Trauma

Mild traumatic brain injury (TBI) is linked to a significantly increased risk for a host of subsequent cardiovascular, endocrine, neurologic, and psychiatric disorders, new research shows.

Incidence of hypertension, coronary heart disease, diabetes, stroke, depression, and dementia all began to increase soon after the brain injury and persisted over a decade in both mild and moderate to severe TBI.

Researchers found the multisystem comorbidities in all age groups, including in patients as young as 18. They also found that patients who developed multiple postinjury problems had higher mortality during the decade-long follow-up.

The findings suggest patients with TBI may require longer follow-up and proactive screening for multisystem disease, regardless of age or injury severity.

“The fact that both patients with mild and moderate to severe injuries both had long-term ongoing associations with comorbidities that continued over time and that they are cardiovascular, endocrine, neurologic, and behavioral health oriented was pretty striking,” study author Ross Zafonte, DO, PhD, president of Spaulding Rehab Hospital and professor and chair of physical medicine and rehab at Harvard Medical School, both in Boston, told this news organization.

The study was published online in JAMA Network Open.
 

Injury severity not a factor

An estimated 2.8 million individuals in the United States experience TBI every year. Worldwide, the figure may be as high as 74 million.

Studies have long suggested a link between brain injury and subsequent neurologic disorders, but research suggesting a possible link to cardiovascular and endocrine problems has recently gained attention.

Building on a 2021 study that showed increased incidence of cardiovascular issues following a concussion, the researchers examined medical records of previously healthy patients treated for TBI between 2000 and 2015 who also had at least 1 follow-up visit between 6 months and 10 years after the initial injury.

Researchers analyzed data from 13,053 individuals – 4,351 with mild injury (mTBI), 4351 with moderate to severe injury (msTBI), and 4351 with no TBI. The most common cause of injury was a fall. Patients with sports-related injuries were excluded.

Incidence of hypertension was significantly higher among patients with mTBI (hazard ratio, 2.5; 95% confidence interval, 2.1-2.9) and msTBI (HR, 2.4; 95% CI, 2.0-2.9), compared with the unaffected group. Risk for other cardiovascular problems, including hyperlipidemia, obesity, and coronary artery disease, were also higher in the affected groups.

TBI patients also reported higher incidence of endocrine diseases, including diabetes (mTBI: HR, 1.9; 95% CI, 1.4-2.7; msTBI: HR, 1.9; 95% CI, 1.4-2.6). Elevated risk for ischemic stroke or transient ischemic attack was also increased (mTBI: HR, 2.2; 95% CI, 1.4-3.3; msTBI: HR, 3.6; 95% CI, 2.4-5.3).

Regardless of injury severity, patients with TBI had a higher risk for neurologic and psychiatric diseases, particularly depression, dementia, and psychotic disorders. “This tells us that mild TBI is not clean of events,” Dr. Zafonte said.

Surprising rate of comorbidity in youth

Investigators found increased risk for posttrauma comorbidities in all age groups, but researchers were struck by the high rates in younger patients, aged 18-40. Compared with age-matched individuals with no TBI history, hypertension risk was nearly six times higher in those with mTBI (HR, 5.9; 95% CI, 3.9-9.1) and nearly four times higher in patients with msTBI (HR, 3.9; 95% CI, 2.5-6.1).

Rates of hyperlipidemia and diabetes were also higher in younger patients in the mTBI group and posttraumatic seizures and psychiatric disorders were elevated regardless of TBI severity.

Overall, patients with msTBI, but not those with mTBI, were at higher risk for mortality, compared with the unexposed group (432 deaths [9.9%] vs. 250 deaths [5.7%]; P < .001).

“It’s clear that what we may be dealing with is that it holds up even for the younger people,” Dr. Zafonte said. “We used to think brain injury risk is worse in the severe cases, which it is, and it’s worse later on among those who are older, which it is. But our younger folks don’t get away either.”

While the study offers associations between TBI and multisystem health problems, Dr. Zafonte said it’s impossible to say at this point whether the brain injury caused the increased risk for cardiovascular or endocrine problems. Other organ injuries sustained in the trauma may be a contributing factor.

“Further data is needed to elucidate the mechanism and the causative relationships, which we do not have here,” he said.

Many of the postinjury comorbidities emerged a median of 3.5 years after TBI, regardless of severity. But some of the cardiovascular and psychiatric conditions emerged far sooner than that.

That’s important because research suggests less than half of patients with TBI receive follow-up care.

“It does make sense for folks who are interacting with people who’ve had a TBI to be suspicious of medical comorbidities relatively early on, within the first couple of years,” Dr. Zafonte said.

In an invited commentary, Vijay Krishnamoorthy, MD, MPH, PhD, Duke University, Durham, N.C., and Monica S. Vavilala, MD, University of Washington, Seattle, highlight some of the study’s limitations, including a lack of information on comorbidity severity and the lack of a matched group of patients who experienced non-head trauma.

Despite those limitations, the study offers important information on how TBI may affect organs beyond the brain, they noted.

“These observations, if replicated in future studies, raise intriguing implications in the future care of patients with TBI, including heightened chronic disease-screening measures and possibly enhanced guidelines for chronic extracranial organ system care for patients who experience TBI,” Dr. Krishnamoorthy and Dr. Vavilala wrote.

The study received no specific funding. Dr. Zafonte reported having received personal fees from Springer/Demos, serving on scientific advisory boards for Myomo and OnCare and has received funding from the Football Players Health Study at Harvard, funded in part by the National Football League Players Association. Dr. Krishnamoorthy and Dr. Vavilala disclosed no relevant financial relationships.

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

Mild traumatic brain injury (TBI) is linked to a significantly increased risk for a host of subsequent cardiovascular, endocrine, neurologic, and psychiatric disorders, new research shows.

Incidence of hypertension, coronary heart disease, diabetes, stroke, depression, and dementia all began to increase soon after the brain injury and persisted over a decade in both mild and moderate to severe TBI.

Researchers found the multisystem comorbidities in all age groups, including in patients as young as 18. They also found that patients who developed multiple postinjury problems had higher mortality during the decade-long follow-up.

The findings suggest patients with TBI may require longer follow-up and proactive screening for multisystem disease, regardless of age or injury severity.

“The fact that both patients with mild and moderate to severe injuries both had long-term ongoing associations with comorbidities that continued over time and that they are cardiovascular, endocrine, neurologic, and behavioral health oriented was pretty striking,” study author Ross Zafonte, DO, PhD, president of Spaulding Rehab Hospital and professor and chair of physical medicine and rehab at Harvard Medical School, both in Boston, told this news organization.

The study was published online in JAMA Network Open.
 

Injury severity not a factor

An estimated 2.8 million individuals in the United States experience TBI every year. Worldwide, the figure may be as high as 74 million.

Studies have long suggested a link between brain injury and subsequent neurologic disorders, but research suggesting a possible link to cardiovascular and endocrine problems has recently gained attention.

Building on a 2021 study that showed increased incidence of cardiovascular issues following a concussion, the researchers examined medical records of previously healthy patients treated for TBI between 2000 and 2015 who also had at least 1 follow-up visit between 6 months and 10 years after the initial injury.

Researchers analyzed data from 13,053 individuals – 4,351 with mild injury (mTBI), 4351 with moderate to severe injury (msTBI), and 4351 with no TBI. The most common cause of injury was a fall. Patients with sports-related injuries were excluded.

Incidence of hypertension was significantly higher among patients with mTBI (hazard ratio, 2.5; 95% confidence interval, 2.1-2.9) and msTBI (HR, 2.4; 95% CI, 2.0-2.9), compared with the unaffected group. Risk for other cardiovascular problems, including hyperlipidemia, obesity, and coronary artery disease, were also higher in the affected groups.

TBI patients also reported higher incidence of endocrine diseases, including diabetes (mTBI: HR, 1.9; 95% CI, 1.4-2.7; msTBI: HR, 1.9; 95% CI, 1.4-2.6). Elevated risk for ischemic stroke or transient ischemic attack was also increased (mTBI: HR, 2.2; 95% CI, 1.4-3.3; msTBI: HR, 3.6; 95% CI, 2.4-5.3).

Regardless of injury severity, patients with TBI had a higher risk for neurologic and psychiatric diseases, particularly depression, dementia, and psychotic disorders. “This tells us that mild TBI is not clean of events,” Dr. Zafonte said.

Surprising rate of comorbidity in youth

Investigators found increased risk for posttrauma comorbidities in all age groups, but researchers were struck by the high rates in younger patients, aged 18-40. Compared with age-matched individuals with no TBI history, hypertension risk was nearly six times higher in those with mTBI (HR, 5.9; 95% CI, 3.9-9.1) and nearly four times higher in patients with msTBI (HR, 3.9; 95% CI, 2.5-6.1).

Rates of hyperlipidemia and diabetes were also higher in younger patients in the mTBI group and posttraumatic seizures and psychiatric disorders were elevated regardless of TBI severity.

Overall, patients with msTBI, but not those with mTBI, were at higher risk for mortality, compared with the unexposed group (432 deaths [9.9%] vs. 250 deaths [5.7%]; P < .001).

“It’s clear that what we may be dealing with is that it holds up even for the younger people,” Dr. Zafonte said. “We used to think brain injury risk is worse in the severe cases, which it is, and it’s worse later on among those who are older, which it is. But our younger folks don’t get away either.”

While the study offers associations between TBI and multisystem health problems, Dr. Zafonte said it’s impossible to say at this point whether the brain injury caused the increased risk for cardiovascular or endocrine problems. Other organ injuries sustained in the trauma may be a contributing factor.

“Further data is needed to elucidate the mechanism and the causative relationships, which we do not have here,” he said.

Many of the postinjury comorbidities emerged a median of 3.5 years after TBI, regardless of severity. But some of the cardiovascular and psychiatric conditions emerged far sooner than that.

That’s important because research suggests less than half of patients with TBI receive follow-up care.

“It does make sense for folks who are interacting with people who’ve had a TBI to be suspicious of medical comorbidities relatively early on, within the first couple of years,” Dr. Zafonte said.

In an invited commentary, Vijay Krishnamoorthy, MD, MPH, PhD, Duke University, Durham, N.C., and Monica S. Vavilala, MD, University of Washington, Seattle, highlight some of the study’s limitations, including a lack of information on comorbidity severity and the lack of a matched group of patients who experienced non-head trauma.

Despite those limitations, the study offers important information on how TBI may affect organs beyond the brain, they noted.

“These observations, if replicated in future studies, raise intriguing implications in the future care of patients with TBI, including heightened chronic disease-screening measures and possibly enhanced guidelines for chronic extracranial organ system care for patients who experience TBI,” Dr. Krishnamoorthy and Dr. Vavilala wrote.

The study received no specific funding. Dr. Zafonte reported having received personal fees from Springer/Demos, serving on scientific advisory boards for Myomo and OnCare and has received funding from the Football Players Health Study at Harvard, funded in part by the National Football League Players Association. Dr. Krishnamoorthy and Dr. Vavilala disclosed no relevant financial relationships.

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

Mild traumatic brain injury (TBI) is linked to a significantly increased risk for a host of subsequent cardiovascular, endocrine, neurologic, and psychiatric disorders, new research shows.

Incidence of hypertension, coronary heart disease, diabetes, stroke, depression, and dementia all began to increase soon after the brain injury and persisted over a decade in both mild and moderate to severe TBI.

Researchers found the multisystem comorbidities in all age groups, including in patients as young as 18. They also found that patients who developed multiple postinjury problems had higher mortality during the decade-long follow-up.

The findings suggest patients with TBI may require longer follow-up and proactive screening for multisystem disease, regardless of age or injury severity.

“The fact that both patients with mild and moderate to severe injuries both had long-term ongoing associations with comorbidities that continued over time and that they are cardiovascular, endocrine, neurologic, and behavioral health oriented was pretty striking,” study author Ross Zafonte, DO, PhD, president of Spaulding Rehab Hospital and professor and chair of physical medicine and rehab at Harvard Medical School, both in Boston, told this news organization.

The study was published online in JAMA Network Open.
 

Injury severity not a factor

An estimated 2.8 million individuals in the United States experience TBI every year. Worldwide, the figure may be as high as 74 million.

Studies have long suggested a link between brain injury and subsequent neurologic disorders, but research suggesting a possible link to cardiovascular and endocrine problems has recently gained attention.

Building on a 2021 study that showed increased incidence of cardiovascular issues following a concussion, the researchers examined medical records of previously healthy patients treated for TBI between 2000 and 2015 who also had at least 1 follow-up visit between 6 months and 10 years after the initial injury.

Researchers analyzed data from 13,053 individuals – 4,351 with mild injury (mTBI), 4351 with moderate to severe injury (msTBI), and 4351 with no TBI. The most common cause of injury was a fall. Patients with sports-related injuries were excluded.

Incidence of hypertension was significantly higher among patients with mTBI (hazard ratio, 2.5; 95% confidence interval, 2.1-2.9) and msTBI (HR, 2.4; 95% CI, 2.0-2.9), compared with the unaffected group. Risk for other cardiovascular problems, including hyperlipidemia, obesity, and coronary artery disease, were also higher in the affected groups.

TBI patients also reported higher incidence of endocrine diseases, including diabetes (mTBI: HR, 1.9; 95% CI, 1.4-2.7; msTBI: HR, 1.9; 95% CI, 1.4-2.6). Elevated risk for ischemic stroke or transient ischemic attack was also increased (mTBI: HR, 2.2; 95% CI, 1.4-3.3; msTBI: HR, 3.6; 95% CI, 2.4-5.3).

