perinatal into the postnatal period, new research suggests.

The analysis of more than 11,000 pregnant women with depressive symptoms from seven prospective cohorts in Canada, the United Kingdom, and Singapore suggests that depressive symptoms (low, mild, or high levels) start sooner and last longer than is commonly thought.

The term “postnatal depression” is “at odds with existing scientific literature and the experience of clinicians who treat mental disorders in the context of obstetric practice,” said Michael J. Meaney, PhD, professor at McGill University, Montreal, and director of the Translational Neuroscience Program at the Agency for Science, Technology and Research (A*STAR), Singapore. 

“Although we anticipated that the prenatal period would be the primary time of onset and that symptom levels would be largely stable, I was nevertheless surprised at how this pattern was so universal across so many studies,” he said in an interview. “In truth, we saw very little evidence for a postnatal onset.”

This suggests that depressive symptoms start earlier than previously thought, and “that the relevant clinical settings for prevention are those treating women in routine health care, including family medicine,” he added.
 

Start screening sooner 

The investigators examined the course and stability of self-reported depressive symptoms at multiple time points across the perinatal period among 11,563 pregnant women in seven cohorts from the United Kingdom, Canada, and Singapore. Participants’ mean age was 29 years; 87.6% were White, 4.9% were East Asian, and 2.6% were Southeast Asian. 

The analysis tracked depressive symptoms from preconception through pregnancy to 2 years after childbirth. Three groups of mothers were identified in each cohort on the basis of their level of depressive symptoms (low, mild, or high) as assessed by the Edinburgh Postnatal Depression Scale (EPDS) or the Center for Epidemiological Studies Depression (CES-D).

The team found that all mothers within and across all cohorts had stable trajectories of maternal depressive symptoms from pregnancy onward. Trajectories for mothers who passed clinically validated cutoffs for “probable” depression also showed stable trajectories from pregnancy into the postnatal period.

“Taken together, these findings suggest that maternal depressive symptom levels in community-based cohort studies are apparent during pregnancy and remain stable into the postnatal period,” the authors write. “The results point to the early antenatal period as a timepoint for the identification of stable trajectories of maternal depressive symptoms. Public health policies should emphasize the early antenatal period as the optimal timing for interventions targeting maternal depressive symptoms.”

The findings, they note, “underscore the American Psychiatric Association’s recent approach in renaming postpartum depression as peripartum depression.”

Furthermore, a recent paper of the group’s findings details that depressive symptoms may often predate conception. 

“Our findings should serve to universally align practice to prenatal screening,” even though depression screening often takes place in a mid-gestational visit during the second trimester, Dr. Meaney said. “Our findings and those on the effects on child development strongly suggest the timing of the screening must be advanced into the first confirmation of pregnancy.” 
 

Depression is likely worse in the United States

Catherine Monk, PhD, chief of the Division of Women’s Mental Health and professor of medical psychology at Columbia University, Vagelos College of Physicians and Surgeons, New York, said in an interview that the results of the study “amplify similar research findings and the experience of most perinatal clinicians: Depression is stable from pregnancy onwards.”

John Abbott/Columbia University

Dr. Monk, who was not involved in the research, said that “as the authors note, the common focus on postpartum depression misses the months of prior suffering and an opportunity for earlier intervention.” Dr. Monk said she would have liked the results to have been examined further by race and ethnicity and socioeconomic factors. “Also, the combined sample does not include a U.S. cohort. This is significant as the U.S. has the highest maternal morbidity and mortality rate of developed nations, and some reports identify mental health factors as the number-one cause of maternal mortality.”

“Given the tremendous economic, racial, and ethnic inequities in health care – the lack of any kind of health justice – it is quite possible that in the U.S., depression that starts in pregnancy worsens over time, at least for some demographic groups,” Dr. Monk said. “Rates of depression, levels of depression, and the course of it during the peripartum period may be even more dire [in the U.S.] than what is represented in this article.” “What should be practice-changing about this article, and so many others demonstrating the persistent and often high levels of life-threatening depression during pregnancy, is the need for mental health providers to advocate for changes to the low rates of insurance reimbursement that push providers away from accepting insurance and into private practice, making access to affordable mental care nearly impossible for most,” she concluded. 

This study was supported by the Singapore Institute for Clinical Sciences, Agency for Science, Technology, and Research; the Toxic Stress Network of the JPB Foundation; the Hope for Depression Research Foundation; and the Jacob’s Foundation. Dr. Meaney and Dr. Monk report no conflicts of interest.

A version of this article appeared on Medscape.com.

Headache and headache associated with mood disorders are common among individuals from the LGBTQIA+ community, but preconceptions should be abandoned in a diverse population fearful that their gender identity or sexual orientation will lead to mistreatment.

It is “important not to assume that just because someone is a member of the LGBTQ+ community they will need psychiatric or behavioral health support,” said Maya A. Marzouk, PhD, division of behavioral medicine and clinical psychology, Cincinnati Children’s Hospital Medical Center.

Instead, it is useful not to make any assumptions. There is a potential association between minority status and headache susceptibility, but it is more reasonable initially to address the diagnosis and treatment of headache in LGBTQIA+ patients the same way it is addressed in any other patient, Dr. Marzouk said at the 2023 Scottsdale Headache Symposium.

The acronym to describe individuals with gender identities different from male and female and sexual orientations not limited to heterosexuality has been in almost constant evolution over several decades. An addition sign that accompanies LGBTQIA refers to those who do not identify with any letters in the acronym (lesbian, gay, bisexual, transsexual, queer/questioning, intersex, and asexual).
 

Take steps to normalize the interaction

Although many clinicians have been acclimated to these diverse identifies, not all have risen above preconceptions that become obstacles to effective care, according to Dr. Marzouk. In the context of headache management, Dr. Marzouk emphasized the need to be respectful of the range of gender identities and sexual orientations and to take steps to normalize the interaction.

For example, Dr. Marzouk advised using gender-neutral language at the start of each patient encounter and ask open-ended questions about gender, sexual identify, and pronouns to avoid patient discomfort from misidentification. In turn, the clinicians can establish their own gender identification and preferred pronouns to reinforce the idea that doing so is normal behavior.

This change in approach should be made “for all patients. Do not try to guess who needs them,” she said.

Intake forms and office atmosphere, such as signs and images, should also be welcoming to all patients, she added. Rather than trying to make adjustments for a LGBTQIA+ visit, Dr. Marzouk said a uniform approach helps normalize the experience of LGBTQIA+ patients without singling them out.

Despite the effort to provide an open and welcoming environment, Dr. Marzouk acknowledged that mistakes are difficult to avoid for those with limited experience serving the LGBTQIA+ community. When mistakes are made, she advised clinicians to immediately acknowledge the mistake and ask for guidance from the patient.

The potential offense is making the patient feel “other” or abnormal.
 

A higher rate of migraine

The interactions that LBGTQIA+ patients have with others outside their community is a possible explanation for the substantial rate of headache as well as headache with comorbid psychiatric disorders in this population.

In a survey published in 2020, the rate of migraine was 19.7% in heterosexual women, 26.7% in lesbians, and 36.8% in bisexual women. Among men, it rose from 9.8% in heterosexuals to 14.8% in gays and then to 22.8% in bisexuals.

Migraine relative to headache is also associated with more mood disorders among LGBTQIA+ individuals. In a study published in 2022, LGBTQIA+ patients with migraine relative to those with headache were more likely to have depression (46.4% vs. 22.3%; P < .001), anxiety (72.1% vs. 51.6%; P < .001), and posttraumatic stress disorder (37.5% vs. 21.4%; P < .001).
 

A vicious cycle of underdiagnosis and undertreatment

These associations are consistent with minority stress theory, according to Dr. Marzouk. This theory postulates that the associated stress of discrimination, rejection, and microaggressions, such as explicit efforts to make LGBTQIA+ individuals to feel “other,” produces epigenetic changes and dysregulation of the hypothalamic-pituitary-adrenal axis. In turn, this plays a role in the pathogenesis of migraine.

The inconsistency with which minority stress affects LGBTQIA+ patients might be due to relative differences in social support, coping skills, an innate resilience to these effects, Dr. Marzouk explained.

Dr. Marzouk characterized the LGBTQIA+ community as “underserved” for treatment of headache. She suggested that medical mistrust and self-blame among LGBTQIA+ individuals might be factors contributing to a vicious cycle of underdiagnosis and undertreatment. Efforts by the medical community to reach out to the LGBTQIA+ community are appropriate to address an unmet need.

“Individuals with psychiatric comorbidities may experience even more benefit from migraine care,” she said.
 

Clinical studies should be more inclusive

While agreeing in principle with these remarks, Eric A. Kaiser, MD, PhD, department of neurology, University of Pennsylvania, Philadelphia, said that this area would be better advanced if studies routinely included patients with diverse-gender identities and sexual orientations. Speaking about how to organize these studies, Dr. Kaiser suggested that enrollment criteria should explicitly seek these individuals and that these differences should be captured in the baseline characteristics.

“For example, gender options could include man, woman, non-binary, gender diverse, gender nonconforming, or gender nonspecified,” he said.

To close “the significant knowledge gap that exists in managing headache disorders in sexually- and gender- diverse people,” Dr. Kaiser said that clinical research studies, like patient treatment of diverse populations, “should be conducted with welcoming and affirming practices.”

Dr. Marzouk reported no potential conflicts of interest. Dr. Kaiser reported financial relationships with Amgen and Lundbeck.

Headache and headache associated with mood disorders are common among individuals from the LGBTQIA+ community, but preconceptions should be abandoned in a diverse population fearful that their gender identity or sexual orientation will lead to mistreatment.

It is “important not to assume that just because someone is a member of the LGBTQ+ community they will need psychiatric or behavioral health support,” said Maya A. Marzouk, PhD, division of behavioral medicine and clinical psychology, Cincinnati Children’s Hospital Medical Center.

