Traumatic Brain Injury

A tool routinely used to evaluate concussion in college athletes fails to accurately diagnose the condition in many cases, a new study showed.

Investigators found that almost half of athletes diagnosed with a concussion tested normally on the Sports Concussion Assessment Tool 5 (SCAT5), the recommended tool for measuring cognitive skills in concussion evaluations. The most accurate measure of concussion was symptoms reported by the athletes.

“If you don’t do well on the cognitive exam, it suggests you have a concussion. But many people who are concussed do fine on the exam,” lead author Kimberly Harmon, MD, professor of family medicine and section head of sports medicine at the University of Washington School of Medicine, Seattle, said in a news release.

The study was published online in JAMA Network Open.

Introduced in 2004, the SCAT was created to standardize the collection of information clinicians use to diagnose concussion, including evaluation of symptoms, orientation, and balance. It also uses a 10-word list to assess immediate memory and delayed recall.

Dr. Harmon’s own experiences as a team physician led her to wonder about the accuracy of the cognitive screening portion of the SCAT. She saw that “some people were concussed, and they did well on the recall test. Some people weren’t concussed, and they didn’t do well. So I thought we should study it,” she said.

Investigators compared 92 National Collegiate Athletic Association (NCAA) Division 1 athletes who had sustained a concussion between 2020 and 2022 and had a concussion evaluation within 48 hours to 92 matched nonconcussed teammates (overall cohort, 52% men). Most concussions occurred in those who played football, followed by volleyball.

All athletes had previously completed NCAA-required baseline concussion screenings. Participants completed the SCAT5 screening test within 2 weeks of the incident concussion.

No significant differences were found between the baseline scores of athletes with and without concussion. Moreover, responses on the word recall section of the SCAT5 held little predictive value for concussion.

Nearly half (45%) of athletes with concussion performed at or even above their baseline cognitive report, which the authors said highlights the limitations of the cognitive components of SCAT5.

The most accurate predictor of concussion was participants’ responses to questions about their symptoms.

“If you get hit in the head and go to the sideline and say, ‘I have a headache, I’m dizzy, I don’t feel right,’ I can say with pretty good assurance that you have a concussion,” Dr. Harmon continued. “I don’t need to do any testing.”

Unfortunately, the problem is “that some athletes don’t want to come out. They don’t report their symptoms or may not recognize their symptoms. So then you need an objective, accurate test to tell you whether you can safely put the athlete back on the field. We don’t have that right now.”

The study did not control for concussion history, and the all–Division 1 cohort means the findings may not be generalizable to other athletes.

Nevertheless, investigators said the study “affirms that reported symptoms are the most sensitive indicator of concussion, and there are limitations to the objective cognitive testing included in the SCAT.” They concluded that concussion “remains a clinical diagnosis that should be based on a thorough review of signs, symptoms, and clinical findings.”

This study was funded in part by donations from University of Washington alumni Jack and Luellen Cherneski and the Chisholm Foundation. Dr. Harmon reported no relevant financial relationships.

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

A tool routinely used to evaluate concussion in college athletes fails to accurately diagnose the condition in many cases, a new study showed.

Investigators found that almost half of athletes diagnosed with a concussion tested normally on the Sports Concussion Assessment Tool 5 (SCAT5), the recommended tool for measuring cognitive skills in concussion evaluations. The most accurate measure of concussion was symptoms reported by the athletes.

“If you don’t do well on the cognitive exam, it suggests you have a concussion. But many people who are concussed do fine on the exam,” lead author Kimberly Harmon, MD, professor of family medicine and section head of sports medicine at the University of Washington School of Medicine, Seattle, said in a news release.

The study was published online in JAMA Network Open.

Introduced in 2004, the SCAT was created to standardize the collection of information clinicians use to diagnose concussion, including evaluation of symptoms, orientation, and balance. It also uses a 10-word list to assess immediate memory and delayed recall.

Dr. Harmon’s own experiences as a team physician led her to wonder about the accuracy of the cognitive screening portion of the SCAT. She saw that “some people were concussed, and they did well on the recall test. Some people weren’t concussed, and they didn’t do well. So I thought we should study it,” she said.

Investigators compared 92 National Collegiate Athletic Association (NCAA) Division 1 athletes who had sustained a concussion between 2020 and 2022 and had a concussion evaluation within 48 hours to 92 matched nonconcussed teammates (overall cohort, 52% men). Most concussions occurred in those who played football, followed by volleyball.

All athletes had previously completed NCAA-required baseline concussion screenings. Participants completed the SCAT5 screening test within 2 weeks of the incident concussion.

No significant differences were found between the baseline scores of athletes with and without concussion. Moreover, responses on the word recall section of the SCAT5 held little predictive value for concussion.

Nearly half (45%) of athletes with concussion performed at or even above their baseline cognitive report, which the authors said highlights the limitations of the cognitive components of SCAT5.

The most accurate predictor of concussion was participants’ responses to questions about their symptoms.

“If you get hit in the head and go to the sideline and say, ‘I have a headache, I’m dizzy, I don’t feel right,’ I can say with pretty good assurance that you have a concussion,” Dr. Harmon continued. “I don’t need to do any testing.”

Unfortunately, the problem is “that some athletes don’t want to come out. They don’t report their symptoms or may not recognize their symptoms. So then you need an objective, accurate test to tell you whether you can safely put the athlete back on the field. We don’t have that right now.”

The study did not control for concussion history, and the all–Division 1 cohort means the findings may not be generalizable to other athletes.

Nevertheless, investigators said the study “affirms that reported symptoms are the most sensitive indicator of concussion, and there are limitations to the objective cognitive testing included in the SCAT.” They concluded that concussion “remains a clinical diagnosis that should be based on a thorough review of signs, symptoms, and clinical findings.”

This study was funded in part by donations from University of Washington alumni Jack and Luellen Cherneski and the Chisholm Foundation. Dr. Harmon reported no relevant financial relationships.

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

A tool routinely used to evaluate concussion in college athletes fails to accurately diagnose the condition in many cases, a new study showed.

Investigators found that almost half of athletes diagnosed with a concussion tested normally on the Sports Concussion Assessment Tool 5 (SCAT5), the recommended tool for measuring cognitive skills in concussion evaluations. The most accurate measure of concussion was symptoms reported by the athletes.

“If you don’t do well on the cognitive exam, it suggests you have a concussion. But many people who are concussed do fine on the exam,” lead author Kimberly Harmon, MD, professor of family medicine and section head of sports medicine at the University of Washington School of Medicine, Seattle, said in a news release.

The study was published online in JAMA Network Open.

Introduced in 2004, the SCAT was created to standardize the collection of information clinicians use to diagnose concussion, including evaluation of symptoms, orientation, and balance. It also uses a 10-word list to assess immediate memory and delayed recall.

Dr. Harmon’s own experiences as a team physician led her to wonder about the accuracy of the cognitive screening portion of the SCAT. She saw that “some people were concussed, and they did well on the recall test. Some people weren’t concussed, and they didn’t do well. So I thought we should study it,” she said.

Investigators compared 92 National Collegiate Athletic Association (NCAA) Division 1 athletes who had sustained a concussion between 2020 and 2022 and had a concussion evaluation within 48 hours to 92 matched nonconcussed teammates (overall cohort, 52% men). Most concussions occurred in those who played football, followed by volleyball.

All athletes had previously completed NCAA-required baseline concussion screenings. Participants completed the SCAT5 screening test within 2 weeks of the incident concussion.

No significant differences were found between the baseline scores of athletes with and without concussion. Moreover, responses on the word recall section of the SCAT5 held little predictive value for concussion.

Nearly half (45%) of athletes with concussion performed at or even above their baseline cognitive report, which the authors said highlights the limitations of the cognitive components of SCAT5.

The most accurate predictor of concussion was participants’ responses to questions about their symptoms.

“If you get hit in the head and go to the sideline and say, ‘I have a headache, I’m dizzy, I don’t feel right,’ I can say with pretty good assurance that you have a concussion,” Dr. Harmon continued. “I don’t need to do any testing.”

Unfortunately, the problem is “that some athletes don’t want to come out. They don’t report their symptoms or may not recognize their symptoms. So then you need an objective, accurate test to tell you whether you can safely put the athlete back on the field. We don’t have that right now.”

The study did not control for concussion history, and the all–Division 1 cohort means the findings may not be generalizable to other athletes.

Nevertheless, investigators said the study “affirms that reported symptoms are the most sensitive indicator of concussion, and there are limitations to the objective cognitive testing included in the SCAT.” They concluded that concussion “remains a clinical diagnosis that should be based on a thorough review of signs, symptoms, and clinical findings.”

This study was funded in part by donations from University of Washington alumni Jack and Luellen Cherneski and the Chisholm Foundation. Dr. Harmon reported no relevant financial relationships.

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

In October 2023, Robert Card — a grenade instructor in the Army Reserve — shot and killed 18 people in Maine, before turning the gun on himself. As reported by The New York Times, his family said that he had become increasingly erratic and violent during the months before the rampage.

A postmortem conducted by the Chronic Traumatic Encephalopathy (CTE) Center at Boston University found “significant evidence of traumatic brain injuries” [TBIs] and “significant degeneration, axonal and myelin loss, inflammation, and small blood vessel injury” in the white matter, the center’s director, Ann McKee, MD, said in a press release. “These findings align with our previous studies on the effects of blast injury in humans and experimental models.”

Members of the military, such as Mr. Card, are exposed to blasts from repeated firing of heavy weapons not only during combat but also during training.

New data suggest that repeated blast exposure may impair the brain’s waste clearance system, leading to biomarker changes indicative of preclinical Alzheimer’s disease 20 years earlier than typical. A higher index of suspicion for dementia or Alzheimer’s disease may be warranted in patients with a history of blast exposure or subconcussive brain injury who present with cognitive issues, according to experts interviewed.

In 2022, the US Department of Defense (DOD) launched its Warfighter Brain Health Initiative with the aim of “optimizing service member brain health and countering traumatic brain injuries.”

In April 2024, the Blast Overpressure Safety Act was introduced in the Senate to require the DOD to enact better blast screening, tracking, prevention, and treatment. The DOD initiated 26 blast overpressure studies.

Heather Snyder, PhD, Alzheimer’s Association vice president of Medical and Scientific Relations, said that an important component of that research involves “the need to study the difference between TBI-caused dementia and dementia caused independently” and “the need to study biomarkers to better understand the long-term consequences of TBI.”
 

What Is the Underlying Biology?

Dr. Snyder was the lead author of a white paper produced by the Alzheimer’s Association in 2018 on military-related risk factors for Alzheimer’s disease and related dementias. “There is a lot of work trying to understand the effect of pure blast waves on the brain, as opposed to the actual impact of the injury,” she said.

The white paper speculated that blast exposure may be analogous to subconcussive brain injury in athletes where there are no obvious immediate clinical symptoms or neurological dysfunction but which can cause cumulative injury and functional impairment over time.

“We are also trying to understand the underlying biology around brain changes, such as accumulation of tau and amyloid and other specific markers related to brain changes in Alzheimer’s disease,” said Dr. Snyder, chair of the Peer Reviewed Alzheimer’s Research Program Programmatic Panel for Alzheimer’s Disease/Alzheimer’s Disease and Related Dementias and TBI.
 

Common Biomarker Signatures

A recent study in Neurology comparing 51 veterans with mild TBI (mTBI) with 85 veterans and civilians with no lifetime history of TBI is among the first to explore these biomarker changes in human beings.

“Our findings suggest that chronic neuropathologic processes associated with blast mTBI share properties in common with pathogenic processes that are precursors to Alzheimer’s disease onset,” said coauthor Elaine R. Peskind, MD, professor of psychiatry and behavioral sciences, University of Washington, Seattle.

The largely male participants were a mean age of 34 years and underwent standardized clinical and neuropsychological testing as well as lumbar puncture to collect cerebrospinal fluid (CSF). The mTBI group had experienced at least one war zone blast or combined blast/impact that met criteria for mTBI, but 91% had more than one blast mTBI, and the study took place over 13 years.

The researchers found that the mTBI group “had biomarker signatures in common with the earliest stages of Alzheimer’s disease,” said Dr. Peskind.

For example, at age 50, they had lower mean levels of CSF amyloid beta 42 (Abeta42), the earliest marker of brain parenchymal Abeta deposition, compared with the control group (154 pg/mL and 1864 pg/mL lower, respectively).

High CSF phosphorylated tau181 (p-tau181) and total tau are established biomarkers for Alzheimer’s disease. However, levels of these biomarkers remained “relatively constant with age” in participants with mTBI but were higher in older ages for the non-TBI group.

The mTBI group also showed worse cognitive performance at older ages (P < .08). Poorer verbal memory and verbal fluency performance were associated with lower CSF Abeta42 in older participants (P ≤ .05).

In Alzheimer’s disease, a reduction in CSF Abeta42 may occur up to 20 years before the onset of clinical symptoms, according to Dr. Peskind. “But what we don’t know from this study is what this means, as total tau protein and p-tau181 in the CSF were also low, which isn’t entirely typical in the picture of preclinical Alzheimer’s disease,” she said. However, changes in total tau and p-tau181 lag behind changes in Abeta42.
 

Is Impaired Clearance the Culprit?

Coauthor Jeffrey Iliff, PhD, professor, University of Washington Department of Psychiatry and Behavioral Sciences and University of Washington Department of Neurology, Seattle, elaborated.

“In the setting of Alzheimer’s disease, a signature of the disease is reduced CSF Abeta42, which is thought to reflect that much of the amyloid gets ‘stuck’ in the brain in the form of amyloid plaques,” he said. “There are usually higher levels of phosphorylated tau and total tau, which are thought to reflect the presence of tau tangles and degeneration of neurons in the brain. But in this study, all of those were lowered, which is not exactly an Alzheimer’s disease profile.”

Dr. Iliff, associate director for research, VA Northwest Mental Illness Research, Education, and Clinical Center at VA Puget Sound Health Care System, Seattle, suggested that the culprit may be impairment in the brain’s glymphatic system. “Recently described biological research supports [the concept of] clearance of waste out of the brain during sleep via the glymphatic system, with amyloid and tau being cleared from the brain interstitium during sleep.”

A recent hypothesis is that blast TBI impairs that process. “This is why we see less of those proteins in the CSF. They’re not being cleared, which might contribute downstream to the clumping up of protein in the brain,” he suggested.

The evidence base corroborating that hypothesis is in its infancy; however, new research conducted by Dr. Iliff and his colleagues sheds light on this potential mechanism.

In blast TBI, energy from the explosion and resulting overpressure wave are “transmitted through the brain, which causes tissues of different densities — such as gray and white matter — to accelerate at different rates,” according to Dr. Iliff. This results in the shearing and stretching of brain tissue, leading to a “diffuse pattern of tissue damage.”

It is known that blast TBI has clinical overlap and associations with posttraumatic stress disorder (PTSD), depression, and persistent neurobehavioral symptoms; that veterans with a history of TBI are more than twice as likely to die by suicide than veterans with no TBI history; and that TBI may increase the risk for Alzheimer’s disease and related dementing disorders, as well as CTE.

The missing link may be the glymphatic system — a “brain-wide network of perivascular pathways, along which CSF and interstitial fluid (ISF) exchange, supporting the clearance of interstitial solutes, including amyloid-beta.”

Dr. Iliff and his group previously found that glymphatic function is “markedly and chronically impaired” following impact TBI in mice and that this impairment is associated with the mislocalization of astroglial aquaporin 4 (AQP4), a water channel that lines perivascular spaces and plays a role in healthy glymphatic exchange.

In their new study, the researchers examined both the expression and the localization of AQP4 in the human postmortem frontal cortex and found “distinct laminar differences” in AQP4 expression following blast exposure. They observed similar changes as well as impairment of glymphatic function, which emerged 28 days following blast injury in a mouse model of repetitive blast mTBI.

And in a cohort of veterans with blast mTBI, blast exposure was found to be associated with an increased burden of frontal cortical MRI-visible perivascular spaces — a “putative neuroimaging marker” of glymphatic perivascular dysfunction.

The earlier Neurology study “showed impairment of biomarkers in the CSF, but the new study showed ‘why’ or ‘how’ these biomarkers are impaired, which is via impairment of the glymphatic clearance process,” Dr. Iliff explained.
 

Veterans Especially Vulnerable

Dr. Peskind, co-director of the VA Northwest Mental Illness Research, Education and Clinical Center, VA Puget Sound Health Care System, noted that while the veterans in the earlier study had at least one TBI, the average number was 20, and it was more common to have more than 50 mTBIs than to have a single one.

“These were highly exposed combat vets,” she said. “And that number doesn’t even account for subconcussive exposure to blasts, which now appear to cause detectable brain damage, even in the absence of a diagnosable TBI.”

The Maine shooter, Mr. Card, had not seen combat and was not assessed for TBI during a psychiatric hospitalization, according to The New York Times.

Dr. Peskind added that this type of blast damage is likely specific to individuals in the military. “It isn’t the sound that causes the damage,” she explained. “It’s the blast wave, the pressure wave, and there aren’t a lot of other occupations that have those types of occupational exposures.”

Dr. Snyder added that the majority of blast TBIs have been studied in military personnel, and she is not aware of studies that have looked at blast injuries in other industries, such as demolition or mining, to see if they have the same type of biologic consequences.

Dr. Snyder hopes that the researchers will follow the participants in the Neurology study and continue looking at specific markers related to Alzheimer’s disease brain changes. What the research so far shows “is that, at an earlier age, we’re starting to see those markers changing, suggesting that the underlying biology in people with mild blast TBI is similar to the underlying biology in Alzheimer’s disease as well.”

Michael Alosco, PhD, associate professor and vice chair of research, department of neurology, Boston University Chobanian & Avedisian School of Medicine, called the issue of blast exposure and TBI “a very complex and nuanced topic,” especially because TBI is “considered a risk factor of Alzheimer’s disease” and “different types of TBIs could trigger distinct pathophysiologic processes; however, the long-term impact of repetitive blast TBIs on neurodegenerative disease changes remains unknown.”

He coauthored an editorial on the earlier Neurology study that noted its limitations, such as a small sample size and lack of consideration of lifestyle and health factors but acknowledged that the “findings provide preliminary evidence that repetitive blast exposures might influence beta-amyloid accumulation.”
 

Clinical Implications

For Dr. Peskind, the “inflection point” was seeing lower CSF Abeta42, about 20 years earlier than ages 60 and 70, which is more typical in cognitively normal community volunteers.

But she described herself as “loath to say that veterans or service members have a 20-year acceleration of risk of Alzheimer’s disease,” adding, “I don’t want to scare the heck out of our service members of veterans.” Although “this is what we fear, we’re not ready to say it for sure yet because we need to do more work. Nevertheless, it does increase the index of suspicion.”

The clinical take-home messages are not unique to service members or veterans or people with a history of head injuries or a genetic predisposition to Alzheimer’s disease, she emphasized. “If anyone of any age or occupation comes in with cognitive issues, such as [impaired] memory or executive function, they deserve a workup for dementing disorders.” Frontotemporal dementia, for example, can present earlier than Alzheimer’s disease typically does.

Common comorbidities with TBI are PTSD and obstructive sleep apnea (OSA), which can also cause cognitive issues and are also risk factors for dementia.

Dr. Iliff agreed. “If you see a veteran with a history of PTSD, a history of blast TBI, and a history of OSA or some combination of those three, I recommend having a higher index of suspicion [for potential dementia] than for an average person without any of these, even at a younger age than one would ordinarily expect.”

Of all of these factors, the only truly directly modifiable one is sleep disruption, including that caused by OSA or sleep disorders related to PTSD, he added. “Epidemiologic data suggest a connection particularly between midlife sleep disruption and the risk of dementia and Alzheimer’s disease, and so it’s worth thinking about sleep as a modifiable risk factor even as early as the 40s and 50s, whether the patient is or isn’t a veteran.”

Dr. Peskind recommended asking patients, “Do they snore? Do they thrash about during sleep? Do they have trauma nightmares? This will inform the type of intervention required.”

Dr. Alosco added that there is no known “safe” threshold of exposure to blasts, and that thresholds are “unclear, particularly at the individual level.” In American football, there is a dose-response relationship between years of play and risk for later-life neurological disorder. “The best way to mitigate risk is to limit cumulative exposure,” he said.

The study by Li and colleagues was funded by grant funding from the Department of Veterans Affairs Rehabilitation Research and Development Service and the University of Washington Friends of Alzheimer’s Research. Other sources of funding to individual researchers are listed in the original paper. The study by Braun and colleagues was supported by the National Heart, Lung and Blood Institute; the Department of Veterans Affairs Rehabilitation Research and Development Service; and the National Institute on Aging. The white paper included studies that received funding from numerous sources, including the National Institutes of Health and the DOD. Dr. Iliff serves as the chair of the Scientific Advisory Board for Applied Cognition Inc., from which he receives compensation and in which he holds an equity stake. In the last year, he served as a paid consultant to Gryphon Biosciences. Dr. Peskind has served as a paid consultant to the companies Genentech, Roche, and Alpha Cognition. Dr. Alosco was supported by grant funding from the NIH; he received research support from Rainwater Charitable Foundation Inc., and Life Molecular Imaging Inc.; he has received a single honorarium from the Michael J. Fox Foundation for services unrelated to this editorial; and he received royalties from Oxford University Press Inc. The other authors’ disclosures are listed in the original papers.
 