Regardless of injury severity, patients with TBI had a higher risk for neurologic and psychiatric diseases, particularly depression, dementia, and psychotic disorders. “This tells us that mild TBI is not clean of events,” Dr. Zafonte said.

Surprising rate of comorbidity in youth

Investigators found increased risk for posttrauma comorbidities in all age groups, but researchers were struck by the high rates in younger patients, aged 18-40. Compared with age-matched individuals with no TBI history, hypertension risk was nearly six times higher in those with mTBI (HR, 5.9; 95% CI, 3.9-9.1) and nearly four times higher in patients with msTBI (HR, 3.9; 95% CI, 2.5-6.1).

Rates of hyperlipidemia and diabetes were also higher in younger patients in the mTBI group and posttraumatic seizures and psychiatric disorders were elevated regardless of TBI severity.

Overall, patients with msTBI, but not those with mTBI, were at higher risk for mortality, compared with the unexposed group (432 deaths [9.9%] vs. 250 deaths [5.7%]; P < .001).

“It’s clear that what we may be dealing with is that it holds up even for the younger people,” Dr. Zafonte said. “We used to think brain injury risk is worse in the severe cases, which it is, and it’s worse later on among those who are older, which it is. But our younger folks don’t get away either.”

While the study offers associations between TBI and multisystem health problems, Dr. Zafonte said it’s impossible to say at this point whether the brain injury caused the increased risk for cardiovascular or endocrine problems. Other organ injuries sustained in the trauma may be a contributing factor.

“Further data is needed to elucidate the mechanism and the causative relationships, which we do not have here,” he said.

Many of the postinjury comorbidities emerged a median of 3.5 years after TBI, regardless of severity. But some of the cardiovascular and psychiatric conditions emerged far sooner than that.

That’s important because research suggests less than half of patients with TBI receive follow-up care.

“It does make sense for folks who are interacting with people who’ve had a TBI to be suspicious of medical comorbidities relatively early on, within the first couple of years,” Dr. Zafonte said.

In an invited commentary, Vijay Krishnamoorthy, MD, MPH, PhD, Duke University, Durham, N.C., and Monica S. Vavilala, MD, University of Washington, Seattle, highlight some of the study’s limitations, including a lack of information on comorbidity severity and the lack of a matched group of patients who experienced non-head trauma.

Despite those limitations, the study offers important information on how TBI may affect organs beyond the brain, they noted.

“These observations, if replicated in future studies, raise intriguing implications in the future care of patients with TBI, including heightened chronic disease-screening measures and possibly enhanced guidelines for chronic extracranial organ system care for patients who experience TBI,” Dr. Krishnamoorthy and Dr. Vavilala wrote.

The study received no specific funding. Dr. Zafonte reported having received personal fees from Springer/Demos, serving on scientific advisory boards for Myomo and OnCare and has received funding from the Football Players Health Study at Harvard, funded in part by the National Football League Players Association. Dr. Krishnamoorthy and Dr. Vavilala disclosed no relevant financial relationships.

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

Caregivers who brought suicidal adolescents to the emergency department reported safer gun storage practices after firearm counseling – a crucial way to cut gun deaths among children, according to researchers from Cincinnati Children’s Hospital.

In the study, which took place between June 2021 and Feb 2022, gun safety counseling and handouts were provided to 99 families of children who had come to the ED with mental health problems. A separate set of 101 families in similar situations received counseling and handouts, along with two cable-style gun locks.

Four weeks later, parents in both groups reported an increase in safe storage practices in which they locked away all guns in the household. Those offered only counseling increased safe storage by 7.2% – from 89.9% to 97.1%.

The gains were greater for families that received locks in addition to counseling. The number of those who locked away all guns rose from 82.2% to 98.5% – a 16.3% increase. (Roughly one-third of families in both arms of the study were lost to follow-up, according to the researchers, which left 68 families in each group for analysis.)

Several caregivers in each group reported that guns had been removed entirely from the home, and more than 60% in each group said they had bought additional gun locks to secure their weapons.

“The main point of our study is that just-in-time counseling is very effective in helping these families of children with mental health concerns in securing all their guns, and an emergency department visit is a great time to do that,” said Bijan Ketabchi, MD, a clinical fellow in the division of emergency medicine at Cincinnati Children’s Hospital Medical Center, who presented the findings at the Pediatric Academic Societies annual meeting.

Dr. Ketabchi said his department sees 500-700 children each month with mental health concerns, most commonly depression. The mean age of adolescent patients in the study was 14 years.

Suicide is the second-leading cause of death among children in the United States. Both pediatric suicides and firearm suicides have increased in the past 2 decades, Dr. Ketabchi said. The number of youth suicides who use guns has risen 90% since 2008. One in three U.S. families own a firearm, and 4.6 million children live in a home with loaded, unlocked guns.

Among children aged 17 years and younger who die by firearm suicide, 82% used guns belonging to a family member.
 

The right time for the message

Interventions to encourage safe gun storage – at a time when caregivers are really listening – can be lifesaving, Dr. Ketabchi said.

“We know that counseling is really helpful for these families, because when they come to the emergency department with a concern, they can have a teachable moment,” he said in an interview. “It resonates with them a lot more than it normally would because they have experienced something traumatic.”

The importance of safe gun storage in households with adolescents can’t be overstated, even if the children are not at risk of suicide, said Naoka Carey, a doctoral candidate at Boston College.

Ms. Carey authored an article on the prevalence of handguns among adolescents that will be published in May in Pediatrics.

“Three kinds of harm for adolescents with access to guns are accidental injury, homicide, and suicide,” she said. “Families who own guns don’t always know their teens have access to the guns.”

The problem is getting worse. Ms. Carey and colleagues found that, between 2002 and 2019, the rate of children aged 12-17 who reported carrying handguns increased 41%. Most of them were White, and their families were in high-income brackets. New data show that firearm injuries have become the leading cause of death among youth in the United States, eclipsing auto accidents for the first time.

“Preventing tragedy in your family is more than reason enough to secure guns you have,” she said.

Dr. Ketabchi disclosed no relevant financial relationships.

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

Caregivers who brought suicidal adolescents to the emergency department reported safer gun storage practices after firearm counseling – a crucial way to cut gun deaths among children, according to researchers from Cincinnati Children’s Hospital.

In the study, which took place between June 2021 and Feb 2022, gun safety counseling and handouts were provided to 99 families of children who had come to the ED with mental health problems. A separate set of 101 families in similar situations received counseling and handouts, along with two cable-style gun locks.

Four weeks later, parents in both groups reported an increase in safe storage practices in which they locked away all guns in the household. Those offered only counseling increased safe storage by 7.2% – from 89.9% to 97.1%.

The gains were greater for families that received locks in addition to counseling. The number of those who locked away all guns rose from 82.2% to 98.5% – a 16.3% increase. (Roughly one-third of families in both arms of the study were lost to follow-up, according to the researchers, which left 68 families in each group for analysis.)

Several caregivers in each group reported that guns had been removed entirely from the home, and more than 60% in each group said they had bought additional gun locks to secure their weapons.

“The main point of our study is that just-in-time counseling is very effective in helping these families of children with mental health concerns in securing all their guns, and an emergency department visit is a great time to do that,” said Bijan Ketabchi, MD, a clinical fellow in the division of emergency medicine at Cincinnati Children’s Hospital Medical Center, who presented the findings at the Pediatric Academic Societies annual meeting.

Dr. Ketabchi said his department sees 500-700 children each month with mental health concerns, most commonly depression. The mean age of adolescent patients in the study was 14 years.

Suicide is the second-leading cause of death among children in the United States. Both pediatric suicides and firearm suicides have increased in the past 2 decades, Dr. Ketabchi said. The number of youth suicides who use guns has risen 90% since 2008. One in three U.S. families own a firearm, and 4.6 million children live in a home with loaded, unlocked guns.

Among children aged 17 years and younger who die by firearm suicide, 82% used guns belonging to a family member.
 

The right time for the message

Interventions to encourage safe gun storage – at a time when caregivers are really listening – can be lifesaving, Dr. Ketabchi said.

“We know that counseling is really helpful for these families, because when they come to the emergency department with a concern, they can have a teachable moment,” he said in an interview. “It resonates with them a lot more than it normally would because they have experienced something traumatic.”

The importance of safe gun storage in households with adolescents can’t be overstated, even if the children are not at risk of suicide, said Naoka Carey, a doctoral candidate at Boston College.

Ms. Carey authored an article on the prevalence of handguns among adolescents that will be published in May in Pediatrics.

“Three kinds of harm for adolescents with access to guns are accidental injury, homicide, and suicide,” she said. “Families who own guns don’t always know their teens have access to the guns.”

The problem is getting worse. Ms. Carey and colleagues found that, between 2002 and 2019, the rate of children aged 12-17 who reported carrying handguns increased 41%. Most of them were White, and their families were in high-income brackets. New data show that firearm injuries have become the leading cause of death among youth in the United States, eclipsing auto accidents for the first time.

“Preventing tragedy in your family is more than reason enough to secure guns you have,” she said.

Dr. Ketabchi disclosed no relevant financial relationships.

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

Caregivers who brought suicidal adolescents to the emergency department reported safer gun storage practices after firearm counseling – a crucial way to cut gun deaths among children, according to researchers from Cincinnati Children’s Hospital.

In the study, which took place between June 2021 and Feb 2022, gun safety counseling and handouts were provided to 99 families of children who had come to the ED with mental health problems. A separate set of 101 families in similar situations received counseling and handouts, along with two cable-style gun locks.

Four weeks later, parents in both groups reported an increase in safe storage practices in which they locked away all guns in the household. Those offered only counseling increased safe storage by 7.2% – from 89.9% to 97.1%.

The gains were greater for families that received locks in addition to counseling. The number of those who locked away all guns rose from 82.2% to 98.5% – a 16.3% increase. (Roughly one-third of families in both arms of the study were lost to follow-up, according to the researchers, which left 68 families in each group for analysis.)

Several caregivers in each group reported that guns had been removed entirely from the home, and more than 60% in each group said they had bought additional gun locks to secure their weapons.

“The main point of our study is that just-in-time counseling is very effective in helping these families of children with mental health concerns in securing all their guns, and an emergency department visit is a great time to do that,” said Bijan Ketabchi, MD, a clinical fellow in the division of emergency medicine at Cincinnati Children’s Hospital Medical Center, who presented the findings at the Pediatric Academic Societies annual meeting.

Dr. Ketabchi said his department sees 500-700 children each month with mental health concerns, most commonly depression. The mean age of adolescent patients in the study was 14 years.

Suicide is the second-leading cause of death among children in the United States. Both pediatric suicides and firearm suicides have increased in the past 2 decades, Dr. Ketabchi said. The number of youth suicides who use guns has risen 90% since 2008. One in three U.S. families own a firearm, and 4.6 million children live in a home with loaded, unlocked guns.

Among children aged 17 years and younger who die by firearm suicide, 82% used guns belonging to a family member.
 

The right time for the message

Interventions to encourage safe gun storage – at a time when caregivers are really listening – can be lifesaving, Dr. Ketabchi said.

“We know that counseling is really helpful for these families, because when they come to the emergency department with a concern, they can have a teachable moment,” he said in an interview. “It resonates with them a lot more than it normally would because they have experienced something traumatic.”

The importance of safe gun storage in households with adolescents can’t be overstated, even if the children are not at risk of suicide, said Naoka Carey, a doctoral candidate at Boston College.

Ms. Carey authored an article on the prevalence of handguns among adolescents that will be published in May in Pediatrics.

“Three kinds of harm for adolescents with access to guns are accidental injury, homicide, and suicide,” she said. “Families who own guns don’t always know their teens have access to the guns.”

The problem is getting worse. Ms. Carey and colleagues found that, between 2002 and 2019, the rate of children aged 12-17 who reported carrying handguns increased 41%. Most of them were White, and their families were in high-income brackets. New data show that firearm injuries have become the leading cause of death among youth in the United States, eclipsing auto accidents for the first time.

“Preventing tragedy in your family is more than reason enough to secure guns you have,” she said.

Dr. Ketabchi disclosed no relevant financial relationships.

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

A novel endovascular brain-computer interface is safe and effective, allowing paralyzed patients to use their thoughts to perform daily tasks, results of a small, first-in-human study show.

A potential life changer for patients with amyotrophic lateral sclerosis (ALS), the minimally invasive device enables patients to carry out important activities of daily living.

“Our participants are able to use the device to perform tasks like sending email, texting loved ones and caregivers, browsing the web, and doing personal finances such as online banking,” study investigator Douglas J. Weber, PhD, professor of mechanical engineering and neuroscience, Carnegie Mellon University, Pittsburgh, told a press briefing.

The technology allowed one patient to write a book (due out later this year) and another patient to maintain communication despite losing his ability to speak, said the study’s lead investigator, Bruce Campbell, MBBS, PhD, professor of neurology, Royal Melbourne Hospital, University of Melbourne.

“In addition to providing patients with communicative capabilities not possible as a result of their disease, it is our goal to enable patients to be more independently involved in their care going forward, by enabling effective and faster communication directly with their caregiver and physician,” said Dr. Campbell.

The findings were presented at the 2022 annual meeting of the American Academy of Neurology.
 

Minimally invasive

ALS, also known as Lou Gehrig’s disease, is a progressive neurodegenerative disease that affects nerve cells in the brain and spinal cord. Patients with ALS eventually lose the ability to control muscle movement, often leading to total paralysis.