Instead, it is useful not to make any assumptions. There is a potential association between minority status and headache susceptibility, but it is more reasonable initially to address the diagnosis and treatment of headache in LGBTQIA+ patients the same way it is addressed in any other patient, Dr. Marzouk said at the 2023 Scottsdale Headache Symposium.

The acronym to describe individuals with gender identities different from male and female and sexual orientations not limited to heterosexuality has been in almost constant evolution over several decades. An addition sign that accompanies LGBTQIA refers to those who do not identify with any letters in the acronym (lesbian, gay, bisexual, transsexual, queer/questioning, intersex, and asexual).
 

Take steps to normalize the interaction

Although many clinicians have been acclimated to these diverse identifies, not all have risen above preconceptions that become obstacles to effective care, according to Dr. Marzouk. In the context of headache management, Dr. Marzouk emphasized the need to be respectful of the range of gender identities and sexual orientations and to take steps to normalize the interaction.

For example, Dr. Marzouk advised using gender-neutral language at the start of each patient encounter and ask open-ended questions about gender, sexual identify, and pronouns to avoid patient discomfort from misidentification. In turn, the clinicians can establish their own gender identification and preferred pronouns to reinforce the idea that doing so is normal behavior.

This change in approach should be made “for all patients. Do not try to guess who needs them,” she said.

Intake forms and office atmosphere, such as signs and images, should also be welcoming to all patients, she added. Rather than trying to make adjustments for a LGBTQIA+ visit, Dr. Marzouk said a uniform approach helps normalize the experience of LGBTQIA+ patients without singling them out.

Despite the effort to provide an open and welcoming environment, Dr. Marzouk acknowledged that mistakes are difficult to avoid for those with limited experience serving the LGBTQIA+ community. When mistakes are made, she advised clinicians to immediately acknowledge the mistake and ask for guidance from the patient.

The potential offense is making the patient feel “other” or abnormal.
 

A higher rate of migraine

The interactions that LBGTQIA+ patients have with others outside their community is a possible explanation for the substantial rate of headache as well as headache with comorbid psychiatric disorders in this population.

In a survey published in 2020, the rate of migraine was 19.7% in heterosexual women, 26.7% in lesbians, and 36.8% in bisexual women. Among men, it rose from 9.8% in heterosexuals to 14.8% in gays and then to 22.8% in bisexuals.

Migraine relative to headache is also associated with more mood disorders among LGBTQIA+ individuals. In a study published in 2022, LGBTQIA+ patients with migraine relative to those with headache were more likely to have depression (46.4% vs. 22.3%; P < .001), anxiety (72.1% vs. 51.6%; P < .001), and posttraumatic stress disorder (37.5% vs. 21.4%; P < .001).
 

A vicious cycle of underdiagnosis and undertreatment

These associations are consistent with minority stress theory, according to Dr. Marzouk. This theory postulates that the associated stress of discrimination, rejection, and microaggressions, such as explicit efforts to make LGBTQIA+ individuals to feel “other,” produces epigenetic changes and dysregulation of the hypothalamic-pituitary-adrenal axis. In turn, this plays a role in the pathogenesis of migraine.

The inconsistency with which minority stress affects LGBTQIA+ patients might be due to relative differences in social support, coping skills, an innate resilience to these effects, Dr. Marzouk explained.

Dr. Marzouk characterized the LGBTQIA+ community as “underserved” for treatment of headache. She suggested that medical mistrust and self-blame among LGBTQIA+ individuals might be factors contributing to a vicious cycle of underdiagnosis and undertreatment. Efforts by the medical community to reach out to the LGBTQIA+ community are appropriate to address an unmet need.

“Individuals with psychiatric comorbidities may experience even more benefit from migraine care,” she said.
 

Clinical studies should be more inclusive

While agreeing in principle with these remarks, Eric A. Kaiser, MD, PhD, department of neurology, University of Pennsylvania, Philadelphia, said that this area would be better advanced if studies routinely included patients with diverse-gender identities and sexual orientations. Speaking about how to organize these studies, Dr. Kaiser suggested that enrollment criteria should explicitly seek these individuals and that these differences should be captured in the baseline characteristics.

“For example, gender options could include man, woman, non-binary, gender diverse, gender nonconforming, or gender nonspecified,” he said.

To close “the significant knowledge gap that exists in managing headache disorders in sexually- and gender- diverse people,” Dr. Kaiser said that clinical research studies, like patient treatment of diverse populations, “should be conducted with welcoming and affirming practices.”

Dr. Marzouk reported no potential conflicts of interest. Dr. Kaiser reported financial relationships with Amgen and Lundbeck.

Headache and headache associated with mood disorders are common among individuals from the LGBTQIA+ community, but preconceptions should be abandoned in a diverse population fearful that their gender identity or sexual orientation will lead to mistreatment.

It is “important not to assume that just because someone is a member of the LGBTQ+ community they will need psychiatric or behavioral health support,” said Maya A. Marzouk, PhD, division of behavioral medicine and clinical psychology, Cincinnati Children’s Hospital Medical Center.

Instead, it is useful not to make any assumptions. There is a potential association between minority status and headache susceptibility, but it is more reasonable initially to address the diagnosis and treatment of headache in LGBTQIA+ patients the same way it is addressed in any other patient, Dr. Marzouk said at the 2023 Scottsdale Headache Symposium.

The acronym to describe individuals with gender identities different from male and female and sexual orientations not limited to heterosexuality has been in almost constant evolution over several decades. An addition sign that accompanies LGBTQIA refers to those who do not identify with any letters in the acronym (lesbian, gay, bisexual, transsexual, queer/questioning, intersex, and asexual).
 

Take steps to normalize the interaction

Although many clinicians have been acclimated to these diverse identifies, not all have risen above preconceptions that become obstacles to effective care, according to Dr. Marzouk. In the context of headache management, Dr. Marzouk emphasized the need to be respectful of the range of gender identities and sexual orientations and to take steps to normalize the interaction.

For example, Dr. Marzouk advised using gender-neutral language at the start of each patient encounter and ask open-ended questions about gender, sexual identify, and pronouns to avoid patient discomfort from misidentification. In turn, the clinicians can establish their own gender identification and preferred pronouns to reinforce the idea that doing so is normal behavior.

This change in approach should be made “for all patients. Do not try to guess who needs them,” she said.

Intake forms and office atmosphere, such as signs and images, should also be welcoming to all patients, she added. Rather than trying to make adjustments for a LGBTQIA+ visit, Dr. Marzouk said a uniform approach helps normalize the experience of LGBTQIA+ patients without singling them out.

Despite the effort to provide an open and welcoming environment, Dr. Marzouk acknowledged that mistakes are difficult to avoid for those with limited experience serving the LGBTQIA+ community. When mistakes are made, she advised clinicians to immediately acknowledge the mistake and ask for guidance from the patient.

The potential offense is making the patient feel “other” or abnormal.
 

A higher rate of migraine

The interactions that LBGTQIA+ patients have with others outside their community is a possible explanation for the substantial rate of headache as well as headache with comorbid psychiatric disorders in this population.

In a survey published in 2020, the rate of migraine was 19.7% in heterosexual women, 26.7% in lesbians, and 36.8% in bisexual women. Among men, it rose from 9.8% in heterosexuals to 14.8% in gays and then to 22.8% in bisexuals.

Migraine relative to headache is also associated with more mood disorders among LGBTQIA+ individuals. In a study published in 2022, LGBTQIA+ patients with migraine relative to those with headache were more likely to have depression (46.4% vs. 22.3%; P < .001), anxiety (72.1% vs. 51.6%; P < .001), and posttraumatic stress disorder (37.5% vs. 21.4%; P < .001).
 

A vicious cycle of underdiagnosis and undertreatment

These associations are consistent with minority stress theory, according to Dr. Marzouk. This theory postulates that the associated stress of discrimination, rejection, and microaggressions, such as explicit efforts to make LGBTQIA+ individuals to feel “other,” produces epigenetic changes and dysregulation of the hypothalamic-pituitary-adrenal axis. In turn, this plays a role in the pathogenesis of migraine.

The inconsistency with which minority stress affects LGBTQIA+ patients might be due to relative differences in social support, coping skills, an innate resilience to these effects, Dr. Marzouk explained.

Dr. Marzouk characterized the LGBTQIA+ community as “underserved” for treatment of headache. She suggested that medical mistrust and self-blame among LGBTQIA+ individuals might be factors contributing to a vicious cycle of underdiagnosis and undertreatment. Efforts by the medical community to reach out to the LGBTQIA+ community are appropriate to address an unmet need.

“Individuals with psychiatric comorbidities may experience even more benefit from migraine care,” she said.
 

Clinical studies should be more inclusive

While agreeing in principle with these remarks, Eric A. Kaiser, MD, PhD, department of neurology, University of Pennsylvania, Philadelphia, said that this area would be better advanced if studies routinely included patients with diverse-gender identities and sexual orientations. Speaking about how to organize these studies, Dr. Kaiser suggested that enrollment criteria should explicitly seek these individuals and that these differences should be captured in the baseline characteristics.

“For example, gender options could include man, woman, non-binary, gender diverse, gender nonconforming, or gender nonspecified,” he said.

To close “the significant knowledge gap that exists in managing headache disorders in sexually- and gender- diverse people,” Dr. Kaiser said that clinical research studies, like patient treatment of diverse populations, “should be conducted with welcoming and affirming practices.”

Dr. Marzouk reported no potential conflicts of interest. Dr. Kaiser reported financial relationships with Amgen and Lundbeck.

Breast cancer has a worse prognosis when diagnosed during pregnancy or postpartum. Methods for early detection are needed, as evidenced every day in the multidisciplinary unit for treating pregnancy-associated breast cancer, which operates within the breast unit at the Vall d’Hebron University Hospital in Barcelona.

