‘Shockingly High’ Rate of TBI in Older Adults

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Fri, 06/14/2024 - 13:06

 

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.

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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.

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In the Future, a Robot Intensivist May Save Your Life

Article Type
Changed
Tue, 06/04/2024 - 11:05

 

This transcript has been edited for clarity

They call it the “golden hour”: 60 minutes, give or take, when the chance to save the life of a trauma victim is at its greatest. If the patient can be resuscitated and stabilized in that time window, they stand a good chance of surviving. If not, well, they don’t.

But resuscitation is complicated. It requires blood products, fluids, vasopressors — all given in precise doses in response to rapidly changing hemodynamics. To do it right takes specialized training, advanced life support (ALS). If the patient is in a remote area or an area without ALS-certified emergency medical services, or is far from the nearest trauma center, that golden hour is lost. And the patient may be as well.

But we live in the future. We have robots in factories, self-driving cars, autonomous drones. Why not an autonomous trauma doctor? If you are in a life-threatening accident, would you want to be treated ... by a robot?

Enter “resuscitation based on functional hemodynamic monitoring,” or “ReFit,” introduced in this article appearing in the journal Intensive Care Medicine Experimental.

The idea behind ReFit is straightforward. Resuscitation after trauma should be based on hitting key hemodynamic targets using the tools we have available in the field: blood, fluids, pressors. The researchers wanted to develop a closed-loop system, something that could be used by minimally trained personnel. The input to the system? Hemodynamic data, provided through a single measurement device, an arterial catheter. The output: blood, fluids, and pressors, delivered intravenously.

The body (a prototype) of the system looks like this. You can see various pumps labeled with various fluids, electronic controllers, and so forth.

Nate Langer, UPMC


If that’s the body, then this is the brain – a ruggedized laptop interpreting a readout of that arterial catheter.

Nate Langer, UPMC


If that’s the brain, then the ReFit algorithm is the mind. The algorithm does its best to leverage all the data it can, so I want to walk through it in a bit of detail.

Nate Langer, UPMC


First, check to see whether the patient is stable, defined as a heart rate < 110 beats/min and a mean arterial pressure > 60 mm Hg. If not, you’re off to the races, starting with a bolus of whole blood.

Next, the algorithm gets really interesting. If the patient is still unstable, the computer assesses fluid responsiveness by giving a test dose of fluid and measuring the pulse pressure variation. Greater pulse pressure variation means more fluid responsiveness and the algorithm gives more fluid. Less pulse pressure variation leads the algorithm to uptitrate pressors — in this case, norepinephrine.

This cycle of evaluation and response keeps repeating. The computer titrates fluids and pressors up and down entirely on its own, in theory freeing the human team members to do other things, like getting the patient to a trauma center for definitive care.

So, how do you test whether something like this works? Clearly, you don’t want the trial run of a system like this to be used on a real human suffering from a real traumatic injury. 

Once again, we have animals to thank for research advances — in this case, pigs. Fifteen pigs are described in the study. To simulate a severe, hemorrhagic trauma, they were anesthetized and the liver was lacerated. They were then observed passively until the mean arterial pressure had dropped to below 40 mm Hg.

This is a pretty severe injury. Three unfortunate animals served as controls, two of which died within the 3-hour time window of the study. Eight animals were plugged into the ReFit system. 

For a window into what happens during this process, let’s take a look at the mean arterial pressure and heart rate readouts for one of the animals. You see that the blood pressure starts to fall precipitously after the liver laceration. The heart rate quickly picks up to compensate, raising the mean arterial pressure a bit, but this would be unsustainable with ongoing bleeding.

Intensive Care Medicine Experimental


Here, the ReFit system takes over. Autonomously, the system administers two units of blood, followed by fluids, and then norepinephrine or further fluids per the protocol I described earlier. 

Intensive Care Medicine Experimental


The practical upshot of all of this is stabilization, despite an as-yet untreated liver laceration. 

Could an experienced ALS provider do this? Of course. But, as I mentioned before, you aren’t always near an experienced ALS provider.

This is all well and good in the lab, but in the real world, you actually need to transport a trauma patient. The researchers tried this also. To prove feasibility, four pigs were taken from the lab to the top of the University of Pittsburgh Medical Center, flown to Allegheny County Airport and back. Total time before liver laceration repair? Three hours. And all four survived. 

It won’t surprise you to hear that this work was funded by the Department of Defense. You can see how a system like this, made a bit more rugged, a bit smaller, and a bit more self-contained could have real uses in the battlefield. But trauma is not unique to war, and something that can extend the time you have to safely transport a patient to definitive care — well, that’s worth its weight in golden hours. 
 

Dr. Wilson is associate professor of medicine and public health and director of the Clinical and Translational Research Accelerator at Yale University, New Haven, Connecticut. He has disclosed no relevant financial relationships.

A version of this article appeared on Medscape.com.

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This transcript has been edited for clarity

They call it the “golden hour”: 60 minutes, give or take, when the chance to save the life of a trauma victim is at its greatest. If the patient can be resuscitated and stabilized in that time window, they stand a good chance of surviving. If not, well, they don’t.

But resuscitation is complicated. It requires blood products, fluids, vasopressors — all given in precise doses in response to rapidly changing hemodynamics. To do it right takes specialized training, advanced life support (ALS). If the patient is in a remote area or an area without ALS-certified emergency medical services, or is far from the nearest trauma center, that golden hour is lost. And the patient may be as well.

But we live in the future. We have robots in factories, self-driving cars, autonomous drones. Why not an autonomous trauma doctor? If you are in a life-threatening accident, would you want to be treated ... by a robot?

Enter “resuscitation based on functional hemodynamic monitoring,” or “ReFit,” introduced in this article appearing in the journal Intensive Care Medicine Experimental.

The idea behind ReFit is straightforward. Resuscitation after trauma should be based on hitting key hemodynamic targets using the tools we have available in the field: blood, fluids, pressors. The researchers wanted to develop a closed-loop system, something that could be used by minimally trained personnel. The input to the system? Hemodynamic data, provided through a single measurement device, an arterial catheter. The output: blood, fluids, and pressors, delivered intravenously.

The body (a prototype) of the system looks like this. You can see various pumps labeled with various fluids, electronic controllers, and so forth.

Nate Langer, UPMC


If that’s the body, then this is the brain – a ruggedized laptop interpreting a readout of that arterial catheter.

Nate Langer, UPMC


If that’s the brain, then the ReFit algorithm is the mind. The algorithm does its best to leverage all the data it can, so I want to walk through it in a bit of detail.

Nate Langer, UPMC


First, check to see whether the patient is stable, defined as a heart rate < 110 beats/min and a mean arterial pressure > 60 mm Hg. If not, you’re off to the races, starting with a bolus of whole blood.

Next, the algorithm gets really interesting. If the patient is still unstable, the computer assesses fluid responsiveness by giving a test dose of fluid and measuring the pulse pressure variation. Greater pulse pressure variation means more fluid responsiveness and the algorithm gives more fluid. Less pulse pressure variation leads the algorithm to uptitrate pressors — in this case, norepinephrine.

This cycle of evaluation and response keeps repeating. The computer titrates fluids and pressors up and down entirely on its own, in theory freeing the human team members to do other things, like getting the patient to a trauma center for definitive care.

So, how do you test whether something like this works? Clearly, you don’t want the trial run of a system like this to be used on a real human suffering from a real traumatic injury. 

Once again, we have animals to thank for research advances — in this case, pigs. Fifteen pigs are described in the study. To simulate a severe, hemorrhagic trauma, they were anesthetized and the liver was lacerated. They were then observed passively until the mean arterial pressure had dropped to below 40 mm Hg.

This is a pretty severe injury. Three unfortunate animals served as controls, two of which died within the 3-hour time window of the study. Eight animals were plugged into the ReFit system. 

For a window into what happens during this process, let’s take a look at the mean arterial pressure and heart rate readouts for one of the animals. You see that the blood pressure starts to fall precipitously after the liver laceration. The heart rate quickly picks up to compensate, raising the mean arterial pressure a bit, but this would be unsustainable with ongoing bleeding.

Intensive Care Medicine Experimental


Here, the ReFit system takes over. Autonomously, the system administers two units of blood, followed by fluids, and then norepinephrine or further fluids per the protocol I described earlier. 

Intensive Care Medicine Experimental


The practical upshot of all of this is stabilization, despite an as-yet untreated liver laceration. 

Could an experienced ALS provider do this? Of course. But, as I mentioned before, you aren’t always near an experienced ALS provider.

This is all well and good in the lab, but in the real world, you actually need to transport a trauma patient. The researchers tried this also. To prove feasibility, four pigs were taken from the lab to the top of the University of Pittsburgh Medical Center, flown to Allegheny County Airport and back. Total time before liver laceration repair? Three hours. And all four survived. 

It won’t surprise you to hear that this work was funded by the Department of Defense. You can see how a system like this, made a bit more rugged, a bit smaller, and a bit more self-contained could have real uses in the battlefield. But trauma is not unique to war, and something that can extend the time you have to safely transport a patient to definitive care — well, that’s worth its weight in golden hours. 
 

Dr. Wilson is associate professor of medicine and public health and director of the Clinical and Translational Research Accelerator at Yale University, New Haven, Connecticut. He has disclosed no relevant financial relationships.

A version of this article appeared on Medscape.com.

 

This transcript has been edited for clarity

They call it the “golden hour”: 60 minutes, give or take, when the chance to save the life of a trauma victim is at its greatest. If the patient can be resuscitated and stabilized in that time window, they stand a good chance of surviving. If not, well, they don’t.

But resuscitation is complicated. It requires blood products, fluids, vasopressors — all given in precise doses in response to rapidly changing hemodynamics. To do it right takes specialized training, advanced life support (ALS). If the patient is in a remote area or an area without ALS-certified emergency medical services, or is far from the nearest trauma center, that golden hour is lost. And the patient may be as well.

But we live in the future. We have robots in factories, self-driving cars, autonomous drones. Why not an autonomous trauma doctor? If you are in a life-threatening accident, would you want to be treated ... by a robot?

Enter “resuscitation based on functional hemodynamic monitoring,” or “ReFit,” introduced in this article appearing in the journal Intensive Care Medicine Experimental.

The idea behind ReFit is straightforward. Resuscitation after trauma should be based on hitting key hemodynamic targets using the tools we have available in the field: blood, fluids, pressors. The researchers wanted to develop a closed-loop system, something that could be used by minimally trained personnel. The input to the system? Hemodynamic data, provided through a single measurement device, an arterial catheter. The output: blood, fluids, and pressors, delivered intravenously.

The body (a prototype) of the system looks like this. You can see various pumps labeled with various fluids, electronic controllers, and so forth.

Nate Langer, UPMC


If that’s the body, then this is the brain – a ruggedized laptop interpreting a readout of that arterial catheter.

Nate Langer, UPMC


If that’s the brain, then the ReFit algorithm is the mind. The algorithm does its best to leverage all the data it can, so I want to walk through it in a bit of detail.

Nate Langer, UPMC


First, check to see whether the patient is stable, defined as a heart rate < 110 beats/min and a mean arterial pressure > 60 mm Hg. If not, you’re off to the races, starting with a bolus of whole blood.

Next, the algorithm gets really interesting. If the patient is still unstable, the computer assesses fluid responsiveness by giving a test dose of fluid and measuring the pulse pressure variation. Greater pulse pressure variation means more fluid responsiveness and the algorithm gives more fluid. Less pulse pressure variation leads the algorithm to uptitrate pressors — in this case, norepinephrine.

This cycle of evaluation and response keeps repeating. The computer titrates fluids and pressors up and down entirely on its own, in theory freeing the human team members to do other things, like getting the patient to a trauma center for definitive care.

So, how do you test whether something like this works? Clearly, you don’t want the trial run of a system like this to be used on a real human suffering from a real traumatic injury. 

Once again, we have animals to thank for research advances — in this case, pigs. Fifteen pigs are described in the study. To simulate a severe, hemorrhagic trauma, they were anesthetized and the liver was lacerated. They were then observed passively until the mean arterial pressure had dropped to below 40 mm Hg.

This is a pretty severe injury. Three unfortunate animals served as controls, two of which died within the 3-hour time window of the study. Eight animals were plugged into the ReFit system. 

For a window into what happens during this process, let’s take a look at the mean arterial pressure and heart rate readouts for one of the animals. You see that the blood pressure starts to fall precipitously after the liver laceration. The heart rate quickly picks up to compensate, raising the mean arterial pressure a bit, but this would be unsustainable with ongoing bleeding.

Intensive Care Medicine Experimental


Here, the ReFit system takes over. Autonomously, the system administers two units of blood, followed by fluids, and then norepinephrine or further fluids per the protocol I described earlier. 

Intensive Care Medicine Experimental


The practical upshot of all of this is stabilization, despite an as-yet untreated liver laceration. 

Could an experienced ALS provider do this? Of course. But, as I mentioned before, you aren’t always near an experienced ALS provider.

This is all well and good in the lab, but in the real world, you actually need to transport a trauma patient. The researchers tried this also. To prove feasibility, four pigs were taken from the lab to the top of the University of Pittsburgh Medical Center, flown to Allegheny County Airport and back. Total time before liver laceration repair? Three hours. And all four survived. 

It won’t surprise you to hear that this work was funded by the Department of Defense. You can see how a system like this, made a bit more rugged, a bit smaller, and a bit more self-contained could have real uses in the battlefield. But trauma is not unique to war, and something that can extend the time you have to safely transport a patient to definitive care — well, that’s worth its weight in golden hours. 
 