“Extending the period in which patients are able to communicate with loved ones and caregivers could provide a very meaningful benefit to patients with ALS,” said Dr. Weber.

Brain-computer interfaces measure and translate brain signals, with some functioning as motor neuro-prostheses. These devices provide direct communication between the brain and an external device by recording and decoding signals from the precentral gyrus as the result of movement intention.

“The technology has potential to empower the more than five million people in the U.S. who are severely paralyzed to once again perform important activities of daily living independently,” said Dr. Weber.

Until now, motor neuro-prostheses required surgery to remove a portion of the skull and place electrodes on to the brain. However, the new minimally invasive motor neuro-prostheses reach the brain by vascular access, dispensing with the need for a craniotomy.

“The brain-computer interface device used in our study is unique in that it does not require invasive open surgery to implant,” said Dr. Weber. “Instead this is an endovascular brain-computer interface.”

Using a catheter, surgeons feed the BCI through one of two jugular veins in the neck. They position an array of 16 sensors or electrodes on a stent-like scaffold that deploys against the walls of the superior sagittal sinus.
 

No adverse events

Describing the device, Dr. Weber said the electrodes or sensing elements are tiny and the body of the stent, which serves as a scaffold to support the electrodes, resembles a standard endovascular stent.

“It’s very small at the time of delivery because it’s held within the body of a catheter, but then when deployed it expands to contact the wall of the vein.”

The device transmits brain signals from the motor cortex to an electronics unit, located in a subcutaneous pocket that decodes movement signals. The machine-learning decoder is programmed as follows: When a trainer asked participants to attempt certain movements, like tapping their foot or extending their knee, the decoder analyzes nerve cell signals from those movement attempts. The decoder is able to translate movement signals into computer navigation.

The study included four patients with ALS who were paralyzed because of the disease and were trained to use the device.

A key safety endpoint was device-related serious adverse events resulting in death or increased disability during the post-implant evaluation period. Results showed all four participants successfully completed the 12-month follow-up with no serious adverse events.

Researchers also assessed target vessel patency and incidence of device migration at 3 and 12 months. Postoperative imaging showed that in all participants, the blood vessel that held the implanted device remained open and stayed in place.

Addressing the potential for blood clots, Dr. Weber said that so far there has been no sign of clotting or vascular occlusion.

“The device itself integrates well into the walls of the blood vessel over time,” he said. “Within the acute period after implantation, there’s time where the device is exposed to the blood stream, but once it becomes encapsulated and fully integrated into the blood vessel wall, the risks of thrombosis diminish.”
 

Greater independence

Researchers also recorded signal fidelity and stability over 12 months and use of the brain-computer interface to perform routine tasks. All participants learned to use the motor neuro-prostheses with eye tracking for computer use. Eye tracking technology helps a computer determine what a person is looking at.

Using the system, patients were able to complete tasks without help. These included text messaging and managing finances. “Since the device is fully implanted and easy for patients to use, they can use the technology independently and in their own home,” said Dr. Weber.

Although the study started with patients with ALS, those paralyzed from other causes, such as an upper spinal cord injury or brain-stem stroke could also benefit from this technology, Dr. Weber said. In addition, the technology could be expanded to broaden brain communication capabilities potentially to include robotic limbs, he said.

There’s even the potential to use this minimally invasive brain interface technology to deliver therapies like deep brain stimulation, which Dr. Weber noted is a growing field. “It’s [the] early days, but it’s a very exciting new direction for brain interface technology,” he said.

Researchers are now recruiting patients for the first U.S.-based feasibility trial of the device that will be funded by the NIH, said Dr. Weber. A limitation of the research was the study’s small size.
 

Advancing the field

Reached for a comment, Kevin C. Davis, an MD and PhD student in the department of biomedical engineering, University of Miami Miller School of Medicine, said this new work moves the field forward in an important way.

Dr. Davis and colleagues have shown the effectiveness of another technology used to overcome paralysis – a small portable system that facilitates hand grasp of a patient with a spinal cord injury. He reported on this DBS-based BCI system at the American Association of Neurological Surgeons (AANS) 2021 Annual Meeting.

Developing effective brain-computer interfaces, and motor neural prosthetics that avoid surgery, as the team did in this new study, is “worth exploring,” said Dr. Davis.

However, although the device used in this new study avoids cranial surgery, “sole vascular access may limit the device’s ability to reach other areas of the brain more suitable for upper-limb motor prosthetics,” he said.

“Determining how much function such a device could provide to individuals with locked-in syndrome or paralysis will be important in determining its viability as an eventual clinical tool for patients.”

The study was supported by Synchron, the maker of the device, the U.S. Defense Advanced Research Projects Agency, the Office of Naval Research, the National Health and Medical Research Council of Australia, the Australian Federal Government Foundation, and the Motor Neuron Disease Research Institute of Australia.

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

A novel endovascular brain-computer interface is safe and effective, allowing paralyzed patients to use their thoughts to perform daily tasks, results of a small, first-in-human study show.

A potential life changer for patients with amyotrophic lateral sclerosis (ALS), the minimally invasive device enables patients to carry out important activities of daily living.

“Our participants are able to use the device to perform tasks like sending email, texting loved ones and caregivers, browsing the web, and doing personal finances such as online banking,” study investigator Douglas J. Weber, PhD, professor of mechanical engineering and neuroscience, Carnegie Mellon University, Pittsburgh, told a press briefing.

The technology allowed one patient to write a book (due out later this year) and another patient to maintain communication despite losing his ability to speak, said the study’s lead investigator, Bruce Campbell, MBBS, PhD, professor of neurology, Royal Melbourne Hospital, University of Melbourne.

“In addition to providing patients with communicative capabilities not possible as a result of their disease, it is our goal to enable patients to be more independently involved in their care going forward, by enabling effective and faster communication directly with their caregiver and physician,” said Dr. Campbell.

The findings were presented at the 2022 annual meeting of the American Academy of Neurology.
 

Minimally invasive

ALS, also known as Lou Gehrig’s disease, is a progressive neurodegenerative disease that affects nerve cells in the brain and spinal cord. Patients with ALS eventually lose the ability to control muscle movement, often leading to total paralysis.

“Extending the period in which patients are able to communicate with loved ones and caregivers could provide a very meaningful benefit to patients with ALS,” said Dr. Weber.

Brain-computer interfaces measure and translate brain signals, with some functioning as motor neuro-prostheses. These devices provide direct communication between the brain and an external device by recording and decoding signals from the precentral gyrus as the result of movement intention.

“The technology has potential to empower the more than five million people in the U.S. who are severely paralyzed to once again perform important activities of daily living independently,” said Dr. Weber.

Until now, motor neuro-prostheses required surgery to remove a portion of the skull and place electrodes on to the brain. However, the new minimally invasive motor neuro-prostheses reach the brain by vascular access, dispensing with the need for a craniotomy.

“The brain-computer interface device used in our study is unique in that it does not require invasive open surgery to implant,” said Dr. Weber. “Instead this is an endovascular brain-computer interface.”

Using a catheter, surgeons feed the BCI through one of two jugular veins in the neck. They position an array of 16 sensors or electrodes on a stent-like scaffold that deploys against the walls of the superior sagittal sinus.
 

No adverse events

Describing the device, Dr. Weber said the electrodes or sensing elements are tiny and the body of the stent, which serves as a scaffold to support the electrodes, resembles a standard endovascular stent.

“It’s very small at the time of delivery because it’s held within the body of a catheter, but then when deployed it expands to contact the wall of the vein.”

The device transmits brain signals from the motor cortex to an electronics unit, located in a subcutaneous pocket that decodes movement signals. The machine-learning decoder is programmed as follows: When a trainer asked participants to attempt certain movements, like tapping their foot or extending their knee, the decoder analyzes nerve cell signals from those movement attempts. The decoder is able to translate movement signals into computer navigation.

The study included four patients with ALS who were paralyzed because of the disease and were trained to use the device.

A key safety endpoint was device-related serious adverse events resulting in death or increased disability during the post-implant evaluation period. Results showed all four participants successfully completed the 12-month follow-up with no serious adverse events.

Researchers also assessed target vessel patency and incidence of device migration at 3 and 12 months. Postoperative imaging showed that in all participants, the blood vessel that held the implanted device remained open and stayed in place.

Addressing the potential for blood clots, Dr. Weber said that so far there has been no sign of clotting or vascular occlusion.

“The device itself integrates well into the walls of the blood vessel over time,” he said. “Within the acute period after implantation, there’s time where the device is exposed to the blood stream, but once it becomes encapsulated and fully integrated into the blood vessel wall, the risks of thrombosis diminish.”
 

Greater independence

Researchers also recorded signal fidelity and stability over 12 months and use of the brain-computer interface to perform routine tasks. All participants learned to use the motor neuro-prostheses with eye tracking for computer use. Eye tracking technology helps a computer determine what a person is looking at.

Using the system, patients were able to complete tasks without help. These included text messaging and managing finances. “Since the device is fully implanted and easy for patients to use, they can use the technology independently and in their own home,” said Dr. Weber.

Although the study started with patients with ALS, those paralyzed from other causes, such as an upper spinal cord injury or brain-stem stroke could also benefit from this technology, Dr. Weber said. In addition, the technology could be expanded to broaden brain communication capabilities potentially to include robotic limbs, he said.

There’s even the potential to use this minimally invasive brain interface technology to deliver therapies like deep brain stimulation, which Dr. Weber noted is a growing field. “It’s [the] early days, but it’s a very exciting new direction for brain interface technology,” he said.

Researchers are now recruiting patients for the first U.S.-based feasibility trial of the device that will be funded by the NIH, said Dr. Weber. A limitation of the research was the study’s small size.
 

Advancing the field

Reached for a comment, Kevin C. Davis, an MD and PhD student in the department of biomedical engineering, University of Miami Miller School of Medicine, said this new work moves the field forward in an important way.

Dr. Davis and colleagues have shown the effectiveness of another technology used to overcome paralysis – a small portable system that facilitates hand grasp of a patient with a spinal cord injury. He reported on this DBS-based BCI system at the American Association of Neurological Surgeons (AANS) 2021 Annual Meeting.

Developing effective brain-computer interfaces, and motor neural prosthetics that avoid surgery, as the team did in this new study, is “worth exploring,” said Dr. Davis.

However, although the device used in this new study avoids cranial surgery, “sole vascular access may limit the device’s ability to reach other areas of the brain more suitable for upper-limb motor prosthetics,” he said.

“Determining how much function such a device could provide to individuals with locked-in syndrome or paralysis will be important in determining its viability as an eventual clinical tool for patients.”

The study was supported by Synchron, the maker of the device, the U.S. Defense Advanced Research Projects Agency, the Office of Naval Research, the National Health and Medical Research Council of Australia, the Australian Federal Government Foundation, and the Motor Neuron Disease Research Institute of Australia.

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

A novel endovascular brain-computer interface is safe and effective, allowing paralyzed patients to use their thoughts to perform daily tasks, results of a small, first-in-human study show.

A potential life changer for patients with amyotrophic lateral sclerosis (ALS), the minimally invasive device enables patients to carry out important activities of daily living.

“Our participants are able to use the device to perform tasks like sending email, texting loved ones and caregivers, browsing the web, and doing personal finances such as online banking,” study investigator Douglas J. Weber, PhD, professor of mechanical engineering and neuroscience, Carnegie Mellon University, Pittsburgh, told a press briefing.

The technology allowed one patient to write a book (due out later this year) and another patient to maintain communication despite losing his ability to speak, said the study’s lead investigator, Bruce Campbell, MBBS, PhD, professor of neurology, Royal Melbourne Hospital, University of Melbourne.

“In addition to providing patients with communicative capabilities not possible as a result of their disease, it is our goal to enable patients to be more independently involved in their care going forward, by enabling effective and faster communication directly with their caregiver and physician,” said Dr. Campbell.

The findings were presented at the 2022 annual meeting of the American Academy of Neurology.
 

Minimally invasive

ALS, also known as Lou Gehrig’s disease, is a progressive neurodegenerative disease that affects nerve cells in the brain and spinal cord. Patients with ALS eventually lose the ability to control muscle movement, often leading to total paralysis.

“Extending the period in which patients are able to communicate with loved ones and caregivers could provide a very meaningful benefit to patients with ALS,” said Dr. Weber.

Brain-computer interfaces measure and translate brain signals, with some functioning as motor neuro-prostheses. These devices provide direct communication between the brain and an external device by recording and decoding signals from the precentral gyrus as the result of movement intention.

“The technology has potential to empower the more than five million people in the U.S. who are severely paralyzed to once again perform important activities of daily living independently,” said Dr. Weber.

Until now, motor neuro-prostheses required surgery to remove a portion of the skull and place electrodes on to the brain. However, the new minimally invasive motor neuro-prostheses reach the brain by vascular access, dispensing with the need for a craniotomy.

“The brain-computer interface device used in our study is unique in that it does not require invasive open surgery to implant,” said Dr. Weber. “Instead this is an endovascular brain-computer interface.”

Using a catheter, surgeons feed the BCI through one of two jugular veins in the neck. They position an array of 16 sensors or electrodes on a stent-like scaffold that deploys against the walls of the superior sagittal sinus.
 

No adverse events

Describing the device, Dr. Weber said the electrodes or sensing elements are tiny and the body of the stent, which serves as a scaffold to support the electrodes, resembles a standard endovascular stent.

“It’s very small at the time of delivery because it’s held within the body of a catheter, but then when deployed it expands to contact the wall of the vein.”