The team working in this field is led by Cristina Saura, PhD, who is also head of the Breast Cancer Group at the Vall d’Hebron Institute of Oncology (VHIO). The results of a study recently published in Cancer Discovery show, for the first time, that breast milk from breast cancer patients contains circulating tumor DNA that can be detected by a liquid biopsy of the milk.

Dr. Saura explained in an interview why they began to pursue this research, which, in one sense, fell into their laps. “In this case, it arose from the concerns of a breast cancer patient who was diagnosed while pregnant with her third daughter. She was actually the one who came up with the idea for the project. She was worried that she had transmitted the tumor through her breast milk to her second daughter while breastfeeding. She had been breastfeeding for a long time and had stretched it out until shortly before she was diagnosed with breast cancer. So she brought us a sample of breast milk that she had stored in her freezer.

“So, thanks to her, that’s where our project started. Though we knew that breast cancer is not transmitted through breast milk, we decided to test the sample and look for markers that could help our research. In the end, when we analyzed the patient’s breast milk, we found DNA with the same mutation that was present in her tumor,” explained Dr. Saura. She noted that the breast milk they analyzed had been frozen for more than a year before the patient’s cancer diagnosis.

In terms of methodology, Ana Vivancos, PhD, head of the VHIO cancer genomics group and also one of the authors of the study, explained that they used two techniques to analyze the breast milk and blood samples: next-generation sequencing and droplet digital polymerase chain reaction. These methods confirmed the presence of ctDNA in the breast milk.
 

High-sensitivity genomic panel

“We were able to detect tumor mutations in milk samples from 13 of the 15 patients with breast cancer who were tested, while circulating tumor DNA was detected in only one of all the blood samples that were collected at the same time,” said Dr. Vivancos. “The samples from the two patients for whom no mutation was detected were discovered to be colostrum that had been collected during the first few hours of lactation.”

As a next step to make this finding practically useful, the research team designed a genomic panel using next-generation sequencing as a potential method for early detection of breast cancer. “We’ve developed a panel that uses hybrid capture chemistry and unique molecular identifiers that ensure better sensitivity during next-generation sequencing. The panel has been calibrated, based on the existing literature, to detect the genes that are most frequently mutated in breast cancer in young women under 45 years old.”

According to Dr. Vivancos, the sensitivity of this panel exceeds 70%. This means that for all the patient samples analyzed using this panel, 7 out of 10 cases are detected with 100% specificity.

“In practice, the panel design allows us to detect mutations in more than 95% of breast cancer cases in women under 45 years old. Therefore, using this panel for early detection of this type of tumor during lactation should contribute to addressing a medical need that, until today, has gone unmet,” noted Dr. Vivancos.

As for this unresolved need, Dr. Saura explained that there is currently no system or tool available to allow early suspicion of breast tumors in pregnant women prior to diagnosis. “That’s exactly the goal of this research: to screen for breast cancer in women who have just given birth. Now, it needs to be validated in a larger group of women in a clinical trial.”
 

More direct contact with tumor cells

In Dr. Saura’s opinion, in Spain, just like taking a small blood sample from newborns in a heel-prick test to rule out metabolic diseases, milk samples could be taken from women who give birth to rule out or diagnose breast cancer.

As to the potential advantages that breast milk liquid biopsy could have over similar techniques like blood liquid biopsy, Dr. Vivancos pointed to the results of her study: “We have seen that breast milk liquid biopsy was positive for the presence of circulating tumor DNA in 87% of cases, whereas blood only revealed the presence of this marker in 8% of cases. This difference indicates that breast milk is a biofluid that is in more direct contact with tumor cells and therefore will be more informative in earlier stages.”

Dr. Saura explained that the data does not lie when it comes to these tumors in pregnant or postpartum women. “In general, they tend to have a worse prognosis because, in most cases, they are diagnosed in advanced stages. Furthermore, it is typically assumed that the physiological changes in the breasts during gestation and lactation, which are considered to be normal, may hide a developing tumor. The fact is that postpartum breast cancer, understood to be the 10 years after delivery, accounts for 40%-45% of breast cancer cases diagnosed before age 45.”

The researchers plan to continue this project. “Our next step to confirm the usefulness of breast milk as a new tool for liquid biopsy for early detection of breast cancer during the postpartum period is to perform this noninvasive test in thousands of women,” said Dr. Saura.
 

Goal: Standardize the test as a screening method

“Based on the results we’ve published, we’re starting a study aimed at collecting breast milk samples from 5,000 healthy women around the world who became pregnant at age 40 or older, or who got pregnant at any age and carry mutations that increase their risk of breast cancer,” Dr. Saura added.

When asked when they expect to have preliminary results from this new study, Dr. Saura stated that it’s not yet possible to say exactly when. “We’re still waiting for funding to continue this project, but we continue performing analyses on a case-by-case basis. Of course, if we detect any abnormalities in these women, we will follow the established protocol to confirm diagnosis and start treatment if necessary.”

When asked whether it is reasonable to expect breast milk liquid biopsy to become normalized as a screening method for women of childbearing age who have a history or risk factors for developing breast cancer, Dr. Vivancos said, “That’s the scenario we see in the future and what we wish to contribute toward by providing scientific evidence to make it a reality.”

“For now, our goal is to validate whether circulating tumor DNA can be detected by breast milk liquid biopsy even before breast cancer can be diagnosed using conventional imaging techniques. If we can validate these preliminary results, we will be able to detect breast cancer early using a noninvasive test like breast milk liquid biopsy,” explained Saura.

Lastly, and in view of the issues that are still unresolved when it comes to the detection and treatment of breast cancer during pregnancy, Dr. Saura highlighted the emotional impact that a diagnosis of pregnancy-related cancer has on women and on those close to them. “But the first thing they need to know is that diagnosis is not necessarily synonymous with termination of the pregnancy. On the contrary, this tumor can be treated during pregnancy, since surgery can be performed at any time, and chemotherapy can be started in the second trimester. Proof of this is the 72 children who have been born under these circumstances in the past 20 years at the Vall d’Hebrón University Hospital. This hospital is a pioneer in Spain thanks to its multidisciplinary program for education and specific follow-up with women who have been diagnosed with a breast tumor during pregnancy.”

Dr. Saura and Dr. Vivancos reported no relevant financial relationships.

This article was translated from the Medscape Spanish edition. A version of this article appeared on Medscape.com.

Breast cancer has a worse prognosis when diagnosed during pregnancy or postpartum. Methods for early detection are needed, as evidenced every day in the multidisciplinary unit for treating pregnancy-associated breast cancer, which operates within the breast unit at the Vall d’Hebron University Hospital in Barcelona.

The team working in this field is led by Cristina Saura, PhD, who is also head of the Breast Cancer Group at the Vall d’Hebron Institute of Oncology (VHIO). The results of a study recently published in Cancer Discovery show, for the first time, that breast milk from breast cancer patients contains circulating tumor DNA that can be detected by a liquid biopsy of the milk.

Dr. Saura explained in an interview why they began to pursue this research, which, in one sense, fell into their laps. “In this case, it arose from the concerns of a breast cancer patient who was diagnosed while pregnant with her third daughter. She was actually the one who came up with the idea for the project. She was worried that she had transmitted the tumor through her breast milk to her second daughter while breastfeeding. She had been breastfeeding for a long time and had stretched it out until shortly before she was diagnosed with breast cancer. So she brought us a sample of breast milk that she had stored in her freezer.

“So, thanks to her, that’s where our project started. Though we knew that breast cancer is not transmitted through breast milk, we decided to test the sample and look for markers that could help our research. In the end, when we analyzed the patient’s breast milk, we found DNA with the same mutation that was present in her tumor,” explained Dr. Saura. She noted that the breast milk they analyzed had been frozen for more than a year before the patient’s cancer diagnosis.

In terms of methodology, Ana Vivancos, PhD, head of the VHIO cancer genomics group and also one of the authors of the study, explained that they used two techniques to analyze the breast milk and blood samples: next-generation sequencing and droplet digital polymerase chain reaction. These methods confirmed the presence of ctDNA in the breast milk.
 

High-sensitivity genomic panel

“We were able to detect tumor mutations in milk samples from 13 of the 15 patients with breast cancer who were tested, while circulating tumor DNA was detected in only one of all the blood samples that were collected at the same time,” said Dr. Vivancos. “The samples from the two patients for whom no mutation was detected were discovered to be colostrum that had been collected during the first few hours of lactation.”

As a next step to make this finding practically useful, the research team designed a genomic panel using next-generation sequencing as a potential method for early detection of breast cancer. “We’ve developed a panel that uses hybrid capture chemistry and unique molecular identifiers that ensure better sensitivity during next-generation sequencing. The panel has been calibrated, based on the existing literature, to detect the genes that are most frequently mutated in breast cancer in young women under 45 years old.”

According to Dr. Vivancos, the sensitivity of this panel exceeds 70%. This means that for all the patient samples analyzed using this panel, 7 out of 10 cases are detected with 100% specificity.

“In practice, the panel design allows us to detect mutations in more than 95% of breast cancer cases in women under 45 years old. Therefore, using this panel for early detection of this type of tumor during lactation should contribute to addressing a medical need that, until today, has gone unmet,” noted Dr. Vivancos.

As for this unresolved need, Dr. Saura explained that there is currently no system or tool available to allow early suspicion of breast tumors in pregnant women prior to diagnosis. “That’s exactly the goal of this research: to screen for breast cancer in women who have just given birth. Now, it needs to be validated in a larger group of women in a clinical trial.”
 

More direct contact with tumor cells

In Dr. Saura’s opinion, in Spain, just like taking a small blood sample from newborns in a heel-prick test to rule out metabolic diseases, milk samples could be taken from women who give birth to rule out or diagnose breast cancer.