A version of this article appeared on Medscape.com.

In October 2023, Robert Card — a grenade instructor in the Army Reserve — shot and killed 18 people in Maine, before turning the gun on himself. As reported by The New York Times, his family said that he had become increasingly erratic and violent during the months before the rampage.

A postmortem conducted by the Chronic Traumatic Encephalopathy (CTE) Center at Boston University found “significant evidence of traumatic brain injuries” [TBIs] and “significant degeneration, axonal and myelin loss, inflammation, and small blood vessel injury” in the white matter, the center’s director, Ann McKee, MD, said in a press release. “These findings align with our previous studies on the effects of blast injury in humans and experimental models.”

Members of the military, such as Mr. Card, are exposed to blasts from repeated firing of heavy weapons not only during combat but also during training.

New data suggest that repeated blast exposure may impair the brain’s waste clearance system, leading to biomarker changes indicative of preclinical Alzheimer’s disease 20 years earlier than typical. A higher index of suspicion for dementia or Alzheimer’s disease may be warranted in patients with a history of blast exposure or subconcussive brain injury who present with cognitive issues, according to experts interviewed.

In 2022, the US Department of Defense (DOD) launched its Warfighter Brain Health Initiative with the aim of “optimizing service member brain health and countering traumatic brain injuries.”

In April 2024, the Blast Overpressure Safety Act was introduced in the Senate to require the DOD to enact better blast screening, tracking, prevention, and treatment. The DOD initiated 26 blast overpressure studies.

Heather Snyder, PhD, Alzheimer’s Association vice president of Medical and Scientific Relations, said that an important component of that research involves “the need to study the difference between TBI-caused dementia and dementia caused independently” and “the need to study biomarkers to better understand the long-term consequences of TBI.”
 

What Is the Underlying Biology?

Dr. Snyder was the lead author of a white paper produced by the Alzheimer’s Association in 2018 on military-related risk factors for Alzheimer’s disease and related dementias. “There is a lot of work trying to understand the effect of pure blast waves on the brain, as opposed to the actual impact of the injury,” she said.

The white paper speculated that blast exposure may be analogous to subconcussive brain injury in athletes where there are no obvious immediate clinical symptoms or neurological dysfunction but which can cause cumulative injury and functional impairment over time.

“We are also trying to understand the underlying biology around brain changes, such as accumulation of tau and amyloid and other specific markers related to brain changes in Alzheimer’s disease,” said Dr. Snyder, chair of the Peer Reviewed Alzheimer’s Research Program Programmatic Panel for Alzheimer’s Disease/Alzheimer’s Disease and Related Dementias and TBI.
 

Common Biomarker Signatures

A recent study in Neurology comparing 51 veterans with mild TBI (mTBI) with 85 veterans and civilians with no lifetime history of TBI is among the first to explore these biomarker changes in human beings.

“Our findings suggest that chronic neuropathologic processes associated with blast mTBI share properties in common with pathogenic processes that are precursors to Alzheimer’s disease onset,” said coauthor Elaine R. Peskind, MD, professor of psychiatry and behavioral sciences, University of Washington, Seattle.

The largely male participants were a mean age of 34 years and underwent standardized clinical and neuropsychological testing as well as lumbar puncture to collect cerebrospinal fluid (CSF). The mTBI group had experienced at least one war zone blast or combined blast/impact that met criteria for mTBI, but 91% had more than one blast mTBI, and the study took place over 13 years.

The researchers found that the mTBI group “had biomarker signatures in common with the earliest stages of Alzheimer’s disease,” said Dr. Peskind.

For example, at age 50, they had lower mean levels of CSF amyloid beta 42 (Abeta42), the earliest marker of brain parenchymal Abeta deposition, compared with the control group (154 pg/mL and 1864 pg/mL lower, respectively).

High CSF phosphorylated tau181 (p-tau181) and total tau are established biomarkers for Alzheimer’s disease. However, levels of these biomarkers remained “relatively constant with age” in participants with mTBI but were higher in older ages for the non-TBI group.

The mTBI group also showed worse cognitive performance at older ages (P < .08). Poorer verbal memory and verbal fluency performance were associated with lower CSF Abeta42 in older participants (P ≤ .05).

In Alzheimer’s disease, a reduction in CSF Abeta42 may occur up to 20 years before the onset of clinical symptoms, according to Dr. Peskind. “But what we don’t know from this study is what this means, as total tau protein and p-tau181 in the CSF were also low, which isn’t entirely typical in the picture of preclinical Alzheimer’s disease,” she said. However, changes in total tau and p-tau181 lag behind changes in Abeta42.
 

Is Impaired Clearance the Culprit?

Coauthor Jeffrey Iliff, PhD, professor, University of Washington Department of Psychiatry and Behavioral Sciences and University of Washington Department of Neurology, Seattle, elaborated.

“In the setting of Alzheimer’s disease, a signature of the disease is reduced CSF Abeta42, which is thought to reflect that much of the amyloid gets ‘stuck’ in the brain in the form of amyloid plaques,” he said. “There are usually higher levels of phosphorylated tau and total tau, which are thought to reflect the presence of tau tangles and degeneration of neurons in the brain. But in this study, all of those were lowered, which is not exactly an Alzheimer’s disease profile.”

Dr. Iliff, associate director for research, VA Northwest Mental Illness Research, Education, and Clinical Center at VA Puget Sound Health Care System, Seattle, suggested that the culprit may be impairment in the brain’s glymphatic system. “Recently described biological research supports [the concept of] clearance of waste out of the brain during sleep via the glymphatic system, with amyloid and tau being cleared from the brain interstitium during sleep.”

A recent hypothesis is that blast TBI impairs that process. “This is why we see less of those proteins in the CSF. They’re not being cleared, which might contribute downstream to the clumping up of protein in the brain,” he suggested.

The evidence base corroborating that hypothesis is in its infancy; however, new research conducted by Dr. Iliff and his colleagues sheds light on this potential mechanism.

In blast TBI, energy from the explosion and resulting overpressure wave are “transmitted through the brain, which causes tissues of different densities — such as gray and white matter — to accelerate at different rates,” according to Dr. Iliff. This results in the shearing and stretching of brain tissue, leading to a “diffuse pattern of tissue damage.”

It is known that blast TBI has clinical overlap and associations with posttraumatic stress disorder (PTSD), depression, and persistent neurobehavioral symptoms; that veterans with a history of TBI are more than twice as likely to die by suicide than veterans with no TBI history; and that TBI may increase the risk for Alzheimer’s disease and related dementing disorders, as well as CTE.

The missing link may be the glymphatic system — a “brain-wide network of perivascular pathways, along which CSF and interstitial fluid (ISF) exchange, supporting the clearance of interstitial solutes, including amyloid-beta.”

Dr. Iliff and his group previously found that glymphatic function is “markedly and chronically impaired” following impact TBI in mice and that this impairment is associated with the mislocalization of astroglial aquaporin 4 (AQP4), a water channel that lines perivascular spaces and plays a role in healthy glymphatic exchange.

In their new study, the researchers examined both the expression and the localization of AQP4 in the human postmortem frontal cortex and found “distinct laminar differences” in AQP4 expression following blast exposure. They observed similar changes as well as impairment of glymphatic function, which emerged 28 days following blast injury in a mouse model of repetitive blast mTBI.

And in a cohort of veterans with blast mTBI, blast exposure was found to be associated with an increased burden of frontal cortical MRI-visible perivascular spaces — a “putative neuroimaging marker” of glymphatic perivascular dysfunction.

The earlier Neurology study “showed impairment of biomarkers in the CSF, but the new study showed ‘why’ or ‘how’ these biomarkers are impaired, which is via impairment of the glymphatic clearance process,” Dr. Iliff explained.
 

Veterans Especially Vulnerable

Dr. Peskind, co-director of the VA Northwest Mental Illness Research, Education and Clinical Center, VA Puget Sound Health Care System, noted that while the veterans in the earlier study had at least one TBI, the average number was 20, and it was more common to have more than 50 mTBIs than to have a single one.

“These were highly exposed combat vets,” she said. “And that number doesn’t even account for subconcussive exposure to blasts, which now appear to cause detectable brain damage, even in the absence of a diagnosable TBI.”

The Maine shooter, Mr. Card, had not seen combat and was not assessed for TBI during a psychiatric hospitalization, according to The New York Times.

Dr. Peskind added that this type of blast damage is likely specific to individuals in the military. “It isn’t the sound that causes the damage,” she explained. “It’s the blast wave, the pressure wave, and there aren’t a lot of other occupations that have those types of occupational exposures.”

Dr. Snyder added that the majority of blast TBIs have been studied in military personnel, and she is not aware of studies that have looked at blast injuries in other industries, such as demolition or mining, to see if they have the same type of biologic consequences.

Dr. Snyder hopes that the researchers will follow the participants in the Neurology study and continue looking at specific markers related to Alzheimer’s disease brain changes. What the research so far shows “is that, at an earlier age, we’re starting to see those markers changing, suggesting that the underlying biology in people with mild blast TBI is similar to the underlying biology in Alzheimer’s disease as well.”

Michael Alosco, PhD, associate professor and vice chair of research, department of neurology, Boston University Chobanian & Avedisian School of Medicine, called the issue of blast exposure and TBI “a very complex and nuanced topic,” especially because TBI is “considered a risk factor of Alzheimer’s disease” and “different types of TBIs could trigger distinct pathophysiologic processes; however, the long-term impact of repetitive blast TBIs on neurodegenerative disease changes remains unknown.”

He coauthored an editorial on the earlier Neurology study that noted its limitations, such as a small sample size and lack of consideration of lifestyle and health factors but acknowledged that the “findings provide preliminary evidence that repetitive blast exposures might influence beta-amyloid accumulation.”
 

Clinical Implications

For Dr. Peskind, the “inflection point” was seeing lower CSF Abeta42, about 20 years earlier than ages 60 and 70, which is more typical in cognitively normal community volunteers.

But she described herself as “loath to say that veterans or service members have a 20-year acceleration of risk of Alzheimer’s disease,” adding, “I don’t want to scare the heck out of our service members of veterans.” Although “this is what we fear, we’re not ready to say it for sure yet because we need to do more work. Nevertheless, it does increase the index of suspicion.”

The clinical take-home messages are not unique to service members or veterans or people with a history of head injuries or a genetic predisposition to Alzheimer’s disease, she emphasized. “If anyone of any age or occupation comes in with cognitive issues, such as [impaired] memory or executive function, they deserve a workup for dementing disorders.” Frontotemporal dementia, for example, can present earlier than Alzheimer’s disease typically does.

Common comorbidities with TBI are PTSD and obstructive sleep apnea (OSA), which can also cause cognitive issues and are also risk factors for dementia.

Dr. Iliff agreed. “If you see a veteran with a history of PTSD, a history of blast TBI, and a history of OSA or some combination of those three, I recommend having a higher index of suspicion [for potential dementia] than for an average person without any of these, even at a younger age than one would ordinarily expect.”

Of all of these factors, the only truly directly modifiable one is sleep disruption, including that caused by OSA or sleep disorders related to PTSD, he added. “Epidemiologic data suggest a connection particularly between midlife sleep disruption and the risk of dementia and Alzheimer’s disease, and so it’s worth thinking about sleep as a modifiable risk factor even as early as the 40s and 50s, whether the patient is or isn’t a veteran.”

Dr. Peskind recommended asking patients, “Do they snore? Do they thrash about during sleep? Do they have trauma nightmares? This will inform the type of intervention required.”

Dr. Alosco added that there is no known “safe” threshold of exposure to blasts, and that thresholds are “unclear, particularly at the individual level.” In American football, there is a dose-response relationship between years of play and risk for later-life neurological disorder. “The best way to mitigate risk is to limit cumulative exposure,” he said.

The study by Li and colleagues was funded by grant funding from the Department of Veterans Affairs Rehabilitation Research and Development Service and the University of Washington Friends of Alzheimer’s Research. Other sources of funding to individual researchers are listed in the original paper. The study by Braun and colleagues was supported by the National Heart, Lung and Blood Institute; the Department of Veterans Affairs Rehabilitation Research and Development Service; and the National Institute on Aging. The white paper included studies that received funding from numerous sources, including the National Institutes of Health and the DOD. Dr. Iliff serves as the chair of the Scientific Advisory Board for Applied Cognition Inc., from which he receives compensation and in which he holds an equity stake. In the last year, he served as a paid consultant to Gryphon Biosciences. Dr. Peskind has served as a paid consultant to the companies Genentech, Roche, and Alpha Cognition. Dr. Alosco was supported by grant funding from the NIH; he received research support from Rainwater Charitable Foundation Inc., and Life Molecular Imaging Inc.; he has received a single honorarium from the Michael J. Fox Foundation for services unrelated to this editorial; and he received royalties from Oxford University Press Inc. The other authors’ disclosures are listed in the original papers.
 

A version of this article appeared on Medscape.com.

In October 2023, Robert Card — a grenade instructor in the Army Reserve — shot and killed 18 people in Maine, before turning the gun on himself. As reported by The New York Times, his family said that he had become increasingly erratic and violent during the months before the rampage.

A postmortem conducted by the Chronic Traumatic Encephalopathy (CTE) Center at Boston University found “significant evidence of traumatic brain injuries” [TBIs] and “significant degeneration, axonal and myelin loss, inflammation, and small blood vessel injury” in the white matter, the center’s director, Ann McKee, MD, said in a press release. “These findings align with our previous studies on the effects of blast injury in humans and experimental models.”

Members of the military, such as Mr. Card, are exposed to blasts from repeated firing of heavy weapons not only during combat but also during training.

New data suggest that repeated blast exposure may impair the brain’s waste clearance system, leading to biomarker changes indicative of preclinical Alzheimer’s disease 20 years earlier than typical. A higher index of suspicion for dementia or Alzheimer’s disease may be warranted in patients with a history of blast exposure or subconcussive brain injury who present with cognitive issues, according to experts interviewed.

In 2022, the US Department of Defense (DOD) launched its Warfighter Brain Health Initiative with the aim of “optimizing service member brain health and countering traumatic brain injuries.”

In April 2024, the Blast Overpressure Safety Act was introduced in the Senate to require the DOD to enact better blast screening, tracking, prevention, and treatment. The DOD initiated 26 blast overpressure studies.

Heather Snyder, PhD, Alzheimer’s Association vice president of Medical and Scientific Relations, said that an important component of that research involves “the need to study the difference between TBI-caused dementia and dementia caused independently” and “the need to study biomarkers to better understand the long-term consequences of TBI.”
 

What Is the Underlying Biology?

Dr. Snyder was the lead author of a white paper produced by the Alzheimer’s Association in 2018 on military-related risk factors for Alzheimer’s disease and related dementias. “There is a lot of work trying to understand the effect of pure blast waves on the brain, as opposed to the actual impact of the injury,” she said.

The white paper speculated that blast exposure may be analogous to subconcussive brain injury in athletes where there are no obvious immediate clinical symptoms or neurological dysfunction but which can cause cumulative injury and functional impairment over time.

“We are also trying to understand the underlying biology around brain changes, such as accumulation of tau and amyloid and other specific markers related to brain changes in Alzheimer’s disease,” said Dr. Snyder, chair of the Peer Reviewed Alzheimer’s Research Program Programmatic Panel for Alzheimer’s Disease/Alzheimer’s Disease and Related Dementias and TBI.
 

Common Biomarker Signatures

A recent study in Neurology comparing 51 veterans with mild TBI (mTBI) with 85 veterans and civilians with no lifetime history of TBI is among the first to explore these biomarker changes in human beings.

“Our findings suggest that chronic neuropathologic processes associated with blast mTBI share properties in common with pathogenic processes that are precursors to Alzheimer’s disease onset,” said coauthor Elaine R. Peskind, MD, professor of psychiatry and behavioral sciences, University of Washington, Seattle.

The largely male participants were a mean age of 34 years and underwent standardized clinical and neuropsychological testing as well as lumbar puncture to collect cerebrospinal fluid (CSF). The mTBI group had experienced at least one war zone blast or combined blast/impact that met criteria for mTBI, but 91% had more than one blast mTBI, and the study took place over 13 years.

The researchers found that the mTBI group “had biomarker signatures in common with the earliest stages of Alzheimer’s disease,” said Dr. Peskind.

For example, at age 50, they had lower mean levels of CSF amyloid beta 42 (Abeta42), the earliest marker of brain parenchymal Abeta deposition, compared with the control group (154 pg/mL and 1864 pg/mL lower, respectively).

High CSF phosphorylated tau181 (p-tau181) and total tau are established biomarkers for Alzheimer’s disease. However, levels of these biomarkers remained “relatively constant with age” in participants with mTBI but were higher in older ages for the non-TBI group.

The mTBI group also showed worse cognitive performance at older ages (P < .08). Poorer verbal memory and verbal fluency performance were associated with lower CSF Abeta42 in older participants (P ≤ .05).

In Alzheimer’s disease, a reduction in CSF Abeta42 may occur up to 20 years before the onset of clinical symptoms, according to Dr. Peskind. “But what we don’t know from this study is what this means, as total tau protein and p-tau181 in the CSF were also low, which isn’t entirely typical in the picture of preclinical Alzheimer’s disease,” she said. However, changes in total tau and p-tau181 lag behind changes in Abeta42.
 

Is Impaired Clearance the Culprit?

Coauthor Jeffrey Iliff, PhD, professor, University of Washington Department of Psychiatry and Behavioral Sciences and University of Washington Department of Neurology, Seattle, elaborated.

“In the setting of Alzheimer’s disease, a signature of the disease is reduced CSF Abeta42, which is thought to reflect that much of the amyloid gets ‘stuck’ in the brain in the form of amyloid plaques,” he said. “There are usually higher levels of phosphorylated tau and total tau, which are thought to reflect the presence of tau tangles and degeneration of neurons in the brain. But in this study, all of those were lowered, which is not exactly an Alzheimer’s disease profile.”

Dr. Iliff, associate director for research, VA Northwest Mental Illness Research, Education, and Clinical Center at VA Puget Sound Health Care System, Seattle, suggested that the culprit may be impairment in the brain’s glymphatic system. “Recently described biological research supports [the concept of] clearance of waste out of the brain during sleep via the glymphatic system, with amyloid and tau being cleared from the brain interstitium during sleep.”

A recent hypothesis is that blast TBI impairs that process. “This is why we see less of those proteins in the CSF. They’re not being cleared, which might contribute downstream to the clumping up of protein in the brain,” he suggested.

The evidence base corroborating that hypothesis is in its infancy; however, new research conducted by Dr. Iliff and his colleagues sheds light on this potential mechanism.

In blast TBI, energy from the explosion and resulting overpressure wave are “transmitted through the brain, which causes tissues of different densities — such as gray and white matter — to accelerate at different rates,” according to Dr. Iliff. This results in the shearing and stretching of brain tissue, leading to a “diffuse pattern of tissue damage.”

It is known that blast TBI has clinical overlap and associations with posttraumatic stress disorder (PTSD), depression, and persistent neurobehavioral symptoms; that veterans with a history of TBI are more than twice as likely to die by suicide than veterans with no TBI history; and that TBI may increase the risk for Alzheimer’s disease and related dementing disorders, as well as CTE.

The missing link may be the glymphatic system — a “brain-wide network of perivascular pathways, along which CSF and interstitial fluid (ISF) exchange, supporting the clearance of interstitial solutes, including amyloid-beta.”

Dr. Iliff and his group previously found that glymphatic function is “markedly and chronically impaired” following impact TBI in mice and that this impairment is associated with the mislocalization of astroglial aquaporin 4 (AQP4), a water channel that lines perivascular spaces and plays a role in healthy glymphatic exchange.

In their new study, the researchers examined both the expression and the localization of AQP4 in the human postmortem frontal cortex and found “distinct laminar differences” in AQP4 expression following blast exposure. They observed similar changes as well as impairment of glymphatic function, which emerged 28 days following blast injury in a mouse model of repetitive blast mTBI.

And in a cohort of veterans with blast mTBI, blast exposure was found to be associated with an increased burden of frontal cortical MRI-visible perivascular spaces — a “putative neuroimaging marker” of glymphatic perivascular dysfunction.

The earlier Neurology study “showed impairment of biomarkers in the CSF, but the new study showed ‘why’ or ‘how’ these biomarkers are impaired, which is via impairment of the glymphatic clearance process,” Dr. Iliff explained.
 