The device transmits brain signals from the motor cortex to an electronics unit, located in a subcutaneous pocket that decodes movement signals. The machine-learning decoder is programmed as follows: When a trainer asked participants to attempt certain movements, like tapping their foot or extending their knee, the decoder analyzes nerve cell signals from those movement attempts. The decoder is able to translate movement signals into computer navigation.

The study included four patients with ALS who were paralyzed because of the disease and were trained to use the device.

A key safety endpoint was device-related serious adverse events resulting in death or increased disability during the post-implant evaluation period. Results showed all four participants successfully completed the 12-month follow-up with no serious adverse events.

Researchers also assessed target vessel patency and incidence of device migration at 3 and 12 months. Postoperative imaging showed that in all participants, the blood vessel that held the implanted device remained open and stayed in place.

Addressing the potential for blood clots, Dr. Weber said that so far there has been no sign of clotting or vascular occlusion.

“The device itself integrates well into the walls of the blood vessel over time,” he said. “Within the acute period after implantation, there’s time where the device is exposed to the blood stream, but once it becomes encapsulated and fully integrated into the blood vessel wall, the risks of thrombosis diminish.”
 

Greater independence

Researchers also recorded signal fidelity and stability over 12 months and use of the brain-computer interface to perform routine tasks. All participants learned to use the motor neuro-prostheses with eye tracking for computer use. Eye tracking technology helps a computer determine what a person is looking at.

Using the system, patients were able to complete tasks without help. These included text messaging and managing finances. “Since the device is fully implanted and easy for patients to use, they can use the technology independently and in their own home,” said Dr. Weber.

Although the study started with patients with ALS, those paralyzed from other causes, such as an upper spinal cord injury or brain-stem stroke could also benefit from this technology, Dr. Weber said. In addition, the technology could be expanded to broaden brain communication capabilities potentially to include robotic limbs, he said.

There’s even the potential to use this minimally invasive brain interface technology to deliver therapies like deep brain stimulation, which Dr. Weber noted is a growing field. “It’s [the] early days, but it’s a very exciting new direction for brain interface technology,” he said.

Researchers are now recruiting patients for the first U.S.-based feasibility trial of the device that will be funded by the NIH, said Dr. Weber. A limitation of the research was the study’s small size.
 

Advancing the field

Reached for a comment, Kevin C. Davis, an MD and PhD student in the department of biomedical engineering, University of Miami Miller School of Medicine, said this new work moves the field forward in an important way.

Dr. Davis and colleagues have shown the effectiveness of another technology used to overcome paralysis – a small portable system that facilitates hand grasp of a patient with a spinal cord injury. He reported on this DBS-based BCI system at the American Association of Neurological Surgeons (AANS) 2021 Annual Meeting.

Developing effective brain-computer interfaces, and motor neural prosthetics that avoid surgery, as the team did in this new study, is “worth exploring,” said Dr. Davis.

However, although the device used in this new study avoids cranial surgery, “sole vascular access may limit the device’s ability to reach other areas of the brain more suitable for upper-limb motor prosthetics,” he said.

“Determining how much function such a device could provide to individuals with locked-in syndrome or paralysis will be important in determining its viability as an eventual clinical tool for patients.”

The study was supported by Synchron, the maker of the device, the U.S. Defense Advanced Research Projects Agency, the Office of Naval Research, the National Health and Medical Research Council of Australia, the Australian Federal Government Foundation, and the Motor Neuron Disease Research Institute of Australia.

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

Many emergency departments are currently unable to provide care for geriatric patients that meets best practices and guidelines recommended by several major medical organizations, but a panel discussion in 2021 at the American Academy of Emergency Medicine’s Scientific Assembly identified three areas in which realistic improvements might be achieved.

In an article published online in the Journal of Emergency Medicine, Richard D. Shih, MD, of Florida Atlantic University, Boca Raton, and colleagues synthesized the presentation and discussion of an expert panel on the topic of the GED guidelines and the current realities of patient care.

The Geriatric Emergency Department (GED) Guidelines, published in 2014 in Annals of Emergency Medicine, were endorsed by the American College of Emergency Physicians, American Geriatrics Society, Emergency Nurses Association, and Society for Academic Emergency Medicine.

“With the substantial challenges in providing guideline-recommended care in EDs, this article will explore three high-impact GED clinical conditions to highlight guideline recommendations, challenges, and opportunities, and discuss realistically achievable expectations for non–GED-accredited institutions,” the authors wrote. The article addressed the ED patient with delirium, the ED fall patient, and the ED patient with polypharmacy.
 

Geriatric patients and delirium

When delirium in older adults is not identified in the ED, the patient’s 6-month mortality rate significantly increases, but few EDs have delirium screening protocols, the authors said. Challenges included the time and money needed to educate staff, on top of multiple mandatory training requirements on other topics. Delirium screening in the clinical setting also requires personnel to conduct assessments, and time to document symptoms and screening results in medical records.

“Perhaps the highest priority challenge for delirium experts is to evaluate and publish effective delirium intervention strategies because current evidence is completely lacking for ED-based delirium prevention or treatment,” they said. In the meantime, developing outcome measures for quality improvement of delirium care will require institutional support as well as education.
 

Geriatric patients and falls

Approximately one third of community-dwelling adults older than 65 years suffer falls, but data suggest that fewer than half of these individuals report falls to their doctors. “Older adults who present to an ED after a fall have an approximately 30% greater risk of functional decline and depression at 6 months after the event,” the authors noted.

The GED guidelines call for a comprehensive approach to evaluating and managing falls in older adults, but many of these “are untested in the ED,” the authors said. The recommended protocol includes an initial assessment of fall risk, followed by, for those at low risk, tailored recommendations for education and the use of community resources. Additional recommendations for those at high risk of falls include multifactorial assessment of modifiable risk factors, including peripheral neuropathy, balance/gait assessment, and medication review.

However, this best practice workflow is beyond the resource capacity of most EDs, the authors noted. “When ED resources are insufficient to support best practices, the care should focus on educating patients and caregivers about the significance of a fall event, providing educational materials (e.g., [the Centers for Disease Control and Prevention’s] STEADI materials), and assessing safety with respect to mobility for immediate return to the home environment and follow-up with a PCP.”
 

Geriatric patients and polypharmacy

Polypharmacy is common among older adults by virtue of their greater number of illnesses and comorbid conditions, and polypharmacy also has been associated with more adverse drug reactions, the authors said. The AGS Beers Criteria identifies medications associated with adverse drug reactions, but it is not practical for use in a busy ED setting. Instead, the authors suggested a more practical approach of focusing on a smaller list of common medications that tend to cause the adverse events that may result in ED visits.

“Perhaps targeting patients on multiple (three or more) psychoactive medications, drugs that can cause hypotension, or hypoglycemics could not only be done quickly, but identify patients in whom deprescribing should be considered in the ED,” the authors wrote. Deprescribing is a complicated process, however, and may be more effective when done via the patient’s primary care provider or in a geriatric consultation.

The GED Guidelines highlighted the specific needs of the geriatric population in the ED, the authors said. Widespread implementation remains a challenge, but many organizations provide resources to help improve care of geriatric patients in the ED and beyond.

In particular, the Geriatric Emergency Care Applied Research Network and Geriatric Emergency Department Collaborative provide funding opportunities, updated and focused published reviews, and webinars (some including free continuing medical education) for the entire health care team, including hospital administrators, the authors said.
 

Article brings attention to clinical realities

“The reality is that the overwhelming majority of emergency departments in the United States, if not globally, are simply not equipped – operationally or financially – to meet the rigorous standards that are required to fulfill the goals of operating an accredited geriatric ED,” Robert D. Glatter, MD, an emergency medicine physician at Lenox Hill Hospital, New York, said in an interview.

“Drawing attention to this important gap in accreditation is critical to not only inform hospitals, health care providers and stakeholders, but the public, patients, and their families about the important work that needs to be done to better equip all EDs with the proper tools and educational approaches to more effectively care for the geriatric community,” Dr. Glatter emphasized.

“There are currently three tiers of accreditation, with level 1 being the highest,” he explained, but there are only 100 geriatric ED accreditation-certified hospitals across the United States.

“I am not surprised at all by the challenges of implementing current GED guidelines,” said Dr. Glatter. “It comes down to operational and budget considerations, which ultimately compete with many other departments and regulatory constraints in any given hospital.”

However, “the bottom line is that such guidelines are designed with patient safety in mind, making them important issues in the eyes of any hospital administrator looking to improve outcomes and reduce medicolegal risk or exposure impacting geriatric patients in the emergency department,” he noted. 

Ultimately, guideline adherence “comes down to budget decisions, and where hospitals must invest their money to meet the bottom line,” said Dr. Glatter. “Making modifications to hospital infrastructure and architecture to accommodate geriatric patients may not be the top priority of hospital administrators when confronted with multiple competing interests. But, if it impacts patient safety, the decision to invest in structural and operational improvements may certainly have additional and important considerations.

“Until Medicare, or even the Joint Commission on Accreditation of Hospitals, adopts geriatric guidelines in emergency departments as a requirement for accreditation, there may not be adequate incentives in place currently to satisfy the intent of having a rigorous set of guidelines in the first place,” Dr. Glatter added. 

Despite the limitations of applying the current guidelines, there are some steps hospitals can take, said Dr. Glatter. “They can institute new measures in a graded fashion, with the goal of taking the important steps to satisfy at least some components of the guidelines. Attention to details can go a long way, such as rails in bathrooms, better lighting, and treads on floors that may reduce the risk of falls in the ED itself.

“Attention to fall prevention by assessing contributors including polypharmacy, gait instability, and quality of footwear can impact risk of future ED visits. Having incentives in place by Medicare or JACO may force the hand of hospital administrators to comply with geriatric guidelines and place emphasis on compliance,” noted Dr. Glatter.

More research is needed that “looks at costs of implementing geriatric guidelines in typical community and academic EDs and how this impacts key metrics such as length of stay, effect on reimbursement per ICD-10 code, and savings, if any, realized in reduced malpractice claims related to missed diagnoses (such as delirium), injuries, (patient falls), or medical misadventures due to polypharmacy,” he said.

The article received no outside funding. The authors disclosed no relevant financial relationships. Dr. Glatter disclosed no relevant financial relationships, and serves on the advisory board of Medscape Emergency Medicine.

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

Many emergency departments are currently unable to provide care for geriatric patients that meets best practices and guidelines recommended by several major medical organizations, but a panel discussion in 2021 at the American Academy of Emergency Medicine’s Scientific Assembly identified three areas in which realistic improvements might be achieved.

In an article published online in the Journal of Emergency Medicine, Richard D. Shih, MD, of Florida Atlantic University, Boca Raton, and colleagues synthesized the presentation and discussion of an expert panel on the topic of the GED guidelines and the current realities of patient care.

The Geriatric Emergency Department (GED) Guidelines, published in 2014 in Annals of Emergency Medicine, were endorsed by the American College of Emergency Physicians, American Geriatrics Society, Emergency Nurses Association, and Society for Academic Emergency Medicine.

“With the substantial challenges in providing guideline-recommended care in EDs, this article will explore three high-impact GED clinical conditions to highlight guideline recommendations, challenges, and opportunities, and discuss realistically achievable expectations for non–GED-accredited institutions,” the authors wrote. The article addressed the ED patient with delirium, the ED fall patient, and the ED patient with polypharmacy.
 

Geriatric patients and delirium

When delirium in older adults is not identified in the ED, the patient’s 6-month mortality rate significantly increases, but few EDs have delirium screening protocols, the authors said. Challenges included the time and money needed to educate staff, on top of multiple mandatory training requirements on other topics. Delirium screening in the clinical setting also requires personnel to conduct assessments, and time to document symptoms and screening results in medical records.

“Perhaps the highest priority challenge for delirium experts is to evaluate and publish effective delirium intervention strategies because current evidence is completely lacking for ED-based delirium prevention or treatment,” they said. In the meantime, developing outcome measures for quality improvement of delirium care will require institutional support as well as education.
 

Geriatric patients and falls

Approximately one third of community-dwelling adults older than 65 years suffer falls, but data suggest that fewer than half of these individuals report falls to their doctors. “Older adults who present to an ED after a fall have an approximately 30% greater risk of functional decline and depression at 6 months after the event,” the authors noted.

The GED guidelines call for a comprehensive approach to evaluating and managing falls in older adults, but many of these “are untested in the ED,” the authors said. The recommended protocol includes an initial assessment of fall risk, followed by, for those at low risk, tailored recommendations for education and the use of community resources. Additional recommendations for those at high risk of falls include multifactorial assessment of modifiable risk factors, including peripheral neuropathy, balance/gait assessment, and medication review.

However, this best practice workflow is beyond the resource capacity of most EDs, the authors noted. “When ED resources are insufficient to support best practices, the care should focus on educating patients and caregivers about the significance of a fall event, providing educational materials (e.g., [the Centers for Disease Control and Prevention’s] STEADI materials), and assessing safety with respect to mobility for immediate return to the home environment and follow-up with a PCP.”
 

Geriatric patients and polypharmacy

Polypharmacy is common among older adults by virtue of their greater number of illnesses and comorbid conditions, and polypharmacy also has been associated with more adverse drug reactions, the authors said. The AGS Beers Criteria identifies medications associated with adverse drug reactions, but it is not practical for use in a busy ED setting. Instead, the authors suggested a more practical approach of focusing on a smaller list of common medications that tend to cause the adverse events that may result in ED visits.