As to the potential advantages that breast milk liquid biopsy could have over similar techniques like blood liquid biopsy, Dr. Vivancos pointed to the results of her study: “We have seen that breast milk liquid biopsy was positive for the presence of circulating tumor DNA in 87% of cases, whereas blood only revealed the presence of this marker in 8% of cases. This difference indicates that breast milk is a biofluid that is in more direct contact with tumor cells and therefore will be more informative in earlier stages.”

Dr. Saura explained that the data does not lie when it comes to these tumors in pregnant or postpartum women. “In general, they tend to have a worse prognosis because, in most cases, they are diagnosed in advanced stages. Furthermore, it is typically assumed that the physiological changes in the breasts during gestation and lactation, which are considered to be normal, may hide a developing tumor. The fact is that postpartum breast cancer, understood to be the 10 years after delivery, accounts for 40%-45% of breast cancer cases diagnosed before age 45.”

The researchers plan to continue this project. “Our next step to confirm the usefulness of breast milk as a new tool for liquid biopsy for early detection of breast cancer during the postpartum period is to perform this noninvasive test in thousands of women,” said Dr. Saura.
 

Goal: Standardize the test as a screening method

“Based on the results we’ve published, we’re starting a study aimed at collecting breast milk samples from 5,000 healthy women around the world who became pregnant at age 40 or older, or who got pregnant at any age and carry mutations that increase their risk of breast cancer,” Dr. Saura added.

When asked when they expect to have preliminary results from this new study, Dr. Saura stated that it’s not yet possible to say exactly when. “We’re still waiting for funding to continue this project, but we continue performing analyses on a case-by-case basis. Of course, if we detect any abnormalities in these women, we will follow the established protocol to confirm diagnosis and start treatment if necessary.”

When asked whether it is reasonable to expect breast milk liquid biopsy to become normalized as a screening method for women of childbearing age who have a history or risk factors for developing breast cancer, Dr. Vivancos said, “That’s the scenario we see in the future and what we wish to contribute toward by providing scientific evidence to make it a reality.”

“For now, our goal is to validate whether circulating tumor DNA can be detected by breast milk liquid biopsy even before breast cancer can be diagnosed using conventional imaging techniques. If we can validate these preliminary results, we will be able to detect breast cancer early using a noninvasive test like breast milk liquid biopsy,” explained Saura.

Lastly, and in view of the issues that are still unresolved when it comes to the detection and treatment of breast cancer during pregnancy, Dr. Saura highlighted the emotional impact that a diagnosis of pregnancy-related cancer has on women and on those close to them. “But the first thing they need to know is that diagnosis is not necessarily synonymous with termination of the pregnancy. On the contrary, this tumor can be treated during pregnancy, since surgery can be performed at any time, and chemotherapy can be started in the second trimester. Proof of this is the 72 children who have been born under these circumstances in the past 20 years at the Vall d’Hebrón University Hospital. This hospital is a pioneer in Spain thanks to its multidisciplinary program for education and specific follow-up with women who have been diagnosed with a breast tumor during pregnancy.”

Dr. Saura and Dr. Vivancos reported no relevant financial relationships.

This article was translated from the Medscape Spanish edition. A version of this article appeared on Medscape.com.

Breast cancer has a worse prognosis when diagnosed during pregnancy or postpartum. Methods for early detection are needed, as evidenced every day in the multidisciplinary unit for treating pregnancy-associated breast cancer, which operates within the breast unit at the Vall d’Hebron University Hospital in Barcelona.

The team working in this field is led by Cristina Saura, PhD, who is also head of the Breast Cancer Group at the Vall d’Hebron Institute of Oncology (VHIO). The results of a study recently published in Cancer Discovery show, for the first time, that breast milk from breast cancer patients contains circulating tumor DNA that can be detected by a liquid biopsy of the milk.

Dr. Saura explained in an interview why they began to pursue this research, which, in one sense, fell into their laps. “In this case, it arose from the concerns of a breast cancer patient who was diagnosed while pregnant with her third daughter. She was actually the one who came up with the idea for the project. She was worried that she had transmitted the tumor through her breast milk to her second daughter while breastfeeding. She had been breastfeeding for a long time and had stretched it out until shortly before she was diagnosed with breast cancer. So she brought us a sample of breast milk that she had stored in her freezer.

“So, thanks to her, that’s where our project started. Though we knew that breast cancer is not transmitted through breast milk, we decided to test the sample and look for markers that could help our research. In the end, when we analyzed the patient’s breast milk, we found DNA with the same mutation that was present in her tumor,” explained Dr. Saura. She noted that the breast milk they analyzed had been frozen for more than a year before the patient’s cancer diagnosis.

In terms of methodology, Ana Vivancos, PhD, head of the VHIO cancer genomics group and also one of the authors of the study, explained that they used two techniques to analyze the breast milk and blood samples: next-generation sequencing and droplet digital polymerase chain reaction. These methods confirmed the presence of ctDNA in the breast milk.
 

High-sensitivity genomic panel

“We were able to detect tumor mutations in milk samples from 13 of the 15 patients with breast cancer who were tested, while circulating tumor DNA was detected in only one of all the blood samples that were collected at the same time,” said Dr. Vivancos. “The samples from the two patients for whom no mutation was detected were discovered to be colostrum that had been collected during the first few hours of lactation.”

As a next step to make this finding practically useful, the research team designed a genomic panel using next-generation sequencing as a potential method for early detection of breast cancer. “We’ve developed a panel that uses hybrid capture chemistry and unique molecular identifiers that ensure better sensitivity during next-generation sequencing. The panel has been calibrated, based on the existing literature, to detect the genes that are most frequently mutated in breast cancer in young women under 45 years old.”

According to Dr. Vivancos, the sensitivity of this panel exceeds 70%. This means that for all the patient samples analyzed using this panel, 7 out of 10 cases are detected with 100% specificity.

“In practice, the panel design allows us to detect mutations in more than 95% of breast cancer cases in women under 45 years old. Therefore, using this panel for early detection of this type of tumor during lactation should contribute to addressing a medical need that, until today, has gone unmet,” noted Dr. Vivancos.

As for this unresolved need, Dr. Saura explained that there is currently no system or tool available to allow early suspicion of breast tumors in pregnant women prior to diagnosis. “That’s exactly the goal of this research: to screen for breast cancer in women who have just given birth. Now, it needs to be validated in a larger group of women in a clinical trial.”
 

More direct contact with tumor cells

In Dr. Saura’s opinion, in Spain, just like taking a small blood sample from newborns in a heel-prick test to rule out metabolic diseases, milk samples could be taken from women who give birth to rule out or diagnose breast cancer.

As to the potential advantages that breast milk liquid biopsy could have over similar techniques like blood liquid biopsy, Dr. Vivancos pointed to the results of her study: “We have seen that breast milk liquid biopsy was positive for the presence of circulating tumor DNA in 87% of cases, whereas blood only revealed the presence of this marker in 8% of cases. This difference indicates that breast milk is a biofluid that is in more direct contact with tumor cells and therefore will be more informative in earlier stages.”

Dr. Saura explained that the data does not lie when it comes to these tumors in pregnant or postpartum women. “In general, they tend to have a worse prognosis because, in most cases, they are diagnosed in advanced stages. Furthermore, it is typically assumed that the physiological changes in the breasts during gestation and lactation, which are considered to be normal, may hide a developing tumor. The fact is that postpartum breast cancer, understood to be the 10 years after delivery, accounts for 40%-45% of breast cancer cases diagnosed before age 45.”

The researchers plan to continue this project. “Our next step to confirm the usefulness of breast milk as a new tool for liquid biopsy for early detection of breast cancer during the postpartum period is to perform this noninvasive test in thousands of women,” said Dr. Saura.
 

Goal: Standardize the test as a screening method

“Based on the results we’ve published, we’re starting a study aimed at collecting breast milk samples from 5,000 healthy women around the world who became pregnant at age 40 or older, or who got pregnant at any age and carry mutations that increase their risk of breast cancer,” Dr. Saura added.

When asked when they expect to have preliminary results from this new study, Dr. Saura stated that it’s not yet possible to say exactly when. “We’re still waiting for funding to continue this project, but we continue performing analyses on a case-by-case basis. Of course, if we detect any abnormalities in these women, we will follow the established protocol to confirm diagnosis and start treatment if necessary.”

When asked whether it is reasonable to expect breast milk liquid biopsy to become normalized as a screening method for women of childbearing age who have a history or risk factors for developing breast cancer, Dr. Vivancos said, “That’s the scenario we see in the future and what we wish to contribute toward by providing scientific evidence to make it a reality.”

“For now, our goal is to validate whether circulating tumor DNA can be detected by breast milk liquid biopsy even before breast cancer can be diagnosed using conventional imaging techniques. If we can validate these preliminary results, we will be able to detect breast cancer early using a noninvasive test like breast milk liquid biopsy,” explained Saura.

Lastly, and in view of the issues that are still unresolved when it comes to the detection and treatment of breast cancer during pregnancy, Dr. Saura highlighted the emotional impact that a diagnosis of pregnancy-related cancer has on women and on those close to them. “But the first thing they need to know is that diagnosis is not necessarily synonymous with termination of the pregnancy. On the contrary, this tumor can be treated during pregnancy, since surgery can be performed at any time, and chemotherapy can be started in the second trimester. Proof of this is the 72 children who have been born under these circumstances in the past 20 years at the Vall d’Hebrón University Hospital. This hospital is a pioneer in Spain thanks to its multidisciplinary program for education and specific follow-up with women who have been diagnosed with a breast tumor during pregnancy.”

Dr. Saura and Dr. Vivancos reported no relevant financial relationships.

This article was translated from the Medscape Spanish edition. A version of this article appeared on Medscape.com.

SAN DIEGO – Treatment with benralizumab (Fasenra) achieved remission at 36 and 48 weeks at rates similar to those of mepolizumab (Nucala) in a head-to-head phase 3 trial of the two drugs for patients with a relapsing or refractory case of the rare vasculitis eosinophilic granulomatosis with polyangiitis (EGPA).

