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Disparate views on managing incidental imaging findings made during clinical research — particularly for unclear results — signal a need for standardized guidance, according to recent survey results.

Respondents were split on whether it was the site primary investigator’s responsibility to decide which incidental findings should be reported back to the patient, and the most commonly cited challenges included adequately explaining these findings and the follow-up required. These issues were most present when dealing with nonspecific incidental findings or findings of unclear importance, said lead author Jane S. Kang, MD, a bioethicist and associate professor of medicine in the Division of Rheumatology at Columbia University Irving Medical Center, New York City.

 

“It can be difficult to have a clear approach” when it comes to these situations that are not black and white, and it is hard to get a clear answer, she said in an interview.

The survey included responses from investigators from the Treatments Against Rheumatoid Arthritis and Effect on 18F-fluorodeoxyglucose (FDG) PET/CT (TARGET) trial, conducted between 2015 and 2021. The 24-week trial included patients from 28 centers in the United States to investigate how different disease-modifying antirheumatic drugs can reduce cardiovascular and joint inflammation, assessed via whole body FDG PET/CT. The survey was a planned substudy of the TARGET trial and is “the first study that examines researchers’ attitudes and beliefs regarding incidental research findings from whole body FDG PET/CT,” Kang and her coauthors wrote.

This news organization reported the main results of the TARGET trial in 2022.

Eighteen of the 28 site primary investigators (PIs) of the TARGET trial participated in the survey, which was published in Arthritis Care & Research in September 2024.

 

TARGET Trial Incidental Findings

The TARGET trial enrolled 159 patients, of whom 82% had at least one incidental finding and 62% had one or more FDG-avid incidental findings. There were 46 “clinically actionable findings” for 40 participants overall; the reading radiologists recommended additional imaging for 28 findings and specialist consultation or procedural evaluation for 15 findings.

Details on these incidental findings were presented in a poster at the annual meeting of the American College of Rheumatology (ACR), held in Washington, DC.

The most common non–FDG-avid findings were pulmonary nodules, diverticulosis, cholelithiasis, sinus disease, and vascular calcifications. The most common FDG-avid findings were hypermetabolic lymphadenopathy, increased gastric/esophageal uptake, increased bowel uptake, and increased pharyngeal uptake.

In the related survey, 11 respondents (61%) said they returned any incidental findings to participants and 5 (28%) did not; the remaining 2 respondents did not know.

Across all study PIs, 22% felt that incidental findings were beneficial, 39% said they were potentially beneficial, and 11% said they were potentially detrimental. PIs that ranked incidental findings as potentially detrimental pointed to how these findings led to invasive additional testing.

“One of my subjects was found to have diverticulosis, which needed an invasive procedure to rule out malignancy,” one respondent wrote. “However, the subject had already had a colonoscopy months prior to the PET findings, which was still not deemed sufficient by the nuclear radiologist and GI consultant, so he had to have another colonoscopy, which was benign, but uncomfortable.” 

 

Obligation to Return Findings

All investigators agreed that incidental findings should be shared with patients if they revealed a high-risk medical condition that can be treated; had important health implications such as premature death or substantial morbidity; and their health could be improved with proven preventive or therapeutic interventions.

There was more disagreement on whether to share that the FDG PET/CT revealed no findings or if the test revealed a finding without clear medical importance of which the research participant may not be aware.

An example of a less-specific finding could be something like increased FDG uptake in a particular area, like the bowel, Kang explained.

“The question is: What does that mean?” she said. “How do you interpret that?”

While some PIs might feel obligated to share all results with patients, sharing ambiguous incidental findings will likely not be helpful to the patient, said Arthur Caplan, PhD, of the Division of Medical Ethics at New York University (NYU) Grossman School of Medicine, New York City.

“Dealing in unknowns and uncertainties when you’re diagnosing doesn’t really do people very much good,” he said in an interview.

While most survey respondents said they were at least moderately obligated to disclose incidental research findings if a patient requests them, Caplan noted that it was ultimately the researchers’ decision.

“Patient preferences are something to take into account, but they’re not final. If the research team says, ‘we don’t know, it’s too uncertain, it’s too new,’ then I don’t think they have any obligation to return that [information],” he said. “You can’t tell somebody what you don’t understand.”

Conversely, the clearer the incidental finding, the stronger the obligation to share that information with research participants, he continued.

 

Need for a Standardized Approach 

The TARGET study, like many research studies, left the management of incidental imaging findings to individual research sites and investigators.

It’s possible that different sites responded to these ambiguous clinical findings in different ways, Kang noted.

“If there’s a situation that’s difficult to interpret as it is, you can imagine that the resulting actions that may result from that can vary, too,” she said, which highlights the need for more specific and standardized guidance.

One way to approach this, Caplan noted, is establishing an agreed-upon approach for dealing with any incidental findings across all research sites before a study begins.

“If there is going to be a common study at many sites, then they should have a common response on what they are going to do,” he noted, and how they will share that information effectively with the research participants to ensure it’s understandable. However, in a lot of research studies, each site has its own approach.

“Right now, it’s all over the place and that shouldn’t be,” he said.

Institutional review boards (IRBs) could be one resource to help build detailed guidance on managing unclear incidental findings in future research, wrote Kang and coauthors.

“For incidental findings from whole body FDG PET/CT that are not clearly actionable or less straightforward, IRBs may consider requiring a certain level of follow-up for different categories or types of incidental findings or require that all incidental findings are reviewed by an independent group that would provide timely recommendations on the most appropriate return and management of those findings,” Kang and colleagues wrote. “With IRB guidance, very specific and detailed policies and procedures for returning and managing incidental findings should be established for every study, with consistency among the research sites of multicenter trials.”

The TARGET trial and survey were funded by a grant from the National Institute of Arthritis and Musculoskeletal and Skin Diseases. Kang reported receiving research funding from the National Institutes of Health and the Rheumatology Research Foundation. Caplan serves as a contributing author for this news organization and served on an independent bioethics panel for compassionate drug use that was funded by Johnson & Johnson through the NYU Grossman School of Medicine.

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

Disparate views on managing incidental imaging findings made during clinical research — particularly for unclear results — signal a need for standardized guidance, according to recent survey results.

Respondents were split on whether it was the site primary investigator’s responsibility to decide which incidental findings should be reported back to the patient, and the most commonly cited challenges included adequately explaining these findings and the follow-up required. These issues were most present when dealing with nonspecific incidental findings or findings of unclear importance, said lead author Jane S. Kang, MD, a bioethicist and associate professor of medicine in the Division of Rheumatology at Columbia University Irving Medical Center, New York City.

 

“It can be difficult to have a clear approach” when it comes to these situations that are not black and white, and it is hard to get a clear answer, she said in an interview.

The survey included responses from investigators from the Treatments Against Rheumatoid Arthritis and Effect on 18F-fluorodeoxyglucose (FDG) PET/CT (TARGET) trial, conducted between 2015 and 2021. The 24-week trial included patients from 28 centers in the United States to investigate how different disease-modifying antirheumatic drugs can reduce cardiovascular and joint inflammation, assessed via whole body FDG PET/CT. The survey was a planned substudy of the TARGET trial and is “the first study that examines researchers’ attitudes and beliefs regarding incidental research findings from whole body FDG PET/CT,” Kang and her coauthors wrote.

This news organization reported the main results of the TARGET trial in 2022.

Eighteen of the 28 site primary investigators (PIs) of the TARGET trial participated in the survey, which was published in Arthritis Care & Research in September 2024.

 

TARGET Trial Incidental Findings

The TARGET trial enrolled 159 patients, of whom 82% had at least one incidental finding and 62% had one or more FDG-avid incidental findings. There were 46 “clinically actionable findings” for 40 participants overall; the reading radiologists recommended additional imaging for 28 findings and specialist consultation or procedural evaluation for 15 findings.

Details on these incidental findings were presented in a poster at the annual meeting of the American College of Rheumatology (ACR), held in Washington, DC.

The most common non–FDG-avid findings were pulmonary nodules, diverticulosis, cholelithiasis, sinus disease, and vascular calcifications. The most common FDG-avid findings were hypermetabolic lymphadenopathy, increased gastric/esophageal uptake, increased bowel uptake, and increased pharyngeal uptake.

In the related survey, 11 respondents (61%) said they returned any incidental findings to participants and 5 (28%) did not; the remaining 2 respondents did not know.

Across all study PIs, 22% felt that incidental findings were beneficial, 39% said they were potentially beneficial, and 11% said they were potentially detrimental. PIs that ranked incidental findings as potentially detrimental pointed to how these findings led to invasive additional testing.

“One of my subjects was found to have diverticulosis, which needed an invasive procedure to rule out malignancy,” one respondent wrote. “However, the subject had already had a colonoscopy months prior to the PET findings, which was still not deemed sufficient by the nuclear radiologist and GI consultant, so he had to have another colonoscopy, which was benign, but uncomfortable.” 

 

Obligation to Return Findings

All investigators agreed that incidental findings should be shared with patients if they revealed a high-risk medical condition that can be treated; had important health implications such as premature death or substantial morbidity; and their health could be improved with proven preventive or therapeutic interventions.

There was more disagreement on whether to share that the FDG PET/CT revealed no findings or if the test revealed a finding without clear medical importance of which the research participant may not be aware.

An example of a less-specific finding could be something like increased FDG uptake in a particular area, like the bowel, Kang explained.

“The question is: What does that mean?” she said. “How do you interpret that?”

While some PIs might feel obligated to share all results with patients, sharing ambiguous incidental findings will likely not be helpful to the patient, said Arthur Caplan, PhD, of the Division of Medical Ethics at New York University (NYU) Grossman School of Medicine, New York City.

“Dealing in unknowns and uncertainties when you’re diagnosing doesn’t really do people very much good,” he said in an interview.

While most survey respondents said they were at least moderately obligated to disclose incidental research findings if a patient requests them, Caplan noted that it was ultimately the researchers’ decision.

“Patient preferences are something to take into account, but they’re not final. If the research team says, ‘we don’t know, it’s too uncertain, it’s too new,’ then I don’t think they have any obligation to return that [information],” he said. “You can’t tell somebody what you don’t understand.”

Conversely, the clearer the incidental finding, the stronger the obligation to share that information with research participants, he continued.

 

Need for a Standardized Approach 

The TARGET study, like many research studies, left the management of incidental imaging findings to individual research sites and investigators.

It’s possible that different sites responded to these ambiguous clinical findings in different ways, Kang noted.

“If there’s a situation that’s difficult to interpret as it is, you can imagine that the resulting actions that may result from that can vary, too,” she said, which highlights the need for more specific and standardized guidance.

One way to approach this, Caplan noted, is establishing an agreed-upon approach for dealing with any incidental findings across all research sites before a study begins.

“If there is going to be a common study at many sites, then they should have a common response on what they are going to do,” he noted, and how they will share that information effectively with the research participants to ensure it’s understandable. However, in a lot of research studies, each site has its own approach.

“Right now, it’s all over the place and that shouldn’t be,” he said.

Institutional review boards (IRBs) could be one resource to help build detailed guidance on managing unclear incidental findings in future research, wrote Kang and coauthors.

“For incidental findings from whole body FDG PET/CT that are not clearly actionable or less straightforward, IRBs may consider requiring a certain level of follow-up for different categories or types of incidental findings or require that all incidental findings are reviewed by an independent group that would provide timely recommendations on the most appropriate return and management of those findings,” Kang and colleagues wrote. “With IRB guidance, very specific and detailed policies and procedures for returning and managing incidental findings should be established for every study, with consistency among the research sites of multicenter trials.”

The TARGET trial and survey were funded by a grant from the National Institute of Arthritis and Musculoskeletal and Skin Diseases. Kang reported receiving research funding from the National Institutes of Health and the Rheumatology Research Foundation. Caplan serves as a contributing author for this news organization and served on an independent bioethics panel for compassionate drug use that was funded by Johnson & Johnson through the NYU Grossman School of Medicine.

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

Disparate views on managing incidental imaging findings made during clinical research — particularly for unclear results — signal a need for standardized guidance, according to recent survey results.

Respondents were split on whether it was the site primary investigator’s responsibility to decide which incidental findings should be reported back to the patient, and the most commonly cited challenges included adequately explaining these findings and the follow-up required. These issues were most present when dealing with nonspecific incidental findings or findings of unclear importance, said lead author Jane S. Kang, MD, a bioethicist and associate professor of medicine in the Division of Rheumatology at Columbia University Irving Medical Center, New York City.

 

“It can be difficult to have a clear approach” when it comes to these situations that are not black and white, and it is hard to get a clear answer, she said in an interview.

The survey included responses from investigators from the Treatments Against Rheumatoid Arthritis and Effect on 18F-fluorodeoxyglucose (FDG) PET/CT (TARGET) trial, conducted between 2015 and 2021. The 24-week trial included patients from 28 centers in the United States to investigate how different disease-modifying antirheumatic drugs can reduce cardiovascular and joint inflammation, assessed via whole body FDG PET/CT. The survey was a planned substudy of the TARGET trial and is “the first study that examines researchers’ attitudes and beliefs regarding incidental research findings from whole body FDG PET/CT,” Kang and her coauthors wrote.

This news organization reported the main results of the TARGET trial in 2022.

Eighteen of the 28 site primary investigators (PIs) of the TARGET trial participated in the survey, which was published in Arthritis Care & Research in September 2024.

 

TARGET Trial Incidental Findings

The TARGET trial enrolled 159 patients, of whom 82% had at least one incidental finding and 62% had one or more FDG-avid incidental findings. There were 46 “clinically actionable findings” for 40 participants overall; the reading radiologists recommended additional imaging for 28 findings and specialist consultation or procedural evaluation for 15 findings.

Details on these incidental findings were presented in a poster at the annual meeting of the American College of Rheumatology (ACR), held in Washington, DC.

The most common non–FDG-avid findings were pulmonary nodules, diverticulosis, cholelithiasis, sinus disease, and vascular calcifications. The most common FDG-avid findings were hypermetabolic lymphadenopathy, increased gastric/esophageal uptake, increased bowel uptake, and increased pharyngeal uptake.

In the related survey, 11 respondents (61%) said they returned any incidental findings to participants and 5 (28%) did not; the remaining 2 respondents did not know.

Across all study PIs, 22% felt that incidental findings were beneficial, 39% said they were potentially beneficial, and 11% said they were potentially detrimental. PIs that ranked incidental findings as potentially detrimental pointed to how these findings led to invasive additional testing.

“One of my subjects was found to have diverticulosis, which needed an invasive procedure to rule out malignancy,” one respondent wrote. “However, the subject had already had a colonoscopy months prior to the PET findings, which was still not deemed sufficient by the nuclear radiologist and GI consultant, so he had to have another colonoscopy, which was benign, but uncomfortable.” 

 

Obligation to Return Findings

All investigators agreed that incidental findings should be shared with patients if they revealed a high-risk medical condition that can be treated; had important health implications such as premature death or substantial morbidity; and their health could be improved with proven preventive or therapeutic interventions.

There was more disagreement on whether to share that the FDG PET/CT revealed no findings or if the test revealed a finding without clear medical importance of which the research participant may not be aware.

An example of a less-specific finding could be something like increased FDG uptake in a particular area, like the bowel, Kang explained.

“The question is: What does that mean?” she said. “How do you interpret that?”

While some PIs might feel obligated to share all results with patients, sharing ambiguous incidental findings will likely not be helpful to the patient, said Arthur Caplan, PhD, of the Division of Medical Ethics at New York University (NYU) Grossman School of Medicine, New York City.

“Dealing in unknowns and uncertainties when you’re diagnosing doesn’t really do people very much good,” he said in an interview.

While most survey respondents said they were at least moderately obligated to disclose incidental research findings if a patient requests them, Caplan noted that it was ultimately the researchers’ decision.

“Patient preferences are something to take into account, but they’re not final. If the research team says, ‘we don’t know, it’s too uncertain, it’s too new,’ then I don’t think they have any obligation to return that [information],” he said. “You can’t tell somebody what you don’t understand.”

Conversely, the clearer the incidental finding, the stronger the obligation to share that information with research participants, he continued.

 

Need for a Standardized Approach 

The TARGET study, like many research studies, left the management of incidental imaging findings to individual research sites and investigators.

It’s possible that different sites responded to these ambiguous clinical findings in different ways, Kang noted.

“If there’s a situation that’s difficult to interpret as it is, you can imagine that the resulting actions that may result from that can vary, too,” she said, which highlights the need for more specific and standardized guidance.

One way to approach this, Caplan noted, is establishing an agreed-upon approach for dealing with any incidental findings across all research sites before a study begins.

“If there is going to be a common study at many sites, then they should have a common response on what they are going to do,” he noted, and how they will share that information effectively with the research participants to ensure it’s understandable. However, in a lot of research studies, each site has its own approach.

“Right now, it’s all over the place and that shouldn’t be,” he said.

Institutional review boards (IRBs) could be one resource to help build detailed guidance on managing unclear incidental findings in future research, wrote Kang and coauthors.

“For incidental findings from whole body FDG PET/CT that are not clearly actionable or less straightforward, IRBs may consider requiring a certain level of follow-up for different categories or types of incidental findings or require that all incidental findings are reviewed by an independent group that would provide timely recommendations on the most appropriate return and management of those findings,” Kang and colleagues wrote. “With IRB guidance, very specific and detailed policies and procedures for returning and managing incidental findings should be established for every study, with consistency among the research sites of multicenter trials.”

The TARGET trial and survey were funded by a grant from the National Institute of Arthritis and Musculoskeletal and Skin Diseases. Kang reported receiving research funding from the National Institutes of Health and the Rheumatology Research Foundation. Caplan serves as a contributing author for this news organization and served on an independent bioethics panel for compassionate drug use that was funded by Johnson & Johnson through the NYU Grossman School of Medicine.

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

Microplastics have been found in the lungs, liver, blood, and heart. Now, researchers report they have found the first evidence of the substances in human brains.

In a recent case series study that examined olfactory bulb tissue from deceased individuals, 8 of the 15 decedent brains showed the presence of microplastics, most commonly polypropylene, a plastic typically used in food packaging and water bottles.

Measuring less than 5 mm in size, microplastics are formed over time as plastic materials break down but don’t biodegrade. Exposure to these substances can come through food, air, and skin absorption.

While scientists are learning more about how these substances are absorbed by the body, questions remain about how much exposure is safe, what effect — if any — microplastics could have on brain function, and what clinicians should tell their patients.

 

What Are the Major Health Concerns?

The Plastic Health Council estimates that more than 500 million metric tons of plastic are produced worldwide each year. In addition, it reports that plastic products can contain more than 16,000 chemicals, about a quarter of which have been found to be hazardous to human health and the environment. Microplastics and nanoplastics can enter the body through the air, in food, or absorption through the skin.

A study published in March showed that patients with carotid plaques and the presence of microplastics and nanoplastics were at an increased risk for death or major cardiovascular events.

Other studies have shown a link between these substances and placental inflammation and preterm births, reduced male fertility, and endocrine disruption — as well as accelerated spread of cancer cells in the gut.

There is also evidence suggesting that microplastics may facilitate the development of antibiotic resistance in bacteria and could contribute to the rise in food allergies.

And now, Thais Mauad, MD, PhD, and colleagues have found the substances in the brain.

 

How Is the Brain Affected?

The investigators examined olfactory bulb tissues from 15 deceased Sao Paulo, Brazil, residents ranging in age from 33 to 100 years who underwent routine coroner autopsies. All but three of the participants were men.

Exclusion criteria included having undergone previous neurosurgical interventions. The tissues were analyzed using micro–Fourier transform infrared spectroscopy (µFTIR).

In addition, the researchers practiced a “plastic-free approach” in their analysis, which included using filters and covering glassware and samples with aluminum foil.

Study findings showed microplastics in 8 of the 15 participants — including in the centenarian. In total, there were 16 synthetic polymer particles and fibers detected, with up to four microplastics detected per olfactory bulb. Polypropylene was the most common polymer found (44%), followed by polyamide, nylon, and polyethylene vinyl acetate. These substances are commonly used in a wide range of products, including food packaging, textiles, kitchen utensils, medical devices, and adhesives.

The microplastic particles ranged in length from 5.5 to 26 microns (one millionth of a meter), with a width that ranged from 3 to 25 microns. The mean fiber length and width was 21 and 4 microns, respectively. For comparison, the diameter of one human hair averages about 70 microns, according to the US Food and Drug Administration (FDA).

“To our knowledge, this is the first study in which the presence of microplastics in the human brain was identified and characterized using µFTIR,” the researchers wrote.

 

How Do Microplastics Reach the Brain?

Although the possibility of microplastics crossing the blood-brain barrier has been questioned, senior investigator Mauad, associate professor in the Department of Pathology, the University of Sao Paulo in Brazil, noted that the olfactory pathway could offer an entry route through inhalation of the particles.

This means that “breathing within indoor environments could be a major source of plastic pollution in the brain,” she said in a press release.

“With much smaller nanoplastics entering the body with greater ease, the total level of plastic particles may be much higher. What is worrying is the capacity of such particles to be internalized by cells and alter how our bodies function,” she added.

Mauad said that although questions remain regarding the health implications of their findings, some animal studies have shown that the presence of microplastics in the brain is linked to neurotoxic effects, including oxidative stress.

In addition, exposure to particulate matter has been linked previously to such neurologic conditions as dementia and neurodegenerative conditions such as Parkinson’s disease “seem to have a connection with nasal abnormalities as initial symptoms,” the investigators noted.

While the olfactory pathway appears to be a likely route of exposure the researchers noted that other potential entry routes, including through blood circulation, may also be involved.

The research suggests that inhaling microplastics while indoors may be unavoidable, Mauad said, making it unlikely individuals can eliminate exposure to these substances.

“Everything that surrounds us is plastic. So we can’t really get rid of it,” she said.

 

Are Microplastics Regulated?

The most effective solution would be stricter regulations, Mauad said.

“The industry has chosen to sell many things in plastic, and I think this has to change. We need more policies to decrease plastic production — especially single-use plastic,” she said.

Federal, state, and local regulations for microplastics are “virtually nonexistent,” reported the Interstate Technology and Regulatory Council (ITRC), a state-led coalition that produces documents and trainings related to regulatory issues.

In 2021, the ITRC sent a survey to all US states asking about microplastics regulations. Of the 26 states that responded, only 4 said they had conducted sampling for microplastics. None of the responders indicated they had established any criteria or standards for microplastics, although eight states indicated they had plans to pursue them in the future.