“Perhaps targeting patients on multiple (three or more) psychoactive medications, drugs that can cause hypotension, or hypoglycemics could not only be done quickly, but identify patients in whom deprescribing should be considered in the ED,” the authors wrote. Deprescribing is a complicated process, however, and may be more effective when done via the patient’s primary care provider or in a geriatric consultation.

The GED Guidelines highlighted the specific needs of the geriatric population in the ED, the authors said. Widespread implementation remains a challenge, but many organizations provide resources to help improve care of geriatric patients in the ED and beyond.

In particular, the Geriatric Emergency Care Applied Research Network and Geriatric Emergency Department Collaborative provide funding opportunities, updated and focused published reviews, and webinars (some including free continuing medical education) for the entire health care team, including hospital administrators, the authors said.
 

Article brings attention to clinical realities

“The reality is that the overwhelming majority of emergency departments in the United States, if not globally, are simply not equipped – operationally or financially – to meet the rigorous standards that are required to fulfill the goals of operating an accredited geriatric ED,” Robert D. Glatter, MD, an emergency medicine physician at Lenox Hill Hospital, New York, said in an interview.

“Drawing attention to this important gap in accreditation is critical to not only inform hospitals, health care providers and stakeholders, but the public, patients, and their families about the important work that needs to be done to better equip all EDs with the proper tools and educational approaches to more effectively care for the geriatric community,” Dr. Glatter emphasized.

“There are currently three tiers of accreditation, with level 1 being the highest,” he explained, but there are only 100 geriatric ED accreditation-certified hospitals across the United States.

“I am not surprised at all by the challenges of implementing current GED guidelines,” said Dr. Glatter. “It comes down to operational and budget considerations, which ultimately compete with many other departments and regulatory constraints in any given hospital.”

However, “the bottom line is that such guidelines are designed with patient safety in mind, making them important issues in the eyes of any hospital administrator looking to improve outcomes and reduce medicolegal risk or exposure impacting geriatric patients in the emergency department,” he noted. 

Ultimately, guideline adherence “comes down to budget decisions, and where hospitals must invest their money to meet the bottom line,” said Dr. Glatter. “Making modifications to hospital infrastructure and architecture to accommodate geriatric patients may not be the top priority of hospital administrators when confronted with multiple competing interests. But, if it impacts patient safety, the decision to invest in structural and operational improvements may certainly have additional and important considerations.

“Until Medicare, or even the Joint Commission on Accreditation of Hospitals, adopts geriatric guidelines in emergency departments as a requirement for accreditation, there may not be adequate incentives in place currently to satisfy the intent of having a rigorous set of guidelines in the first place,” Dr. Glatter added. 

Despite the limitations of applying the current guidelines, there are some steps hospitals can take, said Dr. Glatter. “They can institute new measures in a graded fashion, with the goal of taking the important steps to satisfy at least some components of the guidelines. Attention to details can go a long way, such as rails in bathrooms, better lighting, and treads on floors that may reduce the risk of falls in the ED itself.

“Attention to fall prevention by assessing contributors including polypharmacy, gait instability, and quality of footwear can impact risk of future ED visits. Having incentives in place by Medicare or JACO may force the hand of hospital administrators to comply with geriatric guidelines and place emphasis on compliance,” noted Dr. Glatter.

More research is needed that “looks at costs of implementing geriatric guidelines in typical community and academic EDs and how this impacts key metrics such as length of stay, effect on reimbursement per ICD-10 code, and savings, if any, realized in reduced malpractice claims related to missed diagnoses (such as delirium), injuries, (patient falls), or medical misadventures due to polypharmacy,” he said.

The article received no outside funding. The authors disclosed no relevant financial relationships. Dr. Glatter disclosed no relevant financial relationships, and serves on the advisory board of Medscape Emergency Medicine.

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

Many emergency departments are currently unable to provide care for geriatric patients that meets best practices and guidelines recommended by several major medical organizations, but a panel discussion in 2021 at the American Academy of Emergency Medicine’s Scientific Assembly identified three areas in which realistic improvements might be achieved.

In an article published online in the Journal of Emergency Medicine, Richard D. Shih, MD, of Florida Atlantic University, Boca Raton, and colleagues synthesized the presentation and discussion of an expert panel on the topic of the GED guidelines and the current realities of patient care.

The Geriatric Emergency Department (GED) Guidelines, published in 2014 in Annals of Emergency Medicine, were endorsed by the American College of Emergency Physicians, American Geriatrics Society, Emergency Nurses Association, and Society for Academic Emergency Medicine.

“With the substantial challenges in providing guideline-recommended care in EDs, this article will explore three high-impact GED clinical conditions to highlight guideline recommendations, challenges, and opportunities, and discuss realistically achievable expectations for non–GED-accredited institutions,” the authors wrote. The article addressed the ED patient with delirium, the ED fall patient, and the ED patient with polypharmacy.
 

Geriatric patients and delirium

When delirium in older adults is not identified in the ED, the patient’s 6-month mortality rate significantly increases, but few EDs have delirium screening protocols, the authors said. Challenges included the time and money needed to educate staff, on top of multiple mandatory training requirements on other topics. Delirium screening in the clinical setting also requires personnel to conduct assessments, and time to document symptoms and screening results in medical records.

“Perhaps the highest priority challenge for delirium experts is to evaluate and publish effective delirium intervention strategies because current evidence is completely lacking for ED-based delirium prevention or treatment,” they said. In the meantime, developing outcome measures for quality improvement of delirium care will require institutional support as well as education.
 

Geriatric patients and falls

Approximately one third of community-dwelling adults older than 65 years suffer falls, but data suggest that fewer than half of these individuals report falls to their doctors. “Older adults who present to an ED after a fall have an approximately 30% greater risk of functional decline and depression at 6 months after the event,” the authors noted.

The GED guidelines call for a comprehensive approach to evaluating and managing falls in older adults, but many of these “are untested in the ED,” the authors said. The recommended protocol includes an initial assessment of fall risk, followed by, for those at low risk, tailored recommendations for education and the use of community resources. Additional recommendations for those at high risk of falls include multifactorial assessment of modifiable risk factors, including peripheral neuropathy, balance/gait assessment, and medication review.

However, this best practice workflow is beyond the resource capacity of most EDs, the authors noted. “When ED resources are insufficient to support best practices, the care should focus on educating patients and caregivers about the significance of a fall event, providing educational materials (e.g., [the Centers for Disease Control and Prevention’s] STEADI materials), and assessing safety with respect to mobility for immediate return to the home environment and follow-up with a PCP.”
 

Geriatric patients and polypharmacy

Polypharmacy is common among older adults by virtue of their greater number of illnesses and comorbid conditions, and polypharmacy also has been associated with more adverse drug reactions, the authors said. The AGS Beers Criteria identifies medications associated with adverse drug reactions, but it is not practical for use in a busy ED setting. Instead, the authors suggested a more practical approach of focusing on a smaller list of common medications that tend to cause the adverse events that may result in ED visits.

“Perhaps targeting patients on multiple (three or more) psychoactive medications, drugs that can cause hypotension, or hypoglycemics could not only be done quickly, but identify patients in whom deprescribing should be considered in the ED,” the authors wrote. Deprescribing is a complicated process, however, and may be more effective when done via the patient’s primary care provider or in a geriatric consultation.

The GED Guidelines highlighted the specific needs of the geriatric population in the ED, the authors said. Widespread implementation remains a challenge, but many organizations provide resources to help improve care of geriatric patients in the ED and beyond.

In particular, the Geriatric Emergency Care Applied Research Network and Geriatric Emergency Department Collaborative provide funding opportunities, updated and focused published reviews, and webinars (some including free continuing medical education) for the entire health care team, including hospital administrators, the authors said.
 

Article brings attention to clinical realities

“The reality is that the overwhelming majority of emergency departments in the United States, if not globally, are simply not equipped – operationally or financially – to meet the rigorous standards that are required to fulfill the goals of operating an accredited geriatric ED,” Robert D. Glatter, MD, an emergency medicine physician at Lenox Hill Hospital, New York, said in an interview.

“Drawing attention to this important gap in accreditation is critical to not only inform hospitals, health care providers and stakeholders, but the public, patients, and their families about the important work that needs to be done to better equip all EDs with the proper tools and educational approaches to more effectively care for the geriatric community,” Dr. Glatter emphasized.

“There are currently three tiers of accreditation, with level 1 being the highest,” he explained, but there are only 100 geriatric ED accreditation-certified hospitals across the United States.

“I am not surprised at all by the challenges of implementing current GED guidelines,” said Dr. Glatter. “It comes down to operational and budget considerations, which ultimately compete with many other departments and regulatory constraints in any given hospital.”

However, “the bottom line is that such guidelines are designed with patient safety in mind, making them important issues in the eyes of any hospital administrator looking to improve outcomes and reduce medicolegal risk or exposure impacting geriatric patients in the emergency department,” he noted. 

Ultimately, guideline adherence “comes down to budget decisions, and where hospitals must invest their money to meet the bottom line,” said Dr. Glatter. “Making modifications to hospital infrastructure and architecture to accommodate geriatric patients may not be the top priority of hospital administrators when confronted with multiple competing interests. But, if it impacts patient safety, the decision to invest in structural and operational improvements may certainly have additional and important considerations.

“Until Medicare, or even the Joint Commission on Accreditation of Hospitals, adopts geriatric guidelines in emergency departments as a requirement for accreditation, there may not be adequate incentives in place currently to satisfy the intent of having a rigorous set of guidelines in the first place,” Dr. Glatter added. 

Despite the limitations of applying the current guidelines, there are some steps hospitals can take, said Dr. Glatter. “They can institute new measures in a graded fashion, with the goal of taking the important steps to satisfy at least some components of the guidelines. Attention to details can go a long way, such as rails in bathrooms, better lighting, and treads on floors that may reduce the risk of falls in the ED itself.

“Attention to fall prevention by assessing contributors including polypharmacy, gait instability, and quality of footwear can impact risk of future ED visits. Having incentives in place by Medicare or JACO may force the hand of hospital administrators to comply with geriatric guidelines and place emphasis on compliance,” noted Dr. Glatter.

More research is needed that “looks at costs of implementing geriatric guidelines in typical community and academic EDs and how this impacts key metrics such as length of stay, effect on reimbursement per ICD-10 code, and savings, if any, realized in reduced malpractice claims related to missed diagnoses (such as delirium), injuries, (patient falls), or medical misadventures due to polypharmacy,” he said.

The article received no outside funding. The authors disclosed no relevant financial relationships. Dr. Glatter disclosed no relevant financial relationships, and serves on the advisory board of Medscape Emergency Medicine.

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

A breakthrough neuromodulation system rapidly restores motor function in patients with a severe spinal cord injury (SCI), new research shows.

The study demonstrated that an epidural electrical stimulation (EES) system developed specifically for spinal cord injuries enabled three men with complete paralysis to stand, walk, cycle, swim, and move their torso within 1 day.

“Thanks to this technology, we have been able to target individuals with the most serious spinal cord injury, meaning those with clinically complete spinal cord injury, with no sensation and no movement in the legs,” Grégoire Courtine, PhD, professor of neuroscience and neurotechnology at the Swiss Federal Institute of Technology, University Hospital Lausanne (Switzerland), and the University of Lausanne, told reporters attending a press briefing.

The study was published online Feb. 7, 2022, in Nature Medicine.
 

More rapid, precise, effective

SCIs involve severed connections between the brain and extremities. To compensate for these lost connections, researchers have investigated stem cell therapy, brain-machine interfaces, and powered exoskeletons.

However, these approaches aren’t yet ready for prime time.

In the meantime, researchers discovered even patients with a “complete” injury may have low-functioning connections and started investigating epidural stimulators designed to treat chronic pain. Recent studies – including three published in 2018 – showed promise for these pain-related stimulators in patients with incomplete SCI.

But using such “repurposed” technology meant the electrode array was relatively narrow and short, “so we could not target all the regions of the spinal cord involving control of leg and trunk movements,” said Dr. Courtine. With the newer technology “we are much more precise, effective, and more rapid in delivering therapy.”

To develop this new approach, the researchers designed a paddle lead with an arrangement of electrodes that targets sacral, lumbar, and low-thoracic dorsal roots involved in leg and trunk movements. They also established a personalized computational framework that allows for optimal surgical placement of this paddle lead.

In addition, they developed software that renders the configuration of individualized activity–dependent stimulation programs rapid, simple, and predictable.

They tested these neurotechnologies in three men with complete sensorimotor paralysis as part of an ongoing clinical trial. The participants, aged 29, 32, and 41 years, suffered an SCI from a motor bike accident 3, 9, and 1 year before enrollment.

All three patients exhibited complete sensorimotor paralysis. They were unable to take any step, and muscles remained quiescent during these attempts.

A neurosurgeon implanted electrodes along the spinal cord of study subjects. Wires from these electrodes were connected to a neurostimulator implanted under the skin in the abdomen.

The men can select different activity-based programs from a tablet that sends signals to the implanted device.
 

Personalized approach

Within a single day of the surgery, the participants were able to stand, walk, cycle, swim, and control trunk movements.

“It was not perfect at the very beginning, but they could train very early on to have a more fluid gait,” said study investigator neurosurgeon Joceylyne Bloch, MD, associate professor, University of Lausanne and University Hospital Lausanne.

At this stage, not all paralyzed patients are eligible for the procedure. Dr. Bloch explained that at least 6 cm of healthy spinal cord under the lesion is needed to implant the electrodes.

“There’s a huge variability of spinal cord anatomy between individuals. That’s why it’s important to study each person individually and to have individual models in order to be precise.”