Benralizumab, a monoclonal antibody from AstraZeneca that binds to the alpha chain of the interleukin (IL)-5 receptor, is indicated as an add-on maintenance treatment for patients 12 years and older with severe eosinophilic asthma but is not currently approved for EGPA. Mepolizumab is a humanized monoclonal antibody targeting IL-5 and the only approved drug for EGPA.

Peter A. Merkel, MD, presented the trial, known as MANDARA, during a late-breaking poster session at the annual meeting of the American College of Rheumatology. A total of 140 patients with EGPA received either subcutaneous benralizumab 30 mg or mepolizumab 300 mg every 4 weeks for 52 weeks. The trial, which began recruitment in late 2019, was limited to patients at least 18 years of age with relapsing/refractory EGPA that required stable use of oral glucocorticoids (OGCs) and immunosuppressive therapy for at least 4 weeks prior to randomization, and the primary endpoint was the proportion of patients who achieved remission at weeks 36 and 48. Remission was defined as a Birmingham Vasculitis Activity Score (BVAS) of 0 plus an OGC dose of no more than 4 mg/day. Secondary endpoints included rates of accrued and maintained remission, OGC use, clinical benefit and complete response, blood eosinophil counts, total BVAS, and Vascular Damage Index scores. The mean age of the 140 patients was 52 years, and 60% were women.

Dr. Merkel and colleagues reported that the adjusted remission rate at both weeks 36 and 48 was 59.2% for those in the benralizumab arm and 56.5% for those in the mepolizumab arm (P = .7278). The percentage of patients who achieved a BVAS of 0 was similar between the two arms (83% in the benralizumab arm vs. 84.2% for those in the mepolizumab arm; P = .8502), as was the percentage of patients on an OGC dose of up to 4 mg/day (62.1% vs. 57.9%; P = .5942). At 48-52 weeks, 86.1% of patients in the benralizumab arm achieved up to a 50% reduction in OGC use, compared with 73.9% of those in the mepolizumab arm (P = .0611), and 41.4% of patients in the benralizumab arm achieved a 100% reduction in OGC use, compared with 25.8% of those in the mepolizumab arm (P = .0406).

In findings related to safety, the top three adverse events were COVID-19 (21.4% in the benralizumab arm vs. 27.1% in the mepolizumab arm, respectively), headache (17.1% vs. 15.7%), and arthralgia (17.1% vs. 11.4%).

“We were pleased with the findings because they met our expectations,” Dr. Merkel, chief of rheumatology and professor of medicine and epidemiology at the University of Pennsylvania, Philadelphia, said in an interview. “The hypothesis was that these two drugs would be equivalent and safe. The implication for patients is that they’ll have another treatment option for EGPA, which is an underrecognized disease with need for more effective treatments. I anticipate that the drug will be approved for use in EGPA, providing another option for treating this complicated multisystem eosinophilic-associated disease. Having more options for our biologic therapies is good.”

He characterized the retention of patients in MANDARA as “remarkable, despite the COVID-19 pandemic. Patients with rare diseases are quite dedicated to helping conduct research. They know that their disease is not common and that they could help others.”

The study was sponsored and funded by AstraZeneca. Dr. Merkel disclosed that he has received consulting fees and research support from many pharmaceutical companies, including AstraZeneca.

SAN DIEGO – Treatment with benralizumab (Fasenra) achieved remission at 36 and 48 weeks at rates similar to those of mepolizumab (Nucala) in a head-to-head phase 3 trial of the two drugs for patients with a relapsing or refractory case of the rare vasculitis eosinophilic granulomatosis with polyangiitis (EGPA).

Benralizumab, a monoclonal antibody from AstraZeneca that binds to the alpha chain of the interleukin (IL)-5 receptor, is indicated as an add-on maintenance treatment for patients 12 years and older with severe eosinophilic asthma but is not currently approved for EGPA. Mepolizumab is a humanized monoclonal antibody targeting IL-5 and the only approved drug for EGPA.

Peter A. Merkel, MD, presented the trial, known as MANDARA, during a late-breaking poster session at the annual meeting of the American College of Rheumatology. A total of 140 patients with EGPA received either subcutaneous benralizumab 30 mg or mepolizumab 300 mg every 4 weeks for 52 weeks. The trial, which began recruitment in late 2019, was limited to patients at least 18 years of age with relapsing/refractory EGPA that required stable use of oral glucocorticoids (OGCs) and immunosuppressive therapy for at least 4 weeks prior to randomization, and the primary endpoint was the proportion of patients who achieved remission at weeks 36 and 48. Remission was defined as a Birmingham Vasculitis Activity Score (BVAS) of 0 plus an OGC dose of no more than 4 mg/day. Secondary endpoints included rates of accrued and maintained remission, OGC use, clinical benefit and complete response, blood eosinophil counts, total BVAS, and Vascular Damage Index scores. The mean age of the 140 patients was 52 years, and 60% were women.

Dr. Merkel and colleagues reported that the adjusted remission rate at both weeks 36 and 48 was 59.2% for those in the benralizumab arm and 56.5% for those in the mepolizumab arm (P = .7278). The percentage of patients who achieved a BVAS of 0 was similar between the two arms (83% in the benralizumab arm vs. 84.2% for those in the mepolizumab arm; P = .8502), as was the percentage of patients on an OGC dose of up to 4 mg/day (62.1% vs. 57.9%; P = .5942). At 48-52 weeks, 86.1% of patients in the benralizumab arm achieved up to a 50% reduction in OGC use, compared with 73.9% of those in the mepolizumab arm (P = .0611), and 41.4% of patients in the benralizumab arm achieved a 100% reduction in OGC use, compared with 25.8% of those in the mepolizumab arm (P = .0406).

In findings related to safety, the top three adverse events were COVID-19 (21.4% in the benralizumab arm vs. 27.1% in the mepolizumab arm, respectively), headache (17.1% vs. 15.7%), and arthralgia (17.1% vs. 11.4%).

“We were pleased with the findings because they met our expectations,” Dr. Merkel, chief of rheumatology and professor of medicine and epidemiology at the University of Pennsylvania, Philadelphia, said in an interview. “The hypothesis was that these two drugs would be equivalent and safe. The implication for patients is that they’ll have another treatment option for EGPA, which is an underrecognized disease with need for more effective treatments. I anticipate that the drug will be approved for use in EGPA, providing another option for treating this complicated multisystem eosinophilic-associated disease. Having more options for our biologic therapies is good.”

He characterized the retention of patients in MANDARA as “remarkable, despite the COVID-19 pandemic. Patients with rare diseases are quite dedicated to helping conduct research. They know that their disease is not common and that they could help others.”

The study was sponsored and funded by AstraZeneca. Dr. Merkel disclosed that he has received consulting fees and research support from many pharmaceutical companies, including AstraZeneca.

SAN DIEGO – Treatment with benralizumab (Fasenra) achieved remission at 36 and 48 weeks at rates similar to those of mepolizumab (Nucala) in a head-to-head phase 3 trial of the two drugs for patients with a relapsing or refractory case of the rare vasculitis eosinophilic granulomatosis with polyangiitis (EGPA).

Benralizumab, a monoclonal antibody from AstraZeneca that binds to the alpha chain of the interleukin (IL)-5 receptor, is indicated as an add-on maintenance treatment for patients 12 years and older with severe eosinophilic asthma but is not currently approved for EGPA. Mepolizumab is a humanized monoclonal antibody targeting IL-5 and the only approved drug for EGPA.

Peter A. Merkel, MD, presented the trial, known as MANDARA, during a late-breaking poster session at the annual meeting of the American College of Rheumatology. A total of 140 patients with EGPA received either subcutaneous benralizumab 30 mg or mepolizumab 300 mg every 4 weeks for 52 weeks. The trial, which began recruitment in late 2019, was limited to patients at least 18 years of age with relapsing/refractory EGPA that required stable use of oral glucocorticoids (OGCs) and immunosuppressive therapy for at least 4 weeks prior to randomization, and the primary endpoint was the proportion of patients who achieved remission at weeks 36 and 48. Remission was defined as a Birmingham Vasculitis Activity Score (BVAS) of 0 plus an OGC dose of no more than 4 mg/day. Secondary endpoints included rates of accrued and maintained remission, OGC use, clinical benefit and complete response, blood eosinophil counts, total BVAS, and Vascular Damage Index scores. The mean age of the 140 patients was 52 years, and 60% were women.

Dr. Merkel and colleagues reported that the adjusted remission rate at both weeks 36 and 48 was 59.2% for those in the benralizumab arm and 56.5% for those in the mepolizumab arm (P = .7278). The percentage of patients who achieved a BVAS of 0 was similar between the two arms (83% in the benralizumab arm vs. 84.2% for those in the mepolizumab arm; P = .8502), as was the percentage of patients on an OGC dose of up to 4 mg/day (62.1% vs. 57.9%; P = .5942). At 48-52 weeks, 86.1% of patients in the benralizumab arm achieved up to a 50% reduction in OGC use, compared with 73.9% of those in the mepolizumab arm (P = .0611), and 41.4% of patients in the benralizumab arm achieved a 100% reduction in OGC use, compared with 25.8% of those in the mepolizumab arm (P = .0406).

In findings related to safety, the top three adverse events were COVID-19 (21.4% in the benralizumab arm vs. 27.1% in the mepolizumab arm, respectively), headache (17.1% vs. 15.7%), and arthralgia (17.1% vs. 11.4%).

“We were pleased with the findings because they met our expectations,” Dr. Merkel, chief of rheumatology and professor of medicine and epidemiology at the University of Pennsylvania, Philadelphia, said in an interview. “The hypothesis was that these two drugs would be equivalent and safe. The implication for patients is that they’ll have another treatment option for EGPA, which is an underrecognized disease with need for more effective treatments. I anticipate that the drug will be approved for use in EGPA, providing another option for treating this complicated multisystem eosinophilic-associated disease. Having more options for our biologic therapies is good.”