Veterans Especially Vulnerable

Dr. Peskind, co-director of the VA Northwest Mental Illness Research, Education and Clinical Center, VA Puget Sound Health Care System, noted that while the veterans in the earlier study had at least one TBI, the average number was 20, and it was more common to have more than 50 mTBIs than to have a single one.

“These were highly exposed combat vets,” she said. “And that number doesn’t even account for subconcussive exposure to blasts, which now appear to cause detectable brain damage, even in the absence of a diagnosable TBI.”

The Maine shooter, Mr. Card, had not seen combat and was not assessed for TBI during a psychiatric hospitalization, according to The New York Times.

Dr. Peskind added that this type of blast damage is likely specific to individuals in the military. “It isn’t the sound that causes the damage,” she explained. “It’s the blast wave, the pressure wave, and there aren’t a lot of other occupations that have those types of occupational exposures.”

Dr. Snyder added that the majority of blast TBIs have been studied in military personnel, and she is not aware of studies that have looked at blast injuries in other industries, such as demolition or mining, to see if they have the same type of biologic consequences.

Dr. Snyder hopes that the researchers will follow the participants in the Neurology study and continue looking at specific markers related to Alzheimer’s disease brain changes. What the research so far shows “is that, at an earlier age, we’re starting to see those markers changing, suggesting that the underlying biology in people with mild blast TBI is similar to the underlying biology in Alzheimer’s disease as well.”

Michael Alosco, PhD, associate professor and vice chair of research, department of neurology, Boston University Chobanian & Avedisian School of Medicine, called the issue of blast exposure and TBI “a very complex and nuanced topic,” especially because TBI is “considered a risk factor of Alzheimer’s disease” and “different types of TBIs could trigger distinct pathophysiologic processes; however, the long-term impact of repetitive blast TBIs on neurodegenerative disease changes remains unknown.”

He coauthored an editorial on the earlier Neurology study that noted its limitations, such as a small sample size and lack of consideration of lifestyle and health factors but acknowledged that the “findings provide preliminary evidence that repetitive blast exposures might influence beta-amyloid accumulation.”
 

Clinical Implications

For Dr. Peskind, the “inflection point” was seeing lower CSF Abeta42, about 20 years earlier than ages 60 and 70, which is more typical in cognitively normal community volunteers.

But she described herself as “loath to say that veterans or service members have a 20-year acceleration of risk of Alzheimer’s disease,” adding, “I don’t want to scare the heck out of our service members of veterans.” Although “this is what we fear, we’re not ready to say it for sure yet because we need to do more work. Nevertheless, it does increase the index of suspicion.”

The clinical take-home messages are not unique to service members or veterans or people with a history of head injuries or a genetic predisposition to Alzheimer’s disease, she emphasized. “If anyone of any age or occupation comes in with cognitive issues, such as [impaired] memory or executive function, they deserve a workup for dementing disorders.” Frontotemporal dementia, for example, can present earlier than Alzheimer’s disease typically does.

Common comorbidities with TBI are PTSD and obstructive sleep apnea (OSA), which can also cause cognitive issues and are also risk factors for dementia.

Dr. Iliff agreed. “If you see a veteran with a history of PTSD, a history of blast TBI, and a history of OSA or some combination of those three, I recommend having a higher index of suspicion [for potential dementia] than for an average person without any of these, even at a younger age than one would ordinarily expect.”

Of all of these factors, the only truly directly modifiable one is sleep disruption, including that caused by OSA or sleep disorders related to PTSD, he added. “Epidemiologic data suggest a connection particularly between midlife sleep disruption and the risk of dementia and Alzheimer’s disease, and so it’s worth thinking about sleep as a modifiable risk factor even as early as the 40s and 50s, whether the patient is or isn’t a veteran.”

Dr. Peskind recommended asking patients, “Do they snore? Do they thrash about during sleep? Do they have trauma nightmares? This will inform the type of intervention required.”

Dr. Alosco added that there is no known “safe” threshold of exposure to blasts, and that thresholds are “unclear, particularly at the individual level.” In American football, there is a dose-response relationship between years of play and risk for later-life neurological disorder. “The best way to mitigate risk is to limit cumulative exposure,” he said.

The study by Li and colleagues was funded by grant funding from the Department of Veterans Affairs Rehabilitation Research and Development Service and the University of Washington Friends of Alzheimer’s Research. Other sources of funding to individual researchers are listed in the original paper. The study by Braun and colleagues was supported by the National Heart, Lung and Blood Institute; the Department of Veterans Affairs Rehabilitation Research and Development Service; and the National Institute on Aging. The white paper included studies that received funding from numerous sources, including the National Institutes of Health and the DOD. Dr. Iliff serves as the chair of the Scientific Advisory Board for Applied Cognition Inc., from which he receives compensation and in which he holds an equity stake. In the last year, he served as a paid consultant to Gryphon Biosciences. Dr. Peskind has served as a paid consultant to the companies Genentech, Roche, and Alpha Cognition. Dr. Alosco was supported by grant funding from the NIH; he received research support from Rainwater Charitable Foundation Inc., and Life Molecular Imaging Inc.; he has received a single honorarium from the Michael J. Fox Foundation for services unrelated to this editorial; and he received royalties from Oxford University Press Inc. The other authors’ disclosures are listed in the original papers.
 

A version of this article appeared on Medscape.com.

TOPLINE:

Nearly 13% of older adults in the United States were treated for traumatic brain injury (TBI) over an 18-year period, a new study showed.

METHODOLOGY:

• Researchers analyzed data from approximately 9200 Medicare enrollees who were part of the Health and Retirement Study (HRS), aged 65 years and older, from 2000 to 2018.
• The baseline date was the date of the first age eligible HRS core interview in the community in 2000 or later.
• Incident TBI cases came from an updated list of the International Classification of Diseases (ICD), 9th and 10th edition codes, from the Defense and Veterans Brain Injury Center and the Armed Forces Health Surveillance Branch for TBI surveillance.
• Codes corresponded with emergency department, CT, and/or fMRI visits.

TAKEAWAY:

• Almost 13% of older individuals (n = 797) experienced TBI during the study, highlighting its significant prevalence in this population.
• Older adults (mean age at baseline, 75 years) who experienced TBI during the study period were more likely to be women and White individuals as well as individuals having higher levels of education and normal cognition (P < .001), challenging previous assumptions about risk factors.
• The study underscored the need for targeted interventions and research focused on TBI prevention and postdischarge care in older adults.

IN PRACTICE:

“The number of people 65 and older with TBI is shockingly high,” senior author Raquel Gardner, MD, said in a press release. “We need evidence-based guidelines to inform postdischarge care of this very large Medicare population and more research on post-TBI dementia prevention and repeat injury prevention.”

SOURCE:

The study was led by Erica Kornblith, PhD, of the University of California, San Francisco. It was published online in JAMA Network Open.

LIMITATIONS:

The study’s reliance on ICD codes for TBI identification may not capture the full spectrum of TBI severity. Self-reported data on sociodemographic factors may have introduced bias, affecting the accuracy of associations with TBI incidence. In addition, the findings’ generalizability may be limited due to the study’s focus on Medicare enrollees, potentially excluding those from diverse socioeconomic backgrounds.

DISCLOSURES:

The study was funded by the Alzheimer’s Association, the US Department of Veterans Affairs, the National Institute on Aging, and the Department of Defense. Disclosures are noted in the original study.

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 appeared on Medscape.com.

TOPLINE:

Nearly 13% of older adults in the United States were treated for traumatic brain injury (TBI) over an 18-year period, a new study showed.

METHODOLOGY:

• Researchers analyzed data from approximately 9200 Medicare enrollees who were part of the Health and Retirement Study (HRS), aged 65 years and older, from 2000 to 2018.
• The baseline date was the date of the first age eligible HRS core interview in the community in 2000 or later.
• Incident TBI cases came from an updated list of the International Classification of Diseases (ICD), 9th and 10th edition codes, from the Defense and Veterans Brain Injury Center and the Armed Forces Health Surveillance Branch for TBI surveillance.
• Codes corresponded with emergency department, CT, and/or fMRI visits.

TAKEAWAY:

• Almost 13% of older individuals (n = 797) experienced TBI during the study, highlighting its significant prevalence in this population.
• Older adults (mean age at baseline, 75 years) who experienced TBI during the study period were more likely to be women and White individuals as well as individuals having higher levels of education and normal cognition (P < .001), challenging previous assumptions about risk factors.
• The study underscored the need for targeted interventions and research focused on TBI prevention and postdischarge care in older adults.

IN PRACTICE:

“The number of people 65 and older with TBI is shockingly high,” senior author Raquel Gardner, MD, said in a press release. “We need evidence-based guidelines to inform postdischarge care of this very large Medicare population and more research on post-TBI dementia prevention and repeat injury prevention.”

SOURCE:

The study was led by Erica Kornblith, PhD, of the University of California, San Francisco. It was published online in JAMA Network Open.

LIMITATIONS:

The study’s reliance on ICD codes for TBI identification may not capture the full spectrum of TBI severity. Self-reported data on sociodemographic factors may have introduced bias, affecting the accuracy of associations with TBI incidence. In addition, the findings’ generalizability may be limited due to the study’s focus on Medicare enrollees, potentially excluding those from diverse socioeconomic backgrounds.

DISCLOSURES:

The study was funded by the Alzheimer’s Association, the US Department of Veterans Affairs, the National Institute on Aging, and the Department of Defense. Disclosures are noted in the original study.

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 appeared on Medscape.com.

TOPLINE:

Nearly 13% of older adults in the United States were treated for traumatic brain injury (TBI) over an 18-year period, a new study showed.

METHODOLOGY:

• Researchers analyzed data from approximately 9200 Medicare enrollees who were part of the Health and Retirement Study (HRS), aged 65 years and older, from 2000 to 2018.
• The baseline date was the date of the first age eligible HRS core interview in the community in 2000 or later.
• Incident TBI cases came from an updated list of the International Classification of Diseases (ICD), 9th and 10th edition codes, from the Defense and Veterans Brain Injury Center and the Armed Forces Health Surveillance Branch for TBI surveillance.
• Codes corresponded with emergency department, CT, and/or fMRI visits.

TAKEAWAY:

• Almost 13% of older individuals (n = 797) experienced TBI during the study, highlighting its significant prevalence in this population.
• Older adults (mean age at baseline, 75 years) who experienced TBI during the study period were more likely to be women and White individuals as well as individuals having higher levels of education and normal cognition (P < .001), challenging previous assumptions about risk factors.
• The study underscored the need for targeted interventions and research focused on TBI prevention and postdischarge care in older adults.

IN PRACTICE:

“The number of people 65 and older with TBI is shockingly high,” senior author Raquel Gardner, MD, said in a press release. “We need evidence-based guidelines to inform postdischarge care of this very large Medicare population and more research on post-TBI dementia prevention and repeat injury prevention.”

SOURCE:

The study was led by Erica Kornblith, PhD, of the University of California, San Francisco. It was published online in JAMA Network Open.

LIMITATIONS:

The study’s reliance on ICD codes for TBI identification may not capture the full spectrum of TBI severity. Self-reported data on sociodemographic factors may have introduced bias, affecting the accuracy of associations with TBI incidence. In addition, the findings’ generalizability may be limited due to the study’s focus on Medicare enrollees, potentially excluding those from diverse socioeconomic backgrounds.

DISCLOSURES:

The study was funded by the Alzheimer’s Association, the US Department of Veterans Affairs, the National Institute on Aging, and the Department of Defense. Disclosures are noted in the original study.

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 appeared on Medscape.com.

Posttraumatic headache (PTH) is associated with an increase in iron accumulation in certain brain regions , notably those involved in the pain network, early research shows.

Investigators found positive correlations between iron accumulation and headache frequency, number of lifetime mild traumatic brain injuries (mTBIs), and time since last mTBI.

The findings come on the heels of previous research showing patients with iron accumulation in certain brain regions don’t respond as well to treatment, study investigator, Simona Nikolova, PhD, assistant professor of neurology, Mayo Clinic, Phoenix, Arizona, told this news organization.

“This is really important, and doctors need to be aware of it. If you have a patient who is not responding to treatment, then you know what to look at,” she said. 

The findings (Abstract #3379) will be presented on April 15 at the American Academy of Neurology (AAN) 2024 Annual Meeting. 
 

Dose Effect

The study included 60 people with acute PTH due to mTBI. Most were White, and almost half had sustained a concussion due to a fall, with about 30% injured in a vehicle accident and a smaller number injured during a fight.

The mean number of lifetime mTBIs was 2.4, although participants had sustained as many as five or six and as few as one. The mean time from the most recent mTBI was 25 days, and the mean score on the Sport Concussion Assessment Tool (SCAT), which measures postconcussion symptom severity, was 29.

Most in the mTBI group (43) had migraine or probable migraine, and 14 had tension-type headaches. Mean headache frequency was 81%.

Researchers matched these patients with 60 controls without concussion or headache. Because iron accumulation is age-related, they tried to eliminate this covariant by pairing each participant with mTBI with an age- and sex-matched control.

All participants underwent a type of brain MRI known as T2* weighted sequence that can identify brain iron accumulation, a marker of neural injury. 

Investigators found that the PTH group had significantly higher levels of iron accumulation in several areas of the brain, most of which are part of a “pain network” that includes about 63 areas of the brain, Dr. Nikolova said.

The study wasn’t designed to determine how much more iron accumulation mTBI patients had vs controls. 

“We can’t say it was twice as much or three times as much; we can only say it was significant. Measuring concentrations in PTH patients and comparing that with controls is something we haven’t don’t yet,” said Dr. Nikolova.

Areas of the brain with increased iron accumulation, included the periaqueductal gray (PAG), anterior cingulated cortex, and supramarginal gyrus. 

Research suggests patients with migraine who have elevated levels of iron in the PAG have a poorer response to botulinum toxin treatment. An earlier study by the same team showed a poorer response to the calcitonin gene-related peptide inhibitor erenumab in migraine patients with elevated iron in the PAG.

Researchers discovered that those with more lifetime TBIs had higher iron accumulation in the right gyrus rectus and right putamen vs those with fewer injuries and that headache frequency was associated with iron accumulation in the posterior corona radiata, bilateral temporal, right frontal, bilateral supplemental motor area, left fusiform, right hippocampus, sagittal striatum, and left cerebellum.
 

Surprising Result

The investigators also found a link between time since the most recent mTBI and iron accumulation in the bilateral temporal, right hippocampus, posterior and superior corona radiata, bilateral thalamus, right precuneus and cuneus, right lingual, and right cerebellum. 

“The more time that passed since the concussion occurred, the more likely that people had higher iron levels,” said Dr. Nikolova.

It’s perhaps to be expected that the length of time since injury is linked to iron accumulation in the brain as iron accumulates over time. But even those whose injury was relatively recent had higher amounts of iron, which Dr. Nikolova said was “surprising.”

“We thought iron accumulates over time so we were thinking maybe we should be doing a longitudinal study to see what happens, but we see definite iron accumulation due to injury shortly after the injury,” she said.

There was no association between iron accumulation and symptom severity as measured by SCAT scores.
 

Questions Remain

It’s unclear why iron accumulates after an injury or what the ramifications are of this accumulation, Dr. Nikolova noted. 

The imaging used in the study doesn’t distinguish between “bound” iron found after a hemorrhage and “free” iron in the brain. The free iron type has been shown to be increased after TBI and is “the stuff you should be afraid of,” Dr. Nikolova said.

Iron’s role in the metabolic process is important, but must be closely regulated, she said. Even a small accumulation can lead to oxidative stress.

Researchers are investigating whether the findings would be similar in mTBI but no headache and want to increase the number of study participants. A larger, more diverse sample would allow them to probe other questions, including whether iron accumulation is different in men and women. More data could also eventually lead to iron accumulation becoming a biomarker for concussion and PTH, Dr. Nikolova said.

“If you know a certain person has that biomarker, you might be able to administer a drug or some therapeutic procedure to prevent that iron from continuing to accumulate in the brain.”

Chelation drugs and other therapies may clear iron from the body but not necessarily from the brain. 

Commenting on the study for this news organization, Frank Conidi, MD, director, Florida Center for Headache and Sports Neurology, Port St. Lucie , said that the study supports the hypothesis that concussion “is not a benign process for the brain, and the cumulative effect of repetitive head injury can result in permanent brain injury.”

He said that he found the accumulation of iron in cortical structures particularly interesting. This, he said, differs from most current research that suggests head trauma mainly results in damage to white matter tracts.

He prefers the term “concussion” over “mild traumatic brain injury” which was used in the study. “Recent guidelines, including some that I’ve been involved with, have defined mild traumatic brain injury as a more permanent process,” he said.

The study was supported by the US Department of Defense and National Institutes of Health. No relevant conflicts of interest were disclosed. 

A version of this article appeared on Medscape.com.

Posttraumatic headache (PTH) is associated with an increase in iron accumulation in certain brain regions , notably those involved in the pain network, early research shows.

Investigators found positive correlations between iron accumulation and headache frequency, number of lifetime mild traumatic brain injuries (mTBIs), and time since last mTBI.

The findings come on the heels of previous research showing patients with iron accumulation in certain brain regions don’t respond as well to treatment, study investigator, Simona Nikolova, PhD, assistant professor of neurology, Mayo Clinic, Phoenix, Arizona, told this news organization.

“This is really important, and doctors need to be aware of it. If you have a patient who is not responding to treatment, then you know what to look at,” she said. 

The findings (Abstract #3379) will be presented on April 15 at the American Academy of Neurology (AAN) 2024 Annual Meeting. 
 

Dose Effect

The study included 60 people with acute PTH due to mTBI. Most were White, and almost half had sustained a concussion due to a fall, with about 30% injured in a vehicle accident and a smaller number injured during a fight.

The mean number of lifetime mTBIs was 2.4, although participants had sustained as many as five or six and as few as one. The mean time from the most recent mTBI was 25 days, and the mean score on the Sport Concussion Assessment Tool (SCAT), which measures postconcussion symptom severity, was 29.

Most in the mTBI group (43) had migraine or probable migraine, and 14 had tension-type headaches. Mean headache frequency was 81%.

Researchers matched these patients with 60 controls without concussion or headache. Because iron accumulation is age-related, they tried to eliminate this covariant by pairing each participant with mTBI with an age- and sex-matched control.

All participants underwent a type of brain MRI known as T2* weighted sequence that can identify brain iron accumulation, a marker of neural injury. 

Investigators found that the PTH group had significantly higher levels of iron accumulation in several areas of the brain, most of which are part of a “pain network” that includes about 63 areas of the brain, Dr. Nikolova said.

The study wasn’t designed to determine how much more iron accumulation mTBI patients had vs controls. 

“We can’t say it was twice as much or three times as much; we can only say it was significant. Measuring concentrations in PTH patients and comparing that with controls is something we haven’t don’t yet,” said Dr. Nikolova.

Areas of the brain with increased iron accumulation, included the periaqueductal gray (PAG), anterior cingulated cortex, and supramarginal gyrus. 

Research suggests patients with migraine who have elevated levels of iron in the PAG have a poorer response to botulinum toxin treatment. An earlier study by the same team showed a poorer response to the calcitonin gene-related peptide inhibitor erenumab in migraine patients with elevated iron in the PAG.

Researchers discovered that those with more lifetime TBIs had higher iron accumulation in the right gyrus rectus and right putamen vs those with fewer injuries and that headache frequency was associated with iron accumulation in the posterior corona radiata, bilateral temporal, right frontal, bilateral supplemental motor area, left fusiform, right hippocampus, sagittal striatum, and left cerebellum.
 

Surprising Result

The investigators also found a link between time since the most recent mTBI and iron accumulation in the bilateral temporal, right hippocampus, posterior and superior corona radiata, bilateral thalamus, right precuneus and cuneus, right lingual, and right cerebellum. 

“The more time that passed since the concussion occurred, the more likely that people had higher iron levels,” said Dr. Nikolova.

It’s perhaps to be expected that the length of time since injury is linked to iron accumulation in the brain as iron accumulates over time. But even those whose injury was relatively recent had higher amounts of iron, which Dr. Nikolova said was “surprising.”

“We thought iron accumulates over time so we were thinking maybe we should be doing a longitudinal study to see what happens, but we see definite iron accumulation due to injury shortly after the injury,” she said.

There was no association between iron accumulation and symptom severity as measured by SCAT scores.
 

Questions Remain

It’s unclear why iron accumulates after an injury or what the ramifications are of this accumulation, Dr. Nikolova noted. 

The imaging used in the study doesn’t distinguish between “bound” iron found after a hemorrhage and “free” iron in the brain. The free iron type has been shown to be increased after TBI and is “the stuff you should be afraid of,” Dr. Nikolova said.

Iron’s role in the metabolic process is important, but must be closely regulated, she said. Even a small accumulation can lead to oxidative stress.

Researchers are investigating whether the findings would be similar in mTBI but no headache and want to increase the number of study participants. A larger, more diverse sample would allow them to probe other questions, including whether iron accumulation is different in men and women. More data could also eventually lead to iron accumulation becoming a biomarker for concussion and PTH, Dr. Nikolova said.