Researchers envision having “a library of electrode arrays,” added Dr. Courtine. With preoperative imaging of the individual’s spinal cord, “the neurosurgeon can select the more appropriate electrode array for that specific patient.”

Dr. Courtine noted recovery of sensation with the system differs from one individual to another. One study participant, Michel Roccati, now 30, told the briefing he feels a contraction in his muscle during the stimulation.

Currently, only individuals whose injury is more than a year old are included in the study to ensure patients have “a stable lesion” and reached “a plateau of recovery,” said Dr. Bloch. However, animal models show intervening earlier might boost the benefits.

A patient’s age can influence the outcome, as younger patients are likely in better condition and more motivated than older patients, said Dr. Bloch. However, she noted patients closing in on 50 years have responded well to the therapy.

Such stimulation systems may prove useful in treating conditions typically associated with SCI, such as hypertension and bladder control, and perhaps also in patients with Parkinson’s disease, said Dr. Courtine.

The researchers plan to conduct another study that will include a next-generation pulse generator with features that make the stimulation even more effective and user friendly. A voice recognition system could eventually be connected to the system.

“The next step is a minicomputer that you implant in the body that communicates in real time with an external iPhone,” said Dr. Courtine.

ONWARD Medical, which developed the technology, has received a breakthrough device designation from the Food and Drug Administration. The company is in discussions with the FDA to carry out a clinical trial of the device in the United States.
 

A ‘huge step forward’

Peter J. Grahn, PhD, assistant professor, department of physical medicine and rehabilitation and department of neurologic surgery, Mayo Clinic, Rochester, Minn., an author of one of the 2018 studies, said this technology “is a huge step forward” and “really pushes the field.”

Compared with the device used in his study that’s designed to treat neuropathic pain, this new system “is much more capable of dynamic stimulation,” said Dr. Grahn. “You can tailor the stimulation based on which area of the spinal cord you want to target during a specific function.”

There has been “a lot of hope and hype” recently around stem cells and biological molecules that were supposed to be “magic pills” to cure spinal cord dysfunction, said Dr. Grahn. “I don’t think this is one of those.”

However, he questioned the researchers’ use of the word “walking.”

“They say independent stepping or walking is restored on day 1, but the graphs show day 1 function is having over 60% of their body weight supported when they’re taking these steps,” he said.

In addition, the “big question” is how this technology can “be distilled down” into an approach “applicable across rehabilitation centers,” said Dr. Grahn.

The study was supported by numerous organizations, including ONWARD Medical. Dr. Courtine and Dr. Bloch hold various patents in relation with the present work. Dr. Courtine is a consultant with ONWARD Medical, and he and Dr. Bloch are shareholders of ONWARD Medical, a company with direct relationships with the presented work. Dr. Grahn reported no relevant financial relationships.

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

A breakthrough neuromodulation system rapidly restores motor function in patients with a severe spinal cord injury (SCI), new research shows.

The study demonstrated that an epidural electrical stimulation (EES) system developed specifically for spinal cord injuries enabled three men with complete paralysis to stand, walk, cycle, swim, and move their torso within 1 day.

“Thanks to this technology, we have been able to target individuals with the most serious spinal cord injury, meaning those with clinically complete spinal cord injury, with no sensation and no movement in the legs,” Grégoire Courtine, PhD, professor of neuroscience and neurotechnology at the Swiss Federal Institute of Technology, University Hospital Lausanne (Switzerland), and the University of Lausanne, told reporters attending a press briefing.

The study was published online Feb. 7, 2022, in Nature Medicine.
 

More rapid, precise, effective

SCIs involve severed connections between the brain and extremities. To compensate for these lost connections, researchers have investigated stem cell therapy, brain-machine interfaces, and powered exoskeletons.

However, these approaches aren’t yet ready for prime time.

In the meantime, researchers discovered even patients with a “complete” injury may have low-functioning connections and started investigating epidural stimulators designed to treat chronic pain. Recent studies – including three published in 2018 – showed promise for these pain-related stimulators in patients with incomplete SCI.

But using such “repurposed” technology meant the electrode array was relatively narrow and short, “so we could not target all the regions of the spinal cord involving control of leg and trunk movements,” said Dr. Courtine. With the newer technology “we are much more precise, effective, and more rapid in delivering therapy.”

To develop this new approach, the researchers designed a paddle lead with an arrangement of electrodes that targets sacral, lumbar, and low-thoracic dorsal roots involved in leg and trunk movements. They also established a personalized computational framework that allows for optimal surgical placement of this paddle lead.

In addition, they developed software that renders the configuration of individualized activity–dependent stimulation programs rapid, simple, and predictable.

They tested these neurotechnologies in three men with complete sensorimotor paralysis as part of an ongoing clinical trial. The participants, aged 29, 32, and 41 years, suffered an SCI from a motor bike accident 3, 9, and 1 year before enrollment.

All three patients exhibited complete sensorimotor paralysis. They were unable to take any step, and muscles remained quiescent during these attempts.

A neurosurgeon implanted electrodes along the spinal cord of study subjects. Wires from these electrodes were connected to a neurostimulator implanted under the skin in the abdomen.

The men can select different activity-based programs from a tablet that sends signals to the implanted device.
 

Personalized approach

Within a single day of the surgery, the participants were able to stand, walk, cycle, swim, and control trunk movements.

“It was not perfect at the very beginning, but they could train very early on to have a more fluid gait,” said study investigator neurosurgeon Joceylyne Bloch, MD, associate professor, University of Lausanne and University Hospital Lausanne.

At this stage, not all paralyzed patients are eligible for the procedure. Dr. Bloch explained that at least 6 cm of healthy spinal cord under the lesion is needed to implant the electrodes.

“There’s a huge variability of spinal cord anatomy between individuals. That’s why it’s important to study each person individually and to have individual models in order to be precise.”

Researchers envision having “a library of electrode arrays,” added Dr. Courtine. With preoperative imaging of the individual’s spinal cord, “the neurosurgeon can select the more appropriate electrode array for that specific patient.”

Dr. Courtine noted recovery of sensation with the system differs from one individual to another. One study participant, Michel Roccati, now 30, told the briefing he feels a contraction in his muscle during the stimulation.

Currently, only individuals whose injury is more than a year old are included in the study to ensure patients have “a stable lesion” and reached “a plateau of recovery,” said Dr. Bloch. However, animal models show intervening earlier might boost the benefits.

A patient’s age can influence the outcome, as younger patients are likely in better condition and more motivated than older patients, said Dr. Bloch. However, she noted patients closing in on 50 years have responded well to the therapy.

Such stimulation systems may prove useful in treating conditions typically associated with SCI, such as hypertension and bladder control, and perhaps also in patients with Parkinson’s disease, said Dr. Courtine.

The researchers plan to conduct another study that will include a next-generation pulse generator with features that make the stimulation even more effective and user friendly. A voice recognition system could eventually be connected to the system.

“The next step is a minicomputer that you implant in the body that communicates in real time with an external iPhone,” said Dr. Courtine.

ONWARD Medical, which developed the technology, has received a breakthrough device designation from the Food and Drug Administration. The company is in discussions with the FDA to carry out a clinical trial of the device in the United States.
 

A ‘huge step forward’

Peter J. Grahn, PhD, assistant professor, department of physical medicine and rehabilitation and department of neurologic surgery, Mayo Clinic, Rochester, Minn., an author of one of the 2018 studies, said this technology “is a huge step forward” and “really pushes the field.”

Compared with the device used in his study that’s designed to treat neuropathic pain, this new system “is much more capable of dynamic stimulation,” said Dr. Grahn. “You can tailor the stimulation based on which area of the spinal cord you want to target during a specific function.”

There has been “a lot of hope and hype” recently around stem cells and biological molecules that were supposed to be “magic pills” to cure spinal cord dysfunction, said Dr. Grahn. “I don’t think this is one of those.”

However, he questioned the researchers’ use of the word “walking.”

“They say independent stepping or walking is restored on day 1, but the graphs show day 1 function is having over 60% of their body weight supported when they’re taking these steps,” he said.

In addition, the “big question” is how this technology can “be distilled down” into an approach “applicable across rehabilitation centers,” said Dr. Grahn.

The study was supported by numerous organizations, including ONWARD Medical. Dr. Courtine and Dr. Bloch hold various patents in relation with the present work. Dr. Courtine is a consultant with ONWARD Medical, and he and Dr. Bloch are shareholders of ONWARD Medical, a company with direct relationships with the presented work. Dr. Grahn reported no relevant financial relationships.

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

A breakthrough neuromodulation system rapidly restores motor function in patients with a severe spinal cord injury (SCI), new research shows.

The study demonstrated that an epidural electrical stimulation (EES) system developed specifically for spinal cord injuries enabled three men with complete paralysis to stand, walk, cycle, swim, and move their torso within 1 day.

“Thanks to this technology, we have been able to target individuals with the most serious spinal cord injury, meaning those with clinically complete spinal cord injury, with no sensation and no movement in the legs,” Grégoire Courtine, PhD, professor of neuroscience and neurotechnology at the Swiss Federal Institute of Technology, University Hospital Lausanne (Switzerland), and the University of Lausanne, told reporters attending a press briefing.

The study was published online Feb. 7, 2022, in Nature Medicine.
 

More rapid, precise, effective

SCIs involve severed connections between the brain and extremities. To compensate for these lost connections, researchers have investigated stem cell therapy, brain-machine interfaces, and powered exoskeletons.

However, these approaches aren’t yet ready for prime time.

In the meantime, researchers discovered even patients with a “complete” injury may have low-functioning connections and started investigating epidural stimulators designed to treat chronic pain. Recent studies – including three published in 2018 – showed promise for these pain-related stimulators in patients with incomplete SCI.

But using such “repurposed” technology meant the electrode array was relatively narrow and short, “so we could not target all the regions of the spinal cord involving control of leg and trunk movements,” said Dr. Courtine. With the newer technology “we are much more precise, effective, and more rapid in delivering therapy.”

To develop this new approach, the researchers designed a paddle lead with an arrangement of electrodes that targets sacral, lumbar, and low-thoracic dorsal roots involved in leg and trunk movements. They also established a personalized computational framework that allows for optimal surgical placement of this paddle lead.

In addition, they developed software that renders the configuration of individualized activity–dependent stimulation programs rapid, simple, and predictable.

They tested these neurotechnologies in three men with complete sensorimotor paralysis as part of an ongoing clinical trial. The participants, aged 29, 32, and 41 years, suffered an SCI from a motor bike accident 3, 9, and 1 year before enrollment.

All three patients exhibited complete sensorimotor paralysis. They were unable to take any step, and muscles remained quiescent during these attempts.

A neurosurgeon implanted electrodes along the spinal cord of study subjects. Wires from these electrodes were connected to a neurostimulator implanted under the skin in the abdomen.

The men can select different activity-based programs from a tablet that sends signals to the implanted device.
 

Personalized approach

Within a single day of the surgery, the participants were able to stand, walk, cycle, swim, and control trunk movements.

“It was not perfect at the very beginning, but they could train very early on to have a more fluid gait,” said study investigator neurosurgeon Joceylyne Bloch, MD, associate professor, University of Lausanne and University Hospital Lausanne.

At this stage, not all paralyzed patients are eligible for the procedure. Dr. Bloch explained that at least 6 cm of healthy spinal cord under the lesion is needed to implant the electrodes.

“There’s a huge variability of spinal cord anatomy between individuals. That’s why it’s important to study each person individually and to have individual models in order to be precise.”

Researchers envision having “a library of electrode arrays,” added Dr. Courtine. With preoperative imaging of the individual’s spinal cord, “the neurosurgeon can select the more appropriate electrode array for that specific patient.”

Dr. Courtine noted recovery of sensation with the system differs from one individual to another. One study participant, Michel Roccati, now 30, told the briefing he feels a contraction in his muscle during the stimulation.

Currently, only individuals whose injury is more than a year old are included in the study to ensure patients have “a stable lesion” and reached “a plateau of recovery,” said Dr. Bloch. However, animal models show intervening earlier might boost the benefits.

A patient’s age can influence the outcome, as younger patients are likely in better condition and more motivated than older patients, said Dr. Bloch. However, she noted patients closing in on 50 years have responded well to the therapy.

Such stimulation systems may prove useful in treating conditions typically associated with SCI, such as hypertension and bladder control, and perhaps also in patients with Parkinson’s disease, said Dr. Courtine.

The researchers plan to conduct another study that will include a next-generation pulse generator with features that make the stimulation even more effective and user friendly. A voice recognition system could eventually be connected to the system.

“The next step is a minicomputer that you implant in the body that communicates in real time with an external iPhone,” said Dr. Courtine.

ONWARD Medical, which developed the technology, has received a breakthrough device designation from the Food and Drug Administration. The company is in discussions with the FDA to carry out a clinical trial of the device in the United States.
 

A ‘huge step forward’

Peter J. Grahn, PhD, assistant professor, department of physical medicine and rehabilitation and department of neurologic surgery, Mayo Clinic, Rochester, Minn., an author of one of the 2018 studies, said this technology “is a huge step forward” and “really pushes the field.”

Compared with the device used in his study that’s designed to treat neuropathic pain, this new system “is much more capable of dynamic stimulation,” said Dr. Grahn. “You can tailor the stimulation based on which area of the spinal cord you want to target during a specific function.”

There has been “a lot of hope and hype” recently around stem cells and biological molecules that were supposed to be “magic pills” to cure spinal cord dysfunction, said Dr. Grahn. “I don’t think this is one of those.”