He characterized the retention of patients in MANDARA as “remarkable, despite the COVID-19 pandemic. Patients with rare diseases are quite dedicated to helping conduct research. They know that their disease is not common and that they could help others.”

The study was sponsored and funded by AstraZeneca. Dr. Merkel disclosed that he has received consulting fees and research support from many pharmaceutical companies, including AstraZeneca.

Worsening heart failure is accompanied by a build-up of fluid in the lungs. An AI smartphone app that picks up changes in a heart failure patient’s voice quality caused by this fluid accumulation and then alerts the physician about them – nearly 3 weeks before that ongoing decompensation would necessitate hospitalization and/or lead the physician to urgently introduce intravenous diuretics – is getting experts to sit up and take notice.

“In this incredibly prevalent waxing and waning condition, finding ways to identify worsening heart failure to prevent hospitalization and progressive disease is incredibly important,” observed American Heart Association (AHA)-appointed discussant David Ouyang, MD, assistant professor, Smidt Heart Institute, Division of Artificial Intelligence in Medicine, Cedars Sinai, Los Angeles. “Heart failure remains among the most common causes of hospitalization for older adults in the United States.

“The other standout feature is that we all use our cell phones on a daily basis,” Dr. Ouyang said at a late-breaking trial press briefing at the AHA 2023 annual meeting where results of the HearO Community Study were presented. “The ability to capture data from routine speech (patients speak five sentences into their phones every morning) is remarkable ... The HearO^® technology was able to detect a substantial proportion of worsening heart failure events, with an average per individual of only three false positives over the course of a year. And, adherence to the study protocol was 81%. That’s higher than in many other kinds of routine patient monitoring studies,” he added.
 

Accumulating fluid changes speech

Increased hydration may affect speech parameters such as pitch, volume, and dynamics through swelling of soft tissues in the vocal tract (e.g., pharynx, velum, tongue, and vocal folds). In the Israeli study, investigators enrolled 416 adults (75% were male, average age was 68 years) whose New York Heart Association (NYHA) 2-3 heart failure with either reduced or preserved ejection fraction was stable but placed them at-risk for heart failure events. The study goal was to analyze their speech data using the HearO^® system to refine and test its ability to detect impending heart failure deterioration. Patients recorded five sentences in their native language (Hebrew, Russian, Arabic, or English) into the smartphone app daily. In a training phase of the study, distinct speech measures from 263 participants were used to develop the AI algorithm. Then, the algorithm was used in the remaining 153 participants to validate the tool’s effectiveness. In its ultimate form, once a deviation from the patient’s predefined baseline is detected, the app will generate a notice and send it to the health care practitioners.

Lead study author William T. Abraham, MD, FAHA, professor of medicine, physiology, and cell biology; and a College of Medicine Distinguished Professor in the division of cardiovascular medicine at The Ohio State University in Columbus, reported that between Mar. 27, 2018, and Nov. 30, 2021, subjects in the training phase made recordings on 83% of days. They were followed for up to 44 months. The test group made recordings on 81% of days between Feb. 1, 2020, and Apr. 30, 2023, and were followed for up to 31 months. Heart failure events were defined as hospitalization or outpatient intravenous diuretic treatment for worsening heart failure.

In the training phase, the app accurately predicted 44 of 58 heart failure events (76%) and 81% of first events (n = 35) on average 24 days before hospitalization or need for intravenous fluids. In the validation phase, the app was 71% accurate in detecting 10 of 14 heart failure events and 77% of first events (n = 10) on average 26 days in advance of events. In both periods, the app generated about 3 unnecessary alerts per patient year.

Dr. Abraham concluded, “This technology has the potential to improve patient outcomes, keeping patients well and out of the hospital, through the implementation of proactive, outpatient care in response to voice changes.”

The HearO^® technology is being evaluated in an ongoing pivotal trial in the United State4s, Dr. Abraham said. The study is limited, he added, by the small number of patients and heart failure events, particularly in the test group.

“We continue to struggle with the burden of heart failure morbidity,” observed AHA press briefing moderator (and past AHA president) Clyde Yancy, MD, Magerstadt Professor at Northwestern University, Chicago. “So any tool that we can utilize and further refine that helps us address the need for hospitalization becomes very important. The idea that speech evaluation might give us sufficient early warning to forestall any admissions – and consider the cost savings attributable to that – is a very credible goal that we should continue to follow.” He pointed out that the technology enables assessments in the home environment for older patients who are less mobile.

In response to a press briefing question about the potential for physicians to be trained to hear early subtle voice changes on their own, Dr. Abraham stated, “I guess that is unknown, but the important difference is the system’s ability to take data in every day from patients and then process it automatically with AI.”

Joining in, Dr. Yancy said, “You know, this is interesting because even if you saw a patient once a month, which is an incredible frequency for any practice, there’s still 353 days that you haven’t seen the patient.” He noted that the AHA had just announced a multi-million dollar program to more deeply understand telemanagement. “So I think this is here to stay,” Dr. Yancy said.

Dr. Ouyang posed a further question. “Like with most AI recognition tools, we can now identify individuals at risk. How do we get from that step of identifying those at risk to improving their outcomes? This has been a critical question about heart failure, remote management, and remote monitoring, and I think it is a critical question for many of our AI tools.”

Dr. Abraham disclosed that he has received personal fees from Cordio Medical. Dr. Ouyang said that he had no disclosures relevant to this presentation.

Worsening heart failure is accompanied by a build-up of fluid in the lungs. An AI smartphone app that picks up changes in a heart failure patient’s voice quality caused by this fluid accumulation and then alerts the physician about them – nearly 3 weeks before that ongoing decompensation would necessitate hospitalization and/or lead the physician to urgently introduce intravenous diuretics – is getting experts to sit up and take notice.

“In this incredibly prevalent waxing and waning condition, finding ways to identify worsening heart failure to prevent hospitalization and progressive disease is incredibly important,” observed American Heart Association (AHA)-appointed discussant David Ouyang, MD, assistant professor, Smidt Heart Institute, Division of Artificial Intelligence in Medicine, Cedars Sinai, Los Angeles. “Heart failure remains among the most common causes of hospitalization for older adults in the United States.

“The other standout feature is that we all use our cell phones on a daily basis,” Dr. Ouyang said at a late-breaking trial press briefing at the AHA 2023 annual meeting where results of the HearO Community Study were presented. “The ability to capture data from routine speech (patients speak five sentences into their phones every morning) is remarkable ... The HearO^® technology was able to detect a substantial proportion of worsening heart failure events, with an average per individual of only three false positives over the course of a year. And, adherence to the study protocol was 81%. That’s higher than in many other kinds of routine patient monitoring studies,” he added.
 

Accumulating fluid changes speech

Increased hydration may affect speech parameters such as pitch, volume, and dynamics through swelling of soft tissues in the vocal tract (e.g., pharynx, velum, tongue, and vocal folds). In the Israeli study, investigators enrolled 416 adults (75% were male, average age was 68 years) whose New York Heart Association (NYHA) 2-3 heart failure with either reduced or preserved ejection fraction was stable but placed them at-risk for heart failure events. The study goal was to analyze their speech data using the HearO^® system to refine and test its ability to detect impending heart failure deterioration. Patients recorded five sentences in their native language (Hebrew, Russian, Arabic, or English) into the smartphone app daily. In a training phase of the study, distinct speech measures from 263 participants were used to develop the AI algorithm. Then, the algorithm was used in the remaining 153 participants to validate the tool’s effectiveness. In its ultimate form, once a deviation from the patient’s predefined baseline is detected, the app will generate a notice and send it to the health care practitioners.

Lead study author William T. Abraham, MD, FAHA, professor of medicine, physiology, and cell biology; and a College of Medicine Distinguished Professor in the division of cardiovascular medicine at The Ohio State University in Columbus, reported that between Mar. 27, 2018, and Nov. 30, 2021, subjects in the training phase made recordings on 83% of days. They were followed for up to 44 months. The test group made recordings on 81% of days between Feb. 1, 2020, and Apr. 30, 2023, and were followed for up to 31 months. Heart failure events were defined as hospitalization or outpatient intravenous diuretic treatment for worsening heart failure.

In the training phase, the app accurately predicted 44 of 58 heart failure events (76%) and 81% of first events (n = 35) on average 24 days before hospitalization or need for intravenous fluids. In the validation phase, the app was 71% accurate in detecting 10 of 14 heart failure events and 77% of first events (n = 10) on average 26 days in advance of events. In both periods, the app generated about 3 unnecessary alerts per patient year.

Dr. Abraham concluded, “This technology has the potential to improve patient outcomes, keeping patients well and out of the hospital, through the implementation of proactive, outpatient care in response to voice changes.”

The HearO^® technology is being evaluated in an ongoing pivotal trial in the United State4s, Dr. Abraham said. The study is limited, he added, by the small number of patients and heart failure events, particularly in the test group.

“We continue to struggle with the burden of heart failure morbidity,” observed AHA press briefing moderator (and past AHA president) Clyde Yancy, MD, Magerstadt Professor at Northwestern University, Chicago. “So any tool that we can utilize and further refine that helps us address the need for hospitalization becomes very important. The idea that speech evaluation might give us sufficient early warning to forestall any admissions – and consider the cost savings attributable to that – is a very credible goal that we should continue to follow.” He pointed out that the technology enables assessments in the home environment for older patients who are less mobile.

In response to a press briefing question about the potential for physicians to be trained to hear early subtle voice changes on their own, Dr. Abraham stated, “I guess that is unknown, but the important difference is the system’s ability to take data in every day from patients and then process it automatically with AI.”

Joining in, Dr. Yancy said, “You know, this is interesting because even if you saw a patient once a month, which is an incredible frequency for any practice, there’s still 353 days that you haven’t seen the patient.” He noted that the AHA had just announced a multi-million dollar program to more deeply understand telemanagement. “So I think this is here to stay,” Dr. Yancy said.