“If you know a certain person has that biomarker, you might be able to administer a drug or some therapeutic procedure to prevent that iron from continuing to accumulate in the brain.”

Chelation drugs and other therapies may clear iron from the body but not necessarily from the brain. 

Commenting on the study for this news organization, Frank Conidi, MD, director, Florida Center for Headache and Sports Neurology, Port St. Lucie , said that the study supports the hypothesis that concussion “is not a benign process for the brain, and the cumulative effect of repetitive head injury can result in permanent brain injury.”

He said that he found the accumulation of iron in cortical structures particularly interesting. This, he said, differs from most current research that suggests head trauma mainly results in damage to white matter tracts.

He prefers the term “concussion” over “mild traumatic brain injury” which was used in the study. “Recent guidelines, including some that I’ve been involved with, have defined mild traumatic brain injury as a more permanent process,” he said.

The study was supported by the US Department of Defense and National Institutes of Health. No relevant conflicts of interest were disclosed. 

A version of this article appeared on Medscape.com.

Posttraumatic headache (PTH) is associated with an increase in iron accumulation in certain brain regions , notably those involved in the pain network, early research shows.

Investigators found positive correlations between iron accumulation and headache frequency, number of lifetime mild traumatic brain injuries (mTBIs), and time since last mTBI.

The findings come on the heels of previous research showing patients with iron accumulation in certain brain regions don’t respond as well to treatment, study investigator, Simona Nikolova, PhD, assistant professor of neurology, Mayo Clinic, Phoenix, Arizona, told this news organization.

“This is really important, and doctors need to be aware of it. If you have a patient who is not responding to treatment, then you know what to look at,” she said. 

The findings (Abstract #3379) will be presented on April 15 at the American Academy of Neurology (AAN) 2024 Annual Meeting. 
 

Dose Effect

The study included 60 people with acute PTH due to mTBI. Most were White, and almost half had sustained a concussion due to a fall, with about 30% injured in a vehicle accident and a smaller number injured during a fight.

The mean number of lifetime mTBIs was 2.4, although participants had sustained as many as five or six and as few as one. The mean time from the most recent mTBI was 25 days, and the mean score on the Sport Concussion Assessment Tool (SCAT), which measures postconcussion symptom severity, was 29.

Most in the mTBI group (43) had migraine or probable migraine, and 14 had tension-type headaches. Mean headache frequency was 81%.

Researchers matched these patients with 60 controls without concussion or headache. Because iron accumulation is age-related, they tried to eliminate this covariant by pairing each participant with mTBI with an age- and sex-matched control.

All participants underwent a type of brain MRI known as T2* weighted sequence that can identify brain iron accumulation, a marker of neural injury. 

Investigators found that the PTH group had significantly higher levels of iron accumulation in several areas of the brain, most of which are part of a “pain network” that includes about 63 areas of the brain, Dr. Nikolova said.

The study wasn’t designed to determine how much more iron accumulation mTBI patients had vs controls. 

“We can’t say it was twice as much or three times as much; we can only say it was significant. Measuring concentrations in PTH patients and comparing that with controls is something we haven’t don’t yet,” said Dr. Nikolova.

Areas of the brain with increased iron accumulation, included the periaqueductal gray (PAG), anterior cingulated cortex, and supramarginal gyrus. 

Research suggests patients with migraine who have elevated levels of iron in the PAG have a poorer response to botulinum toxin treatment. An earlier study by the same team showed a poorer response to the calcitonin gene-related peptide inhibitor erenumab in migraine patients with elevated iron in the PAG.

Researchers discovered that those with more lifetime TBIs had higher iron accumulation in the right gyrus rectus and right putamen vs those with fewer injuries and that headache frequency was associated with iron accumulation in the posterior corona radiata, bilateral temporal, right frontal, bilateral supplemental motor area, left fusiform, right hippocampus, sagittal striatum, and left cerebellum.
 

Surprising Result

The investigators also found a link between time since the most recent mTBI and iron accumulation in the bilateral temporal, right hippocampus, posterior and superior corona radiata, bilateral thalamus, right precuneus and cuneus, right lingual, and right cerebellum. 

“The more time that passed since the concussion occurred, the more likely that people had higher iron levels,” said Dr. Nikolova.

It’s perhaps to be expected that the length of time since injury is linked to iron accumulation in the brain as iron accumulates over time. But even those whose injury was relatively recent had higher amounts of iron, which Dr. Nikolova said was “surprising.”

“We thought iron accumulates over time so we were thinking maybe we should be doing a longitudinal study to see what happens, but we see definite iron accumulation due to injury shortly after the injury,” she said.

There was no association between iron accumulation and symptom severity as measured by SCAT scores.
 

Questions Remain

It’s unclear why iron accumulates after an injury or what the ramifications are of this accumulation, Dr. Nikolova noted. 

The imaging used in the study doesn’t distinguish between “bound” iron found after a hemorrhage and “free” iron in the brain. The free iron type has been shown to be increased after TBI and is “the stuff you should be afraid of,” Dr. Nikolova said.

Iron’s role in the metabolic process is important, but must be closely regulated, she said. Even a small accumulation can lead to oxidative stress.

Researchers are investigating whether the findings would be similar in mTBI but no headache and want to increase the number of study participants. A larger, more diverse sample would allow them to probe other questions, including whether iron accumulation is different in men and women. More data could also eventually lead to iron accumulation becoming a biomarker for concussion and PTH, Dr. Nikolova said.

“If you know a certain person has that biomarker, you might be able to administer a drug or some therapeutic procedure to prevent that iron from continuing to accumulate in the brain.”

Chelation drugs and other therapies may clear iron from the body but not necessarily from the brain. 

Commenting on the study for this news organization, Frank Conidi, MD, director, Florida Center for Headache and Sports Neurology, Port St. Lucie , said that the study supports the hypothesis that concussion “is not a benign process for the brain, and the cumulative effect of repetitive head injury can result in permanent brain injury.”

He said that he found the accumulation of iron in cortical structures particularly interesting. This, he said, differs from most current research that suggests head trauma mainly results in damage to white matter tracts.

He prefers the term “concussion” over “mild traumatic brain injury” which was used in the study. “Recent guidelines, including some that I’ve been involved with, have defined mild traumatic brain injury as a more permanent process,” he said.

The study was supported by the US Department of Defense and National Institutes of Health. No relevant conflicts of interest were disclosed. 

A version of this article appeared on Medscape.com.

Moderate, severe, and penetrating traumatic brain injury (TBI) is associated with an elevated risk of developing brain cancer, new research suggested. However, mild TBI appears to confer no increased risk.

In a large cohort of post-9/11 US veterans, those who suffered moderate/severe TBI had a nearly twofold increased risk for a subsequent brain cancer diagnosis, while those with penetrating TBI had a greater than threefold increased risk.

“While the absolute number of brain cancer diagnoses was small, these diagnoses are associated with profoundly poor outcomes. Further research of this rare but devastating condition is needed to better identify those at risk and develop screening protocols,” wrote investigators led by Ian Stewart, MD, with the Uniformed Services University of Health Sciences, Bethesda, Maryland.

The study was published online on February 15 in JAMA Network Open.
 

Common War Wound

TBI is one of the most common battlefield wounds among veterans of the Iraq and Afghanistan wars. But evidence to date on the potential association of TBI with the subsequent risk for brain cancer is conflicting, the authors noted.

To investigate further, they reviewed the records of nearly 2 million mostly male US veterans of the Iraq and Afghanistan wars. A total of 449,880 people experienced TBI, which was mild in 385,848 cases, moderate/severe in 46,859 cases, and penetrating in 17,173 cases.

During a median follow-up of 7.2 years, brain cancer occurred in 318 veterans without TBI (0.02%), 80 with mild TBI (0.02%), 17 with moderate/severe TBI (0.04%), and 10 or fewer with penetrating TBI (0.06% or less).

There was a stepwise increase in brain cancer incidence with worse TBI severity. Crude incidence rates per 100,000 person-years were 3.06 for no TBI, 2.85 for mild TBI, 4.88 for moderate/severe TBI, and 10.34 for penetrating TBI.

In the fully adjusted model, moderate/severe TBI showed a near-doubling of brain cancer risk vs no TBI (adjusted hazard ratio [aHR], 1.90; 95% CI, 1.16-3.12), while penetrating TBI was associated with a greater than tripling of risk (aHR, 3.33; 95% CI, 1.71-6.49). There was no significantly increased risk after mild TBI.

There are plausible biological mechanisms linking TBI to brain cancer, the authors noted, including alterations in metabolism, inflammation, astrocyte proliferation, and stem cell migration and differentiation.

They caution that with few female veterans and a predominantly young cohort, the findings may not extend to the general population.
 

Meaningful New Data 

In an accompanying editorial, Elie Massaad, MD, MSc, and Ali Kiapour, PhD, MMSc, Massachusetts General Hospital, Boston, noted that federal data show glioblastoma, the most aggressive malignant brain tumor, is the third leading cause of cancer-related death among active duty personnel.

“Post-9/11 veterans deployed to Iraq, Afghanistan, and elsewhere face a 26% higher glioblastoma rate vs the general public, with an average age of onset decades earlier than in broader populations,” they wrote.

Overall, they noted this new research provides “meaningful data clarifying associations between combat-related TBI severity and subsequent brain cancer risk among post-9/11 veterans.

“Elucidating potential connections between battlefield trauma and longer-term health outcomes is imperative to inform prevention and care approaches for those who have served,” they added.

This study was supported by the Assistant Secretary of Defense for Health Affairs endorsed by the Department of Defense through the Psychological Health/Traumatic Brain Injury Research Program Long-Term Impact of Military Relevant Brain Injury Consortium. The authors and editorialists had declared no relevant conflicts of interest.
 

A version of this article appeared on Medscape.com.

Moderate, severe, and penetrating traumatic brain injury (TBI) is associated with an elevated risk of developing brain cancer, new research suggested. However, mild TBI appears to confer no increased risk.

In a large cohort of post-9/11 US veterans, those who suffered moderate/severe TBI had a nearly twofold increased risk for a subsequent brain cancer diagnosis, while those with penetrating TBI had a greater than threefold increased risk.

“While the absolute number of brain cancer diagnoses was small, these diagnoses are associated with profoundly poor outcomes. Further research of this rare but devastating condition is needed to better identify those at risk and develop screening protocols,” wrote investigators led by Ian Stewart, MD, with the Uniformed Services University of Health Sciences, Bethesda, Maryland.

The study was published online on February 15 in JAMA Network Open.
 

Common War Wound

TBI is one of the most common battlefield wounds among veterans of the Iraq and Afghanistan wars. But evidence to date on the potential association of TBI with the subsequent risk for brain cancer is conflicting, the authors noted.

To investigate further, they reviewed the records of nearly 2 million mostly male US veterans of the Iraq and Afghanistan wars. A total of 449,880 people experienced TBI, which was mild in 385,848 cases, moderate/severe in 46,859 cases, and penetrating in 17,173 cases.

During a median follow-up of 7.2 years, brain cancer occurred in 318 veterans without TBI (0.02%), 80 with mild TBI (0.02%), 17 with moderate/severe TBI (0.04%), and 10 or fewer with penetrating TBI (0.06% or less).

There was a stepwise increase in brain cancer incidence with worse TBI severity. Crude incidence rates per 100,000 person-years were 3.06 for no TBI, 2.85 for mild TBI, 4.88 for moderate/severe TBI, and 10.34 for penetrating TBI.

In the fully adjusted model, moderate/severe TBI showed a near-doubling of brain cancer risk vs no TBI (adjusted hazard ratio [aHR], 1.90; 95% CI, 1.16-3.12), while penetrating TBI was associated with a greater than tripling of risk (aHR, 3.33; 95% CI, 1.71-6.49). There was no significantly increased risk after mild TBI.

There are plausible biological mechanisms linking TBI to brain cancer, the authors noted, including alterations in metabolism, inflammation, astrocyte proliferation, and stem cell migration and differentiation.

They caution that with few female veterans and a predominantly young cohort, the findings may not extend to the general population.
 

Meaningful New Data 

In an accompanying editorial, Elie Massaad, MD, MSc, and Ali Kiapour, PhD, MMSc, Massachusetts General Hospital, Boston, noted that federal data show glioblastoma, the most aggressive malignant brain tumor, is the third leading cause of cancer-related death among active duty personnel.

“Post-9/11 veterans deployed to Iraq, Afghanistan, and elsewhere face a 26% higher glioblastoma rate vs the general public, with an average age of onset decades earlier than in broader populations,” they wrote.

Overall, they noted this new research provides “meaningful data clarifying associations between combat-related TBI severity and subsequent brain cancer risk among post-9/11 veterans.

“Elucidating potential connections between battlefield trauma and longer-term health outcomes is imperative to inform prevention and care approaches for those who have served,” they added.

This study was supported by the Assistant Secretary of Defense for Health Affairs endorsed by the Department of Defense through the Psychological Health/Traumatic Brain Injury Research Program Long-Term Impact of Military Relevant Brain Injury Consortium. The authors and editorialists had declared no relevant conflicts of interest.
 

A version of this article appeared on Medscape.com.

Moderate, severe, and penetrating traumatic brain injury (TBI) is associated with an elevated risk of developing brain cancer, new research suggested. However, mild TBI appears to confer no increased risk.

In a large cohort of post-9/11 US veterans, those who suffered moderate/severe TBI had a nearly twofold increased risk for a subsequent brain cancer diagnosis, while those with penetrating TBI had a greater than threefold increased risk.

“While the absolute number of brain cancer diagnoses was small, these diagnoses are associated with profoundly poor outcomes. Further research of this rare but devastating condition is needed to better identify those at risk and develop screening protocols,” wrote investigators led by Ian Stewart, MD, with the Uniformed Services University of Health Sciences, Bethesda, Maryland.

The study was published online on February 15 in JAMA Network Open.
 

Common War Wound

TBI is one of the most common battlefield wounds among veterans of the Iraq and Afghanistan wars. But evidence to date on the potential association of TBI with the subsequent risk for brain cancer is conflicting, the authors noted.

To investigate further, they reviewed the records of nearly 2 million mostly male US veterans of the Iraq and Afghanistan wars. A total of 449,880 people experienced TBI, which was mild in 385,848 cases, moderate/severe in 46,859 cases, and penetrating in 17,173 cases.

During a median follow-up of 7.2 years, brain cancer occurred in 318 veterans without TBI (0.02%), 80 with mild TBI (0.02%), 17 with moderate/severe TBI (0.04%), and 10 or fewer with penetrating TBI (0.06% or less).

There was a stepwise increase in brain cancer incidence with worse TBI severity. Crude incidence rates per 100,000 person-years were 3.06 for no TBI, 2.85 for mild TBI, 4.88 for moderate/severe TBI, and 10.34 for penetrating TBI.

In the fully adjusted model, moderate/severe TBI showed a near-doubling of brain cancer risk vs no TBI (adjusted hazard ratio [aHR], 1.90; 95% CI, 1.16-3.12), while penetrating TBI was associated with a greater than tripling of risk (aHR, 3.33; 95% CI, 1.71-6.49). There was no significantly increased risk after mild TBI.

There are plausible biological mechanisms linking TBI to brain cancer, the authors noted, including alterations in metabolism, inflammation, astrocyte proliferation, and stem cell migration and differentiation.

They caution that with few female veterans and a predominantly young cohort, the findings may not extend to the general population.
 

Meaningful New Data 

In an accompanying editorial, Elie Massaad, MD, MSc, and Ali Kiapour, PhD, MMSc, Massachusetts General Hospital, Boston, noted that federal data show glioblastoma, the most aggressive malignant brain tumor, is the third leading cause of cancer-related death among active duty personnel.

“Post-9/11 veterans deployed to Iraq, Afghanistan, and elsewhere face a 26% higher glioblastoma rate vs the general public, with an average age of onset decades earlier than in broader populations,” they wrote.

Overall, they noted this new research provides “meaningful data clarifying associations between combat-related TBI severity and subsequent brain cancer risk among post-9/11 veterans.

“Elucidating potential connections between battlefield trauma and longer-term health outcomes is imperative to inform prevention and care approaches for those who have served,” they added.

This study was supported by the Assistant Secretary of Defense for Health Affairs endorsed by the Department of Defense through the Psychological Health/Traumatic Brain Injury Research Program Long-Term Impact of Military Relevant Brain Injury Consortium. The authors and editorialists had declared no relevant conflicts of interest.
 

A version of this article appeared on Medscape.com.

Brain fog is one of the most common, persistent complaints in patients with long COVID. It affects as many as 46% of patients who also deal with other cognitive concerns like memory loss and difficulty concentrating. 

Now, researchers believe they know why. A new study has found that these symptoms may be the result of a viral-borne brain injury that may cause cognitive and mental health issues that persist for years.

Researchers found that 351 patients hospitalized with severe COVID-19 had evidence of a long-term brain injury a year after contracting the SARS-CoV-2 virus. The findings were based on a series of cognitive tests, self-reported symptoms, brain scans, and biomarkers.
 

Brain Deficits Equal to 20 Years of Brain Aging

As part of the preprint study, participants took a cognition test with their scores age-matched to those who had not suffered a serious bout of COVID-19. Then a blood sample was taken to look for specific biomarkers, showing that elevated levels of certain biomarkers were consistent with a brain injury. Using brain scans, researchers also found that certain regions of the brain associated with attention were reduced in volume.

Patients who participated in the study were “less accurate and slower” in their cognition, and suffered from at least one mental health condition, such as depression, anxiety, or posttraumatic stress disorder, according to researchers.

The brain deficits found in COVID-19 patients were equivalent to 20 years of brain aging and provided proof of what doctors have feared: that this virus can damage the brain and result in ongoing mental health issues.

“We found global deficits across cognition,” said lead study author Benedict Michael, PhD, director of the Infection Neuroscience Lab at the University of Liverpool in Liverpool, England. “The cognitive and memory problems that patients complained of were associated with neuroanatomical changes to the brain.”
 

Proof That Symptoms Aren’t ‘Figment’ of Patients’ Imaginations

Cognitive deficits were common among all patients, but the researchers said they don’t yet know whether the brain damage causes permanent cognitive decline. But the research provides patients who have been overlooked by some clinicians with proof that their conditions aren’t a figment of their imaginations, said Karla L. Thompson, PhD, lead neuropsychologist at the University of North Carolina School of Medicine’s COVID Recovery Clinic. 

“Even though we’re several years into this pandemic, there are still a lot of providers who don’t believe that their patients are experiencing these residual symptoms,” said Dr. Thompson, “That’s why the use of biomarkers is important, because it provides an objective indication that the brain has been compromised in some way.”

Some patients with long COVID have said that getting their doctors to believe they have a physical ailment has been a persistent problem throughout the pandemic and especially as it relates to the sometimes-vague collection of symptoms associated with brain fog. One study found that as many as 79% of study respondents reported negative interactions with their healthcare providers when they sought treatment for their long-COVID symptoms.
 

How Do COVID-Related Brain Injuries Happen?

Researchers are unsure what’s causing these brain injuries, though they have identified some clues. Previous research has suggested that such injuries might be the result of a lack of oxygen to the brain, especially in patients who were hospitalized, like those in this study, and were put on ventilators.

Brain scans have previously shown atrophy to the brain›s gray matter in COVID-19 patients, likely caused by inflammation from a heightened immune response rather than the virus itself. This inflammatory response seems to affect the central nervous system. As part of the new study, researchers found some neuroprotective effects of using steroids during hospitalization to reduce brain inflammation.

The results suggest that clinicians should overcome their skepticism and consider the possibility that their patients have suffered a brain injury and should be treated appropriately, said James C. Jackson, PsyD, a neuropsychiatrist at Vanderbilt University School of Medicine. “The old saying is that if it walks like a duck and talks like a duck, it’s a duck,” said Dr. Jackson. 

He contends that treatments used for patients who have brain injuries have also been shown to be effective in treating long COVID–related brain fog symptoms. These may include speech, cognitive, and occupational therapy as well as meeting with a neuropsychiatrist for the treatment of related mental health concerns.
 

A New Path Forward

Treating long-COVID brain fog like a brain injury can help patients get back to some semblance of normalcy, researchers said. “What we’re seeing in terms of brain injury biomarkers and differences in brain scans correlates to real-life problems that these patients are dealing with on a daily basis,” said Dr. Jackson. These include problems at work and in life with multitasking, remembering details, meeting deadlines, synthesizing large amounts of information, and maintaining focus on the task at hand, he said.

There’s also a fear that even with treatment, the aging of the brain caused by the virus might have long-term repercussions and that this enduring injury may cause the early onset of dementia and Alzheimer’s disease in those who were already vulnerable to it. One study, from the National Institute of Neurological Disorders and Stroke (NINDS), found that in those infected with COVID-19 who already had dementia, the virus “rapidly accelerated structural and functional brain deterioration.” 