Although federal regulations include the Microbead-Free Waters Act of 2015 and the Save Our Seas Act 2.0, the rules don’t directly pertain to microplastics.

There are also no regulations currently in place regarding microplastics or nanoplastics in food. A report issued in July by the FDA claimed that “the overall scientific evidence does not demonstrate that levels of microplastics or nanoplastics found in foods pose a risk to human health.”

International efforts to regulate microplastics are much further along. First created in 2022, the treaty would forge an international, legally binding agreement.

While it is a step in the right direction, the Plastic Health Council has cautioned about “the omission of measures in draft provisions that fully address the impact of plastic pollution on human health.” The treaty should reduce plastic production, eliminate single-use plastic items, and call for testing of all chemicals in plastics, the council argues.

The final round of negotiations for the UN Global Plastic Treaty is set for completion before the end of the year.

 

What Should Clinicians Know?

Much remains unknown about the potential health effects of microplastic exposure. So how can clinicians respond to questions from concerned patients?

“We don’t yet have enough evidence about the plastic particle itself, like those highlighted in the current study — and even more so when it comes to nanoplastics, which are a thousand times smaller,” said Phoebe Stapleton, PhD, associated professor in the Department of Pharmacology and Toxicology at the Ernest Mario School of Pharmacy at Rutgers University, Piscataway, New Jersey.

“But we do have a lot of evidence about the chemicals that are used to make plastics, and we’ve already seen regulation there from the EPA. That’s one conversation that clinicians could have with patients: about those chemicals,” she added.

Stapleton recommended clinicians stay current on the latest research and be ready to respond should a patient raise the issue. She also noted the importance of exercising caution when interpreting these new findings.

While the study is important — especially because it highlights inhalation as a viable route of entry — exposure through the olfactory area is still just a theory and hasn’t yet been fully proven.

In addition, Stapleton wonders whether there are tissues where these substances are not found. A discovery like that “would be really exciting because that means that that tissue has mechanisms protecting it, and maybe, we could learn more about how to keep microplastics out,” she said.

She would also like to see more studies on specific adverse health effects from microplastics in the body.

Mauad agreed.

“That’s the next set of questions: What are the toxicities or lack thereof in those tissues? That will give us more information as it pertains to human health. It doesn’t feel good to know they’re in our tissues, but we still don’t have a real understanding of what they’re doing when they’re there,” she said.

The current study was funded by the Alexander von Humboldt Foundation and by grants from the Brazilian Research Council and the Soa State Research Agency. It was also funded by the Plastic Soup Foundation — which, together with A Plastic Planet, forms the Plastic Health Council. The investigators and Stapleton reported no relevant financial relationships.

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

Microplastics have been found in the lungs, liver, blood, and heart. Now, researchers report they have found the first evidence of the substances in human brains.

In a recent case series study that examined olfactory bulb tissue from deceased individuals, 8 of the 15 decedent brains showed the presence of microplastics, most commonly polypropylene, a plastic typically used in food packaging and water bottles.

Measuring less than 5 mm in size, microplastics are formed over time as plastic materials break down but don’t biodegrade. Exposure to these substances can come through food, air, and skin absorption.

While scientists are learning more about how these substances are absorbed by the body, questions remain about how much exposure is safe, what effect — if any — microplastics could have on brain function, and what clinicians should tell their patients.

 

What Are the Major Health Concerns?

The Plastic Health Council estimates that more than 500 million metric tons of plastic are produced worldwide each year. In addition, it reports that plastic products can contain more than 16,000 chemicals, about a quarter of which have been found to be hazardous to human health and the environment. Microplastics and nanoplastics can enter the body through the air, in food, or absorption through the skin.

A study published in March showed that patients with carotid plaques and the presence of microplastics and nanoplastics were at an increased risk for death or major cardiovascular events.

Other studies have shown a link between these substances and placental inflammation and preterm births, reduced male fertility, and endocrine disruption — as well as accelerated spread of cancer cells in the gut.

There is also evidence suggesting that microplastics may facilitate the development of antibiotic resistance in bacteria and could contribute to the rise in food allergies.

And now, Thais Mauad, MD, PhD, and colleagues have found the substances in the brain.

 

How Is the Brain Affected?

The investigators examined olfactory bulb tissues from 15 deceased Sao Paulo, Brazil, residents ranging in age from 33 to 100 years who underwent routine coroner autopsies. All but three of the participants were men.

Exclusion criteria included having undergone previous neurosurgical interventions. The tissues were analyzed using micro–Fourier transform infrared spectroscopy (µFTIR).

In addition, the researchers practiced a “plastic-free approach” in their analysis, which included using filters and covering glassware and samples with aluminum foil.

Study findings showed microplastics in 8 of the 15 participants — including in the centenarian. In total, there were 16 synthetic polymer particles and fibers detected, with up to four microplastics detected per olfactory bulb. Polypropylene was the most common polymer found (44%), followed by polyamide, nylon, and polyethylene vinyl acetate. These substances are commonly used in a wide range of products, including food packaging, textiles, kitchen utensils, medical devices, and adhesives.

The microplastic particles ranged in length from 5.5 to 26 microns (one millionth of a meter), with a width that ranged from 3 to 25 microns. The mean fiber length and width was 21 and 4 microns, respectively. For comparison, the diameter of one human hair averages about 70 microns, according to the US Food and Drug Administration (FDA).

“To our knowledge, this is the first study in which the presence of microplastics in the human brain was identified and characterized using µFTIR,” the researchers wrote.

 

How Do Microplastics Reach the Brain?

Although the possibility of microplastics crossing the blood-brain barrier has been questioned, senior investigator Mauad, associate professor in the Department of Pathology, the University of Sao Paulo in Brazil, noted that the olfactory pathway could offer an entry route through inhalation of the particles.

This means that “breathing within indoor environments could be a major source of plastic pollution in the brain,” she said in a press release.

“With much smaller nanoplastics entering the body with greater ease, the total level of plastic particles may be much higher. What is worrying is the capacity of such particles to be internalized by cells and alter how our bodies function,” she added.

Mauad said that although questions remain regarding the health implications of their findings, some animal studies have shown that the presence of microplastics in the brain is linked to neurotoxic effects, including oxidative stress.

In addition, exposure to particulate matter has been linked previously to such neurologic conditions as dementia and neurodegenerative conditions such as Parkinson’s disease “seem to have a connection with nasal abnormalities as initial symptoms,” the investigators noted.

While the olfactory pathway appears to be a likely route of exposure the researchers noted that other potential entry routes, including through blood circulation, may also be involved.

The research suggests that inhaling microplastics while indoors may be unavoidable, Mauad said, making it unlikely individuals can eliminate exposure to these substances.

“Everything that surrounds us is plastic. So we can’t really get rid of it,” she said.

 

Are Microplastics Regulated?

The most effective solution would be stricter regulations, Mauad said.

“The industry has chosen to sell many things in plastic, and I think this has to change. We need more policies to decrease plastic production — especially single-use plastic,” she said.

Federal, state, and local regulations for microplastics are “virtually nonexistent,” reported the Interstate Technology and Regulatory Council (ITRC), a state-led coalition that produces documents and trainings related to regulatory issues.

In 2021, the ITRC sent a survey to all US states asking about microplastics regulations. Of the 26 states that responded, only 4 said they had conducted sampling for microplastics. None of the responders indicated they had established any criteria or standards for microplastics, although eight states indicated they had plans to pursue them in the future.

Although federal regulations include the Microbead-Free Waters Act of 2015 and the Save Our Seas Act 2.0, the rules don’t directly pertain to microplastics.

There are also no regulations currently in place regarding microplastics or nanoplastics in food. A report issued in July by the FDA claimed that “the overall scientific evidence does not demonstrate that levels of microplastics or nanoplastics found in foods pose a risk to human health.”

International efforts to regulate microplastics are much further along. First created in 2022, the treaty would forge an international, legally binding agreement.

While it is a step in the right direction, the Plastic Health Council has cautioned about “the omission of measures in draft provisions that fully address the impact of plastic pollution on human health.” The treaty should reduce plastic production, eliminate single-use plastic items, and call for testing of all chemicals in plastics, the council argues.

The final round of negotiations for the UN Global Plastic Treaty is set for completion before the end of the year.

 

What Should Clinicians Know?

Much remains unknown about the potential health effects of microplastic exposure. So how can clinicians respond to questions from concerned patients?

“We don’t yet have enough evidence about the plastic particle itself, like those highlighted in the current study — and even more so when it comes to nanoplastics, which are a thousand times smaller,” said Phoebe Stapleton, PhD, associated professor in the Department of Pharmacology and Toxicology at the Ernest Mario School of Pharmacy at Rutgers University, Piscataway, New Jersey.

“But we do have a lot of evidence about the chemicals that are used to make plastics, and we’ve already seen regulation there from the EPA. That’s one conversation that clinicians could have with patients: about those chemicals,” she added.

Stapleton recommended clinicians stay current on the latest research and be ready to respond should a patient raise the issue. She also noted the importance of exercising caution when interpreting these new findings.

While the study is important — especially because it highlights inhalation as a viable route of entry — exposure through the olfactory area is still just a theory and hasn’t yet been fully proven.

In addition, Stapleton wonders whether there are tissues where these substances are not found. A discovery like that “would be really exciting because that means that that tissue has mechanisms protecting it, and maybe, we could learn more about how to keep microplastics out,” she said.

She would also like to see more studies on specific adverse health effects from microplastics in the body.

Mauad agreed.

“That’s the next set of questions: What are the toxicities or lack thereof in those tissues? That will give us more information as it pertains to human health. It doesn’t feel good to know they’re in our tissues, but we still don’t have a real understanding of what they’re doing when they’re there,” she said.

The current study was funded by the Alexander von Humboldt Foundation and by grants from the Brazilian Research Council and the Soa State Research Agency. It was also funded by the Plastic Soup Foundation — which, together with A Plastic Planet, forms the Plastic Health Council. The investigators and Stapleton reported no relevant financial relationships.

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

Microplastics have been found in the lungs, liver, blood, and heart. Now, researchers report they have found the first evidence of the substances in human brains.

In a recent case series study that examined olfactory bulb tissue from deceased individuals, 8 of the 15 decedent brains showed the presence of microplastics, most commonly polypropylene, a plastic typically used in food packaging and water bottles.

Measuring less than 5 mm in size, microplastics are formed over time as plastic materials break down but don’t biodegrade. Exposure to these substances can come through food, air, and skin absorption.

While scientists are learning more about how these substances are absorbed by the body, questions remain about how much exposure is safe, what effect — if any — microplastics could have on brain function, and what clinicians should tell their patients.

 

What Are the Major Health Concerns?

The Plastic Health Council estimates that more than 500 million metric tons of plastic are produced worldwide each year. In addition, it reports that plastic products can contain more than 16,000 chemicals, about a quarter of which have been found to be hazardous to human health and the environment. Microplastics and nanoplastics can enter the body through the air, in food, or absorption through the skin.

A study published in March showed that patients with carotid plaques and the presence of microplastics and nanoplastics were at an increased risk for death or major cardiovascular events.

Other studies have shown a link between these substances and placental inflammation and preterm births, reduced male fertility, and endocrine disruption — as well as accelerated spread of cancer cells in the gut.

There is also evidence suggesting that microplastics may facilitate the development of antibiotic resistance in bacteria and could contribute to the rise in food allergies.

And now, Thais Mauad, MD, PhD, and colleagues have found the substances in the brain.

 

How Is the Brain Affected?

The investigators examined olfactory bulb tissues from 15 deceased Sao Paulo, Brazil, residents ranging in age from 33 to 100 years who underwent routine coroner autopsies. All but three of the participants were men.

Exclusion criteria included having undergone previous neurosurgical interventions. The tissues were analyzed using micro–Fourier transform infrared spectroscopy (µFTIR).

In addition, the researchers practiced a “plastic-free approach” in their analysis, which included using filters and covering glassware and samples with aluminum foil.

Study findings showed microplastics in 8 of the 15 participants — including in the centenarian. In total, there were 16 synthetic polymer particles and fibers detected, with up to four microplastics detected per olfactory bulb. Polypropylene was the most common polymer found (44%), followed by polyamide, nylon, and polyethylene vinyl acetate. These substances are commonly used in a wide range of products, including food packaging, textiles, kitchen utensils, medical devices, and adhesives.

The microplastic particles ranged in length from 5.5 to 26 microns (one millionth of a meter), with a width that ranged from 3 to 25 microns. The mean fiber length and width was 21 and 4 microns, respectively. For comparison, the diameter of one human hair averages about 70 microns, according to the US Food and Drug Administration (FDA).

“To our knowledge, this is the first study in which the presence of microplastics in the human brain was identified and characterized using µFTIR,” the researchers wrote.

 

How Do Microplastics Reach the Brain?

Although the possibility of microplastics crossing the blood-brain barrier has been questioned, senior investigator Mauad, associate professor in the Department of Pathology, the University of Sao Paulo in Brazil, noted that the olfactory pathway could offer an entry route through inhalation of the particles.

This means that “breathing within indoor environments could be a major source of plastic pollution in the brain,” she said in a press release.

“With much smaller nanoplastics entering the body with greater ease, the total level of plastic particles may be much higher. What is worrying is the capacity of such particles to be internalized by cells and alter how our bodies function,” she added.

Mauad said that although questions remain regarding the health implications of their findings, some animal studies have shown that the presence of microplastics in the brain is linked to neurotoxic effects, including oxidative stress.

In addition, exposure to particulate matter has been linked previously to such neurologic conditions as dementia and neurodegenerative conditions such as Parkinson’s disease “seem to have a connection with nasal abnormalities as initial symptoms,” the investigators noted.

While the olfactory pathway appears to be a likely route of exposure the researchers noted that other potential entry routes, including through blood circulation, may also be involved.

The research suggests that inhaling microplastics while indoors may be unavoidable, Mauad said, making it unlikely individuals can eliminate exposure to these substances.

“Everything that surrounds us is plastic. So we can’t really get rid of it,” she said.

 

Are Microplastics Regulated?

The most effective solution would be stricter regulations, Mauad said.

“The industry has chosen to sell many things in plastic, and I think this has to change. We need more policies to decrease plastic production — especially single-use plastic,” she said.

Federal, state, and local regulations for microplastics are “virtually nonexistent,” reported the Interstate Technology and Regulatory Council (ITRC), a state-led coalition that produces documents and trainings related to regulatory issues.

In 2021, the ITRC sent a survey to all US states asking about microplastics regulations. Of the 26 states that responded, only 4 said they had conducted sampling for microplastics. None of the responders indicated they had established any criteria or standards for microplastics, although eight states indicated they had plans to pursue them in the future.

Although federal regulations include the Microbead-Free Waters Act of 2015 and the Save Our Seas Act 2.0, the rules don’t directly pertain to microplastics.

There are also no regulations currently in place regarding microplastics or nanoplastics in food. A report issued in July by the FDA claimed that “the overall scientific evidence does not demonstrate that levels of microplastics or nanoplastics found in foods pose a risk to human health.”

International efforts to regulate microplastics are much further along. First created in 2022, the treaty would forge an international, legally binding agreement.

While it is a step in the right direction, the Plastic Health Council has cautioned about “the omission of measures in draft provisions that fully address the impact of plastic pollution on human health.” The treaty should reduce plastic production, eliminate single-use plastic items, and call for testing of all chemicals in plastics, the council argues.

The final round of negotiations for the UN Global Plastic Treaty is set for completion before the end of the year.

 

What Should Clinicians Know?

Much remains unknown about the potential health effects of microplastic exposure. So how can clinicians respond to questions from concerned patients?

“We don’t yet have enough evidence about the plastic particle itself, like those highlighted in the current study — and even more so when it comes to nanoplastics, which are a thousand times smaller,” said Phoebe Stapleton, PhD, associated professor in the Department of Pharmacology and Toxicology at the Ernest Mario School of Pharmacy at Rutgers University, Piscataway, New Jersey.

“But we do have a lot of evidence about the chemicals that are used to make plastics, and we’ve already seen regulation there from the EPA. That’s one conversation that clinicians could have with patients: about those chemicals,” she added.

Stapleton recommended clinicians stay current on the latest research and be ready to respond should a patient raise the issue. She also noted the importance of exercising caution when interpreting these new findings.

While the study is important — especially because it highlights inhalation as a viable route of entry — exposure through the olfactory area is still just a theory and hasn’t yet been fully proven.

In addition, Stapleton wonders whether there are tissues where these substances are not found. A discovery like that “would be really exciting because that means that that tissue has mechanisms protecting it, and maybe, we could learn more about how to keep microplastics out,” she said.

She would also like to see more studies on specific adverse health effects from microplastics in the body.

Mauad agreed.

“That’s the next set of questions: What are the toxicities or lack thereof in those tissues? That will give us more information as it pertains to human health. It doesn’t feel good to know they’re in our tissues, but we still don’t have a real understanding of what they’re doing when they’re there,” she said.

The current study was funded by the Alexander von Humboldt Foundation and by grants from the Brazilian Research Council and the Soa State Research Agency. It was also funded by the Plastic Soup Foundation — which, together with A Plastic Planet, forms the Plastic Health Council. The investigators and Stapleton reported no relevant financial relationships.

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

This video transcript has been edited for clarity. 

Robert D. Glatter, MD: Hi and welcome. I’m Dr. Robert Glatter, medical adviser for Medscape Emergency Medicine. Joining me today to discuss a novel, plant-based approach to stopping moderate to severe bleeding is Joe Landolina, CEO and cofounder of Cresilon. Welcome, Joe. 

Joe Landolina, MS: Thank you so much for taking the time. It’s great to be here.

Educational Background and Inception of Cresilon

Glatter: It’s a pleasure to have you join me, and I want to congratulate you on your recent 510(k) FDA clearance for your novel product to save lives and stop bleeding. To begin with, can you explain how the idea for launching your company came about? 

Landolina: The way that Cresilon came about was a little bit unorthodox, because I was 17 years old when I invented the technology behind the product that eventually became Traumagel®. 

My grandfather was an ex-pharmaceutical executive, who later in life started a vineyard. I grew up on a vineyard with a winery chemistry lab across the street from my house and a grandfather who learned lab safety in the 60s. So, that meant that the day I learned how to walk, I was tossed into a lab and I fell head over heels in love with lab research.

That started experimentation and my academic pursuits. That led to discovering a blend of two plant-based polymers derived from algae that stop bleeding on contact, effectively creating a mechanical barrier and allowing anything from a gunshot wound to anything quite a bit more minor to stop in a matter of seconds.

Glatter: Your background is in biomedical engineering. How is it that you started tinkering and doing all this type of work? 

Landolina: That’s correct. I did my undergrad in chemical engineering, and my graduate studies were in biomedical engineering. For me, that was supposed to be a pathway into medical school. I always wanted to be a surgeon myself, and I love the field of medicine. 

As a freshman in college at NYU Engineering, I had this idea. I entered it into NYU’s business plan competition, and we won at the engineering school. That gave us just enough capital to start developing and researching Traumagel more, and Cresilon was born out of that research.

 

Techniques for Stopping Hemorrhage

Glatter: In terms of stopping hemorrhage, which takes so many lives in the United States and globally — certainly, uncontrolled hemorrhage — what are the techniques that you see, prior to the arrival of your product, as being effective? Can you elucidate some of these techniques? 

Landolina: In emergency medicine, the primary mode of controlling hemorrhage is passive. It’s what, in Brooklyn, we like to call “pressure and a prayer”, where you have a material that’s either gauze or an impregnated gauze in most cases, where the mode of action is absorbing blood, with the adjunct of pressure by the first responder or by the clinician who’s providing aid.

The idea is to stop the flow of blood to concentrate blood factors at the surface of the gauze product, and to promote either platelet activation or the production of fibrin to create a clot. 

These types of technologies are widespread. There are many versions of this technology carried by EMS agencies, trauma bays, US military soldiers, and soldiers across NATO countries. But these types of technologies tend to be relatively inefficient, meaning that they’re very difficult to get into wounds because of the gauze or the powder form of the devices, and it’s very hard to get them in contact with the form of bleeding.

On top of that, if the patient is clotting compromised or immunocompromised in some way, the ability to create a durable clot that will not be ripped off when you remove the product at the next level of care is also of concern. And so, this type of technology or the type of treatment of massive hemorrhage hasn’t changed in decades.

 

Current Applications and Potential Use

Glatter: I envision this product will be carried by paramedics, used on the battlefield at some point after your FDA clearance, and recently it went through.

Do you see any possibility that this could be an AED equivalent to Stop the Bleed? In other words, could the average lay person be trained to use your product if kits are available? 

Landolina: To be very clear, Traumagel today is only approved or cleared under a “prescription-only” indication, which means that it will not initially be available OTC. However, that is our goal. Our goal is to make this product available and usable by someone with no medical training whatsoever. 

The form factor of being a gel in a syringe lends itself well to that, meaning that we try to make it as easy as point and shoot to control hemorrhage, where there’s not as much technique to be learned in the application of a product like Traumagel as there is in current hemorrhage control techniques. 

 

Mechanism of Action and Physiology

Glatter: Once you apply Traumagel, can you explain what happens to the product after it’s applied and the bleeding has stopped? Does it get reabsorbed by the body? What’s the process here? 

Landolina: Under Traumagel’s indication, because it’s used in traumatic injury, it must be removed within 24 hours.

One of the big benefits of Traumagel is that when the patient produces a blood clot underneath Traumagel, it doesn’t become incorporated within the gel itself. To contrast that with the use of gauze, gauze is porous. The clot ends up wrapped around the fibers of the gauze, so if you peel the gauze away, it’s very likely that clot is coming off with it. The surgeon or the clinician at the next level of care is going to have to deal with the re-bleed. 

You can remove Traumagel cleanly and entirely without disturbing the underlying clot. That’s a major benefit, not only to the patient but also to the next level of care, to the next clinician or physician that is required to remove the product.

Glatter: How is it possible to remove the substance without disturbing the clot? Can you explain in more detail? 

Landolina: That’s one of the hallmarks of these plant-based polymers and the way that we design Traumagel itself. Traumagel is completely nonporous, and it has no fibrous nature to it. What that means is when the patient produces a blood clot or fibrin next to or on top of Traumagel, that fibrin ends up not incorporated within the polymers of Traumagel itself. 