Dr. Wilson is associate professor of medicine and public health and director of the Clinical and Translational Research Accelerator at Yale University, New Haven, Connecticut. He has disclosed no relevant financial relationships.

A version of this article appeared on Medscape.com.

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Attacks on Emergency Room Workers Prompt Debate Over Tougher Penalties

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Changed
Mon, 04/08/2024 - 09:55

Patients hurl verbal abuse at Michelle Ravera every day in the emergency room. Physical violence is less common, she said, but has become a growing threat.

Ravera, an ER nurse at Sutter Medical Center in Sacramento, recalled an incident in which an agitated patient wanted to leave. “Without any warning he just reached up, grabbed my glasses, and punched me in the face,” said Ravera, 54. “And then he was getting ready to attack another patient in the room.” Ravera and hospital security guards subdued the patient so he couldn’t hurt anyone else.

Violence against health care workers is on the rise, including in the ER, where tensions can run high as staff juggle multiple urgent tasks. Covid-19 only made things worse: With routine care harder to come by, many patients ended up in the ER with serious diseases — and brimming with frustrations.

In California, simple assault against workers inside an ER is considered the same as simple assault against almost anyone else, and carries a maximum punishment of a $1,000 fine and six months in jail. In contrast, simple assault against emergency medical workers in the field, such as an EMT responding to a 911 call, carries maximum penalties of a $2,000 fine and a year in jail. Simple assault does not involve the use of a deadly weapon or the intention to inflict serious bodily injury.

State Assembly member Freddie Rodriguez, who worked as an EMT, has authored a bill to make the punishments consistent: a $2,000 fine and one year in jail for simple assault on any on-the-job emergency health care worker, whether in the field or an ER. The measure would also eliminate the discrepancy for simple battery.

Patients and family members are assaulting staff and “doing things they shouldn’t be doing to the people that are there to take care of your loved ones,” said Rodriguez, a Democrat from Pomona. The bill passed the state Assembly unanimously in January and awaits consideration in the Senate.

Rodriguez has introduced similar measures twice before. Then-Gov. Jerry Brown vetoed one in 2015, saying he doubted a longer jail sentence would deter violence. “We need to find more creative ways to protect the safety of these critical workers,” he wrote in his veto message. The 2019 bill died in the state Senate.

Rodriguez said ERs have become more dangerous for health care workers since then and that “there has to be accountability” for violent behavior. Opponents fear stiffer penalties would be levied disproportionately on patients of color or those with developmental disabilities. They also point out that violent patients can already face penalties under existing assault and battery laws.

Data from the California Division of Occupational Safety and Health shows that reported attacks on ER workers by patients, visitors, and strangers jumped about 25% from 2018 to 2023, from 2,587 to 3,238. The rate of attacks per 100,000 ER visits also increased.

Punching, kicking, pushing, and similar aggression accounted for most of the attacks. Only a small number included weapons.

These numbers are likely an undercount, said Al’ai Alvarez, an ER doctor and clinical associate professor at Stanford University’s Department of Emergency Medicine. Many hospital staffers don’t fill out workplace violence reports because they don’t have time or feel nothing will come of it, he said.

Ravera remembers when her community rallied around health care workers at the start of the pandemic, acting respectfully and bringing food and extra N95 masks to workers.

“Then something just switched,” she said. “The patients became angrier and more aggressive.”

Violence can contribute to burnout and drive workers to quit — or worse, said Alvarez, who has lost colleagues to suicide, and thinks burnout was a key factor. “The cost of burnout is more than just loss of productivity,” he said. “It’s loss of human beings that also had the potential to take care of many more people.”

The National Center for Health Workforce Analysis projects California will experience an 18% shortage of all types of nurses in 2035, the third worst in the country.

Federal legislation called the Safety From Violence for Healthcare Employees Act would set sentences of up to 10 years for assault against a health care worker, not limited to emergency workers, and up to 20 years in cases involving dangerous weapons or bodily injury. Though it was introduced in 2023, it has not yet had a committee hearing.

Opponents of the California bill, which include ACLU California Action, the California Public Defenders Association, and advocates for people with autism, argue it wouldn’t deter attacks — and would unfairly target certain patients.

“There’s no evidence to suggest that increased penalties are going to meaningfully address this conduct,” said Eric Henderson, a legislative advocate for ACLU California Action. “Most importantly, there are already laws on the books to address assaultive conduct.”

Beth Burt, executive director of the Autism Society Inland Empire, said the measure doesn’t take into account the special needs of people with autism and other developmental disorders.

The smells, lights, textures, and crowds in the ER can overstimulate a person with autism, she said. When that happens, they can struggle to articulate their feelings, which can result in a violent outburst, “whether it’s a 9-year-old or a 29-year-old,” Burt said.

She worries that hospital staff may misunderstand these reactions, and involve law enforcement when it’s not necessary. As “a parent, it is still my worst fear” that she’ll get a phone call to inform her that her adult son with autism has been arrested, she said.

Burt would rather the state prioritize de-escalation programs over penalties, such as the training programs for first responders she helped create through the Autism Society Inland Empire. After implementing the training, hospital administrators asked Burt to share some strategies with them, she said. Hospital security staffers who do not want to use physical restraints on autistic patients have also sought her advice, she said.

Supporters of the bill, including health care and law enforcement groups, counter that people with mental health conditions or autism who are charged with assault in an ER may be eligible for existing programs that provide mental health treatment in lieu of a criminal sentence.

Stephanie Jensen, an ER nurse and head of governmental affairs for the Emergency Nurses Association, California State Council, said her organization is simply arguing for equity. “If you punch me in the hospital, it’s the same as if you punch me on the street,” she said.

If lawmakers don’t act, she warned, there won’t be enough workers for the patients who need them.

“It’s hard to keep those human resources accessible when it just seems like you’re showing up to get beat up every day,” Jensen said. “The emergency department is taking it on the chin, literally and figuratively.”

This article was produced by KFF Health News, which publishes California Healthline, an editorially independent service of the California Health Care Foundation. KFF Health News is a national newsroom that produces in-depth journalism about health issues and is one of the core operating programs at KFF—an independent source of health policy research, polling, and journalism. Learn more about KFF.

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Patients hurl verbal abuse at Michelle Ravera every day in the emergency room. Physical violence is less common, she said, but has become a growing threat.

Ravera, an ER nurse at Sutter Medical Center in Sacramento, recalled an incident in which an agitated patient wanted to leave. “Without any warning he just reached up, grabbed my glasses, and punched me in the face,” said Ravera, 54. “And then he was getting ready to attack another patient in the room.” Ravera and hospital security guards subdued the patient so he couldn’t hurt anyone else.

Violence against health care workers is on the rise, including in the ER, where tensions can run high as staff juggle multiple urgent tasks. Covid-19 only made things worse: With routine care harder to come by, many patients ended up in the ER with serious diseases — and brimming with frustrations.

In California, simple assault against workers inside an ER is considered the same as simple assault against almost anyone else, and carries a maximum punishment of a $1,000 fine and six months in jail. In contrast, simple assault against emergency medical workers in the field, such as an EMT responding to a 911 call, carries maximum penalties of a $2,000 fine and a year in jail. Simple assault does not involve the use of a deadly weapon or the intention to inflict serious bodily injury.

State Assembly member Freddie Rodriguez, who worked as an EMT, has authored a bill to make the punishments consistent: a $2,000 fine and one year in jail for simple assault on any on-the-job emergency health care worker, whether in the field or an ER. The measure would also eliminate the discrepancy for simple battery.

Patients and family members are assaulting staff and “doing things they shouldn’t be doing to the people that are there to take care of your loved ones,” said Rodriguez, a Democrat from Pomona. The bill passed the state Assembly unanimously in January and awaits consideration in the Senate.

Rodriguez has introduced similar measures twice before. Then-Gov. Jerry Brown vetoed one in 2015, saying he doubted a longer jail sentence would deter violence. “We need to find more creative ways to protect the safety of these critical workers,” he wrote in his veto message. The 2019 bill died in the state Senate.

Rodriguez said ERs have become more dangerous for health care workers since then and that “there has to be accountability” for violent behavior. Opponents fear stiffer penalties would be levied disproportionately on patients of color or those with developmental disabilities. They also point out that violent patients can already face penalties under existing assault and battery laws.

Data from the California Division of Occupational Safety and Health shows that reported attacks on ER workers by patients, visitors, and strangers jumped about 25% from 2018 to 2023, from 2,587 to 3,238. The rate of attacks per 100,000 ER visits also increased.

Punching, kicking, pushing, and similar aggression accounted for most of the attacks. Only a small number included weapons.

These numbers are likely an undercount, said Al’ai Alvarez, an ER doctor and clinical associate professor at Stanford University’s Department of Emergency Medicine. Many hospital staffers don’t fill out workplace violence reports because they don’t have time or feel nothing will come of it, he said.

Ravera remembers when her community rallied around health care workers at the start of the pandemic, acting respectfully and bringing food and extra N95 masks to workers.

“Then something just switched,” she said. “The patients became angrier and more aggressive.”

Violence can contribute to burnout and drive workers to quit — or worse, said Alvarez, who has lost colleagues to suicide, and thinks burnout was a key factor. “The cost of burnout is more than just loss of productivity,” he said. “It’s loss of human beings that also had the potential to take care of many more people.”

The National Center for Health Workforce Analysis projects California will experience an 18% shortage of all types of nurses in 2035, the third worst in the country.

Federal legislation called the Safety From Violence for Healthcare Employees Act would set sentences of up to 10 years for assault against a health care worker, not limited to emergency workers, and up to 20 years in cases involving dangerous weapons or bodily injury. Though it was introduced in 2023, it has not yet had a committee hearing.

Opponents of the California bill, which include ACLU California Action, the California Public Defenders Association, and advocates for people with autism, argue it wouldn’t deter attacks — and would unfairly target certain patients.

“There’s no evidence to suggest that increased penalties are going to meaningfully address this conduct,” said Eric Henderson, a legislative advocate for ACLU California Action. “Most importantly, there are already laws on the books to address assaultive conduct.”

Beth Burt, executive director of the Autism Society Inland Empire, said the measure doesn’t take into account the special needs of people with autism and other developmental disorders.

The smells, lights, textures, and crowds in the ER can overstimulate a person with autism, she said. When that happens, they can struggle to articulate their feelings, which can result in a violent outburst, “whether it’s a 9-year-old or a 29-year-old,” Burt said.

She worries that hospital staff may misunderstand these reactions, and involve law enforcement when it’s not necessary. As “a parent, it is still my worst fear” that she’ll get a phone call to inform her that her adult son with autism has been arrested, she said.

Burt would rather the state prioritize de-escalation programs over penalties, such as the training programs for first responders she helped create through the Autism Society Inland Empire. After implementing the training, hospital administrators asked Burt to share some strategies with them, she said. Hospital security staffers who do not want to use physical restraints on autistic patients have also sought her advice, she said.

Supporters of the bill, including health care and law enforcement groups, counter that people with mental health conditions or autism who are charged with assault in an ER may be eligible for existing programs that provide mental health treatment in lieu of a criminal sentence.

Stephanie Jensen, an ER nurse and head of governmental affairs for the Emergency Nurses Association, California State Council, said her organization is simply arguing for equity. “If you punch me in the hospital, it’s the same as if you punch me on the street,” she said.

If lawmakers don’t act, she warned, there won’t be enough workers for the patients who need them.

“It’s hard to keep those human resources accessible when it just seems like you’re showing up to get beat up every day,” Jensen said. “The emergency department is taking it on the chin, literally and figuratively.”

This article was produced by KFF Health News, which publishes California Healthline, an editorially independent service of the California Health Care Foundation. KFF Health News is a national newsroom that produces in-depth journalism about health issues and is one of the core operating programs at KFF—an independent source of health policy research, polling, and journalism. Learn more about KFF.

Patients hurl verbal abuse at Michelle Ravera every day in the emergency room. Physical violence is less common, she said, but has become a growing threat.

Ravera, an ER nurse at Sutter Medical Center in Sacramento, recalled an incident in which an agitated patient wanted to leave. “Without any warning he just reached up, grabbed my glasses, and punched me in the face,” said Ravera, 54. “And then he was getting ready to attack another patient in the room.” Ravera and hospital security guards subdued the patient so he couldn’t hurt anyone else.

Violence against health care workers is on the rise, including in the ER, where tensions can run high as staff juggle multiple urgent tasks. Covid-19 only made things worse: With routine care harder to come by, many patients ended up in the ER with serious diseases — and brimming with frustrations.

In California, simple assault against workers inside an ER is considered the same as simple assault against almost anyone else, and carries a maximum punishment of a $1,000 fine and six months in jail. In contrast, simple assault against emergency medical workers in the field, such as an EMT responding to a 911 call, carries maximum penalties of a $2,000 fine and a year in jail. Simple assault does not involve the use of a deadly weapon or the intention to inflict serious bodily injury.

State Assembly member Freddie Rodriguez, who worked as an EMT, has authored a bill to make the punishments consistent: a $2,000 fine and one year in jail for simple assault on any on-the-job emergency health care worker, whether in the field or an ER. The measure would also eliminate the discrepancy for simple battery.

Patients and family members are assaulting staff and “doing things they shouldn’t be doing to the people that are there to take care of your loved ones,” said Rodriguez, a Democrat from Pomona. The bill passed the state Assembly unanimously in January and awaits consideration in the Senate.

Rodriguez has introduced similar measures twice before. Then-Gov. Jerry Brown vetoed one in 2015, saying he doubted a longer jail sentence would deter violence. “We need to find more creative ways to protect the safety of these critical workers,” he wrote in his veto message. The 2019 bill died in the state Senate.