“We already know the role that neuroinflammation plays in the brains of patients with Alzheimer’s disease,” said Dr. Thompson. “If long COVID is involved in prolonged inflammation of the brain, it goes a long way in explaining the mechanism underlying [the study’s reported] brain aging.”
 

Still More to Learn

In some ways, this study raises nearly as many questions as it does answers. While it provides concrete evidence around the damage the virus is doing to the brains of patients who contracted severe COVID-19, researchers don’t know about the impact on those who had less serious cases of the virus. 

For Ziyad Al-Aly, MD, chief of research and development at the Veterans Affairs St. Louis Health Care System, the concern is that some long-COVID patients may be suffering from cognitive deficits that are more subtle but still impacting their daily lives, and that they’re not getting the help they need. 

What’s more, said Dr. Al-Aly, it’s unclear whether the impacts of the brain damage are permanent or how to stop them from worsening. Researchers and clinicians need a better understanding of the mechanism that allows this virus to enter the brain and do structural damage. If it’s inflammation, will anti-inflammatory or antiviral medications work at preventing it? Will steroids help to offset the damage? “It’s critical we find some answers,” he said.

“SARS-CoV-2 isn’t going anywhere. It will continue to infect the population, so if this is indeed a virus that damages the brain in the long term or permanently, we need to figure out what can be done to stop it,” said Dr. Al-Aly.

A version of this article appeared on Medscape.com.

Brain fog is one of the most common, persistent complaints in patients with long COVID. It affects as many as 46% of patients who also deal with other cognitive concerns like memory loss and difficulty concentrating. 

Now, researchers believe they know why. A new study has found that these symptoms may be the result of a viral-borne brain injury that may cause cognitive and mental health issues that persist for years.

Researchers found that 351 patients hospitalized with severe COVID-19 had evidence of a long-term brain injury a year after contracting the SARS-CoV-2 virus. The findings were based on a series of cognitive tests, self-reported symptoms, brain scans, and biomarkers.
 

Brain Deficits Equal to 20 Years of Brain Aging

As part of the preprint study, participants took a cognition test with their scores age-matched to those who had not suffered a serious bout of COVID-19. Then a blood sample was taken to look for specific biomarkers, showing that elevated levels of certain biomarkers were consistent with a brain injury. Using brain scans, researchers also found that certain regions of the brain associated with attention were reduced in volume.

Patients who participated in the study were “less accurate and slower” in their cognition, and suffered from at least one mental health condition, such as depression, anxiety, or posttraumatic stress disorder, according to researchers.

The brain deficits found in COVID-19 patients were equivalent to 20 years of brain aging and provided proof of what doctors have feared: that this virus can damage the brain and result in ongoing mental health issues.

“We found global deficits across cognition,” said lead study author Benedict Michael, PhD, director of the Infection Neuroscience Lab at the University of Liverpool in Liverpool, England. “The cognitive and memory problems that patients complained of were associated with neuroanatomical changes to the brain.”
 

Proof That Symptoms Aren’t ‘Figment’ of Patients’ Imaginations

Cognitive deficits were common among all patients, but the researchers said they don’t yet know whether the brain damage causes permanent cognitive decline. But the research provides patients who have been overlooked by some clinicians with proof that their conditions aren’t a figment of their imaginations, said Karla L. Thompson, PhD, lead neuropsychologist at the University of North Carolina School of Medicine’s COVID Recovery Clinic. 

“Even though we’re several years into this pandemic, there are still a lot of providers who don’t believe that their patients are experiencing these residual symptoms,” said Dr. Thompson, “That’s why the use of biomarkers is important, because it provides an objective indication that the brain has been compromised in some way.”

Some patients with long COVID have said that getting their doctors to believe they have a physical ailment has been a persistent problem throughout the pandemic and especially as it relates to the sometimes-vague collection of symptoms associated with brain fog. One study found that as many as 79% of study respondents reported negative interactions with their healthcare providers when they sought treatment for their long-COVID symptoms.
 

How Do COVID-Related Brain Injuries Happen?

Researchers are unsure what’s causing these brain injuries, though they have identified some clues. Previous research has suggested that such injuries might be the result of a lack of oxygen to the brain, especially in patients who were hospitalized, like those in this study, and were put on ventilators.

Brain scans have previously shown atrophy to the brain›s gray matter in COVID-19 patients, likely caused by inflammation from a heightened immune response rather than the virus itself. This inflammatory response seems to affect the central nervous system. As part of the new study, researchers found some neuroprotective effects of using steroids during hospitalization to reduce brain inflammation.

The results suggest that clinicians should overcome their skepticism and consider the possibility that their patients have suffered a brain injury and should be treated appropriately, said James C. Jackson, PsyD, a neuropsychiatrist at Vanderbilt University School of Medicine. “The old saying is that if it walks like a duck and talks like a duck, it’s a duck,” said Dr. Jackson. 

He contends that treatments used for patients who have brain injuries have also been shown to be effective in treating long COVID–related brain fog symptoms. These may include speech, cognitive, and occupational therapy as well as meeting with a neuropsychiatrist for the treatment of related mental health concerns.
 

A New Path Forward

Treating long-COVID brain fog like a brain injury can help patients get back to some semblance of normalcy, researchers said. “What we’re seeing in terms of brain injury biomarkers and differences in brain scans correlates to real-life problems that these patients are dealing with on a daily basis,” said Dr. Jackson. These include problems at work and in life with multitasking, remembering details, meeting deadlines, synthesizing large amounts of information, and maintaining focus on the task at hand, he said.

There’s also a fear that even with treatment, the aging of the brain caused by the virus might have long-term repercussions and that this enduring injury may cause the early onset of dementia and Alzheimer’s disease in those who were already vulnerable to it. One study, from the National Institute of Neurological Disorders and Stroke (NINDS), found that in those infected with COVID-19 who already had dementia, the virus “rapidly accelerated structural and functional brain deterioration.” 

“We already know the role that neuroinflammation plays in the brains of patients with Alzheimer’s disease,” said Dr. Thompson. “If long COVID is involved in prolonged inflammation of the brain, it goes a long way in explaining the mechanism underlying [the study’s reported] brain aging.”
 

Still More to Learn

In some ways, this study raises nearly as many questions as it does answers. While it provides concrete evidence around the damage the virus is doing to the brains of patients who contracted severe COVID-19, researchers don’t know about the impact on those who had less serious cases of the virus. 

For Ziyad Al-Aly, MD, chief of research and development at the Veterans Affairs St. Louis Health Care System, the concern is that some long-COVID patients may be suffering from cognitive deficits that are more subtle but still impacting their daily lives, and that they’re not getting the help they need. 

What’s more, said Dr. Al-Aly, it’s unclear whether the impacts of the brain damage are permanent or how to stop them from worsening. Researchers and clinicians need a better understanding of the mechanism that allows this virus to enter the brain and do structural damage. If it’s inflammation, will anti-inflammatory or antiviral medications work at preventing it? Will steroids help to offset the damage? “It’s critical we find some answers,” he said.

“SARS-CoV-2 isn’t going anywhere. It will continue to infect the population, so if this is indeed a virus that damages the brain in the long term or permanently, we need to figure out what can be done to stop it,” said Dr. Al-Aly.

A version of this article appeared on Medscape.com.

Brain fog is one of the most common, persistent complaints in patients with long COVID. It affects as many as 46% of patients who also deal with other cognitive concerns like memory loss and difficulty concentrating. 

Now, researchers believe they know why. A new study has found that these symptoms may be the result of a viral-borne brain injury that may cause cognitive and mental health issues that persist for years.

Researchers found that 351 patients hospitalized with severe COVID-19 had evidence of a long-term brain injury a year after contracting the SARS-CoV-2 virus. The findings were based on a series of cognitive tests, self-reported symptoms, brain scans, and biomarkers.
 

Brain Deficits Equal to 20 Years of Brain Aging

As part of the preprint study, participants took a cognition test with their scores age-matched to those who had not suffered a serious bout of COVID-19. Then a blood sample was taken to look for specific biomarkers, showing that elevated levels of certain biomarkers were consistent with a brain injury. Using brain scans, researchers also found that certain regions of the brain associated with attention were reduced in volume.

Patients who participated in the study were “less accurate and slower” in their cognition, and suffered from at least one mental health condition, such as depression, anxiety, or posttraumatic stress disorder, according to researchers.

The brain deficits found in COVID-19 patients were equivalent to 20 years of brain aging and provided proof of what doctors have feared: that this virus can damage the brain and result in ongoing mental health issues.

“We found global deficits across cognition,” said lead study author Benedict Michael, PhD, director of the Infection Neuroscience Lab at the University of Liverpool in Liverpool, England. “The cognitive and memory problems that patients complained of were associated with neuroanatomical changes to the brain.”
 

Proof That Symptoms Aren’t ‘Figment’ of Patients’ Imaginations

Cognitive deficits were common among all patients, but the researchers said they don’t yet know whether the brain damage causes permanent cognitive decline. But the research provides patients who have been overlooked by some clinicians with proof that their conditions aren’t a figment of their imaginations, said Karla L. Thompson, PhD, lead neuropsychologist at the University of North Carolina School of Medicine’s COVID Recovery Clinic. 

“Even though we’re several years into this pandemic, there are still a lot of providers who don’t believe that their patients are experiencing these residual symptoms,” said Dr. Thompson, “That’s why the use of biomarkers is important, because it provides an objective indication that the brain has been compromised in some way.”

Some patients with long COVID have said that getting their doctors to believe they have a physical ailment has been a persistent problem throughout the pandemic and especially as it relates to the sometimes-vague collection of symptoms associated with brain fog. One study found that as many as 79% of study respondents reported negative interactions with their healthcare providers when they sought treatment for their long-COVID symptoms.
 

How Do COVID-Related Brain Injuries Happen?

Researchers are unsure what’s causing these brain injuries, though they have identified some clues. Previous research has suggested that such injuries might be the result of a lack of oxygen to the brain, especially in patients who were hospitalized, like those in this study, and were put on ventilators.

Brain scans have previously shown atrophy to the brain›s gray matter in COVID-19 patients, likely caused by inflammation from a heightened immune response rather than the virus itself. This inflammatory response seems to affect the central nervous system. As part of the new study, researchers found some neuroprotective effects of using steroids during hospitalization to reduce brain inflammation.

The results suggest that clinicians should overcome their skepticism and consider the possibility that their patients have suffered a brain injury and should be treated appropriately, said James C. Jackson, PsyD, a neuropsychiatrist at Vanderbilt University School of Medicine. “The old saying is that if it walks like a duck and talks like a duck, it’s a duck,” said Dr. Jackson. 

He contends that treatments used for patients who have brain injuries have also been shown to be effective in treating long COVID–related brain fog symptoms. These may include speech, cognitive, and occupational therapy as well as meeting with a neuropsychiatrist for the treatment of related mental health concerns.
 

A New Path Forward

Treating long-COVID brain fog like a brain injury can help patients get back to some semblance of normalcy, researchers said. “What we’re seeing in terms of brain injury biomarkers and differences in brain scans correlates to real-life problems that these patients are dealing with on a daily basis,” said Dr. Jackson. These include problems at work and in life with multitasking, remembering details, meeting deadlines, synthesizing large amounts of information, and maintaining focus on the task at hand, he said.

There’s also a fear that even with treatment, the aging of the brain caused by the virus might have long-term repercussions and that this enduring injury may cause the early onset of dementia and Alzheimer’s disease in those who were already vulnerable to it. One study, from the National Institute of Neurological Disorders and Stroke (NINDS), found that in those infected with COVID-19 who already had dementia, the virus “rapidly accelerated structural and functional brain deterioration.” 

“We already know the role that neuroinflammation plays in the brains of patients with Alzheimer’s disease,” said Dr. Thompson. “If long COVID is involved in prolonged inflammation of the brain, it goes a long way in explaining the mechanism underlying [the study’s reported] brain aging.”
 

Still More to Learn

In some ways, this study raises nearly as many questions as it does answers. While it provides concrete evidence around the damage the virus is doing to the brains of patients who contracted severe COVID-19, researchers don’t know about the impact on those who had less serious cases of the virus. 

For Ziyad Al-Aly, MD, chief of research and development at the Veterans Affairs St. Louis Health Care System, the concern is that some long-COVID patients may be suffering from cognitive deficits that are more subtle but still impacting their daily lives, and that they’re not getting the help they need. 

What’s more, said Dr. Al-Aly, it’s unclear whether the impacts of the brain damage are permanent or how to stop them from worsening. Researchers and clinicians need a better understanding of the mechanism that allows this virus to enter the brain and do structural damage. If it’s inflammation, will anti-inflammatory or antiviral medications work at preventing it? Will steroids help to offset the damage? “It’s critical we find some answers,” he said.

“SARS-CoV-2 isn’t going anywhere. It will continue to infect the population, so if this is indeed a virus that damages the brain in the long term or permanently, we need to figure out what can be done to stop it,” said Dr. Al-Aly.

A version of this article appeared on Medscape.com.

The long-term impact of traumatic brain injury (TBI) on neurologic and psychiatric function is well-established, but a growing body of research is pointing to unexpected medical sequalae, including cardiovascular disease (CVD).

A recent review looked at the investigation to date into this surprising connection, not only summarizing study findings but also suggesting potential mechanisms that might account for the association.

“This work offers further evidence that individuals with TBI are at an elevated risk of unfavorable cardiovascular outcomes for an extended period following the initial incident; consequently, they should undergo regular monitoring,” senior author Ross Zafonte, DO, president of Spaulding Rehabilitation Network, Boston, and lead author Saef Izzy, MD, MBChB, a neurologist at the Stroke and Cerebrovascular Center of Brigham and Women’s Hospital, Boston, Massachusetts, told this news organization.

“This holds significant importance for healthcare practitioners, as there exist several strategies to mitigate cardiovascular disease risk — including weight management, adopting a healthy diet, engaging in regular physical activity, and quitting smoking,” they stated.

Leslie Croll, MD, American Heart Association volunteer and assistant professor of clinical neurology at the Temple University Lewis Katz School of Medicine, Philadelphia, Pennsylvania, told this news organization that it’s “extremely important to learn more about the interplay between TBI, neurologic disease, psychiatric complications, and the cardiovascular system.”

Hopefully, she added, “future research will help us understand what kind of cardiovascular disease monitoring and prevention measures stand to give TBI patients the most benefit.”
 

Chronic Condition

TBI is “a major cause of long-term disability and premature death,” and is “highly prevalent among contact sports players, military personnel (eg, due to injuries sustained during conflict), and the general population (eg, due to falls and road traffic incidents),” the authors wrote.

Most studies pertaining to TBI have “primarily focused on establishing connections between single TBI, repetitive TBI, and their acute and chronic neurological and psychiatric consequences, such as Parkinson’s disease, Alzheimer’s disease, and chronic traumatic encephalopathy (CTE),” Drs. Zafonte and Izzy noted. By contrast, there has been a “notable lack of research attention given to non-neurological conditions associated with TBI.”

They pointed out that recent insights into TBI — particularly the acknowledgment of TBI as an “emerging chronic condition rather than merely an acute aftermath of brain injury” — have come to light through epidemiologic and pathologic investigations involving military veterans, professional American-style football players, and the civilian population. “This recognition opens up an opportunity to broaden our perspective and delve into the medical aspects of health that may be influenced by TBI.”

To broaden the investigation, the researchers reviewed literature published between January 1, 2001, and June 18, 2023. Of 26,335 articles, they narrowed their review down to 15 studies that investigated CVD, CVD risk factors, and cerebrovascular disease in the chronic phase of TBI, including community, military, or sport-related brain trauma, regardless of the timing of disease occurrence with respect to brain injury via TBI or repetitive head impact.
 

New Cardiovascular Risk

Studies that used national or local registries tended to be retrospective and predominantly conducted in people with preexisting cardiovascular conditions. In these studies, TBI was found to be an independent risk factor for myocardial dysfunction. However, although these studies do provide evidence of elevated cardiovascular risk subsequent to a single TBI, including individuals with preexisting medical comorbidities “makes it difficult to determine the timing of incident cardiovascular disease and cardiovascular risk factors subsequent to brain injury,” they wrote.

However, some studies showed that even individuals with TBI but without preexisting myocardial dysfunction at baseline had a significantly higher risk for CVD than those without a history of TBI.

In fact, several studies included populations without preexisting medical and cardiovascular comorbidities to “better refine the order and timing of CVD and other risk factors in individuals with TBI.”

For example, one study of concussion survivors without preexisting diagnoses showed that cardiovascular, endocrinological, and neuropsychiatric comorbidities occurred at a “significantly higher incidence within 5 years after concussive TBI compared with healthy individuals who were matched in terms of age, race, and sex and didn’t have a TBI exposure.” Other studies yielded similar findings.

Because cardiovascular risk factors and events become more common with age, it’s important to account for age in evaluating the effects of TBI. Although many studies of TBI and subsequent CVD didn’t stratify individuals by age, one 10-year study of people without any known cardiovascular or neuropsychiatric conditions who sustained TBI found that people as young as 18-40 years were more likely to develop hypertension, hyperlipidemia, obesity, and diabetes within 3-5 years following brain injury than matched individuals in the control group.

“Individuals who have encountered TBI, surprisingly even those who are young and in good health with no prior comorbid conditions, face an increased risk of adverse cardiovascular outcomes for an extended duration after the initial event,” Drs. Zafonte and Izzy summarized. “Therefore, it’s imperative that they receive regular and long-term screenings for CVD and associated risk factors.”
 

Bidirectional Relationship

Brain injury has been associated with acute cardiovascular dysfunction, including autonomic heart-brain axis dysregulation, imbalances between the sympathetic and parasympathetic nervous systems, and excessive catecholamine release, the authors noted.

Drs. Zafonte and Izzy suggested several plausible links between TBI and cardiovascular dysfunction, noting that they are “likely multifaceted, potentially encompassing risk factors that span the pre-injury, injury, and post-injury phases of the condition.”

TBI may induce alterations in neurobiological processes, which have been reported to be associated with an increased risk for CVD (eg, chronic dysfunction of the autonomic system, systemic inflammation, and modifications in the brain-gut connection).

Patients with TBI might develop additional risk factors following the injury, including conditions like posttraumatic stress disorder, depression, and other psychiatric illnesses, which are “known to augment the risk of CVD.”

TBI can lead to subsequent behavioral and lifestyle changes that place patients at an elevated risk for both cardiovascular and cognitive dysfunction when compared to the general population of TBI survivors.

There may be additional as yet undefined risks.

They believe there’s a bidirectional relationship between TBI and CVD. “On one hand, TBI has been associated with an elevated risk of CVD,” they said. “Conversely, cardiovascular risk factors such as diabetes, hypertension, hyperlipidemia, and sleep disturbances that have been demonstrated to negatively influence cognitive function and heighten the risk of dementia. Consequently, this interplay can further compound the long-term consequences of the injury.”

Their work aims to try and disentangle this “complex series of relationships.”

They recommend screening to identify diseases in their earliest and “most manageable phases” because TBI has been “unveiled as an underappreciated risk factor for CVD within contact sports, military, and community setting.”

An effective screening program “should rely on quantifiable and dependable biomarkers such as blood pressure, BMI, waist circumference, blood lipid levels, and glucose. Additionally, it should take into account other factors like smoking habits, physical activity, and dietary choices,” they recommended.
 

Heart-Brain Connection

Dr. Croll noted that TBI is “associated with many poorly understood physiologic changes and complications, so it’s exciting to see research aimed at clarifying this chronic disease process.”

In recent years, “we have seen a greater appreciation and understanding of the heart-brain connection,” she said. “Moving forward, more research, including TBI research, will target that connection.”

She added that there are probably “multiple mechanisms” at play underlying the connection between TBI and CVD.

Most importantly, “we are increasingly learning that TBI is not only a discrete event that requires immediate treatment but also a chronic disease process,” and when we “think about the substantial long-term morbidity associated with TBI, we should keep increased risk for CVD on top of mind,” said Dr. Croll.

The review received no funding. Izzy reported receiving grants from the US National Institutes of Health (NIH) and 2023 Stepping Strong Innovator Award. Dr. Zafonte reported receiving grants from the NIH and royalties from Springer and Demos publishing for serving as a coeditor of Brain Injury Medicine. Dr. Zafonte has also served as an adviser to Myomo, Oncare.ai, Nanodiagnostics, and Kisbee. He reported evaluating patients in the Massachusetts General Hospital Brain and Body–TRUST Program, which is funded by the NFL Players Association. The other authors’ disclosures are listed on the original paper. Dr. Croll declared no relevant financial relationships.

A version of this article appeared on Medscape.com.

The long-term impact of traumatic brain injury (TBI) on neurologic and psychiatric function is well-established, but a growing body of research is pointing to unexpected medical sequalae, including cardiovascular disease (CVD).