Dr. Ouyang posed a further question. “Like with most AI recognition tools, we can now identify individuals at risk. How do we get from that step of identifying those at risk to improving their outcomes? This has been a critical question about heart failure, remote management, and remote monitoring, and I think it is a critical question for many of our AI tools.”

Dr. Abraham disclosed that he has received personal fees from Cordio Medical. Dr. Ouyang said that he had no disclosures relevant to this presentation.

Worsening heart failure is accompanied by a build-up of fluid in the lungs. An AI smartphone app that picks up changes in a heart failure patient’s voice quality caused by this fluid accumulation and then alerts the physician about them – nearly 3 weeks before that ongoing decompensation would necessitate hospitalization and/or lead the physician to urgently introduce intravenous diuretics – is getting experts to sit up and take notice.

“In this incredibly prevalent waxing and waning condition, finding ways to identify worsening heart failure to prevent hospitalization and progressive disease is incredibly important,” observed American Heart Association (AHA)-appointed discussant David Ouyang, MD, assistant professor, Smidt Heart Institute, Division of Artificial Intelligence in Medicine, Cedars Sinai, Los Angeles. “Heart failure remains among the most common causes of hospitalization for older adults in the United States.

“The other standout feature is that we all use our cell phones on a daily basis,” Dr. Ouyang said at a late-breaking trial press briefing at the AHA 2023 annual meeting where results of the HearO Community Study were presented. “The ability to capture data from routine speech (patients speak five sentences into their phones every morning) is remarkable ... The HearO^® technology was able to detect a substantial proportion of worsening heart failure events, with an average per individual of only three false positives over the course of a year. And, adherence to the study protocol was 81%. That’s higher than in many other kinds of routine patient monitoring studies,” he added.
 

Accumulating fluid changes speech

Increased hydration may affect speech parameters such as pitch, volume, and dynamics through swelling of soft tissues in the vocal tract (e.g., pharynx, velum, tongue, and vocal folds). In the Israeli study, investigators enrolled 416 adults (75% were male, average age was 68 years) whose New York Heart Association (NYHA) 2-3 heart failure with either reduced or preserved ejection fraction was stable but placed them at-risk for heart failure events. The study goal was to analyze their speech data using the HearO^® system to refine and test its ability to detect impending heart failure deterioration. Patients recorded five sentences in their native language (Hebrew, Russian, Arabic, or English) into the smartphone app daily. In a training phase of the study, distinct speech measures from 263 participants were used to develop the AI algorithm. Then, the algorithm was used in the remaining 153 participants to validate the tool’s effectiveness. In its ultimate form, once a deviation from the patient’s predefined baseline is detected, the app will generate a notice and send it to the health care practitioners.

Lead study author William T. Abraham, MD, FAHA, professor of medicine, physiology, and cell biology; and a College of Medicine Distinguished Professor in the division of cardiovascular medicine at The Ohio State University in Columbus, reported that between Mar. 27, 2018, and Nov. 30, 2021, subjects in the training phase made recordings on 83% of days. They were followed for up to 44 months. The test group made recordings on 81% of days between Feb. 1, 2020, and Apr. 30, 2023, and were followed for up to 31 months. Heart failure events were defined as hospitalization or outpatient intravenous diuretic treatment for worsening heart failure.

In the training phase, the app accurately predicted 44 of 58 heart failure events (76%) and 81% of first events (n = 35) on average 24 days before hospitalization or need for intravenous fluids. In the validation phase, the app was 71% accurate in detecting 10 of 14 heart failure events and 77% of first events (n = 10) on average 26 days in advance of events. In both periods, the app generated about 3 unnecessary alerts per patient year.

Dr. Abraham concluded, “This technology has the potential to improve patient outcomes, keeping patients well and out of the hospital, through the implementation of proactive, outpatient care in response to voice changes.”

The HearO^® technology is being evaluated in an ongoing pivotal trial in the United State4s, Dr. Abraham said. The study is limited, he added, by the small number of patients and heart failure events, particularly in the test group.

“We continue to struggle with the burden of heart failure morbidity,” observed AHA press briefing moderator (and past AHA president) Clyde Yancy, MD, Magerstadt Professor at Northwestern University, Chicago. “So any tool that we can utilize and further refine that helps us address the need for hospitalization becomes very important. The idea that speech evaluation might give us sufficient early warning to forestall any admissions – and consider the cost savings attributable to that – is a very credible goal that we should continue to follow.” He pointed out that the technology enables assessments in the home environment for older patients who are less mobile.

In response to a press briefing question about the potential for physicians to be trained to hear early subtle voice changes on their own, Dr. Abraham stated, “I guess that is unknown, but the important difference is the system’s ability to take data in every day from patients and then process it automatically with AI.”

Joining in, Dr. Yancy said, “You know, this is interesting because even if you saw a patient once a month, which is an incredible frequency for any practice, there’s still 353 days that you haven’t seen the patient.” He noted that the AHA had just announced a multi-million dollar program to more deeply understand telemanagement. “So I think this is here to stay,” Dr. Yancy said.

Dr. Ouyang posed a further question. “Like with most AI recognition tools, we can now identify individuals at risk. How do we get from that step of identifying those at risk to improving their outcomes? This has been a critical question about heart failure, remote management, and remote monitoring, and I think it is a critical question for many of our AI tools.”

Dr. Abraham disclosed that he has received personal fees from Cordio Medical. Dr. Ouyang said that he had no disclosures relevant to this presentation.

PHILADELPHIA – The first in-human study of a gene therapy designed to reduce low-density lipoprotein cholesterol has shown a signal that the treatment works in a small group of patients with heterozygous familial hypercholesterolemia (HeFH).

While one of four patients in the highest-dose groups had a myocardial infarction the day after getting the treatment, investigators have enough confidence to go forward with the next phase of study.

“The HEART-1trial demonstrated the first human proof of concept for in vivo DNA-based editing,” said Andrew Bellinger, MD, PhD, chief scientific officer of Verve Therapeutics, the company developing the treatment. “We saw dose-dependent–based reductions in LDL and the PCSK9 protein.”

The HEART-1 study was a phase 1b trial of VERVE-101, a CRISPR-based gene editing mechanism designed to inactivate the liver gene PCSK9, which contributes to raising cholesterol. “Human genetics suggest that turning off the cholesterol-raising gene PCSK9 in the liver will durably reduce LDL cholesterol,” Dr. Bellinger said in presenting the results at the annual scientific sessions of the American Heart Association.

Lipid nanoparticle

VERVE-101 is designed to be a single-course treatment to specifically treat HeFH, Dr. Bellinger said. He explained how the therapy, given by intravenous infusion, differs from adeno-associated virus vectors that have dominated gene therapy platforms.

“It’s a lipid nanoparticle encapsulating two RNA nanoparticles that are taken up by hepatocytes in the liver from the blood by the LDL receptor,” he explained. “Then the A-to-G–based editor protein and the guide mRNA protein together find the PCSK9 gene in the liver.” That single DNA-base change in one position of the PCSK9 gene is able to turn off PCSK9 production in those liver cells.

Dr. Bellinger presented interim results of the first 10 patients treated in the open-label, single ascending dose study. The patients were male and female, ages 18-75, with HeFH, established atherosclerotic cardiovascular disease and uncontrolled hypercholesterolemia despite being on maximally tolerated lipid-lowering therapy.

They received four different doses: Three patients each received 0.1, 0.3, and 0.45 mg/kg; and one patient received 0.6 mg/kg.

Reductions in blood PCSK9 levels were measured across all dosing groups at 4 weeks, but they were most pronounced in the two highest groups, Dr. Bellinger said. Two patients in the 0.45-mg/kg group had reductions of 59% and 84%. The sole patient in the 0.6-mg/kg arm had a reduction of 47%.

Regarding the 84% reduction in one individual, Dr. Bellinger said, “Roughly 85% of PCSK9 comes from the liver. These data suggest that we have successfully made a single base pair change in both copies of the PCSK9 gene in nearly every hepatocyte in the liver of this individual.”

Those benefits carried over to LDL cholesterol measures, with the highest-dose patients registering 39%, 48% and 55% reductions.
 

Safety outcomes

Two patients had serious cardiovascular (CV) events. One in the 0.3-mg/kg arm died from cardiac arrest 5 weeks after receiving the infusion. A patient in the 0.45-mg/kg arm had a myocardial infarction a day after getting the infusion and then nonsustained ventricular tachycardia (NSVT) 4 weeks later. Dr. Bellinger said an independent review panel determined that the CV events were in line with outcomes for high-risk patients and weren’t directly related to treatment.

He added, “Increased liver transaminases were seen in patients treated in the higher-dose cohorts. It’s transient, asymptomatic, and it resolved quickly.”

The next step involves pursuing only the 0.45- and 0.6-mg/kg doses in the next dose-escalation phase and enrolling an expansion cohort in 2024, Dr. Bellinger said, with a plan to initiate a randomized, placebo-controlled phase 2 trial in 2025.
 

First, do no harm

Karol Watson, MD, PhD, a women’s cardiovascular disease specialist at UCLA, said the promise of gene therapy was “revolutionary,” but that proving safety was critical going forward.

“You’re changing the genome forever,” she said. “Safety is going to be of the utmost importance especially because there are currently safe and efficacious strategies available for lipid lowering. This is a strategy that could be revolutionary, but we have to make sure that it’s safe.”

She pointed to a multinational study from earlier this year that warned about pathogenic consequences from CRISPR-based gene editing. “There are concerns about gene editing,” Dr. Watson said. “This was a whole-genome analysis showing atypical nonhomologous on-target effects of genome editing. Of course this is a very different strategy from what we heard today, but, again, we have to know that this is safe.”