Over time, because Traumagel is a hydrogel, meaning that by weight it’s mostly water, you end up having less adhesion to the clot over time. When it’s time to remove Traumagel from the injury, it has lost almost all of its adhesive capabilities, meaning that when you peel it away, that clot is going to stick better to tissue than it will to the gel itself. 

Glatter: Can you explain a little bit about the matrix that’s formed, the physiology, and how the polymers work to form this matrix? 

Landolina: Sure. Traumagel is made of two polysaccharides that are plant derived. One polysaccharide is polyanionic, and the other is polycationic, meaning one has negative charges and the other has positive charges, which together create almost a Lego block effect, where when the material comes in contact with tissue, it adheres strongly and allows for itself to effectively create a mechanical barrier against bleeding.

Courtesy of Cresilon

Landolina: Even in the face of major arterial blood flow, Traumagel will stay where it needs to stay, and it’s not going to get washed away. This means that it is much more easily appliable to these types of surfaces and will allow the patient to produce their own endogenous fibrin clot at that location.

Like I mentioned before, when that fibrin clot is formed, because the gel itself has no pores or fibers, it doesn’t become incorporated within the fibrin clot. You can take the gel away, leaving that clot behind without the chance of a rebleed.

 

Testing With Major Bleeds

Glatter: In terms of bleeding itself, have you tested your product with major aortic bleeds or carotid bleeds in preclinical work?

Landolina: We have used the US military’s model for lethal hemorrhage, and the idea there is to create a model that is just that — lethal. These are the worst types of bleeds that you can possibly imagine, where the patients are clotting compromised, and where you have, in most cases, a very strong arterial component, so something like a femoral artery bleed.

We’ve also tested in carotid artery, aortic applications, as well as combinations of venous and arterial bleeds. The idea here is to show the use of the product in the absolute worst-case scenario so that when this translates into the clinic, the models that we’ve used for evaluation, hopefully, are worse than what actually rolls into the trauma bay.

Glatter: Excellent. What’s the mean time to stop an arterial vs a venous bleed? Are we talking a matter of seconds?

Landolina: In the case of a healthy patient, meaning a patient without clotting compromise, you’re in a matter of seconds. It’s less than 10 seconds. 

In the case where you have clotting compromise, a deep, complicated wound geometry, we recommend holding a pressure bandage on for 3 minutes just because it increases the chance of Traumagel coming into contact with the bleed, especially when you can’t visualize the bleed in the bleed source. Because of that pressure time, that becomes the mean. But again, it’s highly dependent on the type of bleed and the style of application.

 

Failure Rates and Effectiveness

Glatter: As a segue to that, what is the failure rate based on your studies and internal research using Traumagel? Have there been cases where bleeding has not been able to be stopped? 

Landolina: It depends on the study, but the failure rates are incredibly low with Traumagel, assuming that it’s correctly used. That’s one of the benefits to this product, where with proper technique, with overwrap with gauze, you nearly always get control of hemorrhage with a product like this. 

Glatter: Is manual pressure required in that sense? From what you described earlier, manual pressure would not be required. 

Landolina: It depends on the injury. What we recommend is that, if you have a very deep wound where you cannot visualize the source of bleed, you use pressure to seat Traumagel into the source of bleeding, meaning that you’re following Committee on Tactical Combat Casualty Care (Co-TCCC) regulations or requirements, where you’re over wrapping with gauze, and you’re providing a pressure wrapping to ensure that the Traumagel is in contact with the bleed while it’s doing what it’s doing. 

In most cases, it doesn’t hurt to apply pressure on top of Traumagel as well. In more surface level bleeds, you don’t need pressure at all. 

 

Applications Beyond Trauma

Glatter: Interesting. In terms of further applications (eg, nose bleeds or GYN bleeding, which are life-threatening), do you see this coming as an application for the future? 

Landolina: That’s where we’re working. Traumagel is the successor to an animal health product called Vetigel. The formulations of the gel behind Vetigel and Traumagel are identical. Vetigel has a full surgical indication, and that’s everything from epistaxis to neuro and spine procedures, into cardiovascular and soft tissue surgeries, orthopedic medicine, and so on.

Cresilon’s goal is to eventually expand the indication of our technology to include surgical indications and other indications where we can help any patient that’s bleeding. 

Glatter: That’s important, because we use prehospital whole blood, low titer, specifically, when patients have life-threatening hemorrhage. With your product, that would reduce the amount of blood products that would need to be administered. This could be a real game changer. 

Landolina: Definitely, that’s the goal we’re working on. 

Infection Risks and Biocompatibility

Glatter: In terms of any risk for infection, has that been studied as well? Does Traumagel in any way lead to increased rates of infection?

Landolina: Traumagel is biocompatible. It’s a sterile product. We’ve done the full suite of biocompatibility testing as required by FDA. On top of that, remember that Vetigel, which is the same formulation, is an implantable product. As a result, that has even extended biocompatibility testing beyond what would be necessary for an external product.

In Vetigel’s use case, which has been used now in over 60,000 patients, primarily companion animals, dogs and cats, we haven’t seen instances of infection. There’s no reason to believe that we would see that clinically with Traumagel.

 

Research Collaborations and Future Applications

Glatter: In terms of other research that your company’s embarked on preclinically, I understand there were some studies done at Walter Reed Army Institute of Research. I was wondering if you could expand on these, specifically, in terms of traumatic brain injury (TBI) and hemorrhage related to that. For example, with shrapnel or even a gunshot wound. 

Landolina: The Walter Reed collaboration with Cresilon is something that I’m particularly excited about, because it marks Cresilon’s first project that’s outside the scope of just hemostasis. Walter Reed came to us with this proposal where there’s a big challenge in a subset of TBI called penetrating ballistic-like brain injury, where the brain has been penetrated by a bullet, shrapnel, or some other projectile, and there’s an injury that exposes the brain to the outside. 

Today, there is no standard of care to treat patients with those types of injuries. In many cases, mortality is caused through swelling of the brain, or collapse of the brain. What they came to us with was the potential of using our technology, not primarily as a hemostatic agent, but to be able to stabilize that patient enough to get to the next level of care to be treated by a neurosurgeon.

That study Walter Reed did was just a pilot that was done in small animals. In that pilot, they showed that over the period of treatment, there was no negative change in vital signs, no increase in edema or in swelling, or in any of the biomarkers that were being monitored at that time. 

At the very least, this is not full indication that this indication will work for Cresilon, but it shows that there’s promise. It’s something that we’re working on and hopefully we’ll be able to bring to market soon.

Glatter: Certainly, maintaining intracranial pressure and cerebral perfusion pressures are very critical. In the future, do you think this product would be able to be deployed endovascularly? Imagine this in terms of stopping bleeding from some source, whether it’s from a stroke or another intracranial source. 

Landolina: That’s been an area of interest for us. We have no evidence to prove that indication works at this point, but there’s also nothing to say that it wouldn’t be possible for our technology. At this point, we’ve only looked at a cursory level at those indications. 

Glatter: Does the use of Traumagel obviate the need for a more definitive repair (eg, with sutures) or something that’s more permanent?

Landolina: I always say that Traumagel — and Vetigel, for that matter — is not a replacement for good surgical technique. The surgeon always needs to make his or her best judgment when reviewing the patient. That doesn’t mean that there won’t need to be sutures or vascular repair in most of these cases, especially in major trauma.

Final Takeaways

Glatter: Do you have some bullet points or pearls you could give our audience as a takeaway? 

Landolina: When Cresilon looks at Traumagel — and for us, Traumagel is the next generation of hemostatic agent, especially in trauma care and in emergency medicine — it allows for a far-simplified application of the product and much faster control of hemorrhage with better patient outcomes.

As we roll this out through EMS agencies, trauma hospitals, military agencies, and eventually to the general public through a future indication, it’s something we’re very excited about. Personally, I started this business 14 years ago, and so it’s great to see our mission of saving lives transitioning to saving human lives.

Glatter: I look forward to seeing this product in the emergency department, but also in other settings, such as in the operating room where we can really help patients who are dying from hemorrhage, certainly on the battlefield, and the lay public. If someone were to come upon a patient who’s bleeding out, this could be certainly a game changer and a lifesaver. 

I want to thank you for your time. This is a really important product that’s transformed the lives of so many animals, but also people in the future.

Dr. Glatter is an assistant professor of emergency medicine at Zucker School of Medicine at Hofstra/Northwell in Hempstead, New York. He reported no relevant conflicts of interest. Mr. Landolina is the CEO and co-founder of Cresilon, a biotechnology company specializing in plant-based solutions for emergency bleeding control.

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

This video transcript has been edited for clarity. 

Robert D. Glatter, MD: Hi and welcome. I’m Dr. Robert Glatter, medical adviser for Medscape Emergency Medicine. Joining me today to discuss a novel, plant-based approach to stopping moderate to severe bleeding is Joe Landolina, CEO and cofounder of Cresilon. Welcome, Joe. 

Joe Landolina, MS: Thank you so much for taking the time. It’s great to be here.

Educational Background and Inception of Cresilon

Glatter: It’s a pleasure to have you join me, and I want to congratulate you on your recent 510(k) FDA clearance for your novel product to save lives and stop bleeding. To begin with, can you explain how the idea for launching your company came about? 

Landolina: The way that Cresilon came about was a little bit unorthodox, because I was 17 years old when I invented the technology behind the product that eventually became Traumagel®. 

My grandfather was an ex-pharmaceutical executive, who later in life started a vineyard. I grew up on a vineyard with a winery chemistry lab across the street from my house and a grandfather who learned lab safety in the 60s. So, that meant that the day I learned how to walk, I was tossed into a lab and I fell head over heels in love with lab research.

That started experimentation and my academic pursuits. That led to discovering a blend of two plant-based polymers derived from algae that stop bleeding on contact, effectively creating a mechanical barrier and allowing anything from a gunshot wound to anything quite a bit more minor to stop in a matter of seconds.

Glatter: Your background is in biomedical engineering. How is it that you started tinkering and doing all this type of work? 

Landolina: That’s correct. I did my undergrad in chemical engineering, and my graduate studies were in biomedical engineering. For me, that was supposed to be a pathway into medical school. I always wanted to be a surgeon myself, and I love the field of medicine. 

As a freshman in college at NYU Engineering, I had this idea. I entered it into NYU’s business plan competition, and we won at the engineering school. That gave us just enough capital to start developing and researching Traumagel more, and Cresilon was born out of that research.

 

Techniques for Stopping Hemorrhage

Glatter: In terms of stopping hemorrhage, which takes so many lives in the United States and globally — certainly, uncontrolled hemorrhage — what are the techniques that you see, prior to the arrival of your product, as being effective? Can you elucidate some of these techniques? 

Landolina: In emergency medicine, the primary mode of controlling hemorrhage is passive. It’s what, in Brooklyn, we like to call “pressure and a prayer”, where you have a material that’s either gauze or an impregnated gauze in most cases, where the mode of action is absorbing blood, with the adjunct of pressure by the first responder or by the clinician who’s providing aid.

The idea is to stop the flow of blood to concentrate blood factors at the surface of the gauze product, and to promote either platelet activation or the production of fibrin to create a clot. 

These types of technologies are widespread. There are many versions of this technology carried by EMS agencies, trauma bays, US military soldiers, and soldiers across NATO countries. But these types of technologies tend to be relatively inefficient, meaning that they’re very difficult to get into wounds because of the gauze or the powder form of the devices, and it’s very hard to get them in contact with the form of bleeding.

On top of that, if the patient is clotting compromised or immunocompromised in some way, the ability to create a durable clot that will not be ripped off when you remove the product at the next level of care is also of concern. And so, this type of technology or the type of treatment of massive hemorrhage hasn’t changed in decades.

 

Current Applications and Potential Use

Glatter: I envision this product will be carried by paramedics, used on the battlefield at some point after your FDA clearance, and recently it went through.

Do you see any possibility that this could be an AED equivalent to Stop the Bleed? In other words, could the average lay person be trained to use your product if kits are available? 

Landolina: To be very clear, Traumagel today is only approved or cleared under a “prescription-only” indication, which means that it will not initially be available OTC. However, that is our goal. Our goal is to make this product available and usable by someone with no medical training whatsoever. 

The form factor of being a gel in a syringe lends itself well to that, meaning that we try to make it as easy as point and shoot to control hemorrhage, where there’s not as much technique to be learned in the application of a product like Traumagel as there is in current hemorrhage control techniques. 

 

Mechanism of Action and Physiology

Glatter: Once you apply Traumagel, can you explain what happens to the product after it’s applied and the bleeding has stopped? Does it get reabsorbed by the body? What’s the process here? 

Landolina: Under Traumagel’s indication, because it’s used in traumatic injury, it must be removed within 24 hours.

One of the big benefits of Traumagel is that when the patient produces a blood clot underneath Traumagel, it doesn’t become incorporated within the gel itself. To contrast that with the use of gauze, gauze is porous. The clot ends up wrapped around the fibers of the gauze, so if you peel the gauze away, it’s very likely that clot is coming off with it. The surgeon or the clinician at the next level of care is going to have to deal with the re-bleed. 

You can remove Traumagel cleanly and entirely without disturbing the underlying clot. That’s a major benefit, not only to the patient but also to the next level of care, to the next clinician or physician that is required to remove the product.

Glatter: How is it possible to remove the substance without disturbing the clot? Can you explain in more detail? 

Landolina: That’s one of the hallmarks of these plant-based polymers and the way that we design Traumagel itself. Traumagel is completely nonporous, and it has no fibrous nature to it. What that means is when the patient produces a blood clot or fibrin next to or on top of Traumagel, that fibrin ends up not incorporated within the polymers of Traumagel itself. 

Over time, because Traumagel is a hydrogel, meaning that by weight it’s mostly water, you end up having less adhesion to the clot over time. When it’s time to remove Traumagel from the injury, it has lost almost all of its adhesive capabilities, meaning that when you peel it away, that clot is going to stick better to tissue than it will to the gel itself. 

Glatter: Can you explain a little bit about the matrix that’s formed, the physiology, and how the polymers work to form this matrix? 

Landolina: Sure. Traumagel is made of two polysaccharides that are plant derived. One polysaccharide is polyanionic, and the other is polycationic, meaning one has negative charges and the other has positive charges, which together create almost a Lego block effect, where when the material comes in contact with tissue, it adheres strongly and allows for itself to effectively create a mechanical barrier against bleeding.

Courtesy of Cresilon

Landolina: Even in the face of major arterial blood flow, Traumagel will stay where it needs to stay, and it’s not going to get washed away. This means that it is much more easily appliable to these types of surfaces and will allow the patient to produce their own endogenous fibrin clot at that location.

Like I mentioned before, when that fibrin clot is formed, because the gel itself has no pores or fibers, it doesn’t become incorporated within the fibrin clot. You can take the gel away, leaving that clot behind without the chance of a rebleed.

 

Testing With Major Bleeds

Glatter: In terms of bleeding itself, have you tested your product with major aortic bleeds or carotid bleeds in preclinical work?

Landolina: We have used the US military’s model for lethal hemorrhage, and the idea there is to create a model that is just that — lethal. These are the worst types of bleeds that you can possibly imagine, where the patients are clotting compromised, and where you have, in most cases, a very strong arterial component, so something like a femoral artery bleed.

We’ve also tested in carotid artery, aortic applications, as well as combinations of venous and arterial bleeds. The idea here is to show the use of the product in the absolute worst-case scenario so that when this translates into the clinic, the models that we’ve used for evaluation, hopefully, are worse than what actually rolls into the trauma bay.

Glatter: Excellent. What’s the mean time to stop an arterial vs a venous bleed? Are we talking a matter of seconds?

Landolina: In the case of a healthy patient, meaning a patient without clotting compromise, you’re in a matter of seconds. It’s less than 10 seconds. 

In the case where you have clotting compromise, a deep, complicated wound geometry, we recommend holding a pressure bandage on for 3 minutes just because it increases the chance of Traumagel coming into contact with the bleed, especially when you can’t visualize the bleed in the bleed source. Because of that pressure time, that becomes the mean. But again, it’s highly dependent on the type of bleed and the style of application.

 

Failure Rates and Effectiveness

Glatter: As a segue to that, what is the failure rate based on your studies and internal research using Traumagel? Have there been cases where bleeding has not been able to be stopped? 

Landolina: It depends on the study, but the failure rates are incredibly low with Traumagel, assuming that it’s correctly used. That’s one of the benefits to this product, where with proper technique, with overwrap with gauze, you nearly always get control of hemorrhage with a product like this. 

Glatter: Is manual pressure required in that sense? From what you described earlier, manual pressure would not be required. 

Landolina: It depends on the injury. What we recommend is that, if you have a very deep wound where you cannot visualize the source of bleed, you use pressure to seat Traumagel into the source of bleeding, meaning that you’re following Committee on Tactical Combat Casualty Care (Co-TCCC) regulations or requirements, where you’re over wrapping with gauze, and you’re providing a pressure wrapping to ensure that the Traumagel is in contact with the bleed while it’s doing what it’s doing. 

In most cases, it doesn’t hurt to apply pressure on top of Traumagel as well. In more surface level bleeds, you don’t need pressure at all. 

 

Applications Beyond Trauma

Glatter: Interesting. In terms of further applications (eg, nose bleeds or GYN bleeding, which are life-threatening), do you see this coming as an application for the future? 

Landolina: That’s where we’re working. Traumagel is the successor to an animal health product called Vetigel. The formulations of the gel behind Vetigel and Traumagel are identical. Vetigel has a full surgical indication, and that’s everything from epistaxis to neuro and spine procedures, into cardiovascular and soft tissue surgeries, orthopedic medicine, and so on.

Cresilon’s goal is to eventually expand the indication of our technology to include surgical indications and other indications where we can help any patient that’s bleeding. 

Glatter: That’s important, because we use prehospital whole blood, low titer, specifically, when patients have life-threatening hemorrhage. With your product, that would reduce the amount of blood products that would need to be administered. This could be a real game changer. 

Landolina: Definitely, that’s the goal we’re working on. 

Infection Risks and Biocompatibility

Glatter: In terms of any risk for infection, has that been studied as well? Does Traumagel in any way lead to increased rates of infection?

Landolina: Traumagel is biocompatible. It’s a sterile product. We’ve done the full suite of biocompatibility testing as required by FDA. On top of that, remember that Vetigel, which is the same formulation, is an implantable product. As a result, that has even extended biocompatibility testing beyond what would be necessary for an external product.

In Vetigel’s use case, which has been used now in over 60,000 patients, primarily companion animals, dogs and cats, we haven’t seen instances of infection. There’s no reason to believe that we would see that clinically with Traumagel.

 

Research Collaborations and Future Applications

Glatter: In terms of other research that your company’s embarked on preclinically, I understand there were some studies done at Walter Reed Army Institute of Research. I was wondering if you could expand on these, specifically, in terms of traumatic brain injury (TBI) and hemorrhage related to that. For example, with shrapnel or even a gunshot wound. 

Landolina: The Walter Reed collaboration with Cresilon is something that I’m particularly excited about, because it marks Cresilon’s first project that’s outside the scope of just hemostasis. Walter Reed came to us with this proposal where there’s a big challenge in a subset of TBI called penetrating ballistic-like brain injury, where the brain has been penetrated by a bullet, shrapnel, or some other projectile, and there’s an injury that exposes the brain to the outside. 

Today, there is no standard of care to treat patients with those types of injuries. In many cases, mortality is caused through swelling of the brain, or collapse of the brain. What they came to us with was the potential of using our technology, not primarily as a hemostatic agent, but to be able to stabilize that patient enough to get to the next level of care to be treated by a neurosurgeon.

That study Walter Reed did was just a pilot that was done in small animals. In that pilot, they showed that over the period of treatment, there was no negative change in vital signs, no increase in edema or in swelling, or in any of the biomarkers that were being monitored at that time. 

At the very least, this is not full indication that this indication will work for Cresilon, but it shows that there’s promise. It’s something that we’re working on and hopefully we’ll be able to bring to market soon.

Glatter: Certainly, maintaining intracranial pressure and cerebral perfusion pressures are very critical. In the future, do you think this product would be able to be deployed endovascularly? Imagine this in terms of stopping bleeding from some source, whether it’s from a stroke or another intracranial source. 

Landolina: That’s been an area of interest for us. We have no evidence to prove that indication works at this point, but there’s also nothing to say that it wouldn’t be possible for our technology. At this point, we’ve only looked at a cursory level at those indications. 

Glatter: Does the use of Traumagel obviate the need for a more definitive repair (eg, with sutures) or something that’s more permanent?

Landolina: I always say that Traumagel — and Vetigel, for that matter — is not a replacement for good surgical technique. The surgeon always needs to make his or her best judgment when reviewing the patient. That doesn’t mean that there won’t need to be sutures or vascular repair in most of these cases, especially in major trauma.

Final Takeaways

Glatter: Do you have some bullet points or pearls you could give our audience as a takeaway? 

Landolina: When Cresilon looks at Traumagel — and for us, Traumagel is the next generation of hemostatic agent, especially in trauma care and in emergency medicine — it allows for a far-simplified application of the product and much faster control of hemorrhage with better patient outcomes.

As we roll this out through EMS agencies, trauma hospitals, military agencies, and eventually to the general public through a future indication, it’s something we’re very excited about. Personally, I started this business 14 years ago, and so it’s great to see our mission of saving lives transitioning to saving human lives.

Glatter: I look forward to seeing this product in the emergency department, but also in other settings, such as in the operating room where we can really help patients who are dying from hemorrhage, certainly on the battlefield, and the lay public. If someone were to come upon a patient who’s bleeding out, this could be certainly a game changer and a lifesaver. 

I want to thank you for your time. This is a really important product that’s transformed the lives of so many animals, but also people in the future.

Dr. Glatter is an assistant professor of emergency medicine at Zucker School of Medicine at Hofstra/Northwell in Hempstead, New York. He reported no relevant conflicts of interest. Mr. Landolina is the CEO and co-founder of Cresilon, a biotechnology company specializing in plant-based solutions for emergency bleeding control.

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

This video transcript has been edited for clarity. 

Robert D. Glatter, MD: Hi and welcome. I’m Dr. Robert Glatter, medical adviser for Medscape Emergency Medicine. Joining me today to discuss a novel, plant-based approach to stopping moderate to severe bleeding is Joe Landolina, CEO and cofounder of Cresilon. Welcome, Joe. 

Joe Landolina, MS: Thank you so much for taking the time. It’s great to be here.