A recent review looked at the investigation to date into this surprising connection, not only summarizing study findings but also suggesting potential mechanisms that might account for the association.

“This work offers further evidence that individuals with TBI are at an elevated risk of unfavorable cardiovascular outcomes for an extended period following the initial incident; consequently, they should undergo regular monitoring,” senior author Ross Zafonte, DO, president of Spaulding Rehabilitation Network, Boston, and lead author Saef Izzy, MD, MBChB, a neurologist at the Stroke and Cerebrovascular Center of Brigham and Women’s Hospital, Boston, Massachusetts, told this news organization.

“This holds significant importance for healthcare practitioners, as there exist several strategies to mitigate cardiovascular disease risk — including weight management, adopting a healthy diet, engaging in regular physical activity, and quitting smoking,” they stated.

Leslie Croll, MD, American Heart Association volunteer and assistant professor of clinical neurology at the Temple University Lewis Katz School of Medicine, Philadelphia, Pennsylvania, told this news organization that it’s “extremely important to learn more about the interplay between TBI, neurologic disease, psychiatric complications, and the cardiovascular system.”

Hopefully, she added, “future research will help us understand what kind of cardiovascular disease monitoring and prevention measures stand to give TBI patients the most benefit.”
 

Chronic Condition

TBI is “a major cause of long-term disability and premature death,” and is “highly prevalent among contact sports players, military personnel (eg, due to injuries sustained during conflict), and the general population (eg, due to falls and road traffic incidents),” the authors wrote.

Most studies pertaining to TBI have “primarily focused on establishing connections between single TBI, repetitive TBI, and their acute and chronic neurological and psychiatric consequences, such as Parkinson’s disease, Alzheimer’s disease, and chronic traumatic encephalopathy (CTE),” Drs. Zafonte and Izzy noted. By contrast, there has been a “notable lack of research attention given to non-neurological conditions associated with TBI.”

They pointed out that recent insights into TBI — particularly the acknowledgment of TBI as an “emerging chronic condition rather than merely an acute aftermath of brain injury” — have come to light through epidemiologic and pathologic investigations involving military veterans, professional American-style football players, and the civilian population. “This recognition opens up an opportunity to broaden our perspective and delve into the medical aspects of health that may be influenced by TBI.”

To broaden the investigation, the researchers reviewed literature published between January 1, 2001, and June 18, 2023. Of 26,335 articles, they narrowed their review down to 15 studies that investigated CVD, CVD risk factors, and cerebrovascular disease in the chronic phase of TBI, including community, military, or sport-related brain trauma, regardless of the timing of disease occurrence with respect to brain injury via TBI or repetitive head impact.
 

New Cardiovascular Risk

Studies that used national or local registries tended to be retrospective and predominantly conducted in people with preexisting cardiovascular conditions. In these studies, TBI was found to be an independent risk factor for myocardial dysfunction. However, although these studies do provide evidence of elevated cardiovascular risk subsequent to a single TBI, including individuals with preexisting medical comorbidities “makes it difficult to determine the timing of incident cardiovascular disease and cardiovascular risk factors subsequent to brain injury,” they wrote.

However, some studies showed that even individuals with TBI but without preexisting myocardial dysfunction at baseline had a significantly higher risk for CVD than those without a history of TBI.

In fact, several studies included populations without preexisting medical and cardiovascular comorbidities to “better refine the order and timing of CVD and other risk factors in individuals with TBI.”

For example, one study of concussion survivors without preexisting diagnoses showed that cardiovascular, endocrinological, and neuropsychiatric comorbidities occurred at a “significantly higher incidence within 5 years after concussive TBI compared with healthy individuals who were matched in terms of age, race, and sex and didn’t have a TBI exposure.” Other studies yielded similar findings.

Because cardiovascular risk factors and events become more common with age, it’s important to account for age in evaluating the effects of TBI. Although many studies of TBI and subsequent CVD didn’t stratify individuals by age, one 10-year study of people without any known cardiovascular or neuropsychiatric conditions who sustained TBI found that people as young as 18-40 years were more likely to develop hypertension, hyperlipidemia, obesity, and diabetes within 3-5 years following brain injury than matched individuals in the control group.

“Individuals who have encountered TBI, surprisingly even those who are young and in good health with no prior comorbid conditions, face an increased risk of adverse cardiovascular outcomes for an extended duration after the initial event,” Drs. Zafonte and Izzy summarized. “Therefore, it’s imperative that they receive regular and long-term screenings for CVD and associated risk factors.”
 

Bidirectional Relationship

Brain injury has been associated with acute cardiovascular dysfunction, including autonomic heart-brain axis dysregulation, imbalances between the sympathetic and parasympathetic nervous systems, and excessive catecholamine release, the authors noted.

Drs. Zafonte and Izzy suggested several plausible links between TBI and cardiovascular dysfunction, noting that they are “likely multifaceted, potentially encompassing risk factors that span the pre-injury, injury, and post-injury phases of the condition.”

TBI may induce alterations in neurobiological processes, which have been reported to be associated with an increased risk for CVD (eg, chronic dysfunction of the autonomic system, systemic inflammation, and modifications in the brain-gut connection).

Patients with TBI might develop additional risk factors following the injury, including conditions like posttraumatic stress disorder, depression, and other psychiatric illnesses, which are “known to augment the risk of CVD.”

TBI can lead to subsequent behavioral and lifestyle changes that place patients at an elevated risk for both cardiovascular and cognitive dysfunction when compared to the general population of TBI survivors.

There may be additional as yet undefined risks.

They believe there’s a bidirectional relationship between TBI and CVD. “On one hand, TBI has been associated with an elevated risk of CVD,” they said. “Conversely, cardiovascular risk factors such as diabetes, hypertension, hyperlipidemia, and sleep disturbances that have been demonstrated to negatively influence cognitive function and heighten the risk of dementia. Consequently, this interplay can further compound the long-term consequences of the injury.”

Their work aims to try and disentangle this “complex series of relationships.”

They recommend screening to identify diseases in their earliest and “most manageable phases” because TBI has been “unveiled as an underappreciated risk factor for CVD within contact sports, military, and community setting.”

An effective screening program “should rely on quantifiable and dependable biomarkers such as blood pressure, BMI, waist circumference, blood lipid levels, and glucose. Additionally, it should take into account other factors like smoking habits, physical activity, and dietary choices,” they recommended.
 

Heart-Brain Connection

Dr. Croll noted that TBI is “associated with many poorly understood physiologic changes and complications, so it’s exciting to see research aimed at clarifying this chronic disease process.”

In recent years, “we have seen a greater appreciation and understanding of the heart-brain connection,” she said. “Moving forward, more research, including TBI research, will target that connection.”

She added that there are probably “multiple mechanisms” at play underlying the connection between TBI and CVD.

Most importantly, “we are increasingly learning that TBI is not only a discrete event that requires immediate treatment but also a chronic disease process,” and when we “think about the substantial long-term morbidity associated with TBI, we should keep increased risk for CVD on top of mind,” said Dr. Croll.

The review received no funding. Izzy reported receiving grants from the US National Institutes of Health (NIH) and 2023 Stepping Strong Innovator Award. Dr. Zafonte reported receiving grants from the NIH and royalties from Springer and Demos publishing for serving as a coeditor of Brain Injury Medicine. Dr. Zafonte has also served as an adviser to Myomo, Oncare.ai, Nanodiagnostics, and Kisbee. He reported evaluating patients in the Massachusetts General Hospital Brain and Body–TRUST Program, which is funded by the NFL Players Association. The other authors’ disclosures are listed on the original paper. Dr. Croll declared no relevant financial relationships.

A version of this article appeared on Medscape.com.

The long-term impact of traumatic brain injury (TBI) on neurologic and psychiatric function is well-established, but a growing body of research is pointing to unexpected medical sequalae, including cardiovascular disease (CVD).

A recent review looked at the investigation to date into this surprising connection, not only summarizing study findings but also suggesting potential mechanisms that might account for the association.

“This work offers further evidence that individuals with TBI are at an elevated risk of unfavorable cardiovascular outcomes for an extended period following the initial incident; consequently, they should undergo regular monitoring,” senior author Ross Zafonte, DO, president of Spaulding Rehabilitation Network, Boston, and lead author Saef Izzy, MD, MBChB, a neurologist at the Stroke and Cerebrovascular Center of Brigham and Women’s Hospital, Boston, Massachusetts, told this news organization.

“This holds significant importance for healthcare practitioners, as there exist several strategies to mitigate cardiovascular disease risk — including weight management, adopting a healthy diet, engaging in regular physical activity, and quitting smoking,” they stated.

Leslie Croll, MD, American Heart Association volunteer and assistant professor of clinical neurology at the Temple University Lewis Katz School of Medicine, Philadelphia, Pennsylvania, told this news organization that it’s “extremely important to learn more about the interplay between TBI, neurologic disease, psychiatric complications, and the cardiovascular system.”

Hopefully, she added, “future research will help us understand what kind of cardiovascular disease monitoring and prevention measures stand to give TBI patients the most benefit.”
 

Chronic Condition

TBI is “a major cause of long-term disability and premature death,” and is “highly prevalent among contact sports players, military personnel (eg, due to injuries sustained during conflict), and the general population (eg, due to falls and road traffic incidents),” the authors wrote.

Most studies pertaining to TBI have “primarily focused on establishing connections between single TBI, repetitive TBI, and their acute and chronic neurological and psychiatric consequences, such as Parkinson’s disease, Alzheimer’s disease, and chronic traumatic encephalopathy (CTE),” Drs. Zafonte and Izzy noted. By contrast, there has been a “notable lack of research attention given to non-neurological conditions associated with TBI.”

They pointed out that recent insights into TBI — particularly the acknowledgment of TBI as an “emerging chronic condition rather than merely an acute aftermath of brain injury” — have come to light through epidemiologic and pathologic investigations involving military veterans, professional American-style football players, and the civilian population. “This recognition opens up an opportunity to broaden our perspective and delve into the medical aspects of health that may be influenced by TBI.”

To broaden the investigation, the researchers reviewed literature published between January 1, 2001, and June 18, 2023. Of 26,335 articles, they narrowed their review down to 15 studies that investigated CVD, CVD risk factors, and cerebrovascular disease in the chronic phase of TBI, including community, military, or sport-related brain trauma, regardless of the timing of disease occurrence with respect to brain injury via TBI or repetitive head impact.
 

New Cardiovascular Risk

Studies that used national or local registries tended to be retrospective and predominantly conducted in people with preexisting cardiovascular conditions. In these studies, TBI was found to be an independent risk factor for myocardial dysfunction. However, although these studies do provide evidence of elevated cardiovascular risk subsequent to a single TBI, including individuals with preexisting medical comorbidities “makes it difficult to determine the timing of incident cardiovascular disease and cardiovascular risk factors subsequent to brain injury,” they wrote.

However, some studies showed that even individuals with TBI but without preexisting myocardial dysfunction at baseline had a significantly higher risk for CVD than those without a history of TBI.

In fact, several studies included populations without preexisting medical and cardiovascular comorbidities to “better refine the order and timing of CVD and other risk factors in individuals with TBI.”

For example, one study of concussion survivors without preexisting diagnoses showed that cardiovascular, endocrinological, and neuropsychiatric comorbidities occurred at a “significantly higher incidence within 5 years after concussive TBI compared with healthy individuals who were matched in terms of age, race, and sex and didn’t have a TBI exposure.” Other studies yielded similar findings.

Because cardiovascular risk factors and events become more common with age, it’s important to account for age in evaluating the effects of TBI. Although many studies of TBI and subsequent CVD didn’t stratify individuals by age, one 10-year study of people without any known cardiovascular or neuropsychiatric conditions who sustained TBI found that people as young as 18-40 years were more likely to develop hypertension, hyperlipidemia, obesity, and diabetes within 3-5 years following brain injury than matched individuals in the control group.

“Individuals who have encountered TBI, surprisingly even those who are young and in good health with no prior comorbid conditions, face an increased risk of adverse cardiovascular outcomes for an extended duration after the initial event,” Drs. Zafonte and Izzy summarized. “Therefore, it’s imperative that they receive regular and long-term screenings for CVD and associated risk factors.”
 

Bidirectional Relationship

Brain injury has been associated with acute cardiovascular dysfunction, including autonomic heart-brain axis dysregulation, imbalances between the sympathetic and parasympathetic nervous systems, and excessive catecholamine release, the authors noted.

Drs. Zafonte and Izzy suggested several plausible links between TBI and cardiovascular dysfunction, noting that they are “likely multifaceted, potentially encompassing risk factors that span the pre-injury, injury, and post-injury phases of the condition.”

TBI may induce alterations in neurobiological processes, which have been reported to be associated with an increased risk for CVD (eg, chronic dysfunction of the autonomic system, systemic inflammation, and modifications in the brain-gut connection).

Patients with TBI might develop additional risk factors following the injury, including conditions like posttraumatic stress disorder, depression, and other psychiatric illnesses, which are “known to augment the risk of CVD.”

TBI can lead to subsequent behavioral and lifestyle changes that place patients at an elevated risk for both cardiovascular and cognitive dysfunction when compared to the general population of TBI survivors.

There may be additional as yet undefined risks.

They believe there’s a bidirectional relationship between TBI and CVD. “On one hand, TBI has been associated with an elevated risk of CVD,” they said. “Conversely, cardiovascular risk factors such as diabetes, hypertension, hyperlipidemia, and sleep disturbances that have been demonstrated to negatively influence cognitive function and heighten the risk of dementia. Consequently, this interplay can further compound the long-term consequences of the injury.”

Their work aims to try and disentangle this “complex series of relationships.”

They recommend screening to identify diseases in their earliest and “most manageable phases” because TBI has been “unveiled as an underappreciated risk factor for CVD within contact sports, military, and community setting.”

An effective screening program “should rely on quantifiable and dependable biomarkers such as blood pressure, BMI, waist circumference, blood lipid levels, and glucose. Additionally, it should take into account other factors like smoking habits, physical activity, and dietary choices,” they recommended.
 

Heart-Brain Connection

Dr. Croll noted that TBI is “associated with many poorly understood physiologic changes and complications, so it’s exciting to see research aimed at clarifying this chronic disease process.”

In recent years, “we have seen a greater appreciation and understanding of the heart-brain connection,” she said. “Moving forward, more research, including TBI research, will target that connection.”

She added that there are probably “multiple mechanisms” at play underlying the connection between TBI and CVD.

Most importantly, “we are increasingly learning that TBI is not only a discrete event that requires immediate treatment but also a chronic disease process,” and when we “think about the substantial long-term morbidity associated with TBI, we should keep increased risk for CVD on top of mind,” said Dr. Croll.

The review received no funding. Izzy reported receiving grants from the US National Institutes of Health (NIH) and 2023 Stepping Strong Innovator Award. Dr. Zafonte reported receiving grants from the NIH and royalties from Springer and Demos publishing for serving as a coeditor of Brain Injury Medicine. Dr. Zafonte has also served as an adviser to Myomo, Oncare.ai, Nanodiagnostics, and Kisbee. He reported evaluating patients in the Massachusetts General Hospital Brain and Body–TRUST Program, which is funded by the NFL Players Association. The other authors’ disclosures are listed on the original paper. Dr. Croll declared no relevant financial relationships.

A version of this article appeared on Medscape.com.

Oneirogens are substances that produce or enhance dreamlike states of consciousness—could one of those, ibogaine, be key to relieving the sequelae of traumatic brain injury (TBI) in veterans?

An extract from the root bark of Tabernanthe iboga, an African shrub, ibogaine has both pharmacological and psychological effects. Acting on opioid receptors and the serotonin and dopamine systems, it can relieve withdrawal symptoms and reduce drug cravings—reportedly, often, in just a few hours—and reduce the risk of regular use. The results can last for weeks, months, or sometimes longer.

In the US, ibogaine is a Schedule I drug. Few controlled studies of ibogaine are available; most data come from anecdotal reports and case studies. Clinical research into ibogaine stalled due to legal restrictions that come with a Schedule I drug, as well as concerns about possible cardiac consequences. For example, some reports have described QT interval prolongation, with instances of subsequent fatal arrhythmia.  

That may change now, with findings from the Magnesium–Ibogaine: the Stanford Traumatic Injury to the CNS protocol (MISTIC), which took place at a treatment center in Mexico. Researchers from Stanford School of Medicine and the Veterans Affairs Palo Alto Health Care System combined prophylactic intravenous magnesium with ibogaine, in hopes of mitigating the cardiac risks. Magnesium supplementation has been shown to protect against QT interval prolongation when coadministered with medications that ordinarily would have such an effect.

The researchers studied 30 male Special Operations Forces veterans (SOVs) who had predominantly mild TBI. Of those, 15 participants met the criteria for major depressive disorder, 14 for an anxiety disorder, and 23 for PTSD; 19 had past suicidal ideation and 7 had attempted suicide.

Special Operations Forces, the researchers note, are “deployed at a greater pace and to higher intensity combat than conventional military, exposing them to greater allostatic load and risk of injury, including from blast exposure.” This, they say, may result in a “unique pattern” of physical, cognitive, behavioral, psychiatric, and endocrine-related problems across several domains.

Participants received a mean (SD) of 12.1 (1.2) mg kg^-1 of oral ibogaine. The researchers assessed changes in the World Health Organization Disability Assessment Schedule at baseline, immediately after treatment, and 1 month after treatment. They also assessed changes in posttraumatic stress disorder (PTSD), depression, and anxiety.

The treatment significantly improved functioning both immediately and at 1 month after treatment and PTSD, depression, and anxiety at 1 month after treatment. There were no unexpected or serious treatment-emergent adverse effects, nor were there instances of bradycardia, tachycardia, clinically meaningful QT prolongation, or hemodynamic instability. All participants experienced transient cerebellar signs, such as mild ataxia and intention tremor, that resolved within 24 hours. While experiencing oneirogenic effects, 12 participants were treated for headache, 7 for nausea, 3 for anxiety, 2 for hypertension, and 1 for insomnia. 

At 1 month, suicidal ideation had declined from 47% to 7%—a statistically significant change. “Given the alarming rates of suicide in veterans, as well as evidence that military-related TBI increases the risk of suicide,” the researchers say, “the substantial reduction in SI that we observed—which must be interpreted cautiously as an exploratory analysis—is noteworthy.” TBI also is associated with increased impulsivity, a well-known risk factor for suicide, they note. MISTIC resulted in a measurable improvement in cognitive inhibition.

Results of a neuropsychological battery indicated statistically significant improvements in processing speed and executive functioning (including inhibition, cognitive flexibility, problem-solving, phonemic fluency, and working memory), both immediately after treatment and at 1 month. No declines were noted across any performance domain.

Interestingly, mean performances on these tests moved from the average to the high average score range relative to same-age peers and, in all but one instance, phonemic fluency was high average at baseline and improved to the superior range relative to same-age peers at the 1-month follow-up. Learning and memory tests showed a significant improvement in visual memory and verbal memory. Sustained attention showed a significant improvement in accuracy (detection) and a weak but significant slowing of reaction time, consistent with a prioritization of accuracy over speed and reduced impulsivity.

In a Scientific American article, lead researcher Nolan Williams said he suspects the powerful effects of psychedelics have to do with their “profound ability to increase plasticity in the brain” by “bringing it back to a more juvenile state where reorganization can occur.” People often experience a life review that appears in their minds almost like a slideshow. “It somehow drives a particular sort of psychological phenomenon that you don’t achieve through guidance,” Williams said.

The data from the MISTIC trial in Mexico may spur more research in the US. The National Defense Authorization Act, signed by President Joe Biden last December, authorizes service members diagnosed with PTSD or TBI to take part in clinical studies of any “qualified plant-based alternative therapies.”

“It’s all really timely,” Williams said. “From my perspective, we should have some traction to make a strong argument that the risk-benefit is right.”

Oneirogens are substances that produce or enhance dreamlike states of consciousness—could one of those, ibogaine, be key to relieving the sequelae of traumatic brain injury (TBI) in veterans?

An extract from the root bark of Tabernanthe iboga, an African shrub, ibogaine has both pharmacological and psychological effects. Acting on opioid receptors and the serotonin and dopamine systems, it can relieve withdrawal symptoms and reduce drug cravings—reportedly, often, in just a few hours—and reduce the risk of regular use. The results can last for weeks, months, or sometimes longer.

In the US, ibogaine is a Schedule I drug. Few controlled studies of ibogaine are available; most data come from anecdotal reports and case studies. Clinical research into ibogaine stalled due to legal restrictions that come with a Schedule I drug, as well as concerns about possible cardiac consequences. For example, some reports have described QT interval prolongation, with instances of subsequent fatal arrhythmia.  

That may change now, with findings from the Magnesium–Ibogaine: the Stanford Traumatic Injury to the CNS protocol (MISTIC), which took place at a treatment center in Mexico. Researchers from Stanford School of Medicine and the Veterans Affairs Palo Alto Health Care System combined prophylactic intravenous magnesium with ibogaine, in hopes of mitigating the cardiac risks. Magnesium supplementation has been shown to protect against QT interval prolongation when coadministered with medications that ordinarily would have such an effect.