However, he questioned the researchers’ use of the word “walking.”

“They say independent stepping or walking is restored on day 1, but the graphs show day 1 function is having over 60% of their body weight supported when they’re taking these steps,” he said.

In addition, the “big question” is how this technology can “be distilled down” into an approach “applicable across rehabilitation centers,” said Dr. Grahn.

The study was supported by numerous organizations, including ONWARD Medical. Dr. Courtine and Dr. Bloch hold various patents in relation with the present work. Dr. Courtine is a consultant with ONWARD Medical, and he and Dr. Bloch are shareholders of ONWARD Medical, a company with direct relationships with the presented work. Dr. Grahn reported no relevant financial relationships.

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

In 1948, Sterling Bunnell, MD, used the term no man’s land to describe the area between the A1 pulley at the volar aspect of the metacarpophalangeal joint and the insertion of the flexor digitorum superficialis tendons on the middle phalanx (zone 2).¹ Bunnell’s description referenced the area of land in World War I between the trenches of opposing armies, and his goal was to emphasize the heightened risks of performing tendon repair in this area, as these repairs were notorious for poor outcomes. In lieu of tendon repair, Bunnell advocated treatment of tendon lacerations in this area with tendon excision and grafting.

It was not until the 1960s that researchers began to advocate for acute repair of tendons in this area.^2,3 Since Verdan’s and Kleinart’s work, fastidious adherence to atraumatic technique and improvements in suture technique and rehabilitation protocols have allowed hand surgeons to repair tendons in this area with some level of success. Over the ensuing decades, acute repair of flexor tendon injuries within zone 2 has become the standard of care. The importance of meticulous technique during flexor tendon repair cannot be overemphasized; however, without appropriate hand therapy, even the most meticulous repair may fail.

COVID-19 has created significant barriers to patient care. Reducing travel and limiting face-to-face patient visits have been emphasized as methods that reduce spread of the virus, but these restrictions also prevent patients from easily accessing hand therapy. Recent adoption of telemedicine and videoconferencing technologies may help to reduce some of these barriers, but few previous studies have described the use of videoconferencing technology to supplant face-to-face hand therapy visits. This case describes the use of videoconferencing technology to provide hand therapy for a patient following repair of an acute flexor tendon laceration in zone 2.

Case Presentation

A patient aged < 50 years presented to a US Department of Veterans Affairs (VA) hand surgery clinic 2 days after sustaining a laceration to the flexor digitorum profundus (FDP) in zone 2 of the small finger while cleaning a knife. During the discussion of their treatment options and the recommended postoperative hand therapy protocol, the patient noted difficulty attending postoperative appointments due to COVID-19 as well as a lack of resources. Given these limitations and following discussion with our hand therapist, we discussed the potential for telehealth follow-up with videoconferencing. Four days following the injury, the patient underwent repair of the FDP. During surgery, the laceration was present at the level of the A3 pulley. The FDP was repaired using a 6-0 polypropylene synthetic suture for the epitendinous repair and 4-strand core suture repair using 3-0 Fiberwire suture in a modified cruciate fashion. The A2 and A4 pulleys were preserved, and venting of the pulleys was not required. At the time of surgery, the flexor digitorum superficialis and radial and ulnar digital neurovascular bundles were intact. Following surgical repair of the tendon, the patient was placed into a dorsal blocking splint with a plan for follow-up within 2 to 3 days.

The patient attended the first postoperative visit in person on postoperative day 2. During this visit, the postoperative splint and dressings were removed, and a forearm-based dorsal blocking orthosis was fabricated using thermoplastic. At this visit, the veteran relayed concerns regarding psychosocial and resource barriers in addition to concerns surrounding COVID-19 that would prevent travel to and from hand therapy appointments. Due to these concerns, a passive-motion protocol was initiated using the Indiana manual as a guide.⁴ The patient returned to the hand clinic at 2 weeks after surgery for evaluation by the operating surgeon and suture removal. All visits after the suture removal were conducted via either telehealth with videoconferencing or by telephone (Table 1).

The operative team evaluated the patient 5 times following surgery. Only 2 of these visits were in-person. The patient attended 6 hand therapy sessions with 2 in-person visits to occupational therapy (Figure 1). The remaining 4 visits were conducted using videoconferencing. The patient received therapy supplies by mail as needed, and their use was reviewed in telerehabilitation sessions with videoconferencing as needed. During their postoperative course, the patient experienced little edema or scar tissue formation, and recovery was uncomplicated. The patient developed a mild extensor lag for which a proximal interphalangeal joint spring extension orthosis was provided via mail (Figure 2). The patient admitted only partial adherence with this orthosis, and at discharge, a 10-degree extensor lag remained. The patient was not concerned by this extension deficit and did not experience any associated functional deficits, demonstrated by scores on the Quick Disabilities of the Arm, Shoulder and Hand questionnaire and Patient Specific Functional Scale (Table 2).

Discussion

Few studies have been published that address the efficacy of telerehabilitation after surgical management of traumatic injuries involving the upper extremity. One Australian study performed by Worboys and colleagues concluded that utilization of telehealth services for hand therapy visits may provide accurate patient assessment with favorable patient satisfaction.⁵ Another study performed in the UK by Gilbert and colleagues demonstrated that videoconferencing is well received by patients, as it may offer shorter wait times, improved convenience, and reduced travel cost.

The authors noted that although videoconferencing may not completely replace in-person therapy, it could act as an adjunct.⁶ While these in-person visits may be necessary, particularly to establish care, at least one study has demonstrated that patients may prefer follow-up via telehealth if provided the option.⁷ In a randomized, controlled study performed in Norway, patients were randomized to either an in-person or video consultation with an orthopedic outpatient clinic. Of patients randomized to the in-person clinic visit, 86% preferred to have follow-up via videoconferencing.⁷

Previous studies have demonstrated that telehealth may produce accurate patient assessment, with relatively high patient satisfaction. Given the COVID-19 pandemic and the limitations that this crisis has placed on in-person outpatient visits, clinics that previously may have been resistant to telehealth are adapting and using the technology to meet the needs of their population.⁸ The present case demonstrates that videoconferencing is feasible and may lead to successful results, even for cases requiring significant hand therapy follow-up, such as flexor tendon repairs.

Conclusions

Although in-person hand therapy remains the standard of care following flexor tendon repair of the hand, situations may exist in which hand therapy conducted via telehealth is better than no hand therapy at all. The present case study highlights the use of telehealth as an acceptable supplement to in-person postoperative visits.

In our case, use of a standardized protocol with an emphasis on hand function and patient satisfaction as opposed to strict range of motion measurements produced good results. Although a specific telehealth satisfaction measure was not used in this case, commonly used questionnaires may be integrated into future visits to improve telehealth implementation and patient experience. In this specific case, the veteran felt that hand function was regained and expressed general satisfaction with the telemedicine process at the conclusion of care. While telehealth was a useful adjunct in the treatment of the present patient, further study of videoconferencing should be conducted to determine whether hand therapy conducted via telehealth could be implemented more broadly following upper extremity surgery.

In 1948, Sterling Bunnell, MD, used the term no man’s land to describe the area between the A1 pulley at the volar aspect of the metacarpophalangeal joint and the insertion of the flexor digitorum superficialis tendons on the middle phalanx (zone 2).¹ Bunnell’s description referenced the area of land in World War I between the trenches of opposing armies, and his goal was to emphasize the heightened risks of performing tendon repair in this area, as these repairs were notorious for poor outcomes. In lieu of tendon repair, Bunnell advocated treatment of tendon lacerations in this area with tendon excision and grafting.

It was not until the 1960s that researchers began to advocate for acute repair of tendons in this area.^2,3 Since Verdan’s and Kleinart’s work, fastidious adherence to atraumatic technique and improvements in suture technique and rehabilitation protocols have allowed hand surgeons to repair tendons in this area with some level of success. Over the ensuing decades, acute repair of flexor tendon injuries within zone 2 has become the standard of care. The importance of meticulous technique during flexor tendon repair cannot be overemphasized; however, without appropriate hand therapy, even the most meticulous repair may fail.

COVID-19 has created significant barriers to patient care. Reducing travel and limiting face-to-face patient visits have been emphasized as methods that reduce spread of the virus, but these restrictions also prevent patients from easily accessing hand therapy. Recent adoption of telemedicine and videoconferencing technologies may help to reduce some of these barriers, but few previous studies have described the use of videoconferencing technology to supplant face-to-face hand therapy visits. This case describes the use of videoconferencing technology to provide hand therapy for a patient following repair of an acute flexor tendon laceration in zone 2.

Case Presentation

A patient aged < 50 years presented to a US Department of Veterans Affairs (VA) hand surgery clinic 2 days after sustaining a laceration to the flexor digitorum profundus (FDP) in zone 2 of the small finger while cleaning a knife. During the discussion of their treatment options and the recommended postoperative hand therapy protocol, the patient noted difficulty attending postoperative appointments due to COVID-19 as well as a lack of resources. Given these limitations and following discussion with our hand therapist, we discussed the potential for telehealth follow-up with videoconferencing. Four days following the injury, the patient underwent repair of the FDP. During surgery, the laceration was present at the level of the A3 pulley. The FDP was repaired using a 6-0 polypropylene synthetic suture for the epitendinous repair and 4-strand core suture repair using 3-0 Fiberwire suture in a modified cruciate fashion. The A2 and A4 pulleys were preserved, and venting of the pulleys was not required. At the time of surgery, the flexor digitorum superficialis and radial and ulnar digital neurovascular bundles were intact. Following surgical repair of the tendon, the patient was placed into a dorsal blocking splint with a plan for follow-up within 2 to 3 days.

The patient attended the first postoperative visit in person on postoperative day 2. During this visit, the postoperative splint and dressings were removed, and a forearm-based dorsal blocking orthosis was fabricated using thermoplastic. At this visit, the veteran relayed concerns regarding psychosocial and resource barriers in addition to concerns surrounding COVID-19 that would prevent travel to and from hand therapy appointments. Due to these concerns, a passive-motion protocol was initiated using the Indiana manual as a guide.⁴ The patient returned to the hand clinic at 2 weeks after surgery for evaluation by the operating surgeon and suture removal. All visits after the suture removal were conducted via either telehealth with videoconferencing or by telephone (Table 1).

The operative team evaluated the patient 5 times following surgery. Only 2 of these visits were in-person. The patient attended 6 hand therapy sessions with 2 in-person visits to occupational therapy (Figure 1). The remaining 4 visits were conducted using videoconferencing. The patient received therapy supplies by mail as needed, and their use was reviewed in telerehabilitation sessions with videoconferencing as needed. During their postoperative course, the patient experienced little edema or scar tissue formation, and recovery was uncomplicated. The patient developed a mild extensor lag for which a proximal interphalangeal joint spring extension orthosis was provided via mail (Figure 2). The patient admitted only partial adherence with this orthosis, and at discharge, a 10-degree extensor lag remained. The patient was not concerned by this extension deficit and did not experience any associated functional deficits, demonstrated by scores on the Quick Disabilities of the Arm, Shoulder and Hand questionnaire and Patient Specific Functional Scale (Table 2).

Discussion

Few studies have been published that address the efficacy of telerehabilitation after surgical management of traumatic injuries involving the upper extremity. One Australian study performed by Worboys and colleagues concluded that utilization of telehealth services for hand therapy visits may provide accurate patient assessment with favorable patient satisfaction.⁵ Another study performed in the UK by Gilbert and colleagues demonstrated that videoconferencing is well received by patients, as it may offer shorter wait times, improved convenience, and reduced travel cost.

The authors noted that although videoconferencing may not completely replace in-person therapy, it could act as an adjunct.⁶ While these in-person visits may be necessary, particularly to establish care, at least one study has demonstrated that patients may prefer follow-up via telehealth if provided the option.⁷ In a randomized, controlled study performed in Norway, patients were randomized to either an in-person or video consultation with an orthopedic outpatient clinic. Of patients randomized to the in-person clinic visit, 86% preferred to have follow-up via videoconferencing.⁷

Previous studies have demonstrated that telehealth may produce accurate patient assessment, with relatively high patient satisfaction. Given the COVID-19 pandemic and the limitations that this crisis has placed on in-person outpatient visits, clinics that previously may have been resistant to telehealth are adapting and using the technology to meet the needs of their population.⁸ The present case demonstrates that videoconferencing is feasible and may lead to successful results, even for cases requiring significant hand therapy follow-up, such as flexor tendon repairs.

Conclusions

Although in-person hand therapy remains the standard of care following flexor tendon repair of the hand, situations may exist in which hand therapy conducted via telehealth is better than no hand therapy at all. The present case study highlights the use of telehealth as an acceptable supplement to in-person postoperative visits.

In our case, use of a standardized protocol with an emphasis on hand function and patient satisfaction as opposed to strict range of motion measurements produced good results. Although a specific telehealth satisfaction measure was not used in this case, commonly used questionnaires may be integrated into future visits to improve telehealth implementation and patient experience. In this specific case, the veteran felt that hand function was regained and expressed general satisfaction with the telemedicine process at the conclusion of care. While telehealth was a useful adjunct in the treatment of the present patient, further study of videoconferencing should be conducted to determine whether hand therapy conducted via telehealth could be implemented more broadly following upper extremity surgery.