Educational Background and Inception of Cresilon

Glatter: It’s a pleasure to have you join me, and I want to congratulate you on your recent 510(k) FDA clearance for your novel product to save lives and stop bleeding. To begin with, can you explain how the idea for launching your company came about? 

Landolina: The way that Cresilon came about was a little bit unorthodox, because I was 17 years old when I invented the technology behind the product that eventually became Traumagel®. 

My grandfather was an ex-pharmaceutical executive, who later in life started a vineyard. I grew up on a vineyard with a winery chemistry lab across the street from my house and a grandfather who learned lab safety in the 60s. So, that meant that the day I learned how to walk, I was tossed into a lab and I fell head over heels in love with lab research.

That started experimentation and my academic pursuits. That led to discovering a blend of two plant-based polymers derived from algae that stop bleeding on contact, effectively creating a mechanical barrier and allowing anything from a gunshot wound to anything quite a bit more minor to stop in a matter of seconds.

Glatter: Your background is in biomedical engineering. How is it that you started tinkering and doing all this type of work? 

Landolina: That’s correct. I did my undergrad in chemical engineering, and my graduate studies were in biomedical engineering. For me, that was supposed to be a pathway into medical school. I always wanted to be a surgeon myself, and I love the field of medicine. 

As a freshman in college at NYU Engineering, I had this idea. I entered it into NYU’s business plan competition, and we won at the engineering school. That gave us just enough capital to start developing and researching Traumagel more, and Cresilon was born out of that research.

 

Techniques for Stopping Hemorrhage

Glatter: In terms of stopping hemorrhage, which takes so many lives in the United States and globally — certainly, uncontrolled hemorrhage — what are the techniques that you see, prior to the arrival of your product, as being effective? Can you elucidate some of these techniques? 

Landolina: In emergency medicine, the primary mode of controlling hemorrhage is passive. It’s what, in Brooklyn, we like to call “pressure and a prayer”, where you have a material that’s either gauze or an impregnated gauze in most cases, where the mode of action is absorbing blood, with the adjunct of pressure by the first responder or by the clinician who’s providing aid.

The idea is to stop the flow of blood to concentrate blood factors at the surface of the gauze product, and to promote either platelet activation or the production of fibrin to create a clot. 

These types of technologies are widespread. There are many versions of this technology carried by EMS agencies, trauma bays, US military soldiers, and soldiers across NATO countries. But these types of technologies tend to be relatively inefficient, meaning that they’re very difficult to get into wounds because of the gauze or the powder form of the devices, and it’s very hard to get them in contact with the form of bleeding.

On top of that, if the patient is clotting compromised or immunocompromised in some way, the ability to create a durable clot that will not be ripped off when you remove the product at the next level of care is also of concern. And so, this type of technology or the type of treatment of massive hemorrhage hasn’t changed in decades.

 

Current Applications and Potential Use

Glatter: I envision this product will be carried by paramedics, used on the battlefield at some point after your FDA clearance, and recently it went through.

Do you see any possibility that this could be an AED equivalent to Stop the Bleed? In other words, could the average lay person be trained to use your product if kits are available? 

Landolina: To be very clear, Traumagel today is only approved or cleared under a “prescription-only” indication, which means that it will not initially be available OTC. However, that is our goal. Our goal is to make this product available and usable by someone with no medical training whatsoever. 

The form factor of being a gel in a syringe lends itself well to that, meaning that we try to make it as easy as point and shoot to control hemorrhage, where there’s not as much technique to be learned in the application of a product like Traumagel as there is in current hemorrhage control techniques. 

 

Mechanism of Action and Physiology

Glatter: Once you apply Traumagel, can you explain what happens to the product after it’s applied and the bleeding has stopped? Does it get reabsorbed by the body? What’s the process here? 

Landolina: Under Traumagel’s indication, because it’s used in traumatic injury, it must be removed within 24 hours.

One of the big benefits of Traumagel is that when the patient produces a blood clot underneath Traumagel, it doesn’t become incorporated within the gel itself. To contrast that with the use of gauze, gauze is porous. The clot ends up wrapped around the fibers of the gauze, so if you peel the gauze away, it’s very likely that clot is coming off with it. The surgeon or the clinician at the next level of care is going to have to deal with the re-bleed. 

You can remove Traumagel cleanly and entirely without disturbing the underlying clot. That’s a major benefit, not only to the patient but also to the next level of care, to the next clinician or physician that is required to remove the product.

Glatter: How is it possible to remove the substance without disturbing the clot? Can you explain in more detail? 

Landolina: That’s one of the hallmarks of these plant-based polymers and the way that we design Traumagel itself. Traumagel is completely nonporous, and it has no fibrous nature to it. What that means is when the patient produces a blood clot or fibrin next to or on top of Traumagel, that fibrin ends up not incorporated within the polymers of Traumagel itself. 

Over time, because Traumagel is a hydrogel, meaning that by weight it’s mostly water, you end up having less adhesion to the clot over time. When it’s time to remove Traumagel from the injury, it has lost almost all of its adhesive capabilities, meaning that when you peel it away, that clot is going to stick better to tissue than it will to the gel itself. 

Glatter: Can you explain a little bit about the matrix that’s formed, the physiology, and how the polymers work to form this matrix? 

Landolina: Sure. Traumagel is made of two polysaccharides that are plant derived. One polysaccharide is polyanionic, and the other is polycationic, meaning one has negative charges and the other has positive charges, which together create almost a Lego block effect, where when the material comes in contact with tissue, it adheres strongly and allows for itself to effectively create a mechanical barrier against bleeding.

Courtesy of Cresilon

Landolina: Even in the face of major arterial blood flow, Traumagel will stay where it needs to stay, and it’s not going to get washed away. This means that it is much more easily appliable to these types of surfaces and will allow the patient to produce their own endogenous fibrin clot at that location.

Like I mentioned before, when that fibrin clot is formed, because the gel itself has no pores or fibers, it doesn’t become incorporated within the fibrin clot. You can take the gel away, leaving that clot behind without the chance of a rebleed.

 

Testing With Major Bleeds

Glatter: In terms of bleeding itself, have you tested your product with major aortic bleeds or carotid bleeds in preclinical work?

Landolina: We have used the US military’s model for lethal hemorrhage, and the idea there is to create a model that is just that — lethal. These are the worst types of bleeds that you can possibly imagine, where the patients are clotting compromised, and where you have, in most cases, a very strong arterial component, so something like a femoral artery bleed.

We’ve also tested in carotid artery, aortic applications, as well as combinations of venous and arterial bleeds. The idea here is to show the use of the product in the absolute worst-case scenario so that when this translates into the clinic, the models that we’ve used for evaluation, hopefully, are worse than what actually rolls into the trauma bay.

Glatter: Excellent. What’s the mean time to stop an arterial vs a venous bleed? Are we talking a matter of seconds?

Landolina: In the case of a healthy patient, meaning a patient without clotting compromise, you’re in a matter of seconds. It’s less than 10 seconds. 

In the case where you have clotting compromise, a deep, complicated wound geometry, we recommend holding a pressure bandage on for 3 minutes just because it increases the chance of Traumagel coming into contact with the bleed, especially when you can’t visualize the bleed in the bleed source. Because of that pressure time, that becomes the mean. But again, it’s highly dependent on the type of bleed and the style of application.

 

Failure Rates and Effectiveness

Glatter: As a segue to that, what is the failure rate based on your studies and internal research using Traumagel? Have there been cases where bleeding has not been able to be stopped? 

Landolina: It depends on the study, but the failure rates are incredibly low with Traumagel, assuming that it’s correctly used. That’s one of the benefits to this product, where with proper technique, with overwrap with gauze, you nearly always get control of hemorrhage with a product like this. 

Glatter: Is manual pressure required in that sense? From what you described earlier, manual pressure would not be required. 

Landolina: It depends on the injury. What we recommend is that, if you have a very deep wound where you cannot visualize the source of bleed, you use pressure to seat Traumagel into the source of bleeding, meaning that you’re following Committee on Tactical Combat Casualty Care (Co-TCCC) regulations or requirements, where you’re over wrapping with gauze, and you’re providing a pressure wrapping to ensure that the Traumagel is in contact with the bleed while it’s doing what it’s doing. 

In most cases, it doesn’t hurt to apply pressure on top of Traumagel as well. In more surface level bleeds, you don’t need pressure at all. 

 

Applications Beyond Trauma

Glatter: Interesting. In terms of further applications (eg, nose bleeds or GYN bleeding, which are life-threatening), do you see this coming as an application for the future? 

Landolina: That’s where we’re working. Traumagel is the successor to an animal health product called Vetigel. The formulations of the gel behind Vetigel and Traumagel are identical. Vetigel has a full surgical indication, and that’s everything from epistaxis to neuro and spine procedures, into cardiovascular and soft tissue surgeries, orthopedic medicine, and so on.

Cresilon’s goal is to eventually expand the indication of our technology to include surgical indications and other indications where we can help any patient that’s bleeding. 

Glatter: That’s important, because we use prehospital whole blood, low titer, specifically, when patients have life-threatening hemorrhage. With your product, that would reduce the amount of blood products that would need to be administered. This could be a real game changer. 

Landolina: Definitely, that’s the goal we’re working on. 

Infection Risks and Biocompatibility

Glatter: In terms of any risk for infection, has that been studied as well? Does Traumagel in any way lead to increased rates of infection?

Landolina: Traumagel is biocompatible. It’s a sterile product. We’ve done the full suite of biocompatibility testing as required by FDA. On top of that, remember that Vetigel, which is the same formulation, is an implantable product. As a result, that has even extended biocompatibility testing beyond what would be necessary for an external product.

In Vetigel’s use case, which has been used now in over 60,000 patients, primarily companion animals, dogs and cats, we haven’t seen instances of infection. There’s no reason to believe that we would see that clinically with Traumagel.

 

Research Collaborations and Future Applications

Glatter: In terms of other research that your company’s embarked on preclinically, I understand there were some studies done at Walter Reed Army Institute of Research. I was wondering if you could expand on these, specifically, in terms of traumatic brain injury (TBI) and hemorrhage related to that. For example, with shrapnel or even a gunshot wound. 

Landolina: The Walter Reed collaboration with Cresilon is something that I’m particularly excited about, because it marks Cresilon’s first project that’s outside the scope of just hemostasis. Walter Reed came to us with this proposal where there’s a big challenge in a subset of TBI called penetrating ballistic-like brain injury, where the brain has been penetrated by a bullet, shrapnel, or some other projectile, and there’s an injury that exposes the brain to the outside. 

Today, there is no standard of care to treat patients with those types of injuries. In many cases, mortality is caused through swelling of the brain, or collapse of the brain. What they came to us with was the potential of using our technology, not primarily as a hemostatic agent, but to be able to stabilize that patient enough to get to the next level of care to be treated by a neurosurgeon.

That study Walter Reed did was just a pilot that was done in small animals. In that pilot, they showed that over the period of treatment, there was no negative change in vital signs, no increase in edema or in swelling, or in any of the biomarkers that were being monitored at that time. 

At the very least, this is not full indication that this indication will work for Cresilon, but it shows that there’s promise. It’s something that we’re working on and hopefully we’ll be able to bring to market soon.

Glatter: Certainly, maintaining intracranial pressure and cerebral perfusion pressures are very critical. In the future, do you think this product would be able to be deployed endovascularly? Imagine this in terms of stopping bleeding from some source, whether it’s from a stroke or another intracranial source. 

Landolina: That’s been an area of interest for us. We have no evidence to prove that indication works at this point, but there’s also nothing to say that it wouldn’t be possible for our technology. At this point, we’ve only looked at a cursory level at those indications. 

Glatter: Does the use of Traumagel obviate the need for a more definitive repair (eg, with sutures) or something that’s more permanent?

Landolina: I always say that Traumagel — and Vetigel, for that matter — is not a replacement for good surgical technique. The surgeon always needs to make his or her best judgment when reviewing the patient. That doesn’t mean that there won’t need to be sutures or vascular repair in most of these cases, especially in major trauma.

Final Takeaways

Glatter: Do you have some bullet points or pearls you could give our audience as a takeaway? 

Landolina: When Cresilon looks at Traumagel — and for us, Traumagel is the next generation of hemostatic agent, especially in trauma care and in emergency medicine — it allows for a far-simplified application of the product and much faster control of hemorrhage with better patient outcomes.

As we roll this out through EMS agencies, trauma hospitals, military agencies, and eventually to the general public through a future indication, it’s something we’re very excited about. Personally, I started this business 14 years ago, and so it’s great to see our mission of saving lives transitioning to saving human lives.

Glatter: I look forward to seeing this product in the emergency department, but also in other settings, such as in the operating room where we can really help patients who are dying from hemorrhage, certainly on the battlefield, and the lay public. If someone were to come upon a patient who’s bleeding out, this could be certainly a game changer and a lifesaver. 

I want to thank you for your time. This is a really important product that’s transformed the lives of so many animals, but also people in the future.

Dr. Glatter is an assistant professor of emergency medicine at Zucker School of Medicine at Hofstra/Northwell in Hempstead, New York. He reported no relevant conflicts of interest. Mr. Landolina is the CEO and co-founder of Cresilon, a biotechnology company specializing in plant-based solutions for emergency bleeding control.

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

Long COVID is a symptom-driven disease, meaning that with no cure, physicians primarily treat the symptoms their patients are experiencing. Effective treatments for long COVID remain elusive because what works for one patient may be entirely ineffective for another. But as 2024 winds down, researchers have begun to pinpoint a number of treatments that are bringing relief to the 17 million Americans diagnosed with long COVID.

Here’s a current look at what research has identified as some of the most promising treatments.

 

Low-Dose Naltrexone

Some research suggests that low-dose naltrexone may be helpful for patients suffering from brain fog, pain, sleep issues, and fatigue, said Ziyad Al-Aly, MD, a global expert on long COVID and chief of research and development at the Veterans Affairs St Louis Health Care System in Missouri.

Low-dose naltrexone is an anti-inflammatory agent currently approved by the Food and Drug Administration for the treatment of alcohol and opioid dependence.

“We don’t know the mechanism for how the medication works, and for that matter, we don’t really understand what causes brain fog. But perhaps its anti-inflammatory properties seem to help, and for some patients, low-dose naltrexone has been helpful,” said Al-Aly.

A March 2024 study found that both fatigue and pain were improved in patients taking low-dose naltrexone. In another study, published in the June 2024 issue of Frontiers in Medicine, researchers found that low-dose naltrexone was associated with improvement of several clinical symptoms related to long COVID such as fatigue, poor sleep quality, brain fog, post-exertional malaise, and headache.

 

Selective Serotonin Reuptake Inhibitors (SSRIs) and Antidepressants

In 2023, University of Pennsylvania researchers uncovered a link between long COVID and lower levels of serotonin in the body. This helped point to the potential treatment of using SSRIs to treat the condition.

For patients who have overlapping psychiatric issues that go along with brain fog, SSRIs prescribed to treat depression and other mental health conditions, as well as the antidepressant Wellbutrin, have been shown effective at dealing with concentration issues, brain fog, and depression, said Nisha Viswanathan, MD, director of the University of California, Los Angeles (UCLA) Long COVID Program at UCLA Health.

A study published in the November 2023 issue of the journal Scientific Reports found that SSRIs led to a “considerable reduction of symptoms,” especially brain fog, fatigue, sensory overload, and overall improved functioning. Low-dose Abilify, which contains aripiprazole, an antipsychotic medication, has also been found to be effective for cognitive issues caused by long COVID.

“Abilify is traditionally used for the treatment of schizophrenia or other psychotic disorders, but in a low-dose format, there is some data to suggest that it can also be anti-inflammatory and helpful for cognitive issues like brain fog,” said Viswanathan.

 

Modafinil

Modafinil, a medication previously used for managing narcolepsy, has also been shown effective for the treatment of fatigue and neurocognitive deficits caused by long COVID, said Viswanathan, adding that it’s another medication that she’s found useful for a number of her patients.

It’s thought that these cognitive symptoms are caused by an inflammatory cytokine release that leads to excessive stimulation of neurotransmitters in the body. According to a June 2024 article in the American Journal of Psychiatry, “Modafinil can therapeutically act on these pathways, which possibly contributed to the symptomatic improvement.” But the medication has not been studied widely in patients with long COVID and has been shown to have interactions with other medications.

 

Metformin

Some research has shown that metformin, a well-known diabetes medication, reduces instances of long COVID when taken during the illness’s acute phase. It seems to boost metabolic function in patients.

“It makes sense that it would work because it seems to have anti-inflammatory effects on the body,” said Grace McComsey, MD, who leads one of the 15 nationwide long COVID centers funded by the federal RECOVER (Researching COVID to Enhance Recovery) Initiative in Cleveland, Ohio. McComsey added that it may reduce the viral persistence that causes some forms of long COVID.

A study published in the October 2023 issue of the journal The Lancet Infectious Diseases found that metformin seemed to reduce instances of long COVID in patients who took it after being diagnosed with acute COVID. It seems less effective in patients who already have long COVID.

 

Antihistamines

Other data suggest that some patients with long COVID showed improvement after taking antihistamines. Research has shown that long COVID symptoms improved in 29% of patients with long COVID.

While researchers aren’t sure why antihistamines work to quell long COVID, the thought is that, when mast cells, a white blood cell that’s part of the immune system, shed granules and cause an inflammatory reaction, they release a lot of histamines. Antihistamine medications like famotidine block histamine receptors in the body, improving symptoms like brain fog, difficulty breathing, and elevated heart rate in patients.

“For some patients, these can be a lifesaver,” said David Putrino, the Nash Family Director of the Cohen Center for Recovery from Complex Chronic Illness and a national leader in the treatment of long COVID.

Putrino cautions patients toward taking these and other medications haphazardly without fully understanding that all treatments have risks, especially if they’re taking a number of them.

“Often patients are told that there’s no risk to trying something, but physicians should be counseling their patients and reminding them that there is a risk that includes medication sensitivities and medication interactions,” said Putrino.

The good news is that doctors have begun to identify some treatments that seem to be working in their patients, but we still don’t have the large-scale clinical trials to identify which treatments will work for certain patients and why.

There’s still so much we don’t know, and for physicians on the front lines of treating long COVID, it’s still largely a guessing game. “This is a constellation of symptoms; it’s not just one thing,” said Al-Aly. And while a treatment might be wildly effective for one patient, it might be ineffective or worse, problematic, for another.

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

Long COVID is a symptom-driven disease, meaning that with no cure, physicians primarily treat the symptoms their patients are experiencing. Effective treatments for long COVID remain elusive because what works for one patient may be entirely ineffective for another. But as 2024 winds down, researchers have begun to pinpoint a number of treatments that are bringing relief to the 17 million Americans diagnosed with long COVID.

Here’s a current look at what research has identified as some of the most promising treatments.

 

Low-Dose Naltrexone

Some research suggests that low-dose naltrexone may be helpful for patients suffering from brain fog, pain, sleep issues, and fatigue, said Ziyad Al-Aly, MD, a global expert on long COVID and chief of research and development at the Veterans Affairs St Louis Health Care System in Missouri.

Low-dose naltrexone is an anti-inflammatory agent currently approved by the Food and Drug Administration for the treatment of alcohol and opioid dependence.

“We don’t know the mechanism for how the medication works, and for that matter, we don’t really understand what causes brain fog. But perhaps its anti-inflammatory properties seem to help, and for some patients, low-dose naltrexone has been helpful,” said Al-Aly.

A March 2024 study found that both fatigue and pain were improved in patients taking low-dose naltrexone. In another study, published in the June 2024 issue of Frontiers in Medicine, researchers found that low-dose naltrexone was associated with improvement of several clinical symptoms related to long COVID such as fatigue, poor sleep quality, brain fog, post-exertional malaise, and headache.

 

Selective Serotonin Reuptake Inhibitors (SSRIs) and Antidepressants

In 2023, University of Pennsylvania researchers uncovered a link between long COVID and lower levels of serotonin in the body. This helped point to the potential treatment of using SSRIs to treat the condition.

For patients who have overlapping psychiatric issues that go along with brain fog, SSRIs prescribed to treat depression and other mental health conditions, as well as the antidepressant Wellbutrin, have been shown effective at dealing with concentration issues, brain fog, and depression, said Nisha Viswanathan, MD, director of the University of California, Los Angeles (UCLA) Long COVID Program at UCLA Health.

A study published in the November 2023 issue of the journal Scientific Reports found that SSRIs led to a “considerable reduction of symptoms,” especially brain fog, fatigue, sensory overload, and overall improved functioning. Low-dose Abilify, which contains aripiprazole, an antipsychotic medication, has also been found to be effective for cognitive issues caused by long COVID.

“Abilify is traditionally used for the treatment of schizophrenia or other psychotic disorders, but in a low-dose format, there is some data to suggest that it can also be anti-inflammatory and helpful for cognitive issues like brain fog,” said Viswanathan.

 

Modafinil

Modafinil, a medication previously used for managing narcolepsy, has also been shown effective for the treatment of fatigue and neurocognitive deficits caused by long COVID, said Viswanathan, adding that it’s another medication that she’s found useful for a number of her patients.

It’s thought that these cognitive symptoms are caused by an inflammatory cytokine release that leads to excessive stimulation of neurotransmitters in the body. According to a June 2024 article in the American Journal of Psychiatry, “Modafinil can therapeutically act on these pathways, which possibly contributed to the symptomatic improvement.” But the medication has not been studied widely in patients with long COVID and has been shown to have interactions with other medications.

 

Metformin

Some research has shown that metformin, a well-known diabetes medication, reduces instances of long COVID when taken during the illness’s acute phase. It seems to boost metabolic function in patients.

“It makes sense that it would work because it seems to have anti-inflammatory effects on the body,” said Grace McComsey, MD, who leads one of the 15 nationwide long COVID centers funded by the federal RECOVER (Researching COVID to Enhance Recovery) Initiative in Cleveland, Ohio. McComsey added that it may reduce the viral persistence that causes some forms of long COVID.

A study published in the October 2023 issue of the journal The Lancet Infectious Diseases found that metformin seemed to reduce instances of long COVID in patients who took it after being diagnosed with acute COVID. It seems less effective in patients who already have long COVID.

 

Antihistamines

Other data suggest that some patients with long COVID showed improvement after taking antihistamines. Research has shown that long COVID symptoms improved in 29% of patients with long COVID.

While researchers aren’t sure why antihistamines work to quell long COVID, the thought is that, when mast cells, a white blood cell that’s part of the immune system, shed granules and cause an inflammatory reaction, they release a lot of histamines. Antihistamine medications like famotidine block histamine receptors in the body, improving symptoms like brain fog, difficulty breathing, and elevated heart rate in patients.