Rodriguez said ERs have become more dangerous for health care workers since then and that “there has to be accountability” for violent behavior. Opponents fear stiffer penalties would be levied disproportionately on patients of color or those with developmental disabilities. They also point out that violent patients can already face penalties under existing assault and battery laws.

Data from the California Division of Occupational Safety and Health shows that reported attacks on ER workers by patients, visitors, and strangers jumped about 25% from 2018 to 2023, from 2,587 to 3,238. The rate of attacks per 100,000 ER visits also increased.

Punching, kicking, pushing, and similar aggression accounted for most of the attacks. Only a small number included weapons.

These numbers are likely an undercount, said Al’ai Alvarez, an ER doctor and clinical associate professor at Stanford University’s Department of Emergency Medicine. Many hospital staffers don’t fill out workplace violence reports because they don’t have time or feel nothing will come of it, he said.

Ravera remembers when her community rallied around health care workers at the start of the pandemic, acting respectfully and bringing food and extra N95 masks to workers.

“Then something just switched,” she said. “The patients became angrier and more aggressive.”

Violence can contribute to burnout and drive workers to quit — or worse, said Alvarez, who has lost colleagues to suicide, and thinks burnout was a key factor. “The cost of burnout is more than just loss of productivity,” he said. “It’s loss of human beings that also had the potential to take care of many more people.”

The National Center for Health Workforce Analysis projects California will experience an 18% shortage of all types of nurses in 2035, the third worst in the country.

Federal legislation called the Safety From Violence for Healthcare Employees Act would set sentences of up to 10 years for assault against a health care worker, not limited to emergency workers, and up to 20 years in cases involving dangerous weapons or bodily injury. Though it was introduced in 2023, it has not yet had a committee hearing.

Opponents of the California bill, which include ACLU California Action, the California Public Defenders Association, and advocates for people with autism, argue it wouldn’t deter attacks — and would unfairly target certain patients.

“There’s no evidence to suggest that increased penalties are going to meaningfully address this conduct,” said Eric Henderson, a legislative advocate for ACLU California Action. “Most importantly, there are already laws on the books to address assaultive conduct.”

Beth Burt, executive director of the Autism Society Inland Empire, said the measure doesn’t take into account the special needs of people with autism and other developmental disorders.

The smells, lights, textures, and crowds in the ER can overstimulate a person with autism, she said. When that happens, they can struggle to articulate their feelings, which can result in a violent outburst, “whether it’s a 9-year-old or a 29-year-old,” Burt said.

She worries that hospital staff may misunderstand these reactions, and involve law enforcement when it’s not necessary. As “a parent, it is still my worst fear” that she’ll get a phone call to inform her that her adult son with autism has been arrested, she said.

Burt would rather the state prioritize de-escalation programs over penalties, such as the training programs for first responders she helped create through the Autism Society Inland Empire. After implementing the training, hospital administrators asked Burt to share some strategies with them, she said. Hospital security staffers who do not want to use physical restraints on autistic patients have also sought her advice, she said.

Supporters of the bill, including health care and law enforcement groups, counter that people with mental health conditions or autism who are charged with assault in an ER may be eligible for existing programs that provide mental health treatment in lieu of a criminal sentence.

Stephanie Jensen, an ER nurse and head of governmental affairs for the Emergency Nurses Association, California State Council, said her organization is simply arguing for equity. “If you punch me in the hospital, it’s the same as if you punch me on the street,” she said.

If lawmakers don’t act, she warned, there won’t be enough workers for the patients who need them.

“It’s hard to keep those human resources accessible when it just seems like you’re showing up to get beat up every day,” Jensen said. “The emergency department is taking it on the chin, literally and figuratively.”

This article was produced by KFF Health News, which publishes California Healthline, an editorially independent service of the California Health Care Foundation. KFF Health News is a national newsroom that produces in-depth journalism about health issues and is one of the core operating programs at KFF—an independent source of health policy research, polling, and journalism. Learn more about KFF.

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Can a Stroke Be Caused by Cervical Manipulation?

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Changed
Mon, 03/25/2024 - 15:48

Cervical manipulations have been associated with vascular complications. While the incidence of carotid dissections does not seem to have increased, the question remains open for vertebral artery injuries. We must remain vigilant!

Resorting to joint manipulation for neck pain is not unusual. Currently, cervical manipulation remains a popular first-line treatment for cervicodynia or headaches. Although evidence exists showing that specific joint mobilization can improve this type of symptomatology, there is a possibility that it may risk damaging the cervical arteries and causing ischemic stroke through arterial dissection.

Epidemiologically, internal carotid artery dissection is a relatively rare event with an estimated annual incidence of 1.72 per 100,000 individuals (those most likely to be diagnosed being obviously those leading to hospitalization for stroke) but represents one of the most common causes of stroke in young and middle-aged adults. Faced with case reports that may raise concerns and hypotheses about an associated risk, two studies have sought to delve into the issue.
 

No Increased Carotid Risk Identified

The first study, of a case-cross design, identified all incident cases of ischemic stroke in the territory of the internal carotid artery admitted to the hospital over a 9-year period using administrative healthcare data, the cases being used as their own control by sampling control periods before the date of the index stroke. Thus, 15,523 cases were compared with 62,092 control periods using exposure windows of 1, 3, 7, and 14 days before the stroke. The study also compared post-medical consultation and post-chiropractic consultation outcomes, knowing that as a first-line for complaints of neck pain or headache, patients often turn to one of these two types of primary care clinicians.

However, data analysis shows, among subjects aged under 45 years, positive associations for both different consultations in cases of subsequent carotid stroke (but no association for those aged over 45 years). These associations tended to increase when analyses were limited to visits for diagnoses of neck pain and headaches. Nevertheless, there was no significant difference between risk estimates after chiropractic or general medical consultation.

A notable limitation of this work is that it did not focus on strokes due to vertebral artery dissections that run through the transverse foramina of the cervical vertebrae.
 

A Screening Test Lacking Precision

More recently, the International Federation of Orthopedic Manual Physical Therapists has looked into the subject to refine the assessment of the risk for vascular complications in patients seeking physiotherapy/osteopathy care for neck pain and/or headaches. Through a cross-sectional study involving 150 patients, it tested a vascular complication risk index (from high to low grade, based on history taking and clinical examination), developed to estimate the risk for the presence of vascular rather than musculoskeletal pathology, to determine whether or not there is a contraindication to cervical manipulation.

However, the developed index had only low sensitivity (0.50; 95% CI, 0.39-0.61) and moderate specificity (0.63; 95% CI, 0.51-0.75), knowing that the reference test was a consensus medical decision made by a vascular neurologist, an interventional neurologist, and a neuroradiologist (based on clinical data and cervical MRI). Similarly, positive and negative likelihood ratios were low at 1.36 (95% CI, 0.93-1.99) and 0.79 (95% CI, 0.60-1.05), respectively.

In conclusion, the data from the case-cross study did not seem to demonstrate an excess risk for stroke in the territory of the internal carotid artery after cervical joint manipulations. Associations between cervical manipulation sessions or medical consultations and carotid strokes appear similar and could have been due to the fact that patients with early symptoms related to arterial dissection seek care before developing their stroke.

However, it is regrettable that the study did not focus on vertebral artery dissections, which are anatomically more exposed to cervical chiropractic sessions. Nevertheless, because indices defined from joint tests and medical history are insufficient to identify patients “at risk or in the process of arterial dissection,” and because stroke can result in severe disability, practitioners managing patients with neck pain cannot take this type of complication lightly.

This story was translated from JIM 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.

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Cervical manipulations have been associated with vascular complications. While the incidence of carotid dissections does not seem to have increased, the question remains open for vertebral artery injuries. We must remain vigilant!

Resorting to joint manipulation for neck pain is not unusual. Currently, cervical manipulation remains a popular first-line treatment for cervicodynia or headaches. Although evidence exists showing that specific joint mobilization can improve this type of symptomatology, there is a possibility that it may risk damaging the cervical arteries and causing ischemic stroke through arterial dissection.

Epidemiologically, internal carotid artery dissection is a relatively rare event with an estimated annual incidence of 1.72 per 100,000 individuals (those most likely to be diagnosed being obviously those leading to hospitalization for stroke) but represents one of the most common causes of stroke in young and middle-aged adults. Faced with case reports that may raise concerns and hypotheses about an associated risk, two studies have sought to delve into the issue.
 

No Increased Carotid Risk Identified

The first study, of a case-cross design, identified all incident cases of ischemic stroke in the territory of the internal carotid artery admitted to the hospital over a 9-year period using administrative healthcare data, the cases being used as their own control by sampling control periods before the date of the index stroke. Thus, 15,523 cases were compared with 62,092 control periods using exposure windows of 1, 3, 7, and 14 days before the stroke. The study also compared post-medical consultation and post-chiropractic consultation outcomes, knowing that as a first-line for complaints of neck pain or headache, patients often turn to one of these two types of primary care clinicians.

However, data analysis shows, among subjects aged under 45 years, positive associations for both different consultations in cases of subsequent carotid stroke (but no association for those aged over 45 years). These associations tended to increase when analyses were limited to visits for diagnoses of neck pain and headaches. Nevertheless, there was no significant difference between risk estimates after chiropractic or general medical consultation.

A notable limitation of this work is that it did not focus on strokes due to vertebral artery dissections that run through the transverse foramina of the cervical vertebrae.
 

A Screening Test Lacking Precision

More recently, the International Federation of Orthopedic Manual Physical Therapists has looked into the subject to refine the assessment of the risk for vascular complications in patients seeking physiotherapy/osteopathy care for neck pain and/or headaches. Through a cross-sectional study involving 150 patients, it tested a vascular complication risk index (from high to low grade, based on history taking and clinical examination), developed to estimate the risk for the presence of vascular rather than musculoskeletal pathology, to determine whether or not there is a contraindication to cervical manipulation.

However, the developed index had only low sensitivity (0.50; 95% CI, 0.39-0.61) and moderate specificity (0.63; 95% CI, 0.51-0.75), knowing that the reference test was a consensus medical decision made by a vascular neurologist, an interventional neurologist, and a neuroradiologist (based on clinical data and cervical MRI). Similarly, positive and negative likelihood ratios were low at 1.36 (95% CI, 0.93-1.99) and 0.79 (95% CI, 0.60-1.05), respectively.

In conclusion, the data from the case-cross study did not seem to demonstrate an excess risk for stroke in the territory of the internal carotid artery after cervical joint manipulations. Associations between cervical manipulation sessions or medical consultations and carotid strokes appear similar and could have been due to the fact that patients with early symptoms related to arterial dissection seek care before developing their stroke.

However, it is regrettable that the study did not focus on vertebral artery dissections, which are anatomically more exposed to cervical chiropractic sessions. Nevertheless, because indices defined from joint tests and medical history are insufficient to identify patients “at risk or in the process of arterial dissection,” and because stroke can result in severe disability, practitioners managing patients with neck pain cannot take this type of complication lightly.

This story was translated from JIM 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.

Cervical manipulations have been associated with vascular complications. While the incidence of carotid dissections does not seem to have increased, the question remains open for vertebral artery injuries. We must remain vigilant!

Resorting to joint manipulation for neck pain is not unusual. Currently, cervical manipulation remains a popular first-line treatment for cervicodynia or headaches. Although evidence exists showing that specific joint mobilization can improve this type of symptomatology, there is a possibility that it may risk damaging the cervical arteries and causing ischemic stroke through arterial dissection.

Epidemiologically, internal carotid artery dissection is a relatively rare event with an estimated annual incidence of 1.72 per 100,000 individuals (those most likely to be diagnosed being obviously those leading to hospitalization for stroke) but represents one of the most common causes of stroke in young and middle-aged adults. Faced with case reports that may raise concerns and hypotheses about an associated risk, two studies have sought to delve into the issue.
 

No Increased Carotid Risk Identified

The first study, of a case-cross design, identified all incident cases of ischemic stroke in the territory of the internal carotid artery admitted to the hospital over a 9-year period using administrative healthcare data, the cases being used as their own control by sampling control periods before the date of the index stroke. Thus, 15,523 cases were compared with 62,092 control periods using exposure windows of 1, 3, 7, and 14 days before the stroke. The study also compared post-medical consultation and post-chiropractic consultation outcomes, knowing that as a first-line for complaints of neck pain or headache, patients often turn to one of these two types of primary care clinicians.

However, data analysis shows, among subjects aged under 45 years, positive associations for both different consultations in cases of subsequent carotid stroke (but no association for those aged over 45 years). These associations tended to increase when analyses were limited to visits for diagnoses of neck pain and headaches. Nevertheless, there was no significant difference between risk estimates after chiropractic or general medical consultation.

A notable limitation of this work is that it did not focus on strokes due to vertebral artery dissections that run through the transverse foramina of the cervical vertebrae.
 

A Screening Test Lacking Precision

More recently, the International Federation of Orthopedic Manual Physical Therapists has looked into the subject to refine the assessment of the risk for vascular complications in patients seeking physiotherapy/osteopathy care for neck pain and/or headaches. Through a cross-sectional study involving 150 patients, it tested a vascular complication risk index (from high to low grade, based on history taking and clinical examination), developed to estimate the risk for the presence of vascular rather than musculoskeletal pathology, to determine whether or not there is a contraindication to cervical manipulation.