The researchers studied 30 male Special Operations Forces veterans (SOVs) who had predominantly mild TBI. Of those, 15 participants met the criteria for major depressive disorder, 14 for an anxiety disorder, and 23 for PTSD; 19 had past suicidal ideation and 7 had attempted suicide.

Special Operations Forces, the researchers note, are “deployed at a greater pace and to higher intensity combat than conventional military, exposing them to greater allostatic load and risk of injury, including from blast exposure.” This, they say, may result in a “unique pattern” of physical, cognitive, behavioral, psychiatric, and endocrine-related problems across several domains.

Participants received a mean (SD) of 12.1 (1.2) mg kg^-1 of oral ibogaine. The researchers assessed changes in the World Health Organization Disability Assessment Schedule at baseline, immediately after treatment, and 1 month after treatment. They also assessed changes in posttraumatic stress disorder (PTSD), depression, and anxiety.

The treatment significantly improved functioning both immediately and at 1 month after treatment and PTSD, depression, and anxiety at 1 month after treatment. There were no unexpected or serious treatment-emergent adverse effects, nor were there instances of bradycardia, tachycardia, clinically meaningful QT prolongation, or hemodynamic instability. All participants experienced transient cerebellar signs, such as mild ataxia and intention tremor, that resolved within 24 hours. While experiencing oneirogenic effects, 12 participants were treated for headache, 7 for nausea, 3 for anxiety, 2 for hypertension, and 1 for insomnia. 

At 1 month, suicidal ideation had declined from 47% to 7%—a statistically significant change. “Given the alarming rates of suicide in veterans, as well as evidence that military-related TBI increases the risk of suicide,” the researchers say, “the substantial reduction in SI that we observed—which must be interpreted cautiously as an exploratory analysis—is noteworthy.” TBI also is associated with increased impulsivity, a well-known risk factor for suicide, they note. MISTIC resulted in a measurable improvement in cognitive inhibition.

Results of a neuropsychological battery indicated statistically significant improvements in processing speed and executive functioning (including inhibition, cognitive flexibility, problem-solving, phonemic fluency, and working memory), both immediately after treatment and at 1 month. No declines were noted across any performance domain.

Interestingly, mean performances on these tests moved from the average to the high average score range relative to same-age peers and, in all but one instance, phonemic fluency was high average at baseline and improved to the superior range relative to same-age peers at the 1-month follow-up. Learning and memory tests showed a significant improvement in visual memory and verbal memory. Sustained attention showed a significant improvement in accuracy (detection) and a weak but significant slowing of reaction time, consistent with a prioritization of accuracy over speed and reduced impulsivity.

In a Scientific American article, lead researcher Nolan Williams said he suspects the powerful effects of psychedelics have to do with their “profound ability to increase plasticity in the brain” by “bringing it back to a more juvenile state where reorganization can occur.” People often experience a life review that appears in their minds almost like a slideshow. “It somehow drives a particular sort of psychological phenomenon that you don’t achieve through guidance,” Williams said.

The data from the MISTIC trial in Mexico may spur more research in the US. The National Defense Authorization Act, signed by President Joe Biden last December, authorizes service members diagnosed with PTSD or TBI to take part in clinical studies of any “qualified plant-based alternative therapies.”

“It’s all really timely,” Williams said. “From my perspective, we should have some traction to make a strong argument that the risk-benefit is right.”

Oneirogens are substances that produce or enhance dreamlike states of consciousness—could one of those, ibogaine, be key to relieving the sequelae of traumatic brain injury (TBI) in veterans?

An extract from the root bark of Tabernanthe iboga, an African shrub, ibogaine has both pharmacological and psychological effects. Acting on opioid receptors and the serotonin and dopamine systems, it can relieve withdrawal symptoms and reduce drug cravings—reportedly, often, in just a few hours—and reduce the risk of regular use. The results can last for weeks, months, or sometimes longer.

In the US, ibogaine is a Schedule I drug. Few controlled studies of ibogaine are available; most data come from anecdotal reports and case studies. Clinical research into ibogaine stalled due to legal restrictions that come with a Schedule I drug, as well as concerns about possible cardiac consequences. For example, some reports have described QT interval prolongation, with instances of subsequent fatal arrhythmia.  

That may change now, with findings from the Magnesium–Ibogaine: the Stanford Traumatic Injury to the CNS protocol (MISTIC), which took place at a treatment center in Mexico. Researchers from Stanford School of Medicine and the Veterans Affairs Palo Alto Health Care System combined prophylactic intravenous magnesium with ibogaine, in hopes of mitigating the cardiac risks. Magnesium supplementation has been shown to protect against QT interval prolongation when coadministered with medications that ordinarily would have such an effect.

The researchers studied 30 male Special Operations Forces veterans (SOVs) who had predominantly mild TBI. Of those, 15 participants met the criteria for major depressive disorder, 14 for an anxiety disorder, and 23 for PTSD; 19 had past suicidal ideation and 7 had attempted suicide.

Special Operations Forces, the researchers note, are “deployed at a greater pace and to higher intensity combat than conventional military, exposing them to greater allostatic load and risk of injury, including from blast exposure.” This, they say, may result in a “unique pattern” of physical, cognitive, behavioral, psychiatric, and endocrine-related problems across several domains.

Participants received a mean (SD) of 12.1 (1.2) mg kg^-1 of oral ibogaine. The researchers assessed changes in the World Health Organization Disability Assessment Schedule at baseline, immediately after treatment, and 1 month after treatment. They also assessed changes in posttraumatic stress disorder (PTSD), depression, and anxiety.

The treatment significantly improved functioning both immediately and at 1 month after treatment and PTSD, depression, and anxiety at 1 month after treatment. There were no unexpected or serious treatment-emergent adverse effects, nor were there instances of bradycardia, tachycardia, clinically meaningful QT prolongation, or hemodynamic instability. All participants experienced transient cerebellar signs, such as mild ataxia and intention tremor, that resolved within 24 hours. While experiencing oneirogenic effects, 12 participants were treated for headache, 7 for nausea, 3 for anxiety, 2 for hypertension, and 1 for insomnia. 

At 1 month, suicidal ideation had declined from 47% to 7%—a statistically significant change. “Given the alarming rates of suicide in veterans, as well as evidence that military-related TBI increases the risk of suicide,” the researchers say, “the substantial reduction in SI that we observed—which must be interpreted cautiously as an exploratory analysis—is noteworthy.” TBI also is associated with increased impulsivity, a well-known risk factor for suicide, they note. MISTIC resulted in a measurable improvement in cognitive inhibition.

Results of a neuropsychological battery indicated statistically significant improvements in processing speed and executive functioning (including inhibition, cognitive flexibility, problem-solving, phonemic fluency, and working memory), both immediately after treatment and at 1 month. No declines were noted across any performance domain.

Interestingly, mean performances on these tests moved from the average to the high average score range relative to same-age peers and, in all but one instance, phonemic fluency was high average at baseline and improved to the superior range relative to same-age peers at the 1-month follow-up. Learning and memory tests showed a significant improvement in visual memory and verbal memory. Sustained attention showed a significant improvement in accuracy (detection) and a weak but significant slowing of reaction time, consistent with a prioritization of accuracy over speed and reduced impulsivity.

In a Scientific American article, lead researcher Nolan Williams said he suspects the powerful effects of psychedelics have to do with their “profound ability to increase plasticity in the brain” by “bringing it back to a more juvenile state where reorganization can occur.” People often experience a life review that appears in their minds almost like a slideshow. “It somehow drives a particular sort of psychological phenomenon that you don’t achieve through guidance,” Williams said.

The data from the MISTIC trial in Mexico may spur more research in the US. The National Defense Authorization Act, signed by President Joe Biden last December, authorizes service members diagnosed with PTSD or TBI to take part in clinical studies of any “qualified plant-based alternative therapies.”

“It’s all really timely,” Williams said. “From my perspective, we should have some traction to make a strong argument that the risk-benefit is right.”

The plant-based psychoactive compound ibogaine, combined with magnesium to protect the heart, is linked to improvement in severe psychiatric symptoms including depression, anxiety, and functioning in veterans with traumatic brain injury (TBI), early results from a small study showed.

“The most unique findings we observed are the improvements in disability and cognition. At the start of the study, participants had mild to moderate levels of disability. However, a month after treatment, their average disability rating indicated no disability and cognitive testing indicated improvements in concentration and memory,” study investigator Nolan Williams, MD, Stanford University, Stanford, California, told this news organization.

Also noteworthy were improvements across all participants in posttraumatic stress disorder (PTSD), depression, and anxiety — effects that lasted for at least 1 month after treatment, he said.

“These results are remarkable and exceeded our expectations. There is no drug today that can broadly relieve functional and neuropsychiatric symptoms of TBI as we observed with ibogaine,” Dr. Williams added.

The study was published online on January 5, 2024, in Nature Medicine.
 

‘The Storm Lifted’

Ibogaine is derived from the root bark of the Tabernanthe iboga shrub and related plants and is traditionally used in African spiritual and healing ceremonies.

It is known to interact with multiple neurotransmitter systems and has been studied primarily as a treatment of substance use disorders (SUDs). Some studies of ibogaine for SUDs have also noted improvements in self-reported measures of mood.

In the United States, ibogaine is classified as a Schedule I substance, but legal ibogaine treatments are offered in clinics in Canada and Mexico.

Dr. Williams noted that a handful of US veterans who went to Mexico for ibogaine treatment anecdotally reported improvements a variety of aspects of their lives.

The goal of the current study was to characterize those improvements with structured clinical and neurobiological assessments.

Participants included 30 US Special Operations Forces veterans (SOVs) with predominantly mild TBI from combat/blast exposures and psychiatric symptoms and functional limitations. All of them had independently scheduled themselves for treatment with magnesium and ibogaine at a clinic in Mexico.

Before treatment, the veterans had an average disability rating of 30.2 on the World Health Organization Disability Assessment Scale 2.0, equivalent to mild to moderate disability. One month after ibogaine treatment, that rating improved to 5.1, indicating no disability, the researchers reported.

One month after treatment, participants also experienced average reductions of 88% in PTSD symptoms, 87% in depression symptoms, and 81% in anxiety symptoms relative to before treatment.

Neuropsychological testing revealed improved concentration, information processing, memory, and impulsivity. There was also a substantial reduction in suicidal ideation.

“Before the treatment, I was living life in a blizzard with zero visibility and a cold, hopeless, listless feeling. After ibogaine, the storm lifted,” Sean, a 51-year-old veteran from Arizona with six combat deployments who participated in the study, said in a Stanford news release.

There were no serious side effects of ibogaine, and no instances of heart problems associated with the treatment.

Although the study findings are promising, additional research is needed to address some clear limitations, the researchers noted.

“Most importantly, the study was not controlled and so the relative contribution of any therapeutic benefits from non-ibogaine elements of the experience, such as complementary treatments, group activities, coaching, international travel, expectancy, or other nonspecific effects, cannot be determined,” they wrote.

In addition, follow-up was limited to 1 month, and longer-term data are needed to determine durability of the effects.

“We plan to study this compound further, as well as launch future studies to continue to understand how this drug can be used to treat TBI and possibly as a broader neuro-rehab drug. We will work towards a US-based set of trials to confirm efficacy with a multisite design,” said Dr. Williams.
 

Promising, but Very Preliminary

Commenting on the study for this news organization, Ramon Diaz-Arrastia, MD, PhD, professor of neurology and director of the Clinical TBI Research Center, University of Pennsylvania Perelman School of Medicine, Philadelphia, said the results are “promising, but very preliminary.”

Dr. Diaz-Arrastia noted that this was an open-label, nonrandomized study, early phase 2a study with “highly subjective outcome measures and the likelihood of it being a placebo effect is very high.”

Nonetheless, “there is a lot of interest in these ‘psychedelic’ alkaloids, and ibogaine is a good candidate for further study,” Dr. Diaz-Arrastia said.

Also providing perspective, Alan K. Davis, PhD, director of the Center for Psychedelic Drug Research and Education, Ohio State University, Columbus, said “mounting evidence supports the importance of studying this treatment in rigorous clinical trials in the US.”

Dr. Davis and colleagues recently observed that treatment with two naturally occurring psychedelics — ibogaine and 5-MeO-DMT — was associated with reduced depressive and anxiety symptoms in trauma-exposed SOVs, as previously reported by this news organization.

This new study “basically is a replication of what we’ve already published on this topic, and we published data from much larger samples and longer follow up,” said Dr. Davis.

Dr. Davis said it’s “important for the public to know that there are important and serious risks associated with ibogaine therapy, including the possibility of cardiac problems and death. These risks are compounded when people are in clinics or settings where proper screening and medical oversight are not completed.”

“Furthermore, the long-term effectiveness of this treatment is not well established. It may only help in the short term for most people. For many, ongoing clinical aftercare therapy and other forms of treatment may be needed,” Dr. Davis noted.

The study was independently funded by philanthropic gifts from Steve and Genevieve Jurvetson and another anonymous donor. Williams is an inventor on a patent application related to the safety of MISTIC administration as described in the paper and a separate patent related to the use of ibogaine to treat disorders associated with brain aging. Dr. Davis is a board member at Source Resource Foundation and a lead trainer at Fluence. Dr. Diaz-Arrastia has no relevant disclosures.

A version of this article appeared on Medscape.com.

The plant-based psychoactive compound ibogaine, combined with magnesium to protect the heart, is linked to improvement in severe psychiatric symptoms including depression, anxiety, and functioning in veterans with traumatic brain injury (TBI), early results from a small study showed.

“The most unique findings we observed are the improvements in disability and cognition. At the start of the study, participants had mild to moderate levels of disability. However, a month after treatment, their average disability rating indicated no disability and cognitive testing indicated improvements in concentration and memory,” study investigator Nolan Williams, MD, Stanford University, Stanford, California, told this news organization.

Also noteworthy were improvements across all participants in posttraumatic stress disorder (PTSD), depression, and anxiety — effects that lasted for at least 1 month after treatment, he said.

“These results are remarkable and exceeded our expectations. There is no drug today that can broadly relieve functional and neuropsychiatric symptoms of TBI as we observed with ibogaine,” Dr. Williams added.

The study was published online on January 5, 2024, in Nature Medicine.
 

‘The Storm Lifted’

Ibogaine is derived from the root bark of the Tabernanthe iboga shrub and related plants and is traditionally used in African spiritual and healing ceremonies.

It is known to interact with multiple neurotransmitter systems and has been studied primarily as a treatment of substance use disorders (SUDs). Some studies of ibogaine for SUDs have also noted improvements in self-reported measures of mood.

In the United States, ibogaine is classified as a Schedule I substance, but legal ibogaine treatments are offered in clinics in Canada and Mexico.

Dr. Williams noted that a handful of US veterans who went to Mexico for ibogaine treatment anecdotally reported improvements a variety of aspects of their lives.

The goal of the current study was to characterize those improvements with structured clinical and neurobiological assessments.

Participants included 30 US Special Operations Forces veterans (SOVs) with predominantly mild TBI from combat/blast exposures and psychiatric symptoms and functional limitations. All of them had independently scheduled themselves for treatment with magnesium and ibogaine at a clinic in Mexico.

Before treatment, the veterans had an average disability rating of 30.2 on the World Health Organization Disability Assessment Scale 2.0, equivalent to mild to moderate disability. One month after ibogaine treatment, that rating improved to 5.1, indicating no disability, the researchers reported.

One month after treatment, participants also experienced average reductions of 88% in PTSD symptoms, 87% in depression symptoms, and 81% in anxiety symptoms relative to before treatment.

Neuropsychological testing revealed improved concentration, information processing, memory, and impulsivity. There was also a substantial reduction in suicidal ideation.

“Before the treatment, I was living life in a blizzard with zero visibility and a cold, hopeless, listless feeling. After ibogaine, the storm lifted,” Sean, a 51-year-old veteran from Arizona with six combat deployments who participated in the study, said in a Stanford news release.

There were no serious side effects of ibogaine, and no instances of heart problems associated with the treatment.

Although the study findings are promising, additional research is needed to address some clear limitations, the researchers noted.

“Most importantly, the study was not controlled and so the relative contribution of any therapeutic benefits from non-ibogaine elements of the experience, such as complementary treatments, group activities, coaching, international travel, expectancy, or other nonspecific effects, cannot be determined,” they wrote.

In addition, follow-up was limited to 1 month, and longer-term data are needed to determine durability of the effects.

“We plan to study this compound further, as well as launch future studies to continue to understand how this drug can be used to treat TBI and possibly as a broader neuro-rehab drug. We will work towards a US-based set of trials to confirm efficacy with a multisite design,” said Dr. Williams.
 

Promising, but Very Preliminary

Commenting on the study for this news organization, Ramon Diaz-Arrastia, MD, PhD, professor of neurology and director of the Clinical TBI Research Center, University of Pennsylvania Perelman School of Medicine, Philadelphia, said the results are “promising, but very preliminary.”

Dr. Diaz-Arrastia noted that this was an open-label, nonrandomized study, early phase 2a study with “highly subjective outcome measures and the likelihood of it being a placebo effect is very high.”

Nonetheless, “there is a lot of interest in these ‘psychedelic’ alkaloids, and ibogaine is a good candidate for further study,” Dr. Diaz-Arrastia said.

Also providing perspective, Alan K. Davis, PhD, director of the Center for Psychedelic Drug Research and Education, Ohio State University, Columbus, said “mounting evidence supports the importance of studying this treatment in rigorous clinical trials in the US.”

Dr. Davis and colleagues recently observed that treatment with two naturally occurring psychedelics — ibogaine and 5-MeO-DMT — was associated with reduced depressive and anxiety symptoms in trauma-exposed SOVs, as previously reported by this news organization.

This new study “basically is a replication of what we’ve already published on this topic, and we published data from much larger samples and longer follow up,” said Dr. Davis.

Dr. Davis said it’s “important for the public to know that there are important and serious risks associated with ibogaine therapy, including the possibility of cardiac problems and death. These risks are compounded when people are in clinics or settings where proper screening and medical oversight are not completed.”

“Furthermore, the long-term effectiveness of this treatment is not well established. It may only help in the short term for most people. For many, ongoing clinical aftercare therapy and other forms of treatment may be needed,” Dr. Davis noted.

The study was independently funded by philanthropic gifts from Steve and Genevieve Jurvetson and another anonymous donor. Williams is an inventor on a patent application related to the safety of MISTIC administration as described in the paper and a separate patent related to the use of ibogaine to treat disorders associated with brain aging. Dr. Davis is a board member at Source Resource Foundation and a lead trainer at Fluence. Dr. Diaz-Arrastia has no relevant disclosures.

A version of this article appeared on Medscape.com.

The plant-based psychoactive compound ibogaine, combined with magnesium to protect the heart, is linked to improvement in severe psychiatric symptoms including depression, anxiety, and functioning in veterans with traumatic brain injury (TBI), early results from a small study showed.

“The most unique findings we observed are the improvements in disability and cognition. At the start of the study, participants had mild to moderate levels of disability. However, a month after treatment, their average disability rating indicated no disability and cognitive testing indicated improvements in concentration and memory,” study investigator Nolan Williams, MD, Stanford University, Stanford, California, told this news organization.

Also noteworthy were improvements across all participants in posttraumatic stress disorder (PTSD), depression, and anxiety — effects that lasted for at least 1 month after treatment, he said.

“These results are remarkable and exceeded our expectations. There is no drug today that can broadly relieve functional and neuropsychiatric symptoms of TBI as we observed with ibogaine,” Dr. Williams added.

The study was published online on January 5, 2024, in Nature Medicine.
 

‘The Storm Lifted’

Ibogaine is derived from the root bark of the Tabernanthe iboga shrub and related plants and is traditionally used in African spiritual and healing ceremonies.

It is known to interact with multiple neurotransmitter systems and has been studied primarily as a treatment of substance use disorders (SUDs). Some studies of ibogaine for SUDs have also noted improvements in self-reported measures of mood.

In the United States, ibogaine is classified as a Schedule I substance, but legal ibogaine treatments are offered in clinics in Canada and Mexico.

Dr. Williams noted that a handful of US veterans who went to Mexico for ibogaine treatment anecdotally reported improvements a variety of aspects of their lives.

The goal of the current study was to characterize those improvements with structured clinical and neurobiological assessments.

Participants included 30 US Special Operations Forces veterans (SOVs) with predominantly mild TBI from combat/blast exposures and psychiatric symptoms and functional limitations. All of them had independently scheduled themselves for treatment with magnesium and ibogaine at a clinic in Mexico.

Before treatment, the veterans had an average disability rating of 30.2 on the World Health Organization Disability Assessment Scale 2.0, equivalent to mild to moderate disability. One month after ibogaine treatment, that rating improved to 5.1, indicating no disability, the researchers reported.