“For some patients, these can be a lifesaver,” said David Putrino, the Nash Family Director of the Cohen Center for Recovery from Complex Chronic Illness and a national leader in the treatment of long COVID.

Putrino cautions patients toward taking these and other medications haphazardly without fully understanding that all treatments have risks, especially if they’re taking a number of them.

“Often patients are told that there’s no risk to trying something, but physicians should be counseling their patients and reminding them that there is a risk that includes medication sensitivities and medication interactions,” said Putrino.

The good news is that doctors have begun to identify some treatments that seem to be working in their patients, but we still don’t have the large-scale clinical trials to identify which treatments will work for certain patients and why.

There’s still so much we don’t know, and for physicians on the front lines of treating long COVID, it’s still largely a guessing game. “This is a constellation of symptoms; it’s not just one thing,” said Al-Aly. And while a treatment might be wildly effective for one patient, it might be ineffective or worse, problematic, for another.

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

Long COVID is a symptom-driven disease, meaning that with no cure, physicians primarily treat the symptoms their patients are experiencing. Effective treatments for long COVID remain elusive because what works for one patient may be entirely ineffective for another. But as 2024 winds down, researchers have begun to pinpoint a number of treatments that are bringing relief to the 17 million Americans diagnosed with long COVID.

Here’s a current look at what research has identified as some of the most promising treatments.

 

Low-Dose Naltrexone

Some research suggests that low-dose naltrexone may be helpful for patients suffering from brain fog, pain, sleep issues, and fatigue, said Ziyad Al-Aly, MD, a global expert on long COVID and chief of research and development at the Veterans Affairs St Louis Health Care System in Missouri.

Low-dose naltrexone is an anti-inflammatory agent currently approved by the Food and Drug Administration for the treatment of alcohol and opioid dependence.

“We don’t know the mechanism for how the medication works, and for that matter, we don’t really understand what causes brain fog. But perhaps its anti-inflammatory properties seem to help, and for some patients, low-dose naltrexone has been helpful,” said Al-Aly.

A March 2024 study found that both fatigue and pain were improved in patients taking low-dose naltrexone. In another study, published in the June 2024 issue of Frontiers in Medicine, researchers found that low-dose naltrexone was associated with improvement of several clinical symptoms related to long COVID such as fatigue, poor sleep quality, brain fog, post-exertional malaise, and headache.

 

Selective Serotonin Reuptake Inhibitors (SSRIs) and Antidepressants

In 2023, University of Pennsylvania researchers uncovered a link between long COVID and lower levels of serotonin in the body. This helped point to the potential treatment of using SSRIs to treat the condition.

For patients who have overlapping psychiatric issues that go along with brain fog, SSRIs prescribed to treat depression and other mental health conditions, as well as the antidepressant Wellbutrin, have been shown effective at dealing with concentration issues, brain fog, and depression, said Nisha Viswanathan, MD, director of the University of California, Los Angeles (UCLA) Long COVID Program at UCLA Health.

A study published in the November 2023 issue of the journal Scientific Reports found that SSRIs led to a “considerable reduction of symptoms,” especially brain fog, fatigue, sensory overload, and overall improved functioning. Low-dose Abilify, which contains aripiprazole, an antipsychotic medication, has also been found to be effective for cognitive issues caused by long COVID.

“Abilify is traditionally used for the treatment of schizophrenia or other psychotic disorders, but in a low-dose format, there is some data to suggest that it can also be anti-inflammatory and helpful for cognitive issues like brain fog,” said Viswanathan.

 

Modafinil

Modafinil, a medication previously used for managing narcolepsy, has also been shown effective for the treatment of fatigue and neurocognitive deficits caused by long COVID, said Viswanathan, adding that it’s another medication that she’s found useful for a number of her patients.

It’s thought that these cognitive symptoms are caused by an inflammatory cytokine release that leads to excessive stimulation of neurotransmitters in the body. According to a June 2024 article in the American Journal of Psychiatry, “Modafinil can therapeutically act on these pathways, which possibly contributed to the symptomatic improvement.” But the medication has not been studied widely in patients with long COVID and has been shown to have interactions with other medications.

 

Metformin

Some research has shown that metformin, a well-known diabetes medication, reduces instances of long COVID when taken during the illness’s acute phase. It seems to boost metabolic function in patients.

“It makes sense that it would work because it seems to have anti-inflammatory effects on the body,” said Grace McComsey, MD, who leads one of the 15 nationwide long COVID centers funded by the federal RECOVER (Researching COVID to Enhance Recovery) Initiative in Cleveland, Ohio. McComsey added that it may reduce the viral persistence that causes some forms of long COVID.

A study published in the October 2023 issue of the journal The Lancet Infectious Diseases found that metformin seemed to reduce instances of long COVID in patients who took it after being diagnosed with acute COVID. It seems less effective in patients who already have long COVID.

 

Antihistamines

Other data suggest that some patients with long COVID showed improvement after taking antihistamines. Research has shown that long COVID symptoms improved in 29% of patients with long COVID.

While researchers aren’t sure why antihistamines work to quell long COVID, the thought is that, when mast cells, a white blood cell that’s part of the immune system, shed granules and cause an inflammatory reaction, they release a lot of histamines. Antihistamine medications like famotidine block histamine receptors in the body, improving symptoms like brain fog, difficulty breathing, and elevated heart rate in patients.

“For some patients, these can be a lifesaver,” said David Putrino, the Nash Family Director of the Cohen Center for Recovery from Complex Chronic Illness and a national leader in the treatment of long COVID.

Putrino cautions patients toward taking these and other medications haphazardly without fully understanding that all treatments have risks, especially if they’re taking a number of them.

“Often patients are told that there’s no risk to trying something, but physicians should be counseling their patients and reminding them that there is a risk that includes medication sensitivities and medication interactions,” said Putrino.

The good news is that doctors have begun to identify some treatments that seem to be working in their patients, but we still don’t have the large-scale clinical trials to identify which treatments will work for certain patients and why.

There’s still so much we don’t know, and for physicians on the front lines of treating long COVID, it’s still largely a guessing game. “This is a constellation of symptoms; it’s not just one thing,” said Al-Aly. And while a treatment might be wildly effective for one patient, it might be ineffective or worse, problematic, for another.

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

This video transcript has been edited for clarity. 

Dear colleagues, I am Christoph Diener, from the Faculty of Medicine at the University Duisburg-Essen in Germany. In this video, I would like to cover six publications on stroke, which were published this fall. 

The Best Thrombolytic?

Let me start with systemic thrombolysis. We now have two thrombolytic agents available. One is the well-known alteplase, and newly approved for the treatment of stroke is tenecteplase. The ATTEST-2 study in the United Kingdom, published in The Lancet Neurology, compared tenecteplase 0.25 mg/kg body weight as a bolus with alteplase 0.9 mg/kg body weight as an infusion over 60 minutes in the 4.5-hour time window in 1777 patients with ischemic stroke.

There was no significant difference between the two thrombolytics for the primary endpoint of modified Rankin Scale score after 90 days. There was also no difference with respect to mortality, intracranial bleeding, or extracranial bleeding. 

We finally have 11 randomized controlled trials that compared tenecteplase and alteplase in acute ischemic stroke. A meta-analysis of these randomized trials was published in Neurology. The analysis included 3700 patients treated with tenecteplase and 3700 patients treated with alteplase. For the primary endpoint, excellent functional outcome defined as modified Rankin Scale score 0-1 after 90 days, there was a significant benefit for tenecteplase (relative risk, 1.05), but the absolute difference was very small, at 3%. There was no difference in mortality or bleeding complications. 

In conclusion, I think both substances are great. They are effective. Tenecteplase is most probably the drug which should be used in people who have to transfer from a primary stroke center to a dedicated stroke center that provides thrombectomy. Otherwise, I think it’s a choice of the physician as to which thrombolytic agent to use. 

 

Mobile Stroke Units

A highly debated topic is mobile stroke units. These stroke units have a CT scanner and laboratory on board, and this makes it possible to perform thrombolysis on the way to the hospital. A retrospective, observational study collected data between 2018 and 2023, and included 19,400 patients with acute stroke, of whom 1237, or 6.4%, were treated in a mobile stroke unit. This study was published in JAMA Neurology. 

The modified Rankin Scale score at the time of discharge was better in patients treated with a mobile stroke unit, but the absolute benefit was only 0.03 points on the modified Rankin Scale. The question is whether this is cost-effective, and can we really do this at times when there is a traumatic shortage of physicians and nursing staff in the hospital? 

 

DOAC Reversal Agents

Oral anticoagulation, as you know, is usually considered a contraindication for systemic thrombolysis. Idarucizumab, a monoclonal antibody, was developed to reverse the biological activity of dabigatran and then allow systemic thrombolysis.

A recent publication in Neurology analyzed 13 cohort studies with 553 stroke patients on dabigatran who received idarucizumab prior to systemic thrombolysis, and the rate of intracranial hemorrhage was 4%. This means it’s obviously possible to perform thrombolysis when the activity of dabigatran is neutralized by idarucizumab.

Unfortunately, until today, we have no data on whether this can also be done with andexanet alfa in people who are treated with a factor Xa inhibitor like, for example, apixaban, rivaroxaban, or edoxaban. 

 

Anticoagulation in ESUS 

My next topic is ESUS, or embolic stroke of undetermined source. We have four large randomized trials and three smaller trials that compared antiplatelet therapy with DOACs in patients with ESUS. A group in Neurology published a meta-analysis of seven randomized controlled studies with, altogether, 14,800 patients with ESUS. 

The comparison between antiplatelet therapy and anticoagulants showed no difference for recurrent ischemic stroke, and also not for major subgroups. This means that people with ESUS should receive antiplatelet therapy, most probably aspirin. 

 

Anticoagulation Post–Ischemic Stroke With AF 

My final topic is the optimal time to start anticoagulation in people with atrial fibrillation who suffer an ischemic stroke. The OPTIMAS study, published in The Lancet, randomized 3650 patients who were anticoagulated with DOACs early (which means less than 4 days) or delayed (between 7 and 14 days). There was no difference in the primary endpoint, which was recurrent ischemic stroke, intracranial hemorrhage, or systemic embolism at 90 days.

The conclusion is that, in most cases, we can probably initiate anticoagulation in people with ischemic stroke and atrial fibrillation within the first 4 days. 

Dear colleagues, this is an exciting time for the stroke field. I presented six new studies that have impact, I think, on the management of patients with ischemic stroke.

Dr. Diener is a professor in the Department of Neurology, Stroke Center-Headache Center, University Duisburg-Essen in Germany. He reported conflicts of interest with Abbott, AbbVie, Boehringer Ingelheim, Lundbeck, Novartis, Orion Pharma, Teva, WebMD, and The German Research Council. He also serves on the editorial boards of Cephalalgia, Lancet Neurology, and Drugs.

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

This video transcript has been edited for clarity. 

Dear colleagues, I am Christoph Diener, from the Faculty of Medicine at the University Duisburg-Essen in Germany. In this video, I would like to cover six publications on stroke, which were published this fall. 

The Best Thrombolytic?

Let me start with systemic thrombolysis. We now have two thrombolytic agents available. One is the well-known alteplase, and newly approved for the treatment of stroke is tenecteplase. The ATTEST-2 study in the United Kingdom, published in The Lancet Neurology, compared tenecteplase 0.25 mg/kg body weight as a bolus with alteplase 0.9 mg/kg body weight as an infusion over 60 minutes in the 4.5-hour time window in 1777 patients with ischemic stroke.

There was no significant difference between the two thrombolytics for the primary endpoint of modified Rankin Scale score after 90 days. There was also no difference with respect to mortality, intracranial bleeding, or extracranial bleeding. 

We finally have 11 randomized controlled trials that compared tenecteplase and alteplase in acute ischemic stroke. A meta-analysis of these randomized trials was published in Neurology. The analysis included 3700 patients treated with tenecteplase and 3700 patients treated with alteplase. For the primary endpoint, excellent functional outcome defined as modified Rankin Scale score 0-1 after 90 days, there was a significant benefit for tenecteplase (relative risk, 1.05), but the absolute difference was very small, at 3%. There was no difference in mortality or bleeding complications. 

In conclusion, I think both substances are great. They are effective. Tenecteplase is most probably the drug which should be used in people who have to transfer from a primary stroke center to a dedicated stroke center that provides thrombectomy. Otherwise, I think it’s a choice of the physician as to which thrombolytic agent to use. 

 

Mobile Stroke Units

A highly debated topic is mobile stroke units. These stroke units have a CT scanner and laboratory on board, and this makes it possible to perform thrombolysis on the way to the hospital. A retrospective, observational study collected data between 2018 and 2023, and included 19,400 patients with acute stroke, of whom 1237, or 6.4%, were treated in a mobile stroke unit. This study was published in JAMA Neurology. 

The modified Rankin Scale score at the time of discharge was better in patients treated with a mobile stroke unit, but the absolute benefit was only 0.03 points on the modified Rankin Scale. The question is whether this is cost-effective, and can we really do this at times when there is a traumatic shortage of physicians and nursing staff in the hospital? 

 

DOAC Reversal Agents

Oral anticoagulation, as you know, is usually considered a contraindication for systemic thrombolysis. Idarucizumab, a monoclonal antibody, was developed to reverse the biological activity of dabigatran and then allow systemic thrombolysis.

A recent publication in Neurology analyzed 13 cohort studies with 553 stroke patients on dabigatran who received idarucizumab prior to systemic thrombolysis, and the rate of intracranial hemorrhage was 4%. This means it’s obviously possible to perform thrombolysis when the activity of dabigatran is neutralized by idarucizumab.

Unfortunately, until today, we have no data on whether this can also be done with andexanet alfa in people who are treated with a factor Xa inhibitor like, for example, apixaban, rivaroxaban, or edoxaban. 

 

Anticoagulation in ESUS 

My next topic is ESUS, or embolic stroke of undetermined source. We have four large randomized trials and three smaller trials that compared antiplatelet therapy with DOACs in patients with ESUS. A group in Neurology published a meta-analysis of seven randomized controlled studies with, altogether, 14,800 patients with ESUS. 

The comparison between antiplatelet therapy and anticoagulants showed no difference for recurrent ischemic stroke, and also not for major subgroups. This means that people with ESUS should receive antiplatelet therapy, most probably aspirin. 

 

Anticoagulation Post–Ischemic Stroke With AF 

My final topic is the optimal time to start anticoagulation in people with atrial fibrillation who suffer an ischemic stroke. The OPTIMAS study, published in The Lancet, randomized 3650 patients who were anticoagulated with DOACs early (which means less than 4 days) or delayed (between 7 and 14 days). There was no difference in the primary endpoint, which was recurrent ischemic stroke, intracranial hemorrhage, or systemic embolism at 90 days.

The conclusion is that, in most cases, we can probably initiate anticoagulation in people with ischemic stroke and atrial fibrillation within the first 4 days. 

Dear colleagues, this is an exciting time for the stroke field. I presented six new studies that have impact, I think, on the management of patients with ischemic stroke.

Dr. Diener is a professor in the Department of Neurology, Stroke Center-Headache Center, University Duisburg-Essen in Germany. He reported conflicts of interest with Abbott, AbbVie, Boehringer Ingelheim, Lundbeck, Novartis, Orion Pharma, Teva, WebMD, and The German Research Council. He also serves on the editorial boards of Cephalalgia, Lancet Neurology, and Drugs.

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

This video transcript has been edited for clarity. 

Dear colleagues, I am Christoph Diener, from the Faculty of Medicine at the University Duisburg-Essen in Germany. In this video, I would like to cover six publications on stroke, which were published this fall. 

The Best Thrombolytic?

Let me start with systemic thrombolysis. We now have two thrombolytic agents available. One is the well-known alteplase, and newly approved for the treatment of stroke is tenecteplase. The ATTEST-2 study in the United Kingdom, published in The Lancet Neurology, compared tenecteplase 0.25 mg/kg body weight as a bolus with alteplase 0.9 mg/kg body weight as an infusion over 60 minutes in the 4.5-hour time window in 1777 patients with ischemic stroke.

There was no significant difference between the two thrombolytics for the primary endpoint of modified Rankin Scale score after 90 days. There was also no difference with respect to mortality, intracranial bleeding, or extracranial bleeding. 

We finally have 11 randomized controlled trials that compared tenecteplase and alteplase in acute ischemic stroke. A meta-analysis of these randomized trials was published in Neurology. The analysis included 3700 patients treated with tenecteplase and 3700 patients treated with alteplase. For the primary endpoint, excellent functional outcome defined as modified Rankin Scale score 0-1 after 90 days, there was a significant benefit for tenecteplase (relative risk, 1.05), but the absolute difference was very small, at 3%. There was no difference in mortality or bleeding complications. 

In conclusion, I think both substances are great. They are effective. Tenecteplase is most probably the drug which should be used in people who have to transfer from a primary stroke center to a dedicated stroke center that provides thrombectomy. Otherwise, I think it’s a choice of the physician as to which thrombolytic agent to use. 

 

Mobile Stroke Units

A highly debated topic is mobile stroke units. These stroke units have a CT scanner and laboratory on board, and this makes it possible to perform thrombolysis on the way to the hospital. A retrospective, observational study collected data between 2018 and 2023, and included 19,400 patients with acute stroke, of whom 1237, or 6.4%, were treated in a mobile stroke unit. This study was published in JAMA Neurology. 

The modified Rankin Scale score at the time of discharge was better in patients treated with a mobile stroke unit, but the absolute benefit was only 0.03 points on the modified Rankin Scale. The question is whether this is cost-effective, and can we really do this at times when there is a traumatic shortage of physicians and nursing staff in the hospital? 

 

DOAC Reversal Agents

Oral anticoagulation, as you know, is usually considered a contraindication for systemic thrombolysis. Idarucizumab, a monoclonal antibody, was developed to reverse the biological activity of dabigatran and then allow systemic thrombolysis.

A recent publication in Neurology analyzed 13 cohort studies with 553 stroke patients on dabigatran who received idarucizumab prior to systemic thrombolysis, and the rate of intracranial hemorrhage was 4%. This means it’s obviously possible to perform thrombolysis when the activity of dabigatran is neutralized by idarucizumab.

Unfortunately, until today, we have no data on whether this can also be done with andexanet alfa in people who are treated with a factor Xa inhibitor like, for example, apixaban, rivaroxaban, or edoxaban. 

 

Anticoagulation in ESUS 

My next topic is ESUS, or embolic stroke of undetermined source. We have four large randomized trials and three smaller trials that compared antiplatelet therapy with DOACs in patients with ESUS. A group in Neurology published a meta-analysis of seven randomized controlled studies with, altogether, 14,800 patients with ESUS. 

The comparison between antiplatelet therapy and anticoagulants showed no difference for recurrent ischemic stroke, and also not for major subgroups. This means that people with ESUS should receive antiplatelet therapy, most probably aspirin. 

 

Anticoagulation Post–Ischemic Stroke With AF 

My final topic is the optimal time to start anticoagulation in people with atrial fibrillation who suffer an ischemic stroke. The OPTIMAS study, published in The Lancet, randomized 3650 patients who were anticoagulated with DOACs early (which means less than 4 days) or delayed (between 7 and 14 days). There was no difference in the primary endpoint, which was recurrent ischemic stroke, intracranial hemorrhage, or systemic embolism at 90 days.

The conclusion is that, in most cases, we can probably initiate anticoagulation in people with ischemic stroke and atrial fibrillation within the first 4 days. 

Dear colleagues, this is an exciting time for the stroke field. I presented six new studies that have impact, I think, on the management of patients with ischemic stroke.

Dr. Diener is a professor in the Department of Neurology, Stroke Center-Headache Center, University Duisburg-Essen in Germany. He reported conflicts of interest with Abbott, AbbVie, Boehringer Ingelheim, Lundbeck, Novartis, Orion Pharma, Teva, WebMD, and The German Research Council. He also serves on the editorial boards of Cephalalgia, Lancet Neurology, and Drugs.

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

In a recent survey of 1259 mothers published in the journal Pediatrics, 28% reported they had fallen asleep while feeding their babies, and 83% of those mothers reported that the sleep was unplanned. Although the study sample was small, the investigators found that sociodemographic factors did not increase the odds that a mother would fall asleep while feeding.

These numbers are not surprising, but nonetheless they are concerning because co-sleeping is a known risk factor for sudden unexplained infant death (SUID). Every parent will tell you during the first 6 months of their adventure in parenting they didn’t get enough sleep. In fact some will tell you that sleep deprivation was their chronic state for the child’s first year. 

 

Falling asleep easily at times and places not intended for sleep is the primary symptom of sleep deprivation. SUID is the most tragic event associated with parental sleep deprivation, but it is certainly not the only one. Overtired parents are more likely to be involved in accidents and are more likely to make poor decisions, particularly those regarding how to respond to a crying or misbehaving child.

The investigators found that 24% of mothers who reported that their usual nighttime feeding location was a chair or sofa (14%). Not surprisingly, mothers who fed in chairs were less likely to fall asleep while feeding. Many of these mothers reported that they chose the chair because they thought they would be less likely to fall asleep and/or disturb other family members. One wonders how we should interpret these numbers in light of other research that has found it is “relatively less hazardous to fall asleep with an infant in the adult bed than on a chair or sofa.” Had these chair feeding mothers made the better choice under the circumstances? It would take a much larger and more granular study to answer that question.

Mothers who exclusively breastfed were more likely to fall asleep feeding than were those who partially breastfed or used formula. The investigators postulated that the infants of mothers who exclusively breastfed may have required more feedings because breast milk is more easily and quickly digested. I know this is a common explanation, but in my experience I have found that exclusively breastfed infants often use nursing as pacification and a sleep trigger and spend more time at the breast regardless of how quickly they emptied their stomachs.

This study also examined the effect of repeated educational interventions and support and found that mothers who received an intervention based on safe sleep practices were less likely to fall asleep while feeding than were the mothers who had received the intervention focused on exclusive breastfeeding value and barriers to its adoption.

Certainly, the problem of mothers falling asleep while feeding is one we should address more robustly than we have in the past. Education is one avenue, particularly when it includes the mother’s partner who can play an important role as standby lifeguard to make sure the mother doesn’t fall asleep. Obviously, this is easier said than done because when there is a new baby in the house sleep deprivation is usually a shared experience.