However, the developed index had only low sensitivity (0.50; 95% CI, 0.39-0.61) and moderate specificity (0.63; 95% CI, 0.51-0.75), knowing that the reference test was a consensus medical decision made by a vascular neurologist, an interventional neurologist, and a neuroradiologist (based on clinical data and cervical MRI). Similarly, positive and negative likelihood ratios were low at 1.36 (95% CI, 0.93-1.99) and 0.79 (95% CI, 0.60-1.05), respectively.

In conclusion, the data from the case-cross study did not seem to demonstrate an excess risk for stroke in the territory of the internal carotid artery after cervical joint manipulations. Associations between cervical manipulation sessions or medical consultations and carotid strokes appear similar and could have been due to the fact that patients with early symptoms related to arterial dissection seek care before developing their stroke.

However, it is regrettable that the study did not focus on vertebral artery dissections, which are anatomically more exposed to cervical chiropractic sessions. Nevertheless, because indices defined from joint tests and medical history are insufficient to identify patients “at risk or in the process of arterial dissection,” and because stroke can result in severe disability, practitioners managing patients with neck pain cannot take this type of complication lightly.

This story was translated from JIM 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.

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A New Biomarker of Brain Injury?

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Changed
Wed, 03/06/2024 - 12:58

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.

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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.

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Spinal Cord Injury Tied to Greater Risk for Heart Disease

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Tue, 02/13/2024 - 13:23

 

TOPLINE:

Spinal cord injury (SCI) is associated with a significantly greater risk for heart disease than that of the general non-SCI population, especially among those with severe disability, new observational data suggest.

METHODOLOGY:

  • Researchers analyzed data from Korea’s National Health Insurance Service on 5083 patients with cervical, thoracic, or lumbar SCI (mean age, 58; 75% men) and 1:3 age- and sex-matched non-SCI controls.
  • The study endpoint was new-onset myocardial infarction (MI), heart failure (HF), or atrial fibrillation (AF) during a mean follow-up of 4.3 years.
  • Covariates included low income, living in an urban or rural area, alcohol consumption, smoking status, physical activity engagement, body mass index, and blood pressure; comorbidities included hypertension, type 2 diabetes, and dyslipidemia.

TAKEAWAY:

  • A total of 169 MI events (7.3 per 1000 person-years), 426 HF events (18.8 per 1000 person-years), and 158 AF events (6.8 per 1000 person-years) occurred among SCI survivors.
  • After adjustment, SCI survivors had a higher risk for MI (adjusted hazard ratio [aHR], 2.41), HF (aHR, 2.24), and AF (aHR, 1.84) than that of controls.
  • Among SCI survivors with a disability, the risks increased with disability severity, and those with severe disability had the highest risks for MI (aHR, 3.74), HF (aHR, 3.96), and AF (aHR, 3.32).
  • Cervical and lumbar SCI survivors had an increased risk for heart disease compared with controls regardless of disability, and the risk was slightly higher for those with a disability; for cervical SCI survivors with a disability, aHRs for MI, HF, and AF, respectively, were 2.30, 2.05, and 1.73; for lumbar SCI survivors with a disability, aHRs were 2.79, 2.35, and 2.47.
  • Thoracic SCI survivors with disability had a higher risk for MI (aHR, 5.62) and HF (aHR, 3.31) than controls.

IN PRACTICE:

“[T]he recognition and treatment of modifiable cardiovascular risk factors must be reinforced in the SCI population, [and] proper rehabilitation and education should be considered to prevent autonomic dysreflexia or orthostatic hypotension,” the authors wrote.

In an accompanying editorial, Christopher R. West, PhD, and Jacquelyn J. Cragg, PhD, both of the University of British Columbia, Vancouver, Canada, noted that clinical guidelines for cardiovascular and cardiometabolic disease after SCI don’t include approaches to help mitigate the risk for cardiac events such as those reported in the study; therefore, they wrote, the findings “should act as ‘call-to-arms’ to researchers and clinicians to shift gears from tradition and begin studying the clinical efficacy of neuraxial therapies that could help restore autonomic balance [in SCI], such as targeted neuromodulation.”

SOURCE:

The study was led by Jung Eun Yoo, MD, PhD of Seoul National University College of Medicine, Seoul, South Korea, and published online on February 12 in the Journal of the American College of Cardiology.

LIMITATIONS:

The database was not designed for the SCI population, so data are incomplete. The incidence of thoracic SCI was particularly low. Because SCI survivors may have impaired perception of chest pain in ischemic heart disease, those with asymptomatic or silent heart disease may not have been captured during follow-up. All study participants were Korean, so the findings may not be generalizable to other ethnicities.

DISCLOSURES:

This research was partially supported by a grant from the Korea Health Technology R&D Project through the Korea Health Industry Development Institute, funded by the Ministry of Health and Welfare, South Korea. The study authors and the editorialists had no relevant relationships to disclose.

A version of this article appeared on Medscape.com.

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TOPLINE:

Spinal cord injury (SCI) is associated with a significantly greater risk for heart disease than that of the general non-SCI population, especially among those with severe disability, new observational data suggest.

METHODOLOGY:

  • Researchers analyzed data from Korea’s National Health Insurance Service on 5083 patients with cervical, thoracic, or lumbar SCI (mean age, 58; 75% men) and 1:3 age- and sex-matched non-SCI controls.
  • The study endpoint was new-onset myocardial infarction (MI), heart failure (HF), or atrial fibrillation (AF) during a mean follow-up of 4.3 years.
  • Covariates included low income, living in an urban or rural area, alcohol consumption, smoking status, physical activity engagement, body mass index, and blood pressure; comorbidities included hypertension, type 2 diabetes, and dyslipidemia.

TAKEAWAY:

  • A total of 169 MI events (7.3 per 1000 person-years), 426 HF events (18.8 per 1000 person-years), and 158 AF events (6.8 per 1000 person-years) occurred among SCI survivors.
  • After adjustment, SCI survivors had a higher risk for MI (adjusted hazard ratio [aHR], 2.41), HF (aHR, 2.24), and AF (aHR, 1.84) than that of controls.
  • Among SCI survivors with a disability, the risks increased with disability severity, and those with severe disability had the highest risks for MI (aHR, 3.74), HF (aHR, 3.96), and AF (aHR, 3.32).
  • Cervical and lumbar SCI survivors had an increased risk for heart disease compared with controls regardless of disability, and the risk was slightly higher for those with a disability; for cervical SCI survivors with a disability, aHRs for MI, HF, and AF, respectively, were 2.30, 2.05, and 1.73; for lumbar SCI survivors with a disability, aHRs were 2.79, 2.35, and 2.47.
  • Thoracic SCI survivors with disability had a higher risk for MI (aHR, 5.62) and HF (aHR, 3.31) than controls.

IN PRACTICE:

“[T]he recognition and treatment of modifiable cardiovascular risk factors must be reinforced in the SCI population, [and] proper rehabilitation and education should be considered to prevent autonomic dysreflexia or orthostatic hypotension,” the authors wrote.

In an accompanying editorial, Christopher R. West, PhD, and Jacquelyn J. Cragg, PhD, both of the University of British Columbia, Vancouver, Canada, noted that clinical guidelines for cardiovascular and cardiometabolic disease after SCI don’t include approaches to help mitigate the risk for cardiac events such as those reported in the study; therefore, they wrote, the findings “should act as ‘call-to-arms’ to researchers and clinicians to shift gears from tradition and begin studying the clinical efficacy of neuraxial therapies that could help restore autonomic balance [in SCI], such as targeted neuromodulation.”

SOURCE:

The study was led by Jung Eun Yoo, MD, PhD of Seoul National University College of Medicine, Seoul, South Korea, and published online on February 12 in the Journal of the American College of Cardiology.

LIMITATIONS:

The database was not designed for the SCI population, so data are incomplete. The incidence of thoracic SCI was particularly low. Because SCI survivors may have impaired perception of chest pain in ischemic heart disease, those with asymptomatic or silent heart disease may not have been captured during follow-up. All study participants were Korean, so the findings may not be generalizable to other ethnicities.

DISCLOSURES:

This research was partially supported by a grant from the Korea Health Technology R&D Project through the Korea Health Industry Development Institute, funded by the Ministry of Health and Welfare, South Korea. The study authors and the editorialists had no relevant relationships to disclose.

A version of this article appeared on Medscape.com.

 

TOPLINE:

Spinal cord injury (SCI) is associated with a significantly greater risk for heart disease than that of the general non-SCI population, especially among those with severe disability, new observational data suggest.

METHODOLOGY:

  • Researchers analyzed data from Korea’s National Health Insurance Service on 5083 patients with cervical, thoracic, or lumbar SCI (mean age, 58; 75% men) and 1:3 age- and sex-matched non-SCI controls.
  • The study endpoint was new-onset myocardial infarction (MI), heart failure (HF), or atrial fibrillation (AF) during a mean follow-up of 4.3 years.
  • Covariates included low income, living in an urban or rural area, alcohol consumption, smoking status, physical activity engagement, body mass index, and blood pressure; comorbidities included hypertension, type 2 diabetes, and dyslipidemia.

TAKEAWAY:

  • A total of 169 MI events (7.3 per 1000 person-years), 426 HF events (18.8 per 1000 person-years), and 158 AF events (6.8 per 1000 person-years) occurred among SCI survivors.
  • After adjustment, SCI survivors had a higher risk for MI (adjusted hazard ratio [aHR], 2.41), HF (aHR, 2.24), and AF (aHR, 1.84) than that of controls.
  • Among SCI survivors with a disability, the risks increased with disability severity, and those with severe disability had the highest risks for MI (aHR, 3.74), HF (aHR, 3.96), and AF (aHR, 3.32).
  • Cervical and lumbar SCI survivors had an increased risk for heart disease compared with controls regardless of disability, and the risk was slightly higher for those with a disability; for cervical SCI survivors with a disability, aHRs for MI, HF, and AF, respectively, were 2.30, 2.05, and 1.73; for lumbar SCI survivors with a disability, aHRs were 2.79, 2.35, and 2.47.
  • Thoracic SCI survivors with disability had a higher risk for MI (aHR, 5.62) and HF (aHR, 3.31) than controls.

IN PRACTICE:

“[T]he recognition and treatment of modifiable cardiovascular risk factors must be reinforced in the SCI population, [and] proper rehabilitation and education should be considered to prevent autonomic dysreflexia or orthostatic hypotension,” the authors wrote.

In an accompanying editorial, Christopher R. West, PhD, and Jacquelyn J. Cragg, PhD, both of the University of British Columbia, Vancouver, Canada, noted that clinical guidelines for cardiovascular and cardiometabolic disease after SCI don’t include approaches to help mitigate the risk for cardiac events such as those reported in the study; therefore, they wrote, the findings “should act as ‘call-to-arms’ to researchers and clinicians to shift gears from tradition and begin studying the clinical efficacy of neuraxial therapies that could help restore autonomic balance [in SCI], such as targeted neuromodulation.”

SOURCE:

The study was led by Jung Eun Yoo, MD, PhD of Seoul National University College of Medicine, Seoul, South Korea, and published online on February 12 in the Journal of the American College of Cardiology.

LIMITATIONS:

The database was not designed for the SCI population, so data are incomplete. The incidence of thoracic SCI was particularly low. Because SCI survivors may have impaired perception of chest pain in ischemic heart disease, those with asymptomatic or silent heart disease may not have been captured during follow-up. All study participants were Korean, so the findings may not be generalizable to other ethnicities.

DISCLOSURES:

This research was partially supported by a grant from the Korea Health Technology R&D Project through the Korea Health Industry Development Institute, funded by the Ministry of Health and Welfare, South Korea. The study authors and the editorialists had no relevant relationships to disclose.

A version of this article appeared on Medscape.com.

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A New Treatment Target for PTSD?

Article Type
Changed
Thu, 01/25/2024 - 11:13

Adults with posttraumatic stress disorder (PTSD) have smaller cerebellums than unaffected adults, suggesting that this part of the brain may be a potential therapeutic target.

According to recent research on more than 4000 adults, cerebellum volume was significantly smaller (by about 2%) in those with PTSD than in trauma-exposed and trauma-naive controls without PTSD.

“The differences were largely within the posterior lobe, where a lot of the more cognitive functions attributed to the cerebellum seem to localize, as well as the vermis, which is linked to a lot of emotional processing functions,” lead author Ashley Huggins, PhD, said in a news release.

“If we know what areas are implicated, then we can start to focus interventions like brain stimulation on the cerebellum and potentially improve treatment outcomes,” said Dr. Huggins, who worked on the study while a postdoctoral researcher in the lab of Rajendra A. Morey, MD, at Duke University, Durham, North Carolina, and is now at the University of Arizona, Tucson.

While the cerebellum is known for its role in coordinating movement and balance, it also plays a key role in emotions and memory, which are affected by PTSD.

Smaller cerebellar volume has been observed in some adult and pediatric populations with PTSD.

However, those studies have been limited by either small sample sizes, the failure to consider key neuroanatomical subdivisions of the cerebellum, or a focus on certain populations such as veterans of sexual assault victims with PTSD.

To overcome these limitations, the researchers conducted a mega-analysis of total and subregional cerebellar volumes in a large, multicohort dataset from the Enhancing NeuroImaging Genetics through Meta-Analysis (ENIGMA)-Psychiatric Genomics Consortium PTSD workgroup that was published online on January 10, 2024, in Molecular Psychiatry.

They employed a novel, standardized ENIGMA cerebellum parcellation protocol to quantify cerebellar lobule volumes using structural MRI data from 1642 adults with PTSD and 2573 healthy controls without PTSD (88% trauma-exposed and 12% trauma-naive).

After adjustment for age, gender, and total intracranial volume, PTSD was associated with significant gray and white matter reductions of the cerebellum.