One month after treatment, participants also experienced average reductions of 88% in PTSD symptoms, 87% in depression symptoms, and 81% in anxiety symptoms relative to before treatment.

Neuropsychological testing revealed improved concentration, information processing, memory, and impulsivity. There was also a substantial reduction in suicidal ideation.

“Before the treatment, I was living life in a blizzard with zero visibility and a cold, hopeless, listless feeling. After ibogaine, the storm lifted,” Sean, a 51-year-old veteran from Arizona with six combat deployments who participated in the study, said in a Stanford news release.

There were no serious side effects of ibogaine, and no instances of heart problems associated with the treatment.

Although the study findings are promising, additional research is needed to address some clear limitations, the researchers noted.

“Most importantly, the study was not controlled and so the relative contribution of any therapeutic benefits from non-ibogaine elements of the experience, such as complementary treatments, group activities, coaching, international travel, expectancy, or other nonspecific effects, cannot be determined,” they wrote.

In addition, follow-up was limited to 1 month, and longer-term data are needed to determine durability of the effects.

“We plan to study this compound further, as well as launch future studies to continue to understand how this drug can be used to treat TBI and possibly as a broader neuro-rehab drug. We will work towards a US-based set of trials to confirm efficacy with a multisite design,” said Dr. Williams.
 

Promising, but Very Preliminary

Commenting on the study for this news organization, Ramon Diaz-Arrastia, MD, PhD, professor of neurology and director of the Clinical TBI Research Center, University of Pennsylvania Perelman School of Medicine, Philadelphia, said the results are “promising, but very preliminary.”

Dr. Diaz-Arrastia noted that this was an open-label, nonrandomized study, early phase 2a study with “highly subjective outcome measures and the likelihood of it being a placebo effect is very high.”

Nonetheless, “there is a lot of interest in these ‘psychedelic’ alkaloids, and ibogaine is a good candidate for further study,” Dr. Diaz-Arrastia said.

Also providing perspective, Alan K. Davis, PhD, director of the Center for Psychedelic Drug Research and Education, Ohio State University, Columbus, said “mounting evidence supports the importance of studying this treatment in rigorous clinical trials in the US.”

Dr. Davis and colleagues recently observed that treatment with two naturally occurring psychedelics — ibogaine and 5-MeO-DMT — was associated with reduced depressive and anxiety symptoms in trauma-exposed SOVs, as previously reported by this news organization.

This new study “basically is a replication of what we’ve already published on this topic, and we published data from much larger samples and longer follow up,” said Dr. Davis.

Dr. Davis said it’s “important for the public to know that there are important and serious risks associated with ibogaine therapy, including the possibility of cardiac problems and death. These risks are compounded when people are in clinics or settings where proper screening and medical oversight are not completed.”

“Furthermore, the long-term effectiveness of this treatment is not well established. It may only help in the short term for most people. For many, ongoing clinical aftercare therapy and other forms of treatment may be needed,” Dr. Davis noted.

The study was independently funded by philanthropic gifts from Steve and Genevieve Jurvetson and another anonymous donor. Williams is an inventor on a patent application related to the safety of MISTIC administration as described in the paper and a separate patent related to the use of ibogaine to treat disorders associated with brain aging. Dr. Davis is a board member at Source Resource Foundation and a lead trainer at Fluence. Dr. Diaz-Arrastia has no relevant disclosures.

A version of this article appeared on Medscape.com.

An experimental therapy that uses deep brain stimulation (DBS) to deliver precise electrical pulses to an area deep inside the brain restored executive function in patients with moderate to severe traumatic brain injury (msTBI) and chronic sequelae.

Participants in this first-in-humans trial experienced brain injuries between 3-18 years before the study that left them with persistent neuropsychological impairment and a range of functional disabilities.

This is the first time a DBS device has been implanted in the central thalamus in humans, an area of the brain measuring only a few millimeters wide that helps regulate consciousness.

Placing the electrodes required a novel surgical technique developed by the investigators that included virtual models of each participant’s brain, microelectrode recording, and neuroimaging to identify neuronal circuits affected by the TBI.

After 3 months of 12-hour daily DBS treatments, participants’ performance on cognitive tests improved by an average of 32% from baseline. Participants were able to read books, watch TV shows, play video games, complete schoolwork, and felt significantly less fatigued during the day.

Although the small trial only included five patients, the work is already being hailed by other experts as significant.“We were looking for partial restoration of executive attention and expected [the treatment] would have an effect, but I wouldn’t have anticipated the effect size we saw,” co-lead investigator Nicholas Schiff, MD, professor of neuroscience at Weill Cornell Medical College, New York City, said in an interview.

The findings were published online Dec. 4 in Nature Medicine.

“No Trivial Feat”

An estimated 5.3 million children and adults are living with a permanent TBI-related disability in the US today. There currently is no effective therapy for impaired attention, executive function, working memory or information-processing speed caused by the initial injury.

Previous research suggests that a loss of activity in key brain circuits in the thalamus may be associated with a loss of cognitive function.

The investigators recruited six adults (four men and two women) between the ages of 22 and 60 years with a history of msTBI and chronic neuropsychological impairment and functional disability. One participant was later withdrawn from the trial for protocol noncompliance.

Participants completed a range of questionnaires and tests to establish baseline cognitive, psychological, and quality-of-life status.

To restore lost executive functioning in the brain, investigators had to target not only the central lateral nucleus, but also the neuronal network connected to the region that reaches other parts of the brain.

“To do both of those things we had to develop a whole toolset in order to model both the target and trajectory, which had to be right to make it work properly,” co-lead investigator Jaimie Henderson, MD, professor of neurosurgery at Stanford University College of Medicine, Stanford, California, said in an interview. “That gave us a pretty narrow window in which to work and getting an electrode accurately to this target is not a trivial feat.”

“A Moving Target”

Each participant’s brain physiology was slightly different, meaning the path that worked for one individual might not work for another. The surgery was further complicated by shifting in the brain that occurred as individual electrodes were placed.

“It was a literal moving target,” Dr. Henderson said.

In the beginning, investigators used microelectrode recording to “listen” to individual neurons to see which ones weren’t firing correctly.

When that method failed to offer the precise information needed for electrode placement, the investigators switched to neuroimaging, which allowed them to complete the surgery more quickly and accurately.

Participants remained in the hospital 1-2 days after surgery. They returned for postoperative imaging 30 days after surgery and were randomly assigned to different schedules for a 14-day titration period to optimize DBS stimulation.

The primary outcome was a 10% improvement on part B of the trail-making test, a neuropsychological test that measures executive functioning.

After 90 days of 12-hour daily DBS treatments, participants’ scores increased 15%–52% (average 32%) from baseline. Participants also reported an average of 33% decline in fatigue, one of the most common side effects of msTBI, and an average 80% improvement in attention.

The main safety risk during the 3- to-4-hour procedure is bleeding, which didn’t affect any of the participants in this study. One participant developed a surgical site infection, but all other side effects were mild.

After the 90-day treatment period, the study plan called for patients to be randomly assigned to a blinded withdrawal of treatment, with the DBS turned off for 21 days. Two of the patients declined to be randomized. DBS was turned off in one participant while the other two continued as normal.

After 3 weeks, the patient whose DBS was turned off showed a 34% decline on cognitive tests. The device was reactivated after the study and that participant has since reported improvements.

The DBS devices continue to function in all participants. Although their performance is not being measured as part of the study, anecdotal reports indicate sustained improvement in executive functioning.

“The brain injury causes this global down-regulation of brain function and what we think that this is doing is turning that back up again,” Dr. Henderson said. “At a very simplistic level, what we’re trying to do is turn the lights back up after the dimmer switch is switched down from the injury.”

New Hope

TBI patients are usually treated aggressively during the first year, when significant improvements are most likely, but there are few therapeutic options beyond that time, said neurologist Javier Cardenas, MD, who commented on the findings for this article.

“Many providers throw their hands up after a year in terms of intervention and then we’re always looking at potential declines over time,” said Dr. Cardenas, director of the Concussion and Brain Injury Center at the Rockefeller Neuroscience Institution, West Virginia University, Morgantown. “Most people plateau and don’t decline but we’re always worried about a secondary decline in traumatic brain injury.”Surgery is usually only employed immediately following the brain injury. The notion of surgery as a therapeutic option years after the initial assault on the brain is novel, said Jimmy Yang, MD, assistant professor of neurologic surgery at Ohio State University College of Medicine, Columbus, who commented on the findings for this article.

“While deep brain stimulation surgery in clinical practice is specifically tailored to each patient we treat, this study goes a step further by integrating research tools that have not yet made it to the clinical realm,” Dr. Yang said. “As a result, while these methods are not commonly used in clinical care, the overall strategy highlights how research advances are linked to clinical advances.”

Investigators are working to secure funding for a larger phase 2 trial.

“With millions of people affected by traumatic brain injury but without effective therapies, this study brings hope that options are on the horizon to help these patients,” Dr. Yang said.

The study was supported by funding from the National Institute of Health BRAIN Initiative and a grant from the Translational Science Center at Weill Cornell Medical College. Surgical implants were provided by Medtronic. Dr. Henderson and Dr. Schiff are listed as inventors on several patent applications for the experimental DBS therapy described in the study. Dr. Cardenas and Dr. Yang report no relevant financial relationships.

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

An experimental therapy that uses deep brain stimulation (DBS) to deliver precise electrical pulses to an area deep inside the brain restored executive function in patients with moderate to severe traumatic brain injury (msTBI) and chronic sequelae.

Participants in this first-in-humans trial experienced brain injuries between 3-18 years before the study that left them with persistent neuropsychological impairment and a range of functional disabilities.

This is the first time a DBS device has been implanted in the central thalamus in humans, an area of the brain measuring only a few millimeters wide that helps regulate consciousness.

Placing the electrodes required a novel surgical technique developed by the investigators that included virtual models of each participant’s brain, microelectrode recording, and neuroimaging to identify neuronal circuits affected by the TBI.

After 3 months of 12-hour daily DBS treatments, participants’ performance on cognitive tests improved by an average of 32% from baseline. Participants were able to read books, watch TV shows, play video games, complete schoolwork, and felt significantly less fatigued during the day.

Although the small trial only included five patients, the work is already being hailed by other experts as significant.“We were looking for partial restoration of executive attention and expected [the treatment] would have an effect, but I wouldn’t have anticipated the effect size we saw,” co-lead investigator Nicholas Schiff, MD, professor of neuroscience at Weill Cornell Medical College, New York City, said in an interview.

The findings were published online Dec. 4 in Nature Medicine.

“No Trivial Feat”

An estimated 5.3 million children and adults are living with a permanent TBI-related disability in the US today. There currently is no effective therapy for impaired attention, executive function, working memory or information-processing speed caused by the initial injury.

Previous research suggests that a loss of activity in key brain circuits in the thalamus may be associated with a loss of cognitive function.

The investigators recruited six adults (four men and two women) between the ages of 22 and 60 years with a history of msTBI and chronic neuropsychological impairment and functional disability. One participant was later withdrawn from the trial for protocol noncompliance.

Participants completed a range of questionnaires and tests to establish baseline cognitive, psychological, and quality-of-life status.

To restore lost executive functioning in the brain, investigators had to target not only the central lateral nucleus, but also the neuronal network connected to the region that reaches other parts of the brain.

“To do both of those things we had to develop a whole toolset in order to model both the target and trajectory, which had to be right to make it work properly,” co-lead investigator Jaimie Henderson, MD, professor of neurosurgery at Stanford University College of Medicine, Stanford, California, said in an interview. “That gave us a pretty narrow window in which to work and getting an electrode accurately to this target is not a trivial feat.”

“A Moving Target”

Each participant’s brain physiology was slightly different, meaning the path that worked for one individual might not work for another. The surgery was further complicated by shifting in the brain that occurred as individual electrodes were placed.

“It was a literal moving target,” Dr. Henderson said.

In the beginning, investigators used microelectrode recording to “listen” to individual neurons to see which ones weren’t firing correctly.

When that method failed to offer the precise information needed for electrode placement, the investigators switched to neuroimaging, which allowed them to complete the surgery more quickly and accurately.

Participants remained in the hospital 1-2 days after surgery. They returned for postoperative imaging 30 days after surgery and were randomly assigned to different schedules for a 14-day titration period to optimize DBS stimulation.

The primary outcome was a 10% improvement on part B of the trail-making test, a neuropsychological test that measures executive functioning.

After 90 days of 12-hour daily DBS treatments, participants’ scores increased 15%–52% (average 32%) from baseline. Participants also reported an average of 33% decline in fatigue, one of the most common side effects of msTBI, and an average 80% improvement in attention.

The main safety risk during the 3- to-4-hour procedure is bleeding, which didn’t affect any of the participants in this study. One participant developed a surgical site infection, but all other side effects were mild.

After the 90-day treatment period, the study plan called for patients to be randomly assigned to a blinded withdrawal of treatment, with the DBS turned off for 21 days. Two of the patients declined to be randomized. DBS was turned off in one participant while the other two continued as normal.

After 3 weeks, the patient whose DBS was turned off showed a 34% decline on cognitive tests. The device was reactivated after the study and that participant has since reported improvements.

The DBS devices continue to function in all participants. Although their performance is not being measured as part of the study, anecdotal reports indicate sustained improvement in executive functioning.

“The brain injury causes this global down-regulation of brain function and what we think that this is doing is turning that back up again,” Dr. Henderson said. “At a very simplistic level, what we’re trying to do is turn the lights back up after the dimmer switch is switched down from the injury.”

New Hope

TBI patients are usually treated aggressively during the first year, when significant improvements are most likely, but there are few therapeutic options beyond that time, said neurologist Javier Cardenas, MD, who commented on the findings for this article.

“Many providers throw their hands up after a year in terms of intervention and then we’re always looking at potential declines over time,” said Dr. Cardenas, director of the Concussion and Brain Injury Center at the Rockefeller Neuroscience Institution, West Virginia University, Morgantown. “Most people plateau and don’t decline but we’re always worried about a secondary decline in traumatic brain injury.”Surgery is usually only employed immediately following the brain injury. The notion of surgery as a therapeutic option years after the initial assault on the brain is novel, said Jimmy Yang, MD, assistant professor of neurologic surgery at Ohio State University College of Medicine, Columbus, who commented on the findings for this article.

“While deep brain stimulation surgery in clinical practice is specifically tailored to each patient we treat, this study goes a step further by integrating research tools that have not yet made it to the clinical realm,” Dr. Yang said. “As a result, while these methods are not commonly used in clinical care, the overall strategy highlights how research advances are linked to clinical advances.”

Investigators are working to secure funding for a larger phase 2 trial.

“With millions of people affected by traumatic brain injury but without effective therapies, this study brings hope that options are on the horizon to help these patients,” Dr. Yang said.

The study was supported by funding from the National Institute of Health BRAIN Initiative and a grant from the Translational Science Center at Weill Cornell Medical College. Surgical implants were provided by Medtronic. Dr. Henderson and Dr. Schiff are listed as inventors on several patent applications for the experimental DBS therapy described in the study. Dr. Cardenas and Dr. Yang report no relevant financial relationships.

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

An experimental therapy that uses deep brain stimulation (DBS) to deliver precise electrical pulses to an area deep inside the brain restored executive function in patients with moderate to severe traumatic brain injury (msTBI) and chronic sequelae.

Participants in this first-in-humans trial experienced brain injuries between 3-18 years before the study that left them with persistent neuropsychological impairment and a range of functional disabilities.

This is the first time a DBS device has been implanted in the central thalamus in humans, an area of the brain measuring only a few millimeters wide that helps regulate consciousness.

Placing the electrodes required a novel surgical technique developed by the investigators that included virtual models of each participant’s brain, microelectrode recording, and neuroimaging to identify neuronal circuits affected by the TBI.

After 3 months of 12-hour daily DBS treatments, participants’ performance on cognitive tests improved by an average of 32% from baseline. Participants were able to read books, watch TV shows, play video games, complete schoolwork, and felt significantly less fatigued during the day.

Although the small trial only included five patients, the work is already being hailed by other experts as significant.“We were looking for partial restoration of executive attention and expected [the treatment] would have an effect, but I wouldn’t have anticipated the effect size we saw,” co-lead investigator Nicholas Schiff, MD, professor of neuroscience at Weill Cornell Medical College, New York City, said in an interview.

The findings were published online Dec. 4 in Nature Medicine.

“No Trivial Feat”

An estimated 5.3 million children and adults are living with a permanent TBI-related disability in the US today. There currently is no effective therapy for impaired attention, executive function, working memory or information-processing speed caused by the initial injury.

Previous research suggests that a loss of activity in key brain circuits in the thalamus may be associated with a loss of cognitive function.

The investigators recruited six adults (four men and two women) between the ages of 22 and 60 years with a history of msTBI and chronic neuropsychological impairment and functional disability. One participant was later withdrawn from the trial for protocol noncompliance.

Participants completed a range of questionnaires and tests to establish baseline cognitive, psychological, and quality-of-life status.

To restore lost executive functioning in the brain, investigators had to target not only the central lateral nucleus, but also the neuronal network connected to the region that reaches other parts of the brain.

“To do both of those things we had to develop a whole toolset in order to model both the target and trajectory, which had to be right to make it work properly,” co-lead investigator Jaimie Henderson, MD, professor of neurosurgery at Stanford University College of Medicine, Stanford, California, said in an interview. “That gave us a pretty narrow window in which to work and getting an electrode accurately to this target is not a trivial feat.”

“A Moving Target”

Each participant’s brain physiology was slightly different, meaning the path that worked for one individual might not work for another. The surgery was further complicated by shifting in the brain that occurred as individual electrodes were placed.

“It was a literal moving target,” Dr. Henderson said.

In the beginning, investigators used microelectrode recording to “listen” to individual neurons to see which ones weren’t firing correctly.

When that method failed to offer the precise information needed for electrode placement, the investigators switched to neuroimaging, which allowed them to complete the surgery more quickly and accurately.

Participants remained in the hospital 1-2 days after surgery. They returned for postoperative imaging 30 days after surgery and were randomly assigned to different schedules for a 14-day titration period to optimize DBS stimulation.

The primary outcome was a 10% improvement on part B of the trail-making test, a neuropsychological test that measures executive functioning.

After 90 days of 12-hour daily DBS treatments, participants’ scores increased 15%–52% (average 32%) from baseline. Participants also reported an average of 33% decline in fatigue, one of the most common side effects of msTBI, and an average 80% improvement in attention.

The main safety risk during the 3- to-4-hour procedure is bleeding, which didn’t affect any of the participants in this study. One participant developed a surgical site infection, but all other side effects were mild.

After the 90-day treatment period, the study plan called for patients to be randomly assigned to a blinded withdrawal of treatment, with the DBS turned off for 21 days. Two of the patients declined to be randomized. DBS was turned off in one participant while the other two continued as normal.

After 3 weeks, the patient whose DBS was turned off showed a 34% decline on cognitive tests. The device was reactivated after the study and that participant has since reported improvements.

The DBS devices continue to function in all participants. Although their performance is not being measured as part of the study, anecdotal reports indicate sustained improvement in executive functioning.

“The brain injury causes this global down-regulation of brain function and what we think that this is doing is turning that back up again,” Dr. Henderson said. “At a very simplistic level, what we’re trying to do is turn the lights back up after the dimmer switch is switched down from the injury.”

New Hope

TBI patients are usually treated aggressively during the first year, when significant improvements are most likely, but there are few therapeutic options beyond that time, said neurologist Javier Cardenas, MD, who commented on the findings for this article.

“Many providers throw their hands up after a year in terms of intervention and then we’re always looking at potential declines over time,” said Dr. Cardenas, director of the Concussion and Brain Injury Center at the Rockefeller Neuroscience Institution, West Virginia University, Morgantown. “Most people plateau and don’t decline but we’re always worried about a secondary decline in traumatic brain injury.”Surgery is usually only employed immediately following the brain injury. The notion of surgery as a therapeutic option years after the initial assault on the brain is novel, said Jimmy Yang, MD, assistant professor of neurologic surgery at Ohio State University College of Medicine, Columbus, who commented on the findings for this article.

“While deep brain stimulation surgery in clinical practice is specifically tailored to each patient we treat, this study goes a step further by integrating research tools that have not yet made it to the clinical realm,” Dr. Yang said. “As a result, while these methods are not commonly used in clinical care, the overall strategy highlights how research advances are linked to clinical advances.”

Investigators are working to secure funding for a larger phase 2 trial.

“With millions of people affected by traumatic brain injury but without effective therapies, this study brings hope that options are on the horizon to help these patients,” Dr. Yang said.

The study was supported by funding from the National Institute of Health BRAIN Initiative and a grant from the Translational Science Center at Weill Cornell Medical College. Surgical implants were provided by Medtronic. Dr. Henderson and Dr. Schiff are listed as inventors on several patent applications for the experimental DBS therapy described in the study. Dr. Cardenas and Dr. Yang report no relevant financial relationships.

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