Although I believe that my family is on the verge of gifting me a smartwatch to protect me from my own misadventures, I don’t have any personal experience with these wonders of modern technology. However, I suspect with very little tweaking a wearable sensor could be easily programmed to detect when a mother is beginning to fall asleep while she is feeding her infant. A smartwatch would be an expensive intervention and is unlikely to filter down to economically challenged families. On the other hand, this paper has reinforced our suspicions that sleep-deprived infant feeding is a significant problem. A subsidized loaner program for those families that can’t afford a smartwatch is an option that should be considered. 

 

Dr. Wilkoff practiced primary care pediatrics in Brunswick, Maine, for nearly 40 years. He has authored several books on behavioral pediatrics, including “How to Say No to Your Toddler.” Other than a Littman stethoscope he accepted as a first-year medical student in 1966, Dr. Wilkoff reports having nothing to disclose. Email him at pdnews@mdedge.com.

In a recent survey of 1259 mothers published in the journal Pediatrics, 28% reported they had fallen asleep while feeding their babies, and 83% of those mothers reported that the sleep was unplanned. Although the study sample was small, the investigators found that sociodemographic factors did not increase the odds that a mother would fall asleep while feeding.

These numbers are not surprising, but nonetheless they are concerning because co-sleeping is a known risk factor for sudden unexplained infant death (SUID). Every parent will tell you during the first 6 months of their adventure in parenting they didn’t get enough sleep. In fact some will tell you that sleep deprivation was their chronic state for the child’s first year. 

 

Falling asleep easily at times and places not intended for sleep is the primary symptom of sleep deprivation. SUID is the most tragic event associated with parental sleep deprivation, but it is certainly not the only one. Overtired parents are more likely to be involved in accidents and are more likely to make poor decisions, particularly those regarding how to respond to a crying or misbehaving child.

The investigators found that 24% of mothers who reported that their usual nighttime feeding location was a chair or sofa (14%). Not surprisingly, mothers who fed in chairs were less likely to fall asleep while feeding. Many of these mothers reported that they chose the chair because they thought they would be less likely to fall asleep and/or disturb other family members. One wonders how we should interpret these numbers in light of other research that has found it is “relatively less hazardous to fall asleep with an infant in the adult bed than on a chair or sofa.” Had these chair feeding mothers made the better choice under the circumstances? It would take a much larger and more granular study to answer that question.

Mothers who exclusively breastfed were more likely to fall asleep feeding than were those who partially breastfed or used formula. The investigators postulated that the infants of mothers who exclusively breastfed may have required more feedings because breast milk is more easily and quickly digested. I know this is a common explanation, but in my experience I have found that exclusively breastfed infants often use nursing as pacification and a sleep trigger and spend more time at the breast regardless of how quickly they emptied their stomachs.

This study also examined the effect of repeated educational interventions and support and found that mothers who received an intervention based on safe sleep practices were less likely to fall asleep while feeding than were the mothers who had received the intervention focused on exclusive breastfeeding value and barriers to its adoption.

Certainly, the problem of mothers falling asleep while feeding is one we should address more robustly than we have in the past. Education is one avenue, particularly when it includes the mother’s partner who can play an important role as standby lifeguard to make sure the mother doesn’t fall asleep. Obviously, this is easier said than done because when there is a new baby in the house sleep deprivation is usually a shared experience.

Although I believe that my family is on the verge of gifting me a smartwatch to protect me from my own misadventures, I don’t have any personal experience with these wonders of modern technology. However, I suspect with very little tweaking a wearable sensor could be easily programmed to detect when a mother is beginning to fall asleep while she is feeding her infant. A smartwatch would be an expensive intervention and is unlikely to filter down to economically challenged families. On the other hand, this paper has reinforced our suspicions that sleep-deprived infant feeding is a significant problem. A subsidized loaner program for those families that can’t afford a smartwatch is an option that should be considered. 

 

Dr. Wilkoff practiced primary care pediatrics in Brunswick, Maine, for nearly 40 years. He has authored several books on behavioral pediatrics, including “How to Say No to Your Toddler.” Other than a Littman stethoscope he accepted as a first-year medical student in 1966, Dr. Wilkoff reports having nothing to disclose. Email him at pdnews@mdedge.com.

In a recent survey of 1259 mothers published in the journal Pediatrics, 28% reported they had fallen asleep while feeding their babies, and 83% of those mothers reported that the sleep was unplanned. Although the study sample was small, the investigators found that sociodemographic factors did not increase the odds that a mother would fall asleep while feeding.

These numbers are not surprising, but nonetheless they are concerning because co-sleeping is a known risk factor for sudden unexplained infant death (SUID). Every parent will tell you during the first 6 months of their adventure in parenting they didn’t get enough sleep. In fact some will tell you that sleep deprivation was their chronic state for the child’s first year. 

 

Falling asleep easily at times and places not intended for sleep is the primary symptom of sleep deprivation. SUID is the most tragic event associated with parental sleep deprivation, but it is certainly not the only one. Overtired parents are more likely to be involved in accidents and are more likely to make poor decisions, particularly those regarding how to respond to a crying or misbehaving child.

The investigators found that 24% of mothers who reported that their usual nighttime feeding location was a chair or sofa (14%). Not surprisingly, mothers who fed in chairs were less likely to fall asleep while feeding. Many of these mothers reported that they chose the chair because they thought they would be less likely to fall asleep and/or disturb other family members. One wonders how we should interpret these numbers in light of other research that has found it is “relatively less hazardous to fall asleep with an infant in the adult bed than on a chair or sofa.” Had these chair feeding mothers made the better choice under the circumstances? It would take a much larger and more granular study to answer that question.

Mothers who exclusively breastfed were more likely to fall asleep feeding than were those who partially breastfed or used formula. The investigators postulated that the infants of mothers who exclusively breastfed may have required more feedings because breast milk is more easily and quickly digested. I know this is a common explanation, but in my experience I have found that exclusively breastfed infants often use nursing as pacification and a sleep trigger and spend more time at the breast regardless of how quickly they emptied their stomachs.

This study also examined the effect of repeated educational interventions and support and found that mothers who received an intervention based on safe sleep practices were less likely to fall asleep while feeding than were the mothers who had received the intervention focused on exclusive breastfeeding value and barriers to its adoption.

Certainly, the problem of mothers falling asleep while feeding is one we should address more robustly than we have in the past. Education is one avenue, particularly when it includes the mother’s partner who can play an important role as standby lifeguard to make sure the mother doesn’t fall asleep. Obviously, this is easier said than done because when there is a new baby in the house sleep deprivation is usually a shared experience.

Although I believe that my family is on the verge of gifting me a smartwatch to protect me from my own misadventures, I don’t have any personal experience with these wonders of modern technology. However, I suspect with very little tweaking a wearable sensor could be easily programmed to detect when a mother is beginning to fall asleep while she is feeding her infant. A smartwatch would be an expensive intervention and is unlikely to filter down to economically challenged families. On the other hand, this paper has reinforced our suspicions that sleep-deprived infant feeding is a significant problem. A subsidized loaner program for those families that can’t afford a smartwatch is an option that should be considered. 

 

Dr. Wilkoff practiced primary care pediatrics in Brunswick, Maine, for nearly 40 years. He has authored several books on behavioral pediatrics, including “How to Say No to Your Toddler.” Other than a Littman stethoscope he accepted as a first-year medical student in 1966, Dr. Wilkoff reports having nothing to disclose. Email him at pdnews@mdedge.com.

When a patient signs on to a telehealth portal, there’s little more a provider can do than ask questions. But a new artificial intelligence (AI) technology could allow providers to get feedback about the patient’s blood pressure and diabetes risk just from a video call or a smartphone app.

Researchers at the University of Tokyo in Japan are using AI to determine whether people might have high blood pressure or diabetes based on video data collected with a special sensor. 

The technology relies on photoplethysmography (PPG), which measures changes in blood volume by detecting the amount of light absorbed by blood just below the skin. 

This technology is already used for things like finger pulse oximetry to determine oxygen saturation and heart rate. Wearable devices like Apple Watches and Fitbits also use PPG technologies to detect heart rate and atrial fibrillation.

“If we could detect and accurately measure your blood pressure, heart rate, and oxygen saturation non-invasively that would be fantastic,” said Eugene Yang, MD, professor of medicine in the division of cardiology at the University of Washington School of Medicine in Seattle who was not involved in the study.

 

How Does PPG Work — and Is This New Tech Accurate?

Using PPG, “you’re detecting these small, little blood vessels that sit underneath the surface of your skin,” explained Yang.

“Since both hypertension and diabetes are diseases that damage blood vessels, we thought these diseases might affect blood flow and pulse wave transit times,” said Ryoko Uchida, a project researcher in the cardiology department at the University of Tokyo and one of the leaders of the study.

PPG devices primarily use green light to detect blood flow, as hemoglobin, the oxygen-carrying molecule in blood, absorbs green light most effectively, Yang said. “So, if you extract and remove all the other channels of light and only focus on the green channel, then that’s when you’ll be able to potentially see blood flow and pulsatile blood flow activity,” he noted.

The University of Tokyo researchers used remote or contactless PPG, which requires a short video recording of someone’s face and palms, as the person holds as still as possible. A special sensor collects the video and detects only certain wavelengths of light. Then the researchers developed an AI algorithm to extract data from participants’ skin, such as changes in pulse transit time — the time it takes for the pulse to travel from the palm to the face.

To correlate the video algorithm to blood pressure and diabetes risk, the researchers measured blood participants’ pressure with a continuous sphygmomanometer (an automatic blood pressure cuff) at the same time as they collected the video. They also did a blood A1c test to detect diabetes.

So far, they’ve tested their video algorithm on 215 people. The algorithm applied to a 30-second video was 86% accurate in detecting if blood pressure was above normal, and a 5-second video was 81% accurate in detecting higher blood pressure.

Compared with using hemoglobin A1c blood test results to screen for diabetes, the video algorithm was 75% accurate in identifying people who had subtle blood changes that correlated to diabetes.

“Most of this focus has been on wearable devices, patches, rings, wrist devices,” Yang said, “the facial video stuff is great because you can imagine that there are other ways of applying it.”

Yang, who is also doing research on facial video processing, pointed out it could be helpful not only in telehealth visits, but also for patients in the hospital with highly contagious diseases who need to be in isolation, or just for people using their smartphones. 

“People are tied to their smartphones, so you could imagine that that would be great as a way for people to have awareness about their blood pressure or their diabetes status,” Yang noted.

 

More Work to Do

The study has a few caveats. The special sensor they used in this study isn’t yet integrated into smartphone cameras or other common video recording devices. But Uchida is hopeful that it could be mass-produced and inexpensive to someday add.

Also, the study was done in a Japanese population, and lighter skin may be easier to capture changes in blood flow, Uchida noted. Pulse oximeters, which use the same technology, tend to overestimate blood oxygen in people with darker skin tones.

“It is necessary to test whether the same results are obtained in a variety of subjects other than Japanese and Asians,” Uchida said, in addition to validating the tool with more participants.

The study has also not yet undergone peer review.

And Yang pointed out that this new AI technology provides more of a screening tool to predict who is at high risk for high blood pressure or diabetes, rather than precise measurements for either disease.

There are already some devices that claim to measure blood pressure using PPG technology, like blood pressure monitoring watches. But Yang warns that these kinds of devices aren’t validated, meaning we don’t really know how well they work.

One difficulty in getting any kind of PPG blood pressure monitoring device to market is that the organizations involved in setting medical device standards (like the International Organization for Standards) doesn’t yet have a validation standard for this technology, Yang said, so there’s really no way to consistently verify the technology’s accuracy.

“I am optimistic that we are capable of figuring out how to validate these things. I just think we have so many things we have to iron out before that happens,” Yang explained, noting that it will be at least 3 years before a remote blood monitoring system is widely available.

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

When a patient signs on to a telehealth portal, there’s little more a provider can do than ask questions. But a new artificial intelligence (AI) technology could allow providers to get feedback about the patient’s blood pressure and diabetes risk just from a video call or a smartphone app.

Researchers at the University of Tokyo in Japan are using AI to determine whether people might have high blood pressure or diabetes based on video data collected with a special sensor. 

The technology relies on photoplethysmography (PPG), which measures changes in blood volume by detecting the amount of light absorbed by blood just below the skin. 

This technology is already used for things like finger pulse oximetry to determine oxygen saturation and heart rate. Wearable devices like Apple Watches and Fitbits also use PPG technologies to detect heart rate and atrial fibrillation.

“If we could detect and accurately measure your blood pressure, heart rate, and oxygen saturation non-invasively that would be fantastic,” said Eugene Yang, MD, professor of medicine in the division of cardiology at the University of Washington School of Medicine in Seattle who was not involved in the study.

 

How Does PPG Work — and Is This New Tech Accurate?

Using PPG, “you’re detecting these small, little blood vessels that sit underneath the surface of your skin,” explained Yang.

“Since both hypertension and diabetes are diseases that damage blood vessels, we thought these diseases might affect blood flow and pulse wave transit times,” said Ryoko Uchida, a project researcher in the cardiology department at the University of Tokyo and one of the leaders of the study.

PPG devices primarily use green light to detect blood flow, as hemoglobin, the oxygen-carrying molecule in blood, absorbs green light most effectively, Yang said. “So, if you extract and remove all the other channels of light and only focus on the green channel, then that’s when you’ll be able to potentially see blood flow and pulsatile blood flow activity,” he noted.

The University of Tokyo researchers used remote or contactless PPG, which requires a short video recording of someone’s face and palms, as the person holds as still as possible. A special sensor collects the video and detects only certain wavelengths of light. Then the researchers developed an AI algorithm to extract data from participants’ skin, such as changes in pulse transit time — the time it takes for the pulse to travel from the palm to the face.

To correlate the video algorithm to blood pressure and diabetes risk, the researchers measured blood participants’ pressure with a continuous sphygmomanometer (an automatic blood pressure cuff) at the same time as they collected the video. They also did a blood A1c test to detect diabetes.

So far, they’ve tested their video algorithm on 215 people. The algorithm applied to a 30-second video was 86% accurate in detecting if blood pressure was above normal, and a 5-second video was 81% accurate in detecting higher blood pressure.

Compared with using hemoglobin A1c blood test results to screen for diabetes, the video algorithm was 75% accurate in identifying people who had subtle blood changes that correlated to diabetes.

“Most of this focus has been on wearable devices, patches, rings, wrist devices,” Yang said, “the facial video stuff is great because you can imagine that there are other ways of applying it.”

Yang, who is also doing research on facial video processing, pointed out it could be helpful not only in telehealth visits, but also for patients in the hospital with highly contagious diseases who need to be in isolation, or just for people using their smartphones. 

“People are tied to their smartphones, so you could imagine that that would be great as a way for people to have awareness about their blood pressure or their diabetes status,” Yang noted.

 

More Work to Do

The study has a few caveats. The special sensor they used in this study isn’t yet integrated into smartphone cameras or other common video recording devices. But Uchida is hopeful that it could be mass-produced and inexpensive to someday add.

Also, the study was done in a Japanese population, and lighter skin may be easier to capture changes in blood flow, Uchida noted. Pulse oximeters, which use the same technology, tend to overestimate blood oxygen in people with darker skin tones.

“It is necessary to test whether the same results are obtained in a variety of subjects other than Japanese and Asians,” Uchida said, in addition to validating the tool with more participants.

The study has also not yet undergone peer review.

And Yang pointed out that this new AI technology provides more of a screening tool to predict who is at high risk for high blood pressure or diabetes, rather than precise measurements for either disease.

There are already some devices that claim to measure blood pressure using PPG technology, like blood pressure monitoring watches. But Yang warns that these kinds of devices aren’t validated, meaning we don’t really know how well they work.

One difficulty in getting any kind of PPG blood pressure monitoring device to market is that the organizations involved in setting medical device standards (like the International Organization for Standards) doesn’t yet have a validation standard for this technology, Yang said, so there’s really no way to consistently verify the technology’s accuracy.

“I am optimistic that we are capable of figuring out how to validate these things. I just think we have so many things we have to iron out before that happens,” Yang explained, noting that it will be at least 3 years before a remote blood monitoring system is widely available.

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

When a patient signs on to a telehealth portal, there’s little more a provider can do than ask questions. But a new artificial intelligence (AI) technology could allow providers to get feedback about the patient’s blood pressure and diabetes risk just from a video call or a smartphone app.

Researchers at the University of Tokyo in Japan are using AI to determine whether people might have high blood pressure or diabetes based on video data collected with a special sensor. 

The technology relies on photoplethysmography (PPG), which measures changes in blood volume by detecting the amount of light absorbed by blood just below the skin. 

This technology is already used for things like finger pulse oximetry to determine oxygen saturation and heart rate. Wearable devices like Apple Watches and Fitbits also use PPG technologies to detect heart rate and atrial fibrillation.

“If we could detect and accurately measure your blood pressure, heart rate, and oxygen saturation non-invasively that would be fantastic,” said Eugene Yang, MD, professor of medicine in the division of cardiology at the University of Washington School of Medicine in Seattle who was not involved in the study.

 

How Does PPG Work — and Is This New Tech Accurate?

Using PPG, “you’re detecting these small, little blood vessels that sit underneath the surface of your skin,” explained Yang.

“Since both hypertension and diabetes are diseases that damage blood vessels, we thought these diseases might affect blood flow and pulse wave transit times,” said Ryoko Uchida, a project researcher in the cardiology department at the University of Tokyo and one of the leaders of the study.

PPG devices primarily use green light to detect blood flow, as hemoglobin, the oxygen-carrying molecule in blood, absorbs green light most effectively, Yang said. “So, if you extract and remove all the other channels of light and only focus on the green channel, then that’s when you’ll be able to potentially see blood flow and pulsatile blood flow activity,” he noted.

The University of Tokyo researchers used remote or contactless PPG, which requires a short video recording of someone’s face and palms, as the person holds as still as possible. A special sensor collects the video and detects only certain wavelengths of light. Then the researchers developed an AI algorithm to extract data from participants’ skin, such as changes in pulse transit time — the time it takes for the pulse to travel from the palm to the face.

To correlate the video algorithm to blood pressure and diabetes risk, the researchers measured blood participants’ pressure with a continuous sphygmomanometer (an automatic blood pressure cuff) at the same time as they collected the video. They also did a blood A1c test to detect diabetes.

So far, they’ve tested their video algorithm on 215 people. The algorithm applied to a 30-second video was 86% accurate in detecting if blood pressure was above normal, and a 5-second video was 81% accurate in detecting higher blood pressure.

Compared with using hemoglobin A1c blood test results to screen for diabetes, the video algorithm was 75% accurate in identifying people who had subtle blood changes that correlated to diabetes.

“Most of this focus has been on wearable devices, patches, rings, wrist devices,” Yang said, “the facial video stuff is great because you can imagine that there are other ways of applying it.”

Yang, who is also doing research on facial video processing, pointed out it could be helpful not only in telehealth visits, but also for patients in the hospital with highly contagious diseases who need to be in isolation, or just for people using their smartphones. 

“People are tied to their smartphones, so you could imagine that that would be great as a way for people to have awareness about their blood pressure or their diabetes status,” Yang noted.

 

More Work to Do

The study has a few caveats. The special sensor they used in this study isn’t yet integrated into smartphone cameras or other common video recording devices. But Uchida is hopeful that it could be mass-produced and inexpensive to someday add.

Also, the study was done in a Japanese population, and lighter skin may be easier to capture changes in blood flow, Uchida noted. Pulse oximeters, which use the same technology, tend to overestimate blood oxygen in people with darker skin tones.

“It is necessary to test whether the same results are obtained in a variety of subjects other than Japanese and Asians,” Uchida said, in addition to validating the tool with more participants.

The study has also not yet undergone peer review.

And Yang pointed out that this new AI technology provides more of a screening tool to predict who is at high risk for high blood pressure or diabetes, rather than precise measurements for either disease.

There are already some devices that claim to measure blood pressure using PPG technology, like blood pressure monitoring watches. But Yang warns that these kinds of devices aren’t validated, meaning we don’t really know how well they work.

One difficulty in getting any kind of PPG blood pressure monitoring device to market is that the organizations involved in setting medical device standards (like the International Organization for Standards) doesn’t yet have a validation standard for this technology, Yang said, so there’s really no way to consistently verify the technology’s accuracy.

“I am optimistic that we are capable of figuring out how to validate these things. I just think we have so many things we have to iron out before that happens,” Yang explained, noting that it will be at least 3 years before a remote blood monitoring system is widely available.

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

For some medical students and trainees who go on to become hematologists, attraction to the field happens the first time they’re engrossed in figuring out what a blood smear is telling them. Others get drawn to hematology during a rotation in residency, when they encounter patients with hemophilia or sickle cell disease.

But when it comes to turning people on to the idea of a career in classical hematology (CH), there may be no more powerful influence than a mentor who loves their job. That’s why the field is focusing so much on supporting mentors and mentees amid a stark shortage of classical hematologists.

“Mentorship is key for maintaining trainee interest in the field and for providing role models for career growth,” said Rakhi P. Naik, MD, MHS, associate professor of medicine and director of the Hematology Fellowship Track at Johns Hopkins University, Baltimore, Maryland, in an interview. “This collaboration is especially critical because there are so few trainees and so few mentors currently in the field.”

Now there’s new research backing up the power of mentorship, even when it’s only provided virtually, and a brand-new program aims to unite more mentors and mentees.

Here’s a closer look at mentor-focused efforts to attract medical students to CH.

 

How Severe Is the Shortage in CH?

Patients with conditions treated by classical hematologists are waiting months for appointments at many outpatient centers, with some being forced to wait 6 months or more, said Srikanth Nagalla, MD, chief of benign hematology at Miami Cancer Institute, Florida, in an interview.

The shortage is creating dire problems in the inpatient setting too, Nagalla said. “Serious blood disorders like heparin-induced thrombocytopenia, acute chest syndrome [a complication of sickle cell disease], and thrombotic thrombocytopenic purpura have to be diagnosed and treated in a timely manner. If not, the morbidity and mortality are really high.”

If classical hematologists aren’t available, he said, oncologists and others not trained in hematology will need to cover these patients. 

Hematologist Ariela Marshall, MD, associate professor of medicine at the University of Minnesota in Minneapolis, noted in an interview that the CH shortage comes at a time when medical advances and an aging population are boosting the number of patients with noncancerous blood disorders. Older people are at greater risk for blood clots, she said. And lifespans for patients with bleeding and clotting disorders are rising thanks to effective new treatments.