People with PTSD demonstrated smaller total cerebellum volume as well as reduced volume in subregions primarily within the posterior cerebellum, vermis, and flocculonodular cerebellum than controls.

In general, PTSD severity was more robustly associated with cerebellar volume differences than PTSD diagnosis.

Focusing purely on a “yes-or-no” categorical diagnosis didn’t always provide the clearest picture. “When we looked at PTSD severity, people who had more severe forms of the disorder had an even smaller cerebellar volume,” Dr. Huggins explained in the news release.

Novel Treatment Target

These findings add to “an emerging literature that underscores the relevance of cerebellar structure in the pathophysiology of PTSD,” the researchers noted.

They caution that despite the significant findings suggesting associations between PTSD and smaller cerebellar volumes, effect sizes were small. “As such, it is unlikely that structural cerebellar volumes alone will provide a clinically useful biomarker (eg, for individual-level prediction).”

Nonetheless, the study highlights the cerebellum as a “novel treatment target that may be leveraged to improve treatment outcomes for PTSD,” they wrote.

They noted that prior work has shown that the cerebellum is sensitive to external modulation. For example, noninvasive brain stimulation of the cerebellum has been shown to modulate cognitive, emotional, and social processes commonly disrupted in PTSD.

Commenting on this research, Cyrus A. Raji, MD, PhD, associate professor of radiology and neurology at Washington University in St. Louis, noted that this “large neuroimaging study links PTSD to cerebellar volume loss.”

“However, PTSD and traumatic brain injury frequently co-occur, and PTSD also frequently arises after TBI. Additionally, TBI is strongly linked to cerebellar volume loss,” Dr. Raji pointed out.

“Future studies need to better delineate volume loss from these conditions, especially when they are comorbid, though the expectation is these effects would be additive with TBI being the initial and most severe driving force,” Dr. Raji added.

The research had no commercial funding. Author disclosures are listed with the original article. Dr. Raji is a consultant for Brainreader, Apollo Health, Pacific Neuroscience Foundation, and Neurevolution Medicine LLC.
 

A version of this article appears on Medscape.com.

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Adults with posttraumatic stress disorder (PTSD) have smaller cerebellums than unaffected adults, suggesting that this part of the brain may be a potential therapeutic target.

According to recent research on more than 4000 adults, cerebellum volume was significantly smaller (by about 2%) in those with PTSD than in trauma-exposed and trauma-naive controls without PTSD.

“The differences were largely within the posterior lobe, where a lot of the more cognitive functions attributed to the cerebellum seem to localize, as well as the vermis, which is linked to a lot of emotional processing functions,” lead author Ashley Huggins, PhD, said in a news release.

“If we know what areas are implicated, then we can start to focus interventions like brain stimulation on the cerebellum and potentially improve treatment outcomes,” said Dr. Huggins, who worked on the study while a postdoctoral researcher in the lab of Rajendra A. Morey, MD, at Duke University, Durham, North Carolina, and is now at the University of Arizona, Tucson.

While the cerebellum is known for its role in coordinating movement and balance, it also plays a key role in emotions and memory, which are affected by PTSD.

Smaller cerebellar volume has been observed in some adult and pediatric populations with PTSD.

However, those studies have been limited by either small sample sizes, the failure to consider key neuroanatomical subdivisions of the cerebellum, or a focus on certain populations such as veterans of sexual assault victims with PTSD.

To overcome these limitations, the researchers conducted a mega-analysis of total and subregional cerebellar volumes in a large, multicohort dataset from the Enhancing NeuroImaging Genetics through Meta-Analysis (ENIGMA)-Psychiatric Genomics Consortium PTSD workgroup that was published online on January 10, 2024, in Molecular Psychiatry.

They employed a novel, standardized ENIGMA cerebellum parcellation protocol to quantify cerebellar lobule volumes using structural MRI data from 1642 adults with PTSD and 2573 healthy controls without PTSD (88% trauma-exposed and 12% trauma-naive).

After adjustment for age, gender, and total intracranial volume, PTSD was associated with significant gray and white matter reductions of the cerebellum.

People with PTSD demonstrated smaller total cerebellum volume as well as reduced volume in subregions primarily within the posterior cerebellum, vermis, and flocculonodular cerebellum than controls.

In general, PTSD severity was more robustly associated with cerebellar volume differences than PTSD diagnosis.

Focusing purely on a “yes-or-no” categorical diagnosis didn’t always provide the clearest picture. “When we looked at PTSD severity, people who had more severe forms of the disorder had an even smaller cerebellar volume,” Dr. Huggins explained in the news release.

Novel Treatment Target

These findings add to “an emerging literature that underscores the relevance of cerebellar structure in the pathophysiology of PTSD,” the researchers noted.

They caution that despite the significant findings suggesting associations between PTSD and smaller cerebellar volumes, effect sizes were small. “As such, it is unlikely that structural cerebellar volumes alone will provide a clinically useful biomarker (eg, for individual-level prediction).”

Nonetheless, the study highlights the cerebellum as a “novel treatment target that may be leveraged to improve treatment outcomes for PTSD,” they wrote.

They noted that prior work has shown that the cerebellum is sensitive to external modulation. For example, noninvasive brain stimulation of the cerebellum has been shown to modulate cognitive, emotional, and social processes commonly disrupted in PTSD.

Commenting on this research, Cyrus A. Raji, MD, PhD, associate professor of radiology and neurology at Washington University in St. Louis, noted that this “large neuroimaging study links PTSD to cerebellar volume loss.”

“However, PTSD and traumatic brain injury frequently co-occur, and PTSD also frequently arises after TBI. Additionally, TBI is strongly linked to cerebellar volume loss,” Dr. Raji pointed out.

“Future studies need to better delineate volume loss from these conditions, especially when they are comorbid, though the expectation is these effects would be additive with TBI being the initial and most severe driving force,” Dr. Raji added.

The research had no commercial funding. Author disclosures are listed with the original article. Dr. Raji is a consultant for Brainreader, Apollo Health, Pacific Neuroscience Foundation, and Neurevolution Medicine LLC.
 

A version of this article appears on Medscape.com.

Adults with posttraumatic stress disorder (PTSD) have smaller cerebellums than unaffected adults, suggesting that this part of the brain may be a potential therapeutic target.

According to recent research on more than 4000 adults, cerebellum volume was significantly smaller (by about 2%) in those with PTSD than in trauma-exposed and trauma-naive controls without PTSD.

“The differences were largely within the posterior lobe, where a lot of the more cognitive functions attributed to the cerebellum seem to localize, as well as the vermis, which is linked to a lot of emotional processing functions,” lead author Ashley Huggins, PhD, said in a news release.

“If we know what areas are implicated, then we can start to focus interventions like brain stimulation on the cerebellum and potentially improve treatment outcomes,” said Dr. Huggins, who worked on the study while a postdoctoral researcher in the lab of Rajendra A. Morey, MD, at Duke University, Durham, North Carolina, and is now at the University of Arizona, Tucson.

While the cerebellum is known for its role in coordinating movement and balance, it also plays a key role in emotions and memory, which are affected by PTSD.

Smaller cerebellar volume has been observed in some adult and pediatric populations with PTSD.

However, those studies have been limited by either small sample sizes, the failure to consider key neuroanatomical subdivisions of the cerebellum, or a focus on certain populations such as veterans of sexual assault victims with PTSD.

To overcome these limitations, the researchers conducted a mega-analysis of total and subregional cerebellar volumes in a large, multicohort dataset from the Enhancing NeuroImaging Genetics through Meta-Analysis (ENIGMA)-Psychiatric Genomics Consortium PTSD workgroup that was published online on January 10, 2024, in Molecular Psychiatry.

They employed a novel, standardized ENIGMA cerebellum parcellation protocol to quantify cerebellar lobule volumes using structural MRI data from 1642 adults with PTSD and 2573 healthy controls without PTSD (88% trauma-exposed and 12% trauma-naive).

After adjustment for age, gender, and total intracranial volume, PTSD was associated with significant gray and white matter reductions of the cerebellum.

People with PTSD demonstrated smaller total cerebellum volume as well as reduced volume in subregions primarily within the posterior cerebellum, vermis, and flocculonodular cerebellum than controls.

In general, PTSD severity was more robustly associated with cerebellar volume differences than PTSD diagnosis.

Focusing purely on a “yes-or-no” categorical diagnosis didn’t always provide the clearest picture. “When we looked at PTSD severity, people who had more severe forms of the disorder had an even smaller cerebellar volume,” Dr. Huggins explained in the news release.

Novel Treatment Target

These findings add to “an emerging literature that underscores the relevance of cerebellar structure in the pathophysiology of PTSD,” the researchers noted.

They caution that despite the significant findings suggesting associations between PTSD and smaller cerebellar volumes, effect sizes were small. “As such, it is unlikely that structural cerebellar volumes alone will provide a clinically useful biomarker (eg, for individual-level prediction).”

Nonetheless, the study highlights the cerebellum as a “novel treatment target that may be leveraged to improve treatment outcomes for PTSD,” they wrote.

They noted that prior work has shown that the cerebellum is sensitive to external modulation. For example, noninvasive brain stimulation of the cerebellum has been shown to modulate cognitive, emotional, and social processes commonly disrupted in PTSD.

Commenting on this research, Cyrus A. Raji, MD, PhD, associate professor of radiology and neurology at Washington University in St. Louis, noted that this “large neuroimaging study links PTSD to cerebellar volume loss.”

“However, PTSD and traumatic brain injury frequently co-occur, and PTSD also frequently arises after TBI. Additionally, TBI is strongly linked to cerebellar volume loss,” Dr. Raji pointed out.

“Future studies need to better delineate volume loss from these conditions, especially when they are comorbid, though the expectation is these effects would be additive with TBI being the initial and most severe driving force,” Dr. Raji added.

The research had no commercial funding. Author disclosures are listed with the original article. Dr. Raji is a consultant for Brainreader, Apollo Health, Pacific Neuroscience Foundation, and Neurevolution Medicine LLC.
 

A version of this article appears on Medscape.com.

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A Military Nurse Saves a Life After a Brutal Rollover Crash

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Wed, 01/24/2024 - 15:03

Emergencies happen anywhere and anytime, and sometimes, medical professionals find themselves in situations where they are the only ones who can help. Is There a Doctor in the House? is a series telling these stories.

A week earlier I’d had a heart surgery and was heading out for a post-op appointment when I saw it: I had a flat tire. It didn’t make sense. The tire was brand new, and there was no puncture. But it was flat.

I swapped out the flat for the spare and went off base to a tire shop. While I was there, my surgeon’s office called and rescheduled my appointment for a couple of hours later. That was lucky because by the time the tire was fixed, I had just enough time to get there.

The hospital is right near I-35 in San Antonio, Texas. I got off the freeway and onto the access road and paused to turn into the parking lot. That’s when I heard an enormous crash.

I saw a big poof of white smoke, and a car barreled off the freeway and came rolling down the embankment.

When the car hit the access road, I saw a woman ejected through the windshield. She bounced and landed in the road about 25 feet in front of me.

I put my car in park, grabbed my face mask and gloves, and started running toward her. But another vehicle — a truck towing a trailer — came from behind to drive around me. The driver didn’t realize what had happened and couldn’t stop in time…

The trailer ran over her.

I didn’t know if anyone could’ve survived that, but I went to her. I saw several other bystanders, but they were frozen in shock. I was praying, dear God, if she’s alive, let me do whatever I need to do to save her life.

It was a horrible scene. This poor lady was in a bloody heap in the middle of the road. Her right arm was twisted up under her neck so tightly, she was choking herself. So, the first thing I did was straighten her arm out to protect her airway.

I started yelling at people, “Call 9-1-1! Run to the hospital! Let them know there’s an accident out here, and I need help!”

The woman had a pulse, but it was super rapid. On first glance, she clearly had multiple fractures and a bad head bleed. With the sheer number of times she’d been injured, I didn’t know what was going on internally, but it was bad. She was gargling on her own blood and spitting it up. She was drowning.

A couple of technicians from the hospital came and brought me a tiny emergency kit. It had a blood pressure cuff and an oral airway. All the vital signs indicated the lady was going into shock. She’d lost a lot of blood on the pavement.

I was able to get the oral airway in. A few minutes later, a fire chief showed up. By now, the traffic had backed up so badly, the emergency vehicles couldn’t get in. But he managed to get there another way and gave me a cervical collar (C collar) and an Ambu bag.

I was hyper-focused on what I could do at that moment and what I needed to do next. Her stats were going down, but she still had a pulse. If she lost the pulse or went into a lethal rhythm, I’d have to start cardiopulmonary resuscitation (CPR). I asked the other people, but nobody else knew CPR, so I wouldn’t have help.

I could tell the lady had a pelvic fracture, and we needed to stabilize her. I directed people how to hold her neck safely and log-roll her flat on the ground. I also needed to put pressure on the back of her head because of all the bleeding. I got people to give me their clothes and tried to do that as I was bagging her.

The windows of her vehicle had all been blown out. I asked somebody to go find her purse with her ID. Then I noticed something …

My heart jumped into my stomach.

A car seat. There was an empty child’s car seat in the back of the car.

I started yelling at everyone, “Look for a baby! Go up and down the embankment and across the road. There might have been a baby in the car!”

But there wasn’t. Thank God. She hadn’t been driving with her child.

At that point, a paramedic came running from behind all the traffic. We did life support together until the ambulance finally arrived.

Emergency medical services got an intravenous line in and used medical anti-shock trousers. Thankfully, I already had the C collar on, and we’d been bagging her, so they could load her very quickly.