Despite the small sample size from the two highest-dose groups in the study, Dr. Watson said the investigators have reason for going forward. “I think the preclinical data supports moving forward, but the next studies will have to be scrutinized carefully,” she said. “This is a preventive therapy; the first tenet is to do no harm.”

Dr. Bellinger is an employee of Verve Therapeutics, which sponsored the trial. Dr. Watson disclosed relationships with Boehringer-Ingelheim, Amgen, Lilly and Novartis.

PHILADELPHIA – The first in-human study of a gene therapy designed to reduce low-density lipoprotein cholesterol has shown a signal that the treatment works in a small group of patients with heterozygous familial hypercholesterolemia (HeFH).

While one of four patients in the highest-dose groups had a myocardial infarction the day after getting the treatment, investigators have enough confidence to go forward with the next phase of study.

“The HEART-1trial demonstrated the first human proof of concept for in vivo DNA-based editing,” said Andrew Bellinger, MD, PhD, chief scientific officer of Verve Therapeutics, the company developing the treatment. “We saw dose-dependent–based reductions in LDL and the PCSK9 protein.”

The HEART-1 study was a phase 1b trial of VERVE-101, a CRISPR-based gene editing mechanism designed to inactivate the liver gene PCSK9, which contributes to raising cholesterol. “Human genetics suggest that turning off the cholesterol-raising gene PCSK9 in the liver will durably reduce LDL cholesterol,” Dr. Bellinger said in presenting the results at the annual scientific sessions of the American Heart Association.

Lipid nanoparticle

VERVE-101 is designed to be a single-course treatment to specifically treat HeFH, Dr. Bellinger said. He explained how the therapy, given by intravenous infusion, differs from adeno-associated virus vectors that have dominated gene therapy platforms.

“It’s a lipid nanoparticle encapsulating two RNA nanoparticles that are taken up by hepatocytes in the liver from the blood by the LDL receptor,” he explained. “Then the A-to-G–based editor protein and the guide mRNA protein together find the PCSK9 gene in the liver.” That single DNA-base change in one position of the PCSK9 gene is able to turn off PCSK9 production in those liver cells.

Dr. Bellinger presented interim results of the first 10 patients treated in the open-label, single ascending dose study. The patients were male and female, ages 18-75, with HeFH, established atherosclerotic cardiovascular disease and uncontrolled hypercholesterolemia despite being on maximally tolerated lipid-lowering therapy.

They received four different doses: Three patients each received 0.1, 0.3, and 0.45 mg/kg; and one patient received 0.6 mg/kg.

Reductions in blood PCSK9 levels were measured across all dosing groups at 4 weeks, but they were most pronounced in the two highest groups, Dr. Bellinger said. Two patients in the 0.45-mg/kg group had reductions of 59% and 84%. The sole patient in the 0.6-mg/kg arm had a reduction of 47%.

Regarding the 84% reduction in one individual, Dr. Bellinger said, “Roughly 85% of PCSK9 comes from the liver. These data suggest that we have successfully made a single base pair change in both copies of the PCSK9 gene in nearly every hepatocyte in the liver of this individual.”

Those benefits carried over to LDL cholesterol measures, with the highest-dose patients registering 39%, 48% and 55% reductions.
 

Safety outcomes

Two patients had serious cardiovascular (CV) events. One in the 0.3-mg/kg arm died from cardiac arrest 5 weeks after receiving the infusion. A patient in the 0.45-mg/kg arm had a myocardial infarction a day after getting the infusion and then nonsustained ventricular tachycardia (NSVT) 4 weeks later. Dr. Bellinger said an independent review panel determined that the CV events were in line with outcomes for high-risk patients and weren’t directly related to treatment.

He added, “Increased liver transaminases were seen in patients treated in the higher-dose cohorts. It’s transient, asymptomatic, and it resolved quickly.”

The next step involves pursuing only the 0.45- and 0.6-mg/kg doses in the next dose-escalation phase and enrolling an expansion cohort in 2024, Dr. Bellinger said, with a plan to initiate a randomized, placebo-controlled phase 2 trial in 2025.
 

First, do no harm

Karol Watson, MD, PhD, a women’s cardiovascular disease specialist at UCLA, said the promise of gene therapy was “revolutionary,” but that proving safety was critical going forward.

“You’re changing the genome forever,” she said. “Safety is going to be of the utmost importance especially because there are currently safe and efficacious strategies available for lipid lowering. This is a strategy that could be revolutionary, but we have to make sure that it’s safe.”

She pointed to a multinational study from earlier this year that warned about pathogenic consequences from CRISPR-based gene editing. “There are concerns about gene editing,” Dr. Watson said. “This was a whole-genome analysis showing atypical nonhomologous on-target effects of genome editing. Of course this is a very different strategy from what we heard today, but, again, we have to know that this is safe.”

Despite the small sample size from the two highest-dose groups in the study, Dr. Watson said the investigators have reason for going forward. “I think the preclinical data supports moving forward, but the next studies will have to be scrutinized carefully,” she said. “This is a preventive therapy; the first tenet is to do no harm.”

Dr. Bellinger is an employee of Verve Therapeutics, which sponsored the trial. Dr. Watson disclosed relationships with Boehringer-Ingelheim, Amgen, Lilly and Novartis.

PHILADELPHIA – The first in-human study of a gene therapy designed to reduce low-density lipoprotein cholesterol has shown a signal that the treatment works in a small group of patients with heterozygous familial hypercholesterolemia (HeFH).

While one of four patients in the highest-dose groups had a myocardial infarction the day after getting the treatment, investigators have enough confidence to go forward with the next phase of study.

“The HEART-1trial demonstrated the first human proof of concept for in vivo DNA-based editing,” said Andrew Bellinger, MD, PhD, chief scientific officer of Verve Therapeutics, the company developing the treatment. “We saw dose-dependent–based reductions in LDL and the PCSK9 protein.”

The HEART-1 study was a phase 1b trial of VERVE-101, a CRISPR-based gene editing mechanism designed to inactivate the liver gene PCSK9, which contributes to raising cholesterol. “Human genetics suggest that turning off the cholesterol-raising gene PCSK9 in the liver will durably reduce LDL cholesterol,” Dr. Bellinger said in presenting the results at the annual scientific sessions of the American Heart Association.

Lipid nanoparticle

VERVE-101 is designed to be a single-course treatment to specifically treat HeFH, Dr. Bellinger said. He explained how the therapy, given by intravenous infusion, differs from adeno-associated virus vectors that have dominated gene therapy platforms.

“It’s a lipid nanoparticle encapsulating two RNA nanoparticles that are taken up by hepatocytes in the liver from the blood by the LDL receptor,” he explained. “Then the A-to-G–based editor protein and the guide mRNA protein together find the PCSK9 gene in the liver.” That single DNA-base change in one position of the PCSK9 gene is able to turn off PCSK9 production in those liver cells.

Dr. Bellinger presented interim results of the first 10 patients treated in the open-label, single ascending dose study. The patients were male and female, ages 18-75, with HeFH, established atherosclerotic cardiovascular disease and uncontrolled hypercholesterolemia despite being on maximally tolerated lipid-lowering therapy.

They received four different doses: Three patients each received 0.1, 0.3, and 0.45 mg/kg; and one patient received 0.6 mg/kg.

Reductions in blood PCSK9 levels were measured across all dosing groups at 4 weeks, but they were most pronounced in the two highest groups, Dr. Bellinger said. Two patients in the 0.45-mg/kg group had reductions of 59% and 84%. The sole patient in the 0.6-mg/kg arm had a reduction of 47%.

Regarding the 84% reduction in one individual, Dr. Bellinger said, “Roughly 85% of PCSK9 comes from the liver. These data suggest that we have successfully made a single base pair change in both copies of the PCSK9 gene in nearly every hepatocyte in the liver of this individual.”

Those benefits carried over to LDL cholesterol measures, with the highest-dose patients registering 39%, 48% and 55% reductions.
 

Safety outcomes

Two patients had serious cardiovascular (CV) events. One in the 0.3-mg/kg arm died from cardiac arrest 5 weeks after receiving the infusion. A patient in the 0.45-mg/kg arm had a myocardial infarction a day after getting the infusion and then nonsustained ventricular tachycardia (NSVT) 4 weeks later. Dr. Bellinger said an independent review panel determined that the CV events were in line with outcomes for high-risk patients and weren’t directly related to treatment.

He added, “Increased liver transaminases were seen in patients treated in the higher-dose cohorts. It’s transient, asymptomatic, and it resolved quickly.”

The next step involves pursuing only the 0.45- and 0.6-mg/kg doses in the next dose-escalation phase and enrolling an expansion cohort in 2024, Dr. Bellinger said, with a plan to initiate a randomized, placebo-controlled phase 2 trial in 2025.
 

First, do no harm

Karol Watson, MD, PhD, a women’s cardiovascular disease specialist at UCLA, said the promise of gene therapy was “revolutionary,” but that proving safety was critical going forward.

“You’re changing the genome forever,” she said. “Safety is going to be of the utmost importance especially because there are currently safe and efficacious strategies available for lipid lowering. This is a strategy that could be revolutionary, but we have to make sure that it’s safe.”

She pointed to a multinational study from earlier this year that warned about pathogenic consequences from CRISPR-based gene editing. “There are concerns about gene editing,” Dr. Watson said. “This was a whole-genome analysis showing atypical nonhomologous on-target effects of genome editing. Of course this is a very different strategy from what we heard today, but, again, we have to know that this is safe.”

Despite the small sample size from the two highest-dose groups in the study, Dr. Watson said the investigators have reason for going forward. “I think the preclinical data supports moving forward, but the next studies will have to be scrutinized carefully,” she said. “This is a preventive therapy; the first tenet is to do no harm.”

Dr. Bellinger is an employee of Verve Therapeutics, which sponsored the trial. Dr. Watson disclosed relationships with Boehringer-Ingelheim, Amgen, Lilly and Novartis.