“Because of our larger patient population in CH, we are going to need more classical hematologists to follow them for longer and longer periods of time,” she said. 

There’s no sign yet that newly minted physicians will take up the slack in CH. A 2019 study found that just 4.6% of 626 of hematology/oncology fellows said they planned to go into CH, also known as benign hematology, vs 67.1% who expected to treat patients with solid tumors, blood cancer, or both. The rest, 24.6%, planned to work in CH plus the two oncology fields.

 

Why Does a Shortage Exist?

“The reasons are complex, but one of the most important factors was the combining of the adult hematology and medical oncology training programs by the Accreditation Council for Graduate Medical Education in 1995,” Naik said. “After that time, the majority of fellowship training programs went from having separate programs for hematology and medical oncology to combining the training for the two specialties into one. Because most of these combined training programs resided within Cancer Centers, classical hematology training slowly became de-emphasized.”

As a result, fewer fellows ended up specializing in CH, she said. 

The field of CH also appears to suffer from a less than enticing reputation. According to a 2019 study coauthored by Marshall, surveys of thousands of hematology/oncology fellows found that “hematology, particularly benign hematology, was viewed as having poorer income potential, research funding, job availability, and job security than oncology.”

Regarding pay, Marshall said the good news is that many classical hematologists work in academia, where it’s common for pay to be “equitable across hematology/oncology divisions and based more on academic rank and other factors rather than subspecialty within hematology oncology.”

However, she noted, “this may differ at institutions where hematology and oncology are different departments. For example, centers where oncology is its own department, and hematology is part of the department of medicine.” 

As for job availability, Naik said that there’s plenty of demand. “In academics, it is clear that there are jobs available everywhere, but trainees are often worried about job prospects in private practice. While classical hematology jobs in private practice are not widely advertised, I can attest that there is no shortage of need,” she said. “Many private practices do not specifically advertise for classical hematologists because they assume that classical hematology experts are not available. But I assure you that every private practice my trainees have ever approached is always ecstatic to hire a classical hematologist.”

 

Why Are Mentors Important?

Mentorship is crucial to promoting the value of CH as a great career choice in a competitive environment, classical hematologists say. “We can motivate trainees by showing how the disease states themselves are so fascinating and how the treatments are showing great outcomes,” Nagalla said. “We can show positive results, how patient lives can be changed, and how well-respected across the system [we] are.”

As a selling point, classical hematologists like to emphasize that their field requires intensive detective work. “Let’s say a patient comes with anemia, which might have 15 different causes. You get some labs, and then you systemically rule in or rule out most of these on the differential diagnosis,” Nagalla said. “Then once you narrow it down, you get more labs. You keep going to the next step and next step, and so finally you come to a conclusion.”

As for therapy, Marshall said that “while for many cancers there are specific treatment recommendations for patients with a specific cancer type at a specific stage, there is not always a specific treatment recommendation (or a ‘right answer’) for our CH patients. Treatment planning depends strongly on a patient’s preferences, other medical conditions, and a discussion about risks [and] benefits of different treatment options such that two patients with the same condition may choose two different treatment options.”

Marshall also emphasizes to trainees that “CH is a broad field. Physicians and trainees are able to interact and collaborate with physicians in other specialties such as gastroenterology, cardiology, ob/gyn, and surgical specialties.” 

 

Does Research Support Mentorship in CH?

The 2019 study that revealed just 4.6% of fellows planned to go into CH found that “fellows who planned to enter hematology-only careers were significantly more likely to report having clinical training and mentorship experiences in hematology throughout their training relative to fellows with oncology-only or combined hematology/oncology career plans.”

Now there are more data to support mentorships. For a study published in Blood Advances in September 2024, Zoya Qureshy, MD, an internal medicine chief resident at the University of California at San Diego, and colleagues evaluated a year-long external membership program implemented by the American Society of Hematology (ASH) Medical Educators Institute. 

The program linked 35 US hematology/oncology fellows (80% female, 46% White, 35% Asian) who were interested in CH to 34 North American faculty members. The pairs were told to meet virtually once a month. 

Of 30 mentees and 23 mentors surveyed, 94% and 85%, respectively, said their pairings were good matches. Two thirds of the mentees accepted faculty positions in CH after their mentorships.

“Our study showed that external mentorship in a virtual format is feasible,” Qureshy said in an interview. “Additionally, external mentorship provided benefits such as different perspectives and the opportunity for mentorship for those who may not have it in their field of interest at their home institution.”

Qureshy added that “one strength of our mentorship program was that mentoring pairs were meticulously assigned based on shared interests and background. Many participants cited this common ground as a reason why they thought their mentoring pair was a good match.” 

There’s an important caveat: Most of the mentees weren’t new to CH. About 70% had previously worked with a mentor in the CH field, and 86% had previously conducted research in the field. 

 

What’s Next for Mentorship in CH?

The ASH Hematology-Focused Fellowship Training Program Consortium aims to mint 50 new academic hematologists by 2030 through programs at 12 institutions. “Mentorship is an exciting aspect of the program since it allows classical hematology trainees to form a network of peers nationally and also provides access to mentors across institutions,” Naik said. “And as the workforce grows, there will be more and more role models for future trainees to look up to.”

Moving forward, she said, “we hope to inspire even more institutions to adopt hematology training tracks throughout the country.”

Meanwhile, ASH’s new Classical Hematology Advancement Mentorship is taking applications for its debut 2025 program through January 9, 2025. Trainees will meet monthly with mentors both virtually and in person. Applicants must have been in their first or second year of hematology/oncology fellowship training at accredited programs in the United States as of July 15, 2024.

Naik, Marshall, Nagalla, and Qureshy have no relevant disclosures.

A version of this article appeared on Medscape.com.

For some medical students and trainees who go on to become hematologists, attraction to the field happens the first time they’re engrossed in figuring out what a blood smear is telling them. Others get drawn to hematology during a rotation in residency, when they encounter patients with hemophilia or sickle cell disease.

But when it comes to turning people on to the idea of a career in classical hematology (CH), there may be no more powerful influence than a mentor who loves their job. That’s why the field is focusing so much on supporting mentors and mentees amid a stark shortage of classical hematologists.

“Mentorship is key for maintaining trainee interest in the field and for providing role models for career growth,” said Rakhi P. Naik, MD, MHS, associate professor of medicine and director of the Hematology Fellowship Track at Johns Hopkins University, Baltimore, Maryland, in an interview. “This collaboration is especially critical because there are so few trainees and so few mentors currently in the field.”

Now there’s new research backing up the power of mentorship, even when it’s only provided virtually, and a brand-new program aims to unite more mentors and mentees.

Here’s a closer look at mentor-focused efforts to attract medical students to CH.

 

How Severe Is the Shortage in CH?

Patients with conditions treated by classical hematologists are waiting months for appointments at many outpatient centers, with some being forced to wait 6 months or more, said Srikanth Nagalla, MD, chief of benign hematology at Miami Cancer Institute, Florida, in an interview.

The shortage is creating dire problems in the inpatient setting too, Nagalla said. “Serious blood disorders like heparin-induced thrombocytopenia, acute chest syndrome [a complication of sickle cell disease], and thrombotic thrombocytopenic purpura have to be diagnosed and treated in a timely manner. If not, the morbidity and mortality are really high.”

If classical hematologists aren’t available, he said, oncologists and others not trained in hematology will need to cover these patients. 

Hematologist Ariela Marshall, MD, associate professor of medicine at the University of Minnesota in Minneapolis, noted in an interview that the CH shortage comes at a time when medical advances and an aging population are boosting the number of patients with noncancerous blood disorders. Older people are at greater risk for blood clots, she said. And lifespans for patients with bleeding and clotting disorders are rising thanks to effective new treatments.

“Because of our larger patient population in CH, we are going to need more classical hematologists to follow them for longer and longer periods of time,” she said. 

There’s no sign yet that newly minted physicians will take up the slack in CH. A 2019 study found that just 4.6% of 626 of hematology/oncology fellows said they planned to go into CH, also known as benign hematology, vs 67.1% who expected to treat patients with solid tumors, blood cancer, or both. The rest, 24.6%, planned to work in CH plus the two oncology fields.

 

Why Does a Shortage Exist?

“The reasons are complex, but one of the most important factors was the combining of the adult hematology and medical oncology training programs by the Accreditation Council for Graduate Medical Education in 1995,” Naik said. “After that time, the majority of fellowship training programs went from having separate programs for hematology and medical oncology to combining the training for the two specialties into one. Because most of these combined training programs resided within Cancer Centers, classical hematology training slowly became de-emphasized.”

As a result, fewer fellows ended up specializing in CH, she said. 

The field of CH also appears to suffer from a less than enticing reputation. According to a 2019 study coauthored by Marshall, surveys of thousands of hematology/oncology fellows found that “hematology, particularly benign hematology, was viewed as having poorer income potential, research funding, job availability, and job security than oncology.”

Regarding pay, Marshall said the good news is that many classical hematologists work in academia, where it’s common for pay to be “equitable across hematology/oncology divisions and based more on academic rank and other factors rather than subspecialty within hematology oncology.”

However, she noted, “this may differ at institutions where hematology and oncology are different departments. For example, centers where oncology is its own department, and hematology is part of the department of medicine.” 

As for job availability, Naik said that there’s plenty of demand. “In academics, it is clear that there are jobs available everywhere, but trainees are often worried about job prospects in private practice. While classical hematology jobs in private practice are not widely advertised, I can attest that there is no shortage of need,” she said. “Many private practices do not specifically advertise for classical hematologists because they assume that classical hematology experts are not available. But I assure you that every private practice my trainees have ever approached is always ecstatic to hire a classical hematologist.”

 

Why Are Mentors Important?

Mentorship is crucial to promoting the value of CH as a great career choice in a competitive environment, classical hematologists say. “We can motivate trainees by showing how the disease states themselves are so fascinating and how the treatments are showing great outcomes,” Nagalla said. “We can show positive results, how patient lives can be changed, and how well-respected across the system [we] are.”

As a selling point, classical hematologists like to emphasize that their field requires intensive detective work. “Let’s say a patient comes with anemia, which might have 15 different causes. You get some labs, and then you systemically rule in or rule out most of these on the differential diagnosis,” Nagalla said. “Then once you narrow it down, you get more labs. You keep going to the next step and next step, and so finally you come to a conclusion.”

As for therapy, Marshall said that “while for many cancers there are specific treatment recommendations for patients with a specific cancer type at a specific stage, there is not always a specific treatment recommendation (or a ‘right answer’) for our CH patients. Treatment planning depends strongly on a patient’s preferences, other medical conditions, and a discussion about risks [and] benefits of different treatment options such that two patients with the same condition may choose two different treatment options.”

Marshall also emphasizes to trainees that “CH is a broad field. Physicians and trainees are able to interact and collaborate with physicians in other specialties such as gastroenterology, cardiology, ob/gyn, and surgical specialties.” 

 

Does Research Support Mentorship in CH?

The 2019 study that revealed just 4.6% of fellows planned to go into CH found that “fellows who planned to enter hematology-only careers were significantly more likely to report having clinical training and mentorship experiences in hematology throughout their training relative to fellows with oncology-only or combined hematology/oncology career plans.”

Now there are more data to support mentorships. For a study published in Blood Advances in September 2024, Zoya Qureshy, MD, an internal medicine chief resident at the University of California at San Diego, and colleagues evaluated a year-long external membership program implemented by the American Society of Hematology (ASH) Medical Educators Institute. 

The program linked 35 US hematology/oncology fellows (80% female, 46% White, 35% Asian) who were interested in CH to 34 North American faculty members. The pairs were told to meet virtually once a month. 

Of 30 mentees and 23 mentors surveyed, 94% and 85%, respectively, said their pairings were good matches. Two thirds of the mentees accepted faculty positions in CH after their mentorships.

“Our study showed that external mentorship in a virtual format is feasible,” Qureshy said in an interview. “Additionally, external mentorship provided benefits such as different perspectives and the opportunity for mentorship for those who may not have it in their field of interest at their home institution.”

Qureshy added that “one strength of our mentorship program was that mentoring pairs were meticulously assigned based on shared interests and background. Many participants cited this common ground as a reason why they thought their mentoring pair was a good match.” 

There’s an important caveat: Most of the mentees weren’t new to CH. About 70% had previously worked with a mentor in the CH field, and 86% had previously conducted research in the field. 

 

What’s Next for Mentorship in CH?

The ASH Hematology-Focused Fellowship Training Program Consortium aims to mint 50 new academic hematologists by 2030 through programs at 12 institutions. “Mentorship is an exciting aspect of the program since it allows classical hematology trainees to form a network of peers nationally and also provides access to mentors across institutions,” Naik said. “And as the workforce grows, there will be more and more role models for future trainees to look up to.”

Moving forward, she said, “we hope to inspire even more institutions to adopt hematology training tracks throughout the country.”

Meanwhile, ASH’s new Classical Hematology Advancement Mentorship is taking applications for its debut 2025 program through January 9, 2025. Trainees will meet monthly with mentors both virtually and in person. Applicants must have been in their first or second year of hematology/oncology fellowship training at accredited programs in the United States as of July 15, 2024.

Naik, Marshall, Nagalla, and Qureshy have no relevant disclosures.

A version of this article appeared on Medscape.com.

For some medical students and trainees who go on to become hematologists, attraction to the field happens the first time they’re engrossed in figuring out what a blood smear is telling them. Others get drawn to hematology during a rotation in residency, when they encounter patients with hemophilia or sickle cell disease.

But when it comes to turning people on to the idea of a career in classical hematology (CH), there may be no more powerful influence than a mentor who loves their job. That’s why the field is focusing so much on supporting mentors and mentees amid a stark shortage of classical hematologists.

“Mentorship is key for maintaining trainee interest in the field and for providing role models for career growth,” said Rakhi P. Naik, MD, MHS, associate professor of medicine and director of the Hematology Fellowship Track at Johns Hopkins University, Baltimore, Maryland, in an interview. “This collaboration is especially critical because there are so few trainees and so few mentors currently in the field.”

Now there’s new research backing up the power of mentorship, even when it’s only provided virtually, and a brand-new program aims to unite more mentors and mentees.

Here’s a closer look at mentor-focused efforts to attract medical students to CH.

 

How Severe Is the Shortage in CH?

Patients with conditions treated by classical hematologists are waiting months for appointments at many outpatient centers, with some being forced to wait 6 months or more, said Srikanth Nagalla, MD, chief of benign hematology at Miami Cancer Institute, Florida, in an interview.

The shortage is creating dire problems in the inpatient setting too, Nagalla said. “Serious blood disorders like heparin-induced thrombocytopenia, acute chest syndrome [a complication of sickle cell disease], and thrombotic thrombocytopenic purpura have to be diagnosed and treated in a timely manner. If not, the morbidity and mortality are really high.”

If classical hematologists aren’t available, he said, oncologists and others not trained in hematology will need to cover these patients. 

Hematologist Ariela Marshall, MD, associate professor of medicine at the University of Minnesota in Minneapolis, noted in an interview that the CH shortage comes at a time when medical advances and an aging population are boosting the number of patients with noncancerous blood disorders. Older people are at greater risk for blood clots, she said. And lifespans for patients with bleeding and clotting disorders are rising thanks to effective new treatments.

“Because of our larger patient population in CH, we are going to need more classical hematologists to follow them for longer and longer periods of time,” she said. 

There’s no sign yet that newly minted physicians will take up the slack in CH. A 2019 study found that just 4.6% of 626 of hematology/oncology fellows said they planned to go into CH, also known as benign hematology, vs 67.1% who expected to treat patients with solid tumors, blood cancer, or both. The rest, 24.6%, planned to work in CH plus the two oncology fields.

 

Why Does a Shortage Exist?

“The reasons are complex, but one of the most important factors was the combining of the adult hematology and medical oncology training programs by the Accreditation Council for Graduate Medical Education in 1995,” Naik said. “After that time, the majority of fellowship training programs went from having separate programs for hematology and medical oncology to combining the training for the two specialties into one. Because most of these combined training programs resided within Cancer Centers, classical hematology training slowly became de-emphasized.”

As a result, fewer fellows ended up specializing in CH, she said. 

The field of CH also appears to suffer from a less than enticing reputation. According to a 2019 study coauthored by Marshall, surveys of thousands of hematology/oncology fellows found that “hematology, particularly benign hematology, was viewed as having poorer income potential, research funding, job availability, and job security than oncology.”

Regarding pay, Marshall said the good news is that many classical hematologists work in academia, where it’s common for pay to be “equitable across hematology/oncology divisions and based more on academic rank and other factors rather than subspecialty within hematology oncology.”

However, she noted, “this may differ at institutions where hematology and oncology are different departments. For example, centers where oncology is its own department, and hematology is part of the department of medicine.” 

As for job availability, Naik said that there’s plenty of demand. “In academics, it is clear that there are jobs available everywhere, but trainees are often worried about job prospects in private practice. While classical hematology jobs in private practice are not widely advertised, I can attest that there is no shortage of need,” she said. “Many private practices do not specifically advertise for classical hematologists because they assume that classical hematology experts are not available. But I assure you that every private practice my trainees have ever approached is always ecstatic to hire a classical hematologist.”

 

Why Are Mentors Important?

Mentorship is crucial to promoting the value of CH as a great career choice in a competitive environment, classical hematologists say. “We can motivate trainees by showing how the disease states themselves are so fascinating and how the treatments are showing great outcomes,” Nagalla said. “We can show positive results, how patient lives can be changed, and how well-respected across the system [we] are.”

As a selling point, classical hematologists like to emphasize that their field requires intensive detective work. “Let’s say a patient comes with anemia, which might have 15 different causes. You get some labs, and then you systemically rule in or rule out most of these on the differential diagnosis,” Nagalla said. “Then once you narrow it down, you get more labs. You keep going to the next step and next step, and so finally you come to a conclusion.”

As for therapy, Marshall said that “while for many cancers there are specific treatment recommendations for patients with a specific cancer type at a specific stage, there is not always a specific treatment recommendation (or a ‘right answer’) for our CH patients. Treatment planning depends strongly on a patient’s preferences, other medical conditions, and a discussion about risks [and] benefits of different treatment options such that two patients with the same condition may choose two different treatment options.”

Marshall also emphasizes to trainees that “CH is a broad field. Physicians and trainees are able to interact and collaborate with physicians in other specialties such as gastroenterology, cardiology, ob/gyn, and surgical specialties.” 

 

Does Research Support Mentorship in CH?

The 2019 study that revealed just 4.6% of fellows planned to go into CH found that “fellows who planned to enter hematology-only careers were significantly more likely to report having clinical training and mentorship experiences in hematology throughout their training relative to fellows with oncology-only or combined hematology/oncology career plans.”

Now there are more data to support mentorships. For a study published in Blood Advances in September 2024, Zoya Qureshy, MD, an internal medicine chief resident at the University of California at San Diego, and colleagues evaluated a year-long external membership program implemented by the American Society of Hematology (ASH) Medical Educators Institute. 

The program linked 35 US hematology/oncology fellows (80% female, 46% White, 35% Asian) who were interested in CH to 34 North American faculty members. The pairs were told to meet virtually once a month. 

Of 30 mentees and 23 mentors surveyed, 94% and 85%, respectively, said their pairings were good matches. Two thirds of the mentees accepted faculty positions in CH after their mentorships.

“Our study showed that external mentorship in a virtual format is feasible,” Qureshy said in an interview. “Additionally, external mentorship provided benefits such as different perspectives and the opportunity for mentorship for those who may not have it in their field of interest at their home institution.”

Qureshy added that “one strength of our mentorship program was that mentoring pairs were meticulously assigned based on shared interests and background. Many participants cited this common ground as a reason why they thought their mentoring pair was a good match.” 

There’s an important caveat: Most of the mentees weren’t new to CH. About 70% had previously worked with a mentor in the CH field, and 86% had previously conducted research in the field. 

 

What’s Next for Mentorship in CH?

The ASH Hematology-Focused Fellowship Training Program Consortium aims to mint 50 new academic hematologists by 2030 through programs at 12 institutions. “Mentorship is an exciting aspect of the program since it allows classical hematology trainees to form a network of peers nationally and also provides access to mentors across institutions,” Naik said. “And as the workforce grows, there will be more and more role models for future trainees to look up to.”

Moving forward, she said, “we hope to inspire even more institutions to adopt hematology training tracks throughout the country.”

Meanwhile, ASH’s new Classical Hematology Advancement Mentorship is taking applications for its debut 2025 program through January 9, 2025. Trainees will meet monthly with mentors both virtually and in person. Applicants must have been in their first or second year of hematology/oncology fellowship training at accredited programs in the United States as of July 15, 2024.

Naik, Marshall, Nagalla, and Qureshy have no relevant disclosures.

A version of this article appeared on Medscape.com.

’Tis the season for recognizing seasonal affective disorder (SAD). Just don’t expect to find SAD in diagnostic handbooks.

As a memorable term, SAD “stuck in the general public, and to some extent among health professionals,” said Scott Patten, MD, PhD, professor of psychiatry and epidemiology at the University of Calgary in Alberta, Canada. “But it’s important to emphasize that that’s not an officially recognized diagnosis by the major classifications.”

Researchers coined the term SAD 40 years ago to describe a pattern of depression that sets in during the fall or winter and remits in the spring or summer.

Clinicians are diagnosing the disorder, albeit without that exact moniker.

In the Diagnostic and Statistical Manual of Mental Disorders, Fifth Edition (DSM-5), the condition is considered a subtype of major depression.

So, for patients who meet criteria for recurrent major depressive disorder, the specifier “with seasonal pattern” might be applied.

The subtype covers cases where depressive episodes have followed a seasonal pattern for at least 2 years. Typically, onset occurs in the fall or winter followed by remission in the spring or summer. The opposite pattern is possible but less common.

When stressors such as seasonal unemployment better explain the pattern, the seasonal specifier should not be used, according to the manual. Bipolar disorder can follow a seasonal pattern as well.

Researchers estimate SAD affects about 5% of adults in the United States. The diagnosis is more common in women than in men, and more prevalent farther from the equator.

 

One Hallmark Symptom?

DSM-5 highlights characteristic features of winter depression, including:

• Loss of energy
• Hypersomnia
• A craving for carbohydrates
• Overeating
• Weight gain

Kelly Rohan, PhD, a researcher at the University of Vermont, Burlington, who has studied SAD since the 1990s, sees one symptom as a possible hallmark for the disorder: fatigue.