I got rid of my bloody gloves. I told a police officer I would come back. And then I went to my doctor’s appointment.

The window at my doctor’s office faced the access road, so the people there had seen all the traffic. They asked me what happened, and I said, “It was me. I saw it happen. I tried to help.” I was a little frazzled.

When I got back to the scene, the police and the fire chief kept thanking me for stopping. Why wouldn’t I stop? It was astounding to realize that they imagined somebody wouldn’t stop in a situation like this.

They told me the lady was alive. She was in the intensive care unit in critical condition, but she had survived. At that moment, I had this overwhelming feeling: God had put me in this exact place at the exact time to save her life.

Looking back, I think about how God ordered my steps. Without the mysterious flat tire, I would’ve gone to the hospital earlier. If my appointment hadn’t been rescheduled, I wouldn’t have been on the access road. All those events brought me there.

Several months later, the woman’s family contacted me and asked if we could meet. I found out more about her injuries. She’d had multiple skull fractures, facial fractures, and a broken jaw. Her upper arm was broken in three places. Her clavicle was broken. She had internal bleeding, a pelvic fracture, and a broken leg. She was 28 years old.

She’d had multiple surgeries, spent 2 months in the ICU, and another 3 months in intensive rehab. But she survived. It was incredible.

We all met up at a McDonald’s. First, her little son — who was the baby I thought might have been in the car — ran up to me and said, “Thank you for saving my mommy’s life.”

Then I turned, and there she was — a beautiful lady looking at me with awe and crying, saying, “It’s me.”

She obviously had gone through a transformation from all the injuries and the medications. She had a little bit of a speech delay, but mentally, she was there. She could walk.

 

 

She said, “You’re my angel. God put you there to save my life.” Her family all came up and hugged me. It was so beautiful.

She told me about the accident. She’d been speeding that day, zigzagging through lanes to get around the traffic. And she didn’t have her seatbelt on. She’d driven onto the shoulder to try to pass everyone, but it started narrowing. She clipped somebody’s bumper, went into a tailspin, and collided with a second vehicle, which caused her to flip over and down the embankment.

“God’s given me a new lease on life,” she said, “a fresh start. I will forever wear my seatbelt. And I’m going to do whatever I can to give back to other people because I don’t even feel like I deserve this.”

I just cried.

I’ve been a nurse for 29 years, first on the civilian side and later in the military. I’ve led codes and responded to trauma in a hospital setting or a deployed environment. I was well prepared to do what I did. But doing it under such stress with adrenaline bombarding me ... I’m amazed. I just think God’s hand was on me.

At that time, I was personally going through some things. After my heart surgery, I was in an emotional place where I didn’t feel loved or valued. But when I had that realization — when I knew that I was meant to be there to save her life, I also got the very clear message that I was valued and loved so much.

I know I have a very strong purpose. That day changed my life.
 

US Air Force Lt. Col. Anne Staley is the officer in charge of the Military Training Network, a division of the Defense Health Agency Education and Training Directorate in San Antonio, Texas.

A version of this article appeared on Medscape.com.

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Emergencies happen anywhere and anytime, and sometimes, medical professionals find themselves in situations where they are the only ones who can help. Is There a Doctor in the House? is a series telling these stories.

A week earlier I’d had a heart surgery and was heading out for a post-op appointment when I saw it: I had a flat tire. It didn’t make sense. The tire was brand new, and there was no puncture. But it was flat.

I swapped out the flat for the spare and went off base to a tire shop. While I was there, my surgeon’s office called and rescheduled my appointment for a couple of hours later. That was lucky because by the time the tire was fixed, I had just enough time to get there.

The hospital is right near I-35 in San Antonio, Texas. I got off the freeway and onto the access road and paused to turn into the parking lot. That’s when I heard an enormous crash.

I saw a big poof of white smoke, and a car barreled off the freeway and came rolling down the embankment.

When the car hit the access road, I saw a woman ejected through the windshield. She bounced and landed in the road about 25 feet in front of me.

I put my car in park, grabbed my face mask and gloves, and started running toward her. But another vehicle — a truck towing a trailer — came from behind to drive around me. The driver didn’t realize what had happened and couldn’t stop in time…

The trailer ran over her.

I didn’t know if anyone could’ve survived that, but I went to her. I saw several other bystanders, but they were frozen in shock. I was praying, dear God, if she’s alive, let me do whatever I need to do to save her life.

It was a horrible scene. This poor lady was in a bloody heap in the middle of the road. Her right arm was twisted up under her neck so tightly, she was choking herself. So, the first thing I did was straighten her arm out to protect her airway.

I started yelling at people, “Call 9-1-1! Run to the hospital! Let them know there’s an accident out here, and I need help!”

The woman had a pulse, but it was super rapid. On first glance, she clearly had multiple fractures and a bad head bleed. With the sheer number of times she’d been injured, I didn’t know what was going on internally, but it was bad. She was gargling on her own blood and spitting it up. She was drowning.

A couple of technicians from the hospital came and brought me a tiny emergency kit. It had a blood pressure cuff and an oral airway. All the vital signs indicated the lady was going into shock. She’d lost a lot of blood on the pavement.

I was able to get the oral airway in. A few minutes later, a fire chief showed up. By now, the traffic had backed up so badly, the emergency vehicles couldn’t get in. But he managed to get there another way and gave me a cervical collar (C collar) and an Ambu bag.

I was hyper-focused on what I could do at that moment and what I needed to do next. Her stats were going down, but she still had a pulse. If she lost the pulse or went into a lethal rhythm, I’d have to start cardiopulmonary resuscitation (CPR). I asked the other people, but nobody else knew CPR, so I wouldn’t have help.

I could tell the lady had a pelvic fracture, and we needed to stabilize her. I directed people how to hold her neck safely and log-roll her flat on the ground. I also needed to put pressure on the back of her head because of all the bleeding. I got people to give me their clothes and tried to do that as I was bagging her.

The windows of her vehicle had all been blown out. I asked somebody to go find her purse with her ID. Then I noticed something …

My heart jumped into my stomach.

A car seat. There was an empty child’s car seat in the back of the car.

I started yelling at everyone, “Look for a baby! Go up and down the embankment and across the road. There might have been a baby in the car!”

But there wasn’t. Thank God. She hadn’t been driving with her child.

At that point, a paramedic came running from behind all the traffic. We did life support together until the ambulance finally arrived.

Emergency medical services got an intravenous line in and used medical anti-shock trousers. Thankfully, I already had the C collar on, and we’d been bagging her, so they could load her very quickly.

I got rid of my bloody gloves. I told a police officer I would come back. And then I went to my doctor’s appointment.

The window at my doctor’s office faced the access road, so the people there had seen all the traffic. They asked me what happened, and I said, “It was me. I saw it happen. I tried to help.” I was a little frazzled.

When I got back to the scene, the police and the fire chief kept thanking me for stopping. Why wouldn’t I stop? It was astounding to realize that they imagined somebody wouldn’t stop in a situation like this.

They told me the lady was alive. She was in the intensive care unit in critical condition, but she had survived. At that moment, I had this overwhelming feeling: God had put me in this exact place at the exact time to save her life.

Looking back, I think about how God ordered my steps. Without the mysterious flat tire, I would’ve gone to the hospital earlier. If my appointment hadn’t been rescheduled, I wouldn’t have been on the access road. All those events brought me there.

Several months later, the woman’s family contacted me and asked if we could meet. I found out more about her injuries. She’d had multiple skull fractures, facial fractures, and a broken jaw. Her upper arm was broken in three places. Her clavicle was broken. She had internal bleeding, a pelvic fracture, and a broken leg. She was 28 years old.

She’d had multiple surgeries, spent 2 months in the ICU, and another 3 months in intensive rehab. But she survived. It was incredible.

We all met up at a McDonald’s. First, her little son — who was the baby I thought might have been in the car — ran up to me and said, “Thank you for saving my mommy’s life.”

Then I turned, and there she was — a beautiful lady looking at me with awe and crying, saying, “It’s me.”

She obviously had gone through a transformation from all the injuries and the medications. She had a little bit of a speech delay, but mentally, she was there. She could walk.

 

 

She said, “You’re my angel. God put you there to save my life.” Her family all came up and hugged me. It was so beautiful.

She told me about the accident. She’d been speeding that day, zigzagging through lanes to get around the traffic. And she didn’t have her seatbelt on. She’d driven onto the shoulder to try to pass everyone, but it started narrowing. She clipped somebody’s bumper, went into a tailspin, and collided with a second vehicle, which caused her to flip over and down the embankment.

“God’s given me a new lease on life,” she said, “a fresh start. I will forever wear my seatbelt. And I’m going to do whatever I can to give back to other people because I don’t even feel like I deserve this.”

I just cried.

I’ve been a nurse for 29 years, first on the civilian side and later in the military. I’ve led codes and responded to trauma in a hospital setting or a deployed environment. I was well prepared to do what I did. But doing it under such stress with adrenaline bombarding me ... I’m amazed. I just think God’s hand was on me.

At that time, I was personally going through some things. After my heart surgery, I was in an emotional place where I didn’t feel loved or valued. But when I had that realization — when I knew that I was meant to be there to save her life, I also got the very clear message that I was valued and loved so much.

I know I have a very strong purpose. That day changed my life.
 

US Air Force Lt. Col. Anne Staley is the officer in charge of the Military Training Network, a division of the Defense Health Agency Education and Training Directorate in San Antonio, Texas.

A version of this article appeared on Medscape.com.

Emergencies happen anywhere and anytime, and sometimes, medical professionals find themselves in situations where they are the only ones who can help. Is There a Doctor in the House? is a series telling these stories.

A week earlier I’d had a heart surgery and was heading out for a post-op appointment when I saw it: I had a flat tire. It didn’t make sense. The tire was brand new, and there was no puncture. But it was flat.

I swapped out the flat for the spare and went off base to a tire shop. While I was there, my surgeon’s office called and rescheduled my appointment for a couple of hours later. That was lucky because by the time the tire was fixed, I had just enough time to get there.

The hospital is right near I-35 in San Antonio, Texas. I got off the freeway and onto the access road and paused to turn into the parking lot. That’s when I heard an enormous crash.

I saw a big poof of white smoke, and a car barreled off the freeway and came rolling down the embankment.

When the car hit the access road, I saw a woman ejected through the windshield. She bounced and landed in the road about 25 feet in front of me.

I put my car in park, grabbed my face mask and gloves, and started running toward her. But another vehicle — a truck towing a trailer — came from behind to drive around me. The driver didn’t realize what had happened and couldn’t stop in time…

The trailer ran over her.

I didn’t know if anyone could’ve survived that, but I went to her. I saw several other bystanders, but they were frozen in shock. I was praying, dear God, if she’s alive, let me do whatever I need to do to save her life.

It was a horrible scene. This poor lady was in a bloody heap in the middle of the road. Her right arm was twisted up under her neck so tightly, she was choking herself. So, the first thing I did was straighten her arm out to protect her airway.

I started yelling at people, “Call 9-1-1! Run to the hospital! Let them know there’s an accident out here, and I need help!”

The woman had a pulse, but it was super rapid. On first glance, she clearly had multiple fractures and a bad head bleed. With the sheer number of times she’d been injured, I didn’t know what was going on internally, but it was bad. She was gargling on her own blood and spitting it up. She was drowning.

A couple of technicians from the hospital came and brought me a tiny emergency kit. It had a blood pressure cuff and an oral airway. All the vital signs indicated the lady was going into shock. She’d lost a lot of blood on the pavement.

I was able to get the oral airway in. A few minutes later, a fire chief showed up. By now, the traffic had backed up so badly, the emergency vehicles couldn’t get in. But he managed to get there another way and gave me a cervical collar (C collar) and an Ambu bag.

I was hyper-focused on what I could do at that moment and what I needed to do next. Her stats were going down, but she still had a pulse. If she lost the pulse or went into a lethal rhythm, I’d have to start cardiopulmonary resuscitation (CPR). I asked the other people, but nobody else knew CPR, so I wouldn’t have help.

I could tell the lady had a pelvic fracture, and we needed to stabilize her. I directed people how to hold her neck safely and log-roll her flat on the ground. I also needed to put pressure on the back of her head because of all the bleeding. I got people to give me their clothes and tried to do that as I was bagging her.

The windows of her vehicle had all been blown out. I asked somebody to go find her purse with her ID. Then I noticed something …

My heart jumped into my stomach.

A car seat. There was an empty child’s car seat in the back of the car.

I started yelling at everyone, “Look for a baby! Go up and down the embankment and across the road. There might have been a baby in the car!”

But there wasn’t. Thank God. She hadn’t been driving with her child.

At that point, a paramedic came running from behind all the traffic. We did life support together until the ambulance finally arrived.

Emergency medical services got an intravenous line in and used medical anti-shock trousers. Thankfully, I already had the C collar on, and we’d been bagging her, so they could load her very quickly.

I got rid of my bloody gloves. I told a police officer I would come back. And then I went to my doctor’s appointment.

The window at my doctor’s office faced the access road, so the people there had seen all the traffic. They asked me what happened, and I said, “It was me. I saw it happen. I tried to help.” I was a little frazzled.

When I got back to the scene, the police and the fire chief kept thanking me for stopping. Why wouldn’t I stop? It was astounding to realize that they imagined somebody wouldn’t stop in a situation like this.

They told me the lady was alive. She was in the intensive care unit in critical condition, but she had survived. At that moment, I had this overwhelming feeling: God had put me in this exact place at the exact time to save her life.