“I’ve personally never met someone who met the full diagnostic criteria for the seasonal pattern that did not have fatigue as one of their symptoms,” Rohan said. “In theory, they could exist, but I have spoken to hundreds of people with seasonal depression, and I have never met them if, in fact, they do exist.”

That differs from nonseasonal depression, for which insomnia is a more common problem with sleep, Patten said.

Clinicians look for at least five symptoms of depression that cause substantial impairment and distress for at least 2 weeks, such as pervasive sadness, difficulty concentrating, low self-esteem, or loss of interest in hobbies.

An average episode of winter depression can last 5 months, however, Rohan said. “That’s a long time to be in a major depressive episode.”

 

Seeing Subsyndromal Cases

In people who do not meet criteria for major depression with a seasonal pattern, the change of seasons still can affect energy levels and mood. Some patients have “subsyndromal SAD” and may benefit from treatments that have been developed for SAD such as bright light therapy, said Paul Desan, MD, PhD, director of the Winter Depression Research Clinic at Yale School of Medicine in New Haven, Connecticut.

“Many people come to our clinic because they have seasonal changes that don’t meet the full criteria for depression, but nevertheless, they want help,” Desan said.

The 1984 paper that introduced the term SAD explored artificial bright light as a promising treatment for the condition. The researchers had heard from dozens of patients with “recurrent depressions that occur annually at the same time each year,” and bright light appeared to help alleviate their symptoms.

Subsequent trials have found the approach effective. Even in nonseasonal depression, bright light therapy may increase the likelihood of remission, a recent meta-analysis found. Light therapy also may bolster the effectiveness of antidepressant medication in nonseasonal major depressive disorder, a randomized trial has shown.

Other treatments for SAD include cognitive behavioral therapy (CBT) and bupropion XL, which is approved as a preventive medication. Other drugs for major depressive disorder may be used.

 

Quest for Biomarkers

To better understand SAD and how available treatments work, Rohan is conducting a study that examines potential biomarkers in patients treated with light therapy or CBT. She and her colleagues are examining circadian phase angle difference (how well internal clocks match daily routines) and post-illumination pupil response (how the pupil constricts after a light turns off). They also are measuring participants’ pupil responses and brain activity upon seeing words that are associated with winter or summer (like “blizzard,” “icy,” “sunshine,” and “picnics.”) 

Studies have shown treating patients to remission with CBT reduces the risk for recurrence in subsequent years, relative to other treatment approaches, Rohan said. That may be because CBT gives people tools to avoid slipping into another depressive episode.

 

Avoid Self-Diagnosis

Rohan cautions patients against self-diagnosis and treatment.

“Having a conversation with your doctor is a good starting point,” she said. “Just because you can walk into Costco and walk out with a light box doesn’t mean that you should.” 

Light therapy can have side effects, including headaches, eye strain, and making patients feel wired, and it can be a challenge to determine the right dose, Rohan said.

Desan’s clinic website provides information about available devices for light therapy for patients who are looking to try this approach, but Desan agrees clinicians — especially primary care clinicians — can play a crucial role in helping patients. In more serious cases, a mental health expert may be necessary.

To start light therapy, Desan’s clinic typically recommends patients try 30 minutes of 10,000 lux bright light — roughly the brightness of being outside on a sunny day — before 8 AM for a 4-week trial.

Still, other specific issues might explain why a patient is struggling during winter months, Patten said. For example, people might experience financial stress around the holidays or consume excessive amounts of alcohol during that time.

“It’s important for clinicians to think broadly about it,” Patten said. “It might not always be light therapy or a medication. It might be focusing on some other aspect of what is going on for them in the winter.” 

Rohan’s research is funded by the National Institute of Mental Health, and she receives royalties for a manual on treating SAD with CBT. Patten and Desan had no relevant financial disclosures.

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

’Tis the season for recognizing seasonal affective disorder (SAD). Just don’t expect to find SAD in diagnostic handbooks.

As a memorable term, SAD “stuck in the general public, and to some extent among health professionals,” said Scott Patten, MD, PhD, professor of psychiatry and epidemiology at the University of Calgary in Alberta, Canada. “But it’s important to emphasize that that’s not an officially recognized diagnosis by the major classifications.”

Researchers coined the term SAD 40 years ago to describe a pattern of depression that sets in during the fall or winter and remits in the spring or summer.

Clinicians are diagnosing the disorder, albeit without that exact moniker.

In the Diagnostic and Statistical Manual of Mental Disorders, Fifth Edition (DSM-5), the condition is considered a subtype of major depression.

So, for patients who meet criteria for recurrent major depressive disorder, the specifier “with seasonal pattern” might be applied.

The subtype covers cases where depressive episodes have followed a seasonal pattern for at least 2 years. Typically, onset occurs in the fall or winter followed by remission in the spring or summer. The opposite pattern is possible but less common.

When stressors such as seasonal unemployment better explain the pattern, the seasonal specifier should not be used, according to the manual. Bipolar disorder can follow a seasonal pattern as well.

Researchers estimate SAD affects about 5% of adults in the United States. The diagnosis is more common in women than in men, and more prevalent farther from the equator.

 

One Hallmark Symptom?

DSM-5 highlights characteristic features of winter depression, including:

• Loss of energy
• Hypersomnia
• A craving for carbohydrates
• Overeating
• Weight gain

Kelly Rohan, PhD, a researcher at the University of Vermont, Burlington, who has studied SAD since the 1990s, sees one symptom as a possible hallmark for the disorder: fatigue.

“I’ve personally never met someone who met the full diagnostic criteria for the seasonal pattern that did not have fatigue as one of their symptoms,” Rohan said. “In theory, they could exist, but I have spoken to hundreds of people with seasonal depression, and I have never met them if, in fact, they do exist.”

That differs from nonseasonal depression, for which insomnia is a more common problem with sleep, Patten said.

Clinicians look for at least five symptoms of depression that cause substantial impairment and distress for at least 2 weeks, such as pervasive sadness, difficulty concentrating, low self-esteem, or loss of interest in hobbies.

An average episode of winter depression can last 5 months, however, Rohan said. “That’s a long time to be in a major depressive episode.”

 

Seeing Subsyndromal Cases

In people who do not meet criteria for major depression with a seasonal pattern, the change of seasons still can affect energy levels and mood. Some patients have “subsyndromal SAD” and may benefit from treatments that have been developed for SAD such as bright light therapy, said Paul Desan, MD, PhD, director of the Winter Depression Research Clinic at Yale School of Medicine in New Haven, Connecticut.

“Many people come to our clinic because they have seasonal changes that don’t meet the full criteria for depression, but nevertheless, they want help,” Desan said.

The 1984 paper that introduced the term SAD explored artificial bright light as a promising treatment for the condition. The researchers had heard from dozens of patients with “recurrent depressions that occur annually at the same time each year,” and bright light appeared to help alleviate their symptoms.

Subsequent trials have found the approach effective. Even in nonseasonal depression, bright light therapy may increase the likelihood of remission, a recent meta-analysis found. Light therapy also may bolster the effectiveness of antidepressant medication in nonseasonal major depressive disorder, a randomized trial has shown.

Other treatments for SAD include cognitive behavioral therapy (CBT) and bupropion XL, which is approved as a preventive medication. Other drugs for major depressive disorder may be used.

 

Quest for Biomarkers

To better understand SAD and how available treatments work, Rohan is conducting a study that examines potential biomarkers in patients treated with light therapy or CBT. She and her colleagues are examining circadian phase angle difference (how well internal clocks match daily routines) and post-illumination pupil response (how the pupil constricts after a light turns off). They also are measuring participants’ pupil responses and brain activity upon seeing words that are associated with winter or summer (like “blizzard,” “icy,” “sunshine,” and “picnics.”) 

Studies have shown treating patients to remission with CBT reduces the risk for recurrence in subsequent years, relative to other treatment approaches, Rohan said. That may be because CBT gives people tools to avoid slipping into another depressive episode.

 

Avoid Self-Diagnosis

Rohan cautions patients against self-diagnosis and treatment.

“Having a conversation with your doctor is a good starting point,” she said. “Just because you can walk into Costco and walk out with a light box doesn’t mean that you should.” 

Light therapy can have side effects, including headaches, eye strain, and making patients feel wired, and it can be a challenge to determine the right dose, Rohan said.

Desan’s clinic website provides information about available devices for light therapy for patients who are looking to try this approach, but Desan agrees clinicians — especially primary care clinicians — can play a crucial role in helping patients. In more serious cases, a mental health expert may be necessary.

To start light therapy, Desan’s clinic typically recommends patients try 30 minutes of 10,000 lux bright light — roughly the brightness of being outside on a sunny day — before 8 AM for a 4-week trial.

Still, other specific issues might explain why a patient is struggling during winter months, Patten said. For example, people might experience financial stress around the holidays or consume excessive amounts of alcohol during that time.

“It’s important for clinicians to think broadly about it,” Patten said. “It might not always be light therapy or a medication. It might be focusing on some other aspect of what is going on for them in the winter.” 

Rohan’s research is funded by the National Institute of Mental Health, and she receives royalties for a manual on treating SAD with CBT. Patten and Desan had no relevant financial disclosures.

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

’Tis the season for recognizing seasonal affective disorder (SAD). Just don’t expect to find SAD in diagnostic handbooks.

As a memorable term, SAD “stuck in the general public, and to some extent among health professionals,” said Scott Patten, MD, PhD, professor of psychiatry and epidemiology at the University of Calgary in Alberta, Canada. “But it’s important to emphasize that that’s not an officially recognized diagnosis by the major classifications.”

Researchers coined the term SAD 40 years ago to describe a pattern of depression that sets in during the fall or winter and remits in the spring or summer.

Clinicians are diagnosing the disorder, albeit without that exact moniker.

In the Diagnostic and Statistical Manual of Mental Disorders, Fifth Edition (DSM-5), the condition is considered a subtype of major depression.

So, for patients who meet criteria for recurrent major depressive disorder, the specifier “with seasonal pattern” might be applied.

The subtype covers cases where depressive episodes have followed a seasonal pattern for at least 2 years. Typically, onset occurs in the fall or winter followed by remission in the spring or summer. The opposite pattern is possible but less common.

When stressors such as seasonal unemployment better explain the pattern, the seasonal specifier should not be used, according to the manual. Bipolar disorder can follow a seasonal pattern as well.

Researchers estimate SAD affects about 5% of adults in the United States. The diagnosis is more common in women than in men, and more prevalent farther from the equator.

 

One Hallmark Symptom?

DSM-5 highlights characteristic features of winter depression, including:

• Loss of energy
• Hypersomnia
• A craving for carbohydrates
• Overeating
• Weight gain

Kelly Rohan, PhD, a researcher at the University of Vermont, Burlington, who has studied SAD since the 1990s, sees one symptom as a possible hallmark for the disorder: fatigue.

“I’ve personally never met someone who met the full diagnostic criteria for the seasonal pattern that did not have fatigue as one of their symptoms,” Rohan said. “In theory, they could exist, but I have spoken to hundreds of people with seasonal depression, and I have never met them if, in fact, they do exist.”

That differs from nonseasonal depression, for which insomnia is a more common problem with sleep, Patten said.

Clinicians look for at least five symptoms of depression that cause substantial impairment and distress for at least 2 weeks, such as pervasive sadness, difficulty concentrating, low self-esteem, or loss of interest in hobbies.

An average episode of winter depression can last 5 months, however, Rohan said. “That’s a long time to be in a major depressive episode.”

 

Seeing Subsyndromal Cases

In people who do not meet criteria for major depression with a seasonal pattern, the change of seasons still can affect energy levels and mood. Some patients have “subsyndromal SAD” and may benefit from treatments that have been developed for SAD such as bright light therapy, said Paul Desan, MD, PhD, director of the Winter Depression Research Clinic at Yale School of Medicine in New Haven, Connecticut.

“Many people come to our clinic because they have seasonal changes that don’t meet the full criteria for depression, but nevertheless, they want help,” Desan said.

The 1984 paper that introduced the term SAD explored artificial bright light as a promising treatment for the condition. The researchers had heard from dozens of patients with “recurrent depressions that occur annually at the same time each year,” and bright light appeared to help alleviate their symptoms.

Subsequent trials have found the approach effective. Even in nonseasonal depression, bright light therapy may increase the likelihood of remission, a recent meta-analysis found. Light therapy also may bolster the effectiveness of antidepressant medication in nonseasonal major depressive disorder, a randomized trial has shown.

Other treatments for SAD include cognitive behavioral therapy (CBT) and bupropion XL, which is approved as a preventive medication. Other drugs for major depressive disorder may be used.

 

Quest for Biomarkers

To better understand SAD and how available treatments work, Rohan is conducting a study that examines potential biomarkers in patients treated with light therapy or CBT. She and her colleagues are examining circadian phase angle difference (how well internal clocks match daily routines) and post-illumination pupil response (how the pupil constricts after a light turns off). They also are measuring participants’ pupil responses and brain activity upon seeing words that are associated with winter or summer (like “blizzard,” “icy,” “sunshine,” and “picnics.”) 

Studies have shown treating patients to remission with CBT reduces the risk for recurrence in subsequent years, relative to other treatment approaches, Rohan said. That may be because CBT gives people tools to avoid slipping into another depressive episode.

 

Avoid Self-Diagnosis

Rohan cautions patients against self-diagnosis and treatment.

“Having a conversation with your doctor is a good starting point,” she said. “Just because you can walk into Costco and walk out with a light box doesn’t mean that you should.” 

Light therapy can have side effects, including headaches, eye strain, and making patients feel wired, and it can be a challenge to determine the right dose, Rohan said.

Desan’s clinic website provides information about available devices for light therapy for patients who are looking to try this approach, but Desan agrees clinicians — especially primary care clinicians — can play a crucial role in helping patients. In more serious cases, a mental health expert may be necessary.

To start light therapy, Desan’s clinic typically recommends patients try 30 minutes of 10,000 lux bright light — roughly the brightness of being outside on a sunny day — before 8 AM for a 4-week trial.

Still, other specific issues might explain why a patient is struggling during winter months, Patten said. For example, people might experience financial stress around the holidays or consume excessive amounts of alcohol during that time.

“It’s important for clinicians to think broadly about it,” Patten said. “It might not always be light therapy or a medication. It might be focusing on some other aspect of what is going on for them in the winter.” 

Rohan’s research is funded by the National Institute of Mental Health, and she receives royalties for a manual on treating SAD with CBT. Patten and Desan had no relevant financial disclosures.

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

TOPLINE:

Use of the glucagon-like peptide 1 (GLP-1) receptor agonists semaglutide and liraglutide is linked to a lower risk for alcohol use disorder (AUD)–related hospitalizations, compared with traditional AUD medications, a new study suggested.

METHODOLOGY:

• Researchers conducted a nationwide cohort study from 2006 to 2023 in Sweden that included more than 220,000 individuals with AUD (mean age, 40 years; 64% men).
• Data were obtained from registers of inpatient and specialized outpatient care, sickness absence, and disability pension, with a median follow-up period of 8.8 years.
• The primary exposure measured was the use of individual GLP-1 receptor agonists — commonly used to treat type 2 diabetes and obesity — compared with nonuse.
• The secondary exposure examined was the use of medications indicated for AUD.
• The primary outcome was AUD-related hospitalization; secondary outcomes included hospitalization due to substance use disorder (SUD), somatic hospitalization, and suicide attempts.

TAKEAWAY:

• About 59% of participants experienced AUD-related hospitalization.
• Semaglutide users (n = 4321) had the lowest risk for hospitalization related to AUD (adjusted hazard ratio [aHR], 0.64; 95% CI, 0.50-0.83) and to any SUD (aHR, 0.68; 95% CI, 0.54-0.85).
• Liraglutide users (n = 2509) had the second lowest risk for both AUD-related (aHR, 0.72; 95% CI, 0.57-0.92) and SUD-related (aHR, 0.78; 95% CI, 0.64-0.97) hospitalizations.
• The use of both semaglutide (aHR, 0.78; 95% CI, 0.68-0.90) and liraglutide (aHR, 0.79; 95% CI, 0.69-0.91) was linked to a reduced risk for hospitalization because of somatic reasons but was not associated with the risk of suicide attempts.
• Traditional AUD medications showed modest effectiveness with a slightly decreased but nonsignificant risk for AUD-related hospitalization (aHR, 0.98).

IN PRACTICE:

“AUDs and SUDs are undertreated pharmacologically, despite the availability of effective treatments. However, novel treatments are also needed because existing treatments may not be suitable for all patients. Semaglutide and liraglutide may be effective in the treatment of AUD, and clinical trials are urgently needed to confirm these findings,” the investigators wrote.

SOURCE:

This study was led by Markku Lähteenvuo, MD, PhD, University of Eastern Finland, Niuvanniemi Hospital, Kuopio. It was published online on November 13 in JAMA Psychiatry.

LIMITATIONS:

The observational nature of this study limited causal inferences.

DISCLOSURES:

The data used in this study were obtained from the REWHARD consortium, supported by the Swedish Research Council. Four of the six authors reported receiving grants or personal fees from various sources outside the submitted work, which are fully listed in the original article.

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

TOPLINE:

Use of the glucagon-like peptide 1 (GLP-1) receptor agonists semaglutide and liraglutide is linked to a lower risk for alcohol use disorder (AUD)–related hospitalizations, compared with traditional AUD medications, a new study suggested.

METHODOLOGY:

• Researchers conducted a nationwide cohort study from 2006 to 2023 in Sweden that included more than 220,000 individuals with AUD (mean age, 40 years; 64% men).
• Data were obtained from registers of inpatient and specialized outpatient care, sickness absence, and disability pension, with a median follow-up period of 8.8 years.
• The primary exposure measured was the use of individual GLP-1 receptor agonists — commonly used to treat type 2 diabetes and obesity — compared with nonuse.
• The secondary exposure examined was the use of medications indicated for AUD.
• The primary outcome was AUD-related hospitalization; secondary outcomes included hospitalization due to substance use disorder (SUD), somatic hospitalization, and suicide attempts.

TAKEAWAY:

• About 59% of participants experienced AUD-related hospitalization.
• Semaglutide users (n = 4321) had the lowest risk for hospitalization related to AUD (adjusted hazard ratio [aHR], 0.64; 95% CI, 0.50-0.83) and to any SUD (aHR, 0.68; 95% CI, 0.54-0.85).
• Liraglutide users (n = 2509) had the second lowest risk for both AUD-related (aHR, 0.72; 95% CI, 0.57-0.92) and SUD-related (aHR, 0.78; 95% CI, 0.64-0.97) hospitalizations.
• The use of both semaglutide (aHR, 0.78; 95% CI, 0.68-0.90) and liraglutide (aHR, 0.79; 95% CI, 0.69-0.91) was linked to a reduced risk for hospitalization because of somatic reasons but was not associated with the risk of suicide attempts.
• Traditional AUD medications showed modest effectiveness with a slightly decreased but nonsignificant risk for AUD-related hospitalization (aHR, 0.98).

IN PRACTICE:

“AUDs and SUDs are undertreated pharmacologically, despite the availability of effective treatments. However, novel treatments are also needed because existing treatments may not be suitable for all patients. Semaglutide and liraglutide may be effective in the treatment of AUD, and clinical trials are urgently needed to confirm these findings,” the investigators wrote.

SOURCE:

This study was led by Markku Lähteenvuo, MD, PhD, University of Eastern Finland, Niuvanniemi Hospital, Kuopio. It was published online on November 13 in JAMA Psychiatry.

LIMITATIONS:

The observational nature of this study limited causal inferences.

DISCLOSURES:

The data used in this study were obtained from the REWHARD consortium, supported by the Swedish Research Council. Four of the six authors reported receiving grants or personal fees from various sources outside the submitted work, which are fully listed in the original article.

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

TOPLINE:

Use of the glucagon-like peptide 1 (GLP-1) receptor agonists semaglutide and liraglutide is linked to a lower risk for alcohol use disorder (AUD)–related hospitalizations, compared with traditional AUD medications, a new study suggested.

METHODOLOGY:

• Researchers conducted a nationwide cohort study from 2006 to 2023 in Sweden that included more than 220,000 individuals with AUD (mean age, 40 years; 64% men).
• Data were obtained from registers of inpatient and specialized outpatient care, sickness absence, and disability pension, with a median follow-up period of 8.8 years.
• The primary exposure measured was the use of individual GLP-1 receptor agonists — commonly used to treat type 2 diabetes and obesity — compared with nonuse.
• The secondary exposure examined was the use of medications indicated for AUD.
• The primary outcome was AUD-related hospitalization; secondary outcomes included hospitalization due to substance use disorder (SUD), somatic hospitalization, and suicide attempts.

TAKEAWAY:

• About 59% of participants experienced AUD-related hospitalization.
• Semaglutide users (n = 4321) had the lowest risk for hospitalization related to AUD (adjusted hazard ratio [aHR], 0.64; 95% CI, 0.50-0.83) and to any SUD (aHR, 0.68; 95% CI, 0.54-0.85).
• Liraglutide users (n = 2509) had the second lowest risk for both AUD-related (aHR, 0.72; 95% CI, 0.57-0.92) and SUD-related (aHR, 0.78; 95% CI, 0.64-0.97) hospitalizations.
• The use of both semaglutide (aHR, 0.78; 95% CI, 0.68-0.90) and liraglutide (aHR, 0.79; 95% CI, 0.69-0.91) was linked to a reduced risk for hospitalization because of somatic reasons but was not associated with the risk of suicide attempts.
• Traditional AUD medications showed modest effectiveness with a slightly decreased but nonsignificant risk for AUD-related hospitalization (aHR, 0.98).

IN PRACTICE:

“AUDs and SUDs are undertreated pharmacologically, despite the availability of effective treatments. However, novel treatments are also needed because existing treatments may not be suitable for all patients. Semaglutide and liraglutide may be effective in the treatment of AUD, and clinical trials are urgently needed to confirm these findings,” the investigators wrote.

SOURCE:

This study was led by Markku Lähteenvuo, MD, PhD, University of Eastern Finland, Niuvanniemi Hospital, Kuopio. It was published online on November 13 in JAMA Psychiatry.

LIMITATIONS:

The observational nature of this study limited causal inferences.

DISCLOSURES:

The data used in this study were obtained from the REWHARD consortium, supported by the Swedish Research Council. Four of the six authors reported receiving grants or personal fees from various sources outside the submitted work, which are fully listed in the original article.

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