Looking back, I think about how God ordered my steps. Without the mysterious flat tire, I would’ve gone to the hospital earlier. If my appointment hadn’t been rescheduled, I wouldn’t have been on the access road. All those events brought me there.

Several months later, the woman’s family contacted me and asked if we could meet. I found out more about her injuries. She’d had multiple skull fractures, facial fractures, and a broken jaw. Her upper arm was broken in three places. Her clavicle was broken. She had internal bleeding, a pelvic fracture, and a broken leg. She was 28 years old.

She’d had multiple surgeries, spent 2 months in the ICU, and another 3 months in intensive rehab. But she survived. It was incredible.

We all met up at a McDonald’s. First, her little son — who was the baby I thought might have been in the car — ran up to me and said, “Thank you for saving my mommy’s life.”

Then I turned, and there she was — a beautiful lady looking at me with awe and crying, saying, “It’s me.”

She obviously had gone through a transformation from all the injuries and the medications. She had a little bit of a speech delay, but mentally, she was there. She could walk.

 

 

She said, “You’re my angel. God put you there to save my life.” Her family all came up and hugged me. It was so beautiful.

She told me about the accident. She’d been speeding that day, zigzagging through lanes to get around the traffic. And she didn’t have her seatbelt on. She’d driven onto the shoulder to try to pass everyone, but it started narrowing. She clipped somebody’s bumper, went into a tailspin, and collided with a second vehicle, which caused her to flip over and down the embankment.

“God’s given me a new lease on life,” she said, “a fresh start. I will forever wear my seatbelt. And I’m going to do whatever I can to give back to other people because I don’t even feel like I deserve this.”

I just cried.

I’ve been a nurse for 29 years, first on the civilian side and later in the military. I’ve led codes and responded to trauma in a hospital setting or a deployed environment. I was well prepared to do what I did. But doing it under such stress with adrenaline bombarding me ... I’m amazed. I just think God’s hand was on me.

At that time, I was personally going through some things. After my heart surgery, I was in an emotional place where I didn’t feel loved or valued. But when I had that realization — when I knew that I was meant to be there to save her life, I also got the very clear message that I was valued and loved so much.

I know I have a very strong purpose. That day changed my life.
 

US Air Force Lt. Col. Anne Staley is the officer in charge of the Military Training Network, a division of the Defense Health Agency Education and Training Directorate in San Antonio, Texas.

A version of this article appeared on Medscape.com.

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Christmas: A Time for Love and... Penile Fractures

Article Type
Changed
Thu, 12/21/2023 - 14:12

A power outage, like the 1977 blackout in New York City, can lead to an increase in violent crime. However, complete darkness can also have an upside, as it can encourage intimacy and subsequently boost birth rates. The Christmas season, sometimes called the festival of love, appears to stimulate human interactions. Yet this, also, has its downsides, as recently reported by Dr. Nikolaos Pyrgidis and other urologists at Ludwig Maximilian University of Munich in Germany. The less cheerful aspect of the holiday season is penile fractures.

The team found that the Christmas period, in particular, is that bit more risky for this injury after they evaluated data from about 3400 men (average age 42) treated for penile fractures between 2005 and 2021. The data was provided by Germany’s Federal Bureau of Statistics.

Out of the 3400 penile fractures that were reported during this period, 40 (1.2%) occurred over 51 Christmas days (from 24th to 26th December each year). The daily incidence rate of penile fractures during the Christmas period was 0.78, with an incidence rate ratio (IRR) of 1.43. The authors note that, if every day were like Christmas, there would have been a 43% increase in penile fractures in Germany since 2005. Interestingly, only 28 (0.82%) penile fractures were reported during the New Year (from 31 December to 2 January in the period between 2005 and 2021), with an IRR of 0.98.

More generally, most patients with penile fractures were admitted to the hospital over the weekend (n=1322; IRR 1.58). Notably, Sunday saw the most admissions due to this injury, followed by Saturday. This suggests that men engaging in sexual activities on Saturday night bear the highest risk of penile fractures, followed by those active on Friday nights.

Penile fractures also increased in the summer months (n=929; IRR 1.11). But the COVID-19 pandemic (n=385; IRR 1.06) and the lockdowns (n=93; IRR 1.95%) did not impact the frequency of this injury.

Rare, Painful, and an Emergency

Penile fractures are a rare urological emergency. The tunica albuginea of one or both corpora cavernosa must tear to be considered problematic, as another team of authors reported in a recent publication. Involvement of the urethra and corpus spongiosum is also possible.

Injuries often occur during an erection because it makes the tunica albuginea stiffer and thinner than when the penis is flaccid. Patients report hearing a snap when the penis is forced into an angle during sexual activity. This was reportedly the case with German singer-song writer Dieter Bohlen, whose ex-girlfriend Nadja Abd El Farrag is said to have written in her book “Ungelogen”, or “Honestly”, that there was a sudden snap during an intimate moment one December night (Christmas?), after which she called the fire brigade in her distress.

Multiple Causes Possible

Other factors contributing to penile fractures include rolling over in bed onto an erect penis, forced bending to achieve detumescence, and blunt external traumas like kicks.

Some penile fractures can be caused by patients “kneading and ripping” their erect penis to quickly reduce swelling. In an Iranian study, 269 out of 352 patients (76%) who underwent this process, known as “ taqaandan” in Iran, suffered a penile fracture.

Penile fractures can also occur in children, as evidenced by the case history of a 7-year-old boy described a few years ago in the journal Urology where the cause was a fall onto the penis.

Immediate Action Required

The treatment of choice for a fresh penile fracture is surgical repair of the tunica albuginea defect and, if necessary, the urethra. Timely surgical intervention yields significantly better long-term outcomes than conservative therapy regarding late complications such as erectile dysfunction and penile curvature. It also reduces the rate of early complications, such as severe corporal infections. Conservative therapy should be reserved for patients who explicitly refuse surgical intervention after thorough consultation.

This article was translated from Univadis Germany using ChatGPT followed by human editing.

A version of this article appeared on Medscape.com.

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A power outage, like the 1977 blackout in New York City, can lead to an increase in violent crime. However, complete darkness can also have an upside, as it can encourage intimacy and subsequently boost birth rates. The Christmas season, sometimes called the festival of love, appears to stimulate human interactions. Yet this, also, has its downsides, as recently reported by Dr. Nikolaos Pyrgidis and other urologists at Ludwig Maximilian University of Munich in Germany. The less cheerful aspect of the holiday season is penile fractures.

The team found that the Christmas period, in particular, is that bit more risky for this injury after they evaluated data from about 3400 men (average age 42) treated for penile fractures between 2005 and 2021. The data was provided by Germany’s Federal Bureau of Statistics.

Out of the 3400 penile fractures that were reported during this period, 40 (1.2%) occurred over 51 Christmas days (from 24th to 26th December each year). The daily incidence rate of penile fractures during the Christmas period was 0.78, with an incidence rate ratio (IRR) of 1.43. The authors note that, if every day were like Christmas, there would have been a 43% increase in penile fractures in Germany since 2005. Interestingly, only 28 (0.82%) penile fractures were reported during the New Year (from 31 December to 2 January in the period between 2005 and 2021), with an IRR of 0.98.

More generally, most patients with penile fractures were admitted to the hospital over the weekend (n=1322; IRR 1.58). Notably, Sunday saw the most admissions due to this injury, followed by Saturday. This suggests that men engaging in sexual activities on Saturday night bear the highest risk of penile fractures, followed by those active on Friday nights.

Penile fractures also increased in the summer months (n=929; IRR 1.11). But the COVID-19 pandemic (n=385; IRR 1.06) and the lockdowns (n=93; IRR 1.95%) did not impact the frequency of this injury.

Rare, Painful, and an Emergency

Penile fractures are a rare urological emergency. The tunica albuginea of one or both corpora cavernosa must tear to be considered problematic, as another team of authors reported in a recent publication. Involvement of the urethra and corpus spongiosum is also possible.

Injuries often occur during an erection because it makes the tunica albuginea stiffer and thinner than when the penis is flaccid. Patients report hearing a snap when the penis is forced into an angle during sexual activity. This was reportedly the case with German singer-song writer Dieter Bohlen, whose ex-girlfriend Nadja Abd El Farrag is said to have written in her book “Ungelogen”, or “Honestly”, that there was a sudden snap during an intimate moment one December night (Christmas?), after which she called the fire brigade in her distress.

Multiple Causes Possible

Other factors contributing to penile fractures include rolling over in bed onto an erect penis, forced bending to achieve detumescence, and blunt external traumas like kicks.

Some penile fractures can be caused by patients “kneading and ripping” their erect penis to quickly reduce swelling. In an Iranian study, 269 out of 352 patients (76%) who underwent this process, known as “ taqaandan” in Iran, suffered a penile fracture.

Penile fractures can also occur in children, as evidenced by the case history of a 7-year-old boy described a few years ago in the journal Urology where the cause was a fall onto the penis.

Immediate Action Required

The treatment of choice for a fresh penile fracture is surgical repair of the tunica albuginea defect and, if necessary, the urethra. Timely surgical intervention yields significantly better long-term outcomes than conservative therapy regarding late complications such as erectile dysfunction and penile curvature. It also reduces the rate of early complications, such as severe corporal infections. Conservative therapy should be reserved for patients who explicitly refuse surgical intervention after thorough consultation.

This article was translated from Univadis Germany using ChatGPT followed by human editing.

A version of this article appeared on Medscape.com.

A power outage, like the 1977 blackout in New York City, can lead to an increase in violent crime. However, complete darkness can also have an upside, as it can encourage intimacy and subsequently boost birth rates. The Christmas season, sometimes called the festival of love, appears to stimulate human interactions. Yet this, also, has its downsides, as recently reported by Dr. Nikolaos Pyrgidis and other urologists at Ludwig Maximilian University of Munich in Germany. The less cheerful aspect of the holiday season is penile fractures.

The team found that the Christmas period, in particular, is that bit more risky for this injury after they evaluated data from about 3400 men (average age 42) treated for penile fractures between 2005 and 2021. The data was provided by Germany’s Federal Bureau of Statistics.

Out of the 3400 penile fractures that were reported during this period, 40 (1.2%) occurred over 51 Christmas days (from 24th to 26th December each year). The daily incidence rate of penile fractures during the Christmas period was 0.78, with an incidence rate ratio (IRR) of 1.43. The authors note that, if every day were like Christmas, there would have been a 43% increase in penile fractures in Germany since 2005. Interestingly, only 28 (0.82%) penile fractures were reported during the New Year (from 31 December to 2 January in the period between 2005 and 2021), with an IRR of 0.98.

More generally, most patients with penile fractures were admitted to the hospital over the weekend (n=1322; IRR 1.58). Notably, Sunday saw the most admissions due to this injury, followed by Saturday. This suggests that men engaging in sexual activities on Saturday night bear the highest risk of penile fractures, followed by those active on Friday nights.

Penile fractures also increased in the summer months (n=929; IRR 1.11). But the COVID-19 pandemic (n=385; IRR 1.06) and the lockdowns (n=93; IRR 1.95%) did not impact the frequency of this injury.

Rare, Painful, and an Emergency

Penile fractures are a rare urological emergency. The tunica albuginea of one or both corpora cavernosa must tear to be considered problematic, as another team of authors reported in a recent publication. Involvement of the urethra and corpus spongiosum is also possible.

Injuries often occur during an erection because it makes the tunica albuginea stiffer and thinner than when the penis is flaccid. Patients report hearing a snap when the penis is forced into an angle during sexual activity. This was reportedly the case with German singer-song writer Dieter Bohlen, whose ex-girlfriend Nadja Abd El Farrag is said to have written in her book “Ungelogen”, or “Honestly”, that there was a sudden snap during an intimate moment one December night (Christmas?), after which she called the fire brigade in her distress.

Multiple Causes Possible

Other factors contributing to penile fractures include rolling over in bed onto an erect penis, forced bending to achieve detumescence, and blunt external traumas like kicks.

Some penile fractures can be caused by patients “kneading and ripping” their erect penis to quickly reduce swelling. In an Iranian study, 269 out of 352 patients (76%) who underwent this process, known as “ taqaandan” in Iran, suffered a penile fracture.

Penile fractures can also occur in children, as evidenced by the case history of a 7-year-old boy described a few years ago in the journal Urology where the cause was a fall onto the penis.

Immediate Action Required

The treatment of choice for a fresh penile fracture is surgical repair of the tunica albuginea defect and, if necessary, the urethra. Timely surgical intervention yields significantly better long-term outcomes than conservative therapy regarding late complications such as erectile dysfunction and penile curvature. It also reduces the rate of early complications, such as severe corporal infections. Conservative therapy should be reserved for patients who explicitly refuse surgical intervention after thorough consultation.

This article was translated from Univadis Germany using ChatGPT followed by human editing.

A version of this article appeared on Medscape.com.

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Adverse events in childhood alter brain function

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Fri, 12/08/2023 - 13:36

Early childhood trauma alters brain function in adults, according to new research.

In a meta-analysis of 83 functional magnetic resonance imaging (fMRI) studies that included more than 5000 patients, exposure to adversity was associated with higher amygdala reactivity and lower prefrontal cortical reactivity across a range of task domains. 

The altered responses were only observed in studies including adult participants and were clearest in participants who had been exposed to severe threat and trauma. Children and adolescents did not show significant adversity-related differences in brain function.

“By integrating the results from 83 previous brain imaging studies, we were able to provide what is arguably the clearest evidence to date that adults who have been exposed to early life trauma have different brain responses to psychological challenges,” senior author Marco Leyton, PhD, professor of psychiatry and director of the Temperament Adversity Biology Lab at McGill University in Montreal, Quebec, Canada, said in a press release. “This includes exaggerated responses in a region that processes emotionally intense information (the amygdala) and reduced responses in a region that helps people regulate emotions and associated behaviors (the frontal cortex).”

The findings were published in JAMA Network Open.
 

Changes in Reactivity 

“One big issue we have in psychology, and especially in neuroscience, is that single-study results are often not reproducible,” lead author Niki Hosseini-Kamkar, PhD, neuroimaging research associate at Atlas Institute for Veterans and Families at Royal Ottawa Hospital, said in an interview.

“It was very important to me to use a meta-analysis to get an overall picture of what brain regions are consistently reported across all these different studies. That is what we did here,” she added. Dr. Hosseini-Kamkar conducted this analysis while she was a postdoctoral research fellow at McGill University in Montreal.

She and her group examined adversity exposure and brain function in the following four domains of task-based fMRI: emotion processing, memory processing, inhibitory control, and reward processing. Their study included 5242 participants. The researchers used multilevel kernel density analyses (MKDA) to analyze the data more accurately. 

Adversity exposure was associated with higher amygdala reactivity (P < .001) and lower prefrontal cortical reactivity (P < .001), compared with controls with no adversity exposure.

Threat types of adversity were associated with greater blood-oxygen-level-dependent (BOLD) responses in the superior temporal gyrus and lower prefrontal cortex activity in participants exposed to threat, compared with controls. 

Analysis of studies of inhibitory control tasks found greater activity in the claustrum, anterior cingulate cortex, and insula in the adversity-exposed participants, compared with controls.

In addition, studies that administered emotion processing tasks showed greater amygdala reactivity and lower prefrontal cortex (superior frontal gyrus) reactivity in the adversity exposure group, compared with controls.

“The main takeaway is that there’s an exaggerated activity in the amygdala, and diminished prefrontal cortex activity, and together, this might point to a mechanism for how a history of adversity diminishes the ability to cope with later stressors and can therefore heighten susceptibility to mental illness,” said Dr. Hosseini-Kamkar.
 

‘Important Next Step’ 

“Overall, the meta-analysis by Dr. Hosseini-Kamkar and colleagues represents an important next step in understanding associations of adversity exposure with brain function while highlighting the importance of considering the role of development,” wrote Dylan G. Gee, PhD, associate professor of psychology at Yale University in New Haven, Connecticut, and Alexis Brieant, PhD, assistant professor of research or creative works at the University of Vermont in Burlington, in an accompanying commentary

They also applauded the authors for their use of MKDA. They noted that the technique “allows inferences about the consistency and specificity of brain activation across studies and is thought to be more robust to small sample sizes than activation likelihood estimation (ALE) meta-analysis.” 

Dr. Gee and Dr. Brieant also observed that a recent ALE meta-analysis failed to find a link between adversity and brain function. “Although it is important to note that the file drawer problem — by which researchers are less likely to publish null results — presents challenges to the inferences that can be drawn in the current work, the current study may provide complementary information to prior ALE meta-analyses.” 
 

 

 

Epigenetic Changes? 

Commenting on the findings for this article, Victor Fornari, MD, director of child and adolescent psychiatry at Northwell Health in Glen Oaks, New York, said, “Historically, when someone went through a traumatic event, they were told to just get over it, because somehow trauma doesn’t have a lasting impact on the brain.” Dr. Fornari was not involved in the research.

“We have certainly learned so much more over the past decade about early adversity and that it does have a profound impact on the brain and probably even epigenetic changes in our genes,” Dr. Fornari said.

“This is a very important avenue of investigation. People are really trying to understand if there are biological markers that we can actually measure in the brain that will offer us a window to better understand the consequence of adversity, as well as possible avenues of treatment.” 

No funding source for this study was reported. Dr. Leyton, Dr. Hosseini-Kamkar, and Dr. Fornari report no relevant financial relationships. Gee reports receiving grants from the National Science Foundation and National Institutes of Health outside the submitted work. Dr. Brieant reports receiving grants from the National Institute of Mental Health outside the submitted work. 

A version of this article appeared on Medscape.com.

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Early childhood trauma alters brain function in adults, according to new research.

In a meta-analysis of 83 functional magnetic resonance imaging (fMRI) studies that included more than 5000 patients, exposure to adversity was associated with higher amygdala reactivity and lower prefrontal cortical reactivity across a range of task domains. 

The altered responses were only observed in studies including adult participants and were clearest in participants who had been exposed to severe threat and trauma. Children and adolescents did not show significant adversity-related differences in brain function.

“By integrating the results from 83 previous brain imaging studies, we were able to provide what is arguably the clearest evidence to date that adults who have been exposed to early life trauma have different brain responses to psychological challenges,” senior author Marco Leyton, PhD, professor of psychiatry and director of the Temperament Adversity Biology Lab at McGill University in Montreal, Quebec, Canada, said in a press release. “This includes exaggerated responses in a region that processes emotionally intense information (the amygdala) and reduced responses in a region that helps people regulate emotions and associated behaviors (the frontal cortex).”

The findings were published in JAMA Network Open.
 

Changes in Reactivity 

“One big issue we have in psychology, and especially in neuroscience, is that single-study results are often not reproducible,” lead author Niki Hosseini-Kamkar, PhD, neuroimaging research associate at Atlas Institute for Veterans and Families at Royal Ottawa Hospital, said in an interview.

“It was very important to me to use a meta-analysis to get an overall picture of what brain regions are consistently reported across all these different studies. That is what we did here,” she added. Dr. Hosseini-Kamkar conducted this analysis while she was a postdoctoral research fellow at McGill University in Montreal.

She and her group examined adversity exposure and brain function in the following four domains of task-based fMRI: emotion processing, memory processing, inhibitory control, and reward processing. Their study included 5242 participants. The researchers used multilevel kernel density analyses (MKDA) to analyze the data more accurately. 

Adversity exposure was associated with higher amygdala reactivity (P < .001) and lower prefrontal cortical reactivity (P < .001), compared with controls with no adversity exposure.

Threat types of adversity were associated with greater blood-oxygen-level-dependent (BOLD) responses in the superior temporal gyrus and lower prefrontal cortex activity in participants exposed to threat, compared with controls. 

Analysis of studies of inhibitory control tasks found greater activity in the claustrum, anterior cingulate cortex, and insula in the adversity-exposed participants, compared with controls.

In addition, studies that administered emotion processing tasks showed greater amygdala reactivity and lower prefrontal cortex (superior frontal gyrus) reactivity in the adversity exposure group, compared with controls.

“The main takeaway is that there’s an exaggerated activity in the amygdala, and diminished prefrontal cortex activity, and together, this might point to a mechanism for how a history of adversity diminishes the ability to cope with later stressors and can therefore heighten susceptibility to mental illness,” said Dr. Hosseini-Kamkar.
 

‘Important Next Step’ 

“Overall, the meta-analysis by Dr. Hosseini-Kamkar and colleagues represents an important next step in understanding associations of adversity exposure with brain function while highlighting the importance of considering the role of development,” wrote Dylan G. Gee, PhD, associate professor of psychology at Yale University in New Haven, Connecticut, and Alexis Brieant, PhD, assistant professor of research or creative works at the University of Vermont in Burlington, in an accompanying commentary

They also applauded the authors for their use of MKDA. They noted that the technique “allows inferences about the consistency and specificity of brain activation across studies and is thought to be more robust to small sample sizes than activation likelihood estimation (ALE) meta-analysis.” 

Dr. Gee and Dr. Brieant also observed that a recent ALE meta-analysis failed to find a link between adversity and brain function. “Although it is important to note that the file drawer problem — by which researchers are less likely to publish null results — presents challenges to the inferences that can be drawn in the current work, the current study may provide complementary information to prior ALE meta-analyses.” 
 

 

 

Epigenetic Changes? 

Commenting on the findings for this article, Victor Fornari, MD, director of child and adolescent psychiatry at Northwell Health in Glen Oaks, New York, said, “Historically, when someone went through a traumatic event, they were told to just get over it, because somehow trauma doesn’t have a lasting impact on the brain.” Dr. Fornari was not involved in the research.

“We have certainly learned so much more over the past decade about early adversity and that it does have a profound impact on the brain and probably even epigenetic changes in our genes,” Dr. Fornari said.

“This is a very important avenue of investigation. People are really trying to understand if there are biological markers that we can actually measure in the brain that will offer us a window to better understand the consequence of adversity, as well as possible avenues of treatment.” 

No funding source for this study was reported. Dr. Leyton, Dr. Hosseini-Kamkar, and Dr. Fornari report no relevant financial relationships. Gee reports receiving grants from the National Science Foundation and National Institutes of Health outside the submitted work. Dr. Brieant reports receiving grants from the National Institute of Mental Health outside the submitted work. 

A version of this article appeared on Medscape.com.

Early childhood trauma alters brain function in adults, according to new research.

In a meta-analysis of 83 functional magnetic resonance imaging (fMRI) studies that included more than 5000 patients, exposure to adversity was associated with higher amygdala reactivity and lower prefrontal cortical reactivity across a range of task domains. 

The altered responses were only observed in studies including adult participants and were clearest in participants who had been exposed to severe threat and trauma. Children and adolescents did not show significant adversity-related differences in brain function.

“By integrating the results from 83 previous brain imaging studies, we were able to provide what is arguably the clearest evidence to date that adults who have been exposed to early life trauma have different brain responses to psychological challenges,” senior author Marco Leyton, PhD, professor of psychiatry and director of the Temperament Adversity Biology Lab at McGill University in Montreal, Quebec, Canada, said in a press release. “This includes exaggerated responses in a region that processes emotionally intense information (the amygdala) and reduced responses in a region that helps people regulate emotions and associated behaviors (the frontal cortex).”

The findings were published in JAMA Network Open.
 

Changes in Reactivity 

“One big issue we have in psychology, and especially in neuroscience, is that single-study results are often not reproducible,” lead author Niki Hosseini-Kamkar, PhD, neuroimaging research associate at Atlas Institute for Veterans and Families at Royal Ottawa Hospital, said in an interview.

“It was very important to me to use a meta-analysis to get an overall picture of what brain regions are consistently reported across all these different studies. That is what we did here,” she added. Dr. Hosseini-Kamkar conducted this analysis while she was a postdoctoral research fellow at McGill University in Montreal.

She and her group examined adversity exposure and brain function in the following four domains of task-based fMRI: emotion processing, memory processing, inhibitory control, and reward processing. Their study included 5242 participants. The researchers used multilevel kernel density analyses (MKDA) to analyze the data more accurately. 

Adversity exposure was associated with higher amygdala reactivity (P < .001) and lower prefrontal cortical reactivity (P < .001), compared with controls with no adversity exposure.

Threat types of adversity were associated with greater blood-oxygen-level-dependent (BOLD) responses in the superior temporal gyrus and lower prefrontal cortex activity in participants exposed to threat, compared with controls. 

Analysis of studies of inhibitory control tasks found greater activity in the claustrum, anterior cingulate cortex, and insula in the adversity-exposed participants, compared with controls.

In addition, studies that administered emotion processing tasks showed greater amygdala reactivity and lower prefrontal cortex (superior frontal gyrus) reactivity in the adversity exposure group, compared with controls.

“The main takeaway is that there’s an exaggerated activity in the amygdala, and diminished prefrontal cortex activity, and together, this might point to a mechanism for how a history of adversity diminishes the ability to cope with later stressors and can therefore heighten susceptibility to mental illness,” said Dr. Hosseini-Kamkar.
 

‘Important Next Step’ 

“Overall, the meta-analysis by Dr. Hosseini-Kamkar and colleagues represents an important next step in understanding associations of adversity exposure with brain function while highlighting the importance of considering the role of development,” wrote Dylan G. Gee, PhD, associate professor of psychology at Yale University in New Haven, Connecticut, and Alexis Brieant, PhD, assistant professor of research or creative works at the University of Vermont in Burlington, in an accompanying commentary

They also applauded the authors for their use of MKDA. They noted that the technique “allows inferences about the consistency and specificity of brain activation across studies and is thought to be more robust to small sample sizes than activation likelihood estimation (ALE) meta-analysis.” 

Dr. Gee and Dr. Brieant also observed that a recent ALE meta-analysis failed to find a link between adversity and brain function. “Although it is important to note that the file drawer problem — by which researchers are less likely to publish null results — presents challenges to the inferences that can be drawn in the current work, the current study may provide complementary information to prior ALE meta-analyses.” 
 

 

 

Epigenetic Changes? 

Commenting on the findings for this article, Victor Fornari, MD, director of child and adolescent psychiatry at Northwell Health in Glen Oaks, New York, said, “Historically, when someone went through a traumatic event, they were told to just get over it, because somehow trauma doesn’t have a lasting impact on the brain.” Dr. Fornari was not involved in the research.

“We have certainly learned so much more over the past decade about early adversity and that it does have a profound impact on the brain and probably even epigenetic changes in our genes,” Dr. Fornari said.

“This is a very important avenue of investigation. People are really trying to understand if there are biological markers that we can actually measure in the brain that will offer us a window to better understand the consequence of adversity, as well as possible avenues of treatment.” 

No funding source for this study was reported. Dr. Leyton, Dr. Hosseini-Kamkar, and Dr. Fornari report no relevant financial relationships. Gee reports receiving grants from the National Science Foundation and National Institutes of Health outside the submitted work. Dr. Brieant reports receiving grants from the National Institute of Mental Health outside the submitted work. 

A version of this article appeared on Medscape.com.

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