In 1948, Sterling Bunnell, MD, used the term no man’s land to describe the area between the A1 pulley at the volar aspect of the metacarpophalangeal joint and the insertion of the flexor digitorum superficialis tendons on the middle phalanx (zone 2).¹ Bunnell’s description referenced the area of land in World War I between the trenches of opposing armies, and his goal was to emphasize the heightened risks of performing tendon repair in this area, as these repairs were notorious for poor outcomes. In lieu of tendon repair, Bunnell advocated treatment of tendon lacerations in this area with tendon excision and grafting.

It was not until the 1960s that researchers began to advocate for acute repair of tendons in this area.^2,3 Since Verdan’s and Kleinart’s work, fastidious adherence to atraumatic technique and improvements in suture technique and rehabilitation protocols have allowed hand surgeons to repair tendons in this area with some level of success. Over the ensuing decades, acute repair of flexor tendon injuries within zone 2 has become the standard of care. The importance of meticulous technique during flexor tendon repair cannot be overemphasized; however, without appropriate hand therapy, even the most meticulous repair may fail.

COVID-19 has created significant barriers to patient care. Reducing travel and limiting face-to-face patient visits have been emphasized as methods that reduce spread of the virus, but these restrictions also prevent patients from easily accessing hand therapy. Recent adoption of telemedicine and videoconferencing technologies may help to reduce some of these barriers, but few previous studies have described the use of videoconferencing technology to supplant face-to-face hand therapy visits. This case describes the use of videoconferencing technology to provide hand therapy for a patient following repair of an acute flexor tendon laceration in zone 2.

Case Presentation

A patient aged < 50 years presented to a US Department of Veterans Affairs (VA) hand surgery clinic 2 days after sustaining a laceration to the flexor digitorum profundus (FDP) in zone 2 of the small finger while cleaning a knife. During the discussion of their treatment options and the recommended postoperative hand therapy protocol, the patient noted difficulty attending postoperative appointments due to COVID-19 as well as a lack of resources. Given these limitations and following discussion with our hand therapist, we discussed the potential for telehealth follow-up with videoconferencing. Four days following the injury, the patient underwent repair of the FDP. During surgery, the laceration was present at the level of the A3 pulley. The FDP was repaired using a 6-0 polypropylene synthetic suture for the epitendinous repair and 4-strand core suture repair using 3-0 Fiberwire suture in a modified cruciate fashion. The A2 and A4 pulleys were preserved, and venting of the pulleys was not required. At the time of surgery, the flexor digitorum superficialis and radial and ulnar digital neurovascular bundles were intact. Following surgical repair of the tendon, the patient was placed into a dorsal blocking splint with a plan for follow-up within 2 to 3 days.

The patient attended the first postoperative visit in person on postoperative day 2. During this visit, the postoperative splint and dressings were removed, and a forearm-based dorsal blocking orthosis was fabricated using thermoplastic. At this visit, the veteran relayed concerns regarding psychosocial and resource barriers in addition to concerns surrounding COVID-19 that would prevent travel to and from hand therapy appointments. Due to these concerns, a passive-motion protocol was initiated using the Indiana manual as a guide.⁴ The patient returned to the hand clinic at 2 weeks after surgery for evaluation by the operating surgeon and suture removal. All visits after the suture removal were conducted via either telehealth with videoconferencing or by telephone (Table 1).

The operative team evaluated the patient 5 times following surgery. Only 2 of these visits were in-person. The patient attended 6 hand therapy sessions with 2 in-person visits to occupational therapy (Figure 1). The remaining 4 visits were conducted using videoconferencing. The patient received therapy supplies by mail as needed, and their use was reviewed in telerehabilitation sessions with videoconferencing as needed. During their postoperative course, the patient experienced little edema or scar tissue formation, and recovery was uncomplicated. The patient developed a mild extensor lag for which a proximal interphalangeal joint spring extension orthosis was provided via mail (Figure 2). The patient admitted only partial adherence with this orthosis, and at discharge, a 10-degree extensor lag remained. The patient was not concerned by this extension deficit and did not experience any associated functional deficits, demonstrated by scores on the Quick Disabilities of the Arm, Shoulder and Hand questionnaire and Patient Specific Functional Scale (Table 2).

Discussion

Few studies have been published that address the efficacy of telerehabilitation after surgical management of traumatic injuries involving the upper extremity. One Australian study performed by Worboys and colleagues concluded that utilization of telehealth services for hand therapy visits may provide accurate patient assessment with favorable patient satisfaction.⁵ Another study performed in the UK by Gilbert and colleagues demonstrated that videoconferencing is well received by patients, as it may offer shorter wait times, improved convenience, and reduced travel cost.

The authors noted that although videoconferencing may not completely replace in-person therapy, it could act as an adjunct.⁶ While these in-person visits may be necessary, particularly to establish care, at least one study has demonstrated that patients may prefer follow-up via telehealth if provided the option.⁷ In a randomized, controlled study performed in Norway, patients were randomized to either an in-person or video consultation with an orthopedic outpatient clinic. Of patients randomized to the in-person clinic visit, 86% preferred to have follow-up via videoconferencing.⁷

Previous studies have demonstrated that telehealth may produce accurate patient assessment, with relatively high patient satisfaction. Given the COVID-19 pandemic and the limitations that this crisis has placed on in-person outpatient visits, clinics that previously may have been resistant to telehealth are adapting and using the technology to meet the needs of their population.⁸ The present case demonstrates that videoconferencing is feasible and may lead to successful results, even for cases requiring significant hand therapy follow-up, such as flexor tendon repairs.

Conclusions

Although in-person hand therapy remains the standard of care following flexor tendon repair of the hand, situations may exist in which hand therapy conducted via telehealth is better than no hand therapy at all. The present case study highlights the use of telehealth as an acceptable supplement to in-person postoperative visits.

In our case, use of a standardized protocol with an emphasis on hand function and patient satisfaction as opposed to strict range of motion measurements produced good results. Although a specific telehealth satisfaction measure was not used in this case, commonly used questionnaires may be integrated into future visits to improve telehealth implementation and patient experience. In this specific case, the veteran felt that hand function was regained and expressed general satisfaction with the telemedicine process at the conclusion of care. While telehealth was a useful adjunct in the treatment of the present patient, further study of videoconferencing should be conducted to determine whether hand therapy conducted via telehealth could be implemented more broadly following upper extremity surgery.

Lower back pain (LBP) affects an estimated 9.4% of the global population and has resulted in more years lived with disability than any other health condition.¹ LBP affects a wide range of populations, but US veterans have been shown to have significantly higher rates of back pain than nonveterans. The National Institutes of Health reports that 65.6% of veterans experience chronic pain; 9.1% of veterans experience severe, chronic pain.² Chronic back pain is treated by a range of methods, including medications, surgery, physical therapy (PT), patient education, and behavioral therapy.³ However, chronic neuropathic back pain has been shown to have limited responsiveness to medication.⁴

Neuropathic pain is caused by lesions in the somatosensory nervous system, resulting in spontaneous pain and amplified pain responses to both painful and nonpainful stimuli.⁵ The most common location for neuropathic pain is the back and legs. Between 10% and 40% of people who undergo lumbosacral spine surgery to treat neuropathic radicular pain will experience further neuropathic pain.⁶ This condition is referred to as failed back surgery syndrome or postlaminectomy syndrome (PLS). While neuropathic back pain has had limited responsiveness to medication and repeated lumbosacral spine surgery, spinal cord stimulation (SCS) has shown promise as an effective form of pain treatment for those experiencing PLS and other spine disorders.^7-10 In addition, SCS therapy has had a very low incidence of complications, which may be on the decline with recent technological advancements.¹¹ Patients with a diagnosis of PLS, LBP, or complex regional pain syndrome (CRPS) who have not responded to medications, therapy, and/or injections for ≥ 6 months were eligible for a trial of SCS therapy. Trial leads were placed via the percutaneous route with the battery strapped to the waistline for 3 to 5 days and were removed in clinic. Patients who experienced > 60% pain relief and functional improvement received a SCS implant.

The effectiveness of SCS has been demonstrated in a nonveteran population, but it has not been studied in a veteran population.¹² US Department of Veterans Affairs (VA) health care coverage is different from Medicare and private insurance in that it is classified as a benefit and not insurance. The goals of treatment at the VA may include considerations in addition to feeling better, and patient presentations may not align with those in the private sector.

We hypothesize that SCS is both a safe and beneficial treatment option for veterans with chronic intractable spine and/or extremity pain. The purpose of this study was to determine the efficacy and safety of SCS in a veteran population.

Methods

The efficacy and safety of SCS was determined via a retrospective study. Inclusion criteria for the study consisted of any Southeastern Louisiana Veterans Health Care System (SLVHCS) patient who had an SCS trial and/or implant from 2008 to 2020. Eligible veterans must have had chronic pain for at least 6 months and had previously tried multiple medications, PT, transcutaneous nerve stimulation, facet injections, epidural steroid injections, or surgery without success. For medication therapy to be considered unsuccessful, it must have included acetaminophen, nonsteroidal anti-inflammatory drugs, and ≥ 1 adjuvant medication (gabapentin, duloxetine, amitriptyline, lidocaine, and menthol). A diagnosis of chronic LBP, PLS, cervical or lumbar spondylosis with radiculopathy, complex regional pain syndrome, or chronic pain syndrome was required for eligibility. Patients whose pain decreased by > 60% and had functional improvement in a 3- to 5-day trial received SCS implantation with percutaneous leads by a pain physician or paddle lead by a neurosurgeon.

The SLVHCS Institutional Review Board approved this study. Electronic health records were reviewed to determine patient age, anthropometric data, and date of SCS implantation. Patients were then called and interviewed to complete a survey. After obtaining verbal consent to the study, subjects were surveyed regarding whether the patient would recommend the procedure to peers, adverse effects (AEs) or complications, and the ability to decrease opiates if applicable. A verbal Pain Outcome Questionnaire (POQ) assessment of activities of daily living also was given during the phone interview regarding pain levels before SCS and at the time of the phone interview.¹³ (eAppendix available at doi:10.12788/fp.0204) Following the survey, a chart review was performed to corroborate the given AEs or complications and opiate use information. Before and after results of the POQ were compared via a paired sample t test, and P values < .05 were considered significant. Analyses were performed by IBM SPSS, version 26.

The primary outcome measure for this study was whether veterans would recommend SCS to their peers; in our view, this categorical outcome measure seemed to be more valuable to share with future patients who might be candidates for SCS. Since VA health care coverage and goals of treatment may be different from a nonveteran population, we opted to use this primary measure to decrease the possibility of confounding variables.

Secondary outcome measures included changes in POC scores, improvements in activities of daily living, and decreases in use of opioid pain medications.

POQ responses were recorded during the telephone interviews (0 to 10 scale). A paired sample t test was conducted to compare pain levels before and after SCS implant. Pain levels were gathered in the single phone call. Patient opioid usage, if applicable, was assessed by converting medications to morphine milligram equivalent dosing (MMED). Since patients who were on chronic opioids took multiple formulations, we changed the total daily dose to all morphine; for this study, morphine was considered equivalent to hydrocodone, and oxycodone was 1.5x morphine.

Results

Of the 90 SLVHCS patients who received an SCS implant between 2008 and 2020, 76 were reached by telephone and 65 had their responses recorded in the study. Of the 11 patients who were not included, 5 had the SCS removed; it is unclear whether these veterans would have recommended the treatment. Four were unable to quantify pain and/or SCS effects, and 2 were excluded due to a dementia diagnosis years after the implant. The mean (SD) age of participants was 63.9 (10.3) years. Forty percent of patients had a diabetes mellitus diagnosis and 1 had prediabetes. Patients’ most common qualifying diagnosis for SCS was PLS (47.7%) followed by chronic LBP (26.2%). A percutaneous 2-lead technique was the most common type of SCS type used (60.0%) followed by 1-lead (21.5%). The most common SCS manufacturer was Boston Scientific (87.7%)(Table 1). Most veterans (76.9%) recommended SCS to their peers; 13.8% did not recommend SCS; 9.2% were undecided and stated that they were unable to recommend because they did not want to persuade a peer to get SCS (Figure).

There was a statistically significant decrease in opioid use for the 40 veterans for whom pain medication was converted (P < .001)(Table 2). Six patients reported using opioids at some point but could not remember their dose, and no records were found in their chart review, so they were not included in the MMED analysis. In that group, 4 patients reported using opioids before SCS but discontinued the opioid use after SCS implantation, and 2 patients noted using opioids before SCS and concomitantly. Eighteen subjects reported no opioid use at any point before or after SCS (Table 3).

There were few life-threatening complications of SCS. Three veterans developed skin dehiscence; 2 had dehiscence at the battery/generator site, and 1 had dehiscence at the lead anchor site. Two patients with dehiscence also had morbid obesity, and the third had postoperative malnourishment. The dehiscence occurred 3 and 8 months postoperation. All 3 patients with dehiscence had the SCS explanted, though they were eager to get a new SCS implanted as soon as possible because SCS was their most successful treatment to date.

Discussion

In this nonrandomized retrospective review, SCS was shown to be an effective treatment for intractable spine and/or extremity pain. Veterans’ pain levels were significantly reduced following SCS implantation, and more than three-fourths of veterans recommended SCS to their peers. We used the recommendation of SCS to peers as the most important metric regarding the effectiveness of SCS, as this measure was felt to be more valuable to share with future patients; furthermore, categorical analysis has been shown to be more valuable than ordinal pain scales to measure pain.¹⁴ In addition to wanting to expand the available research to the general public, we wanted a measure that we could easily relay to our patient population regarding SCS.

The explant rate of 14.5% among surveyed veterans falls at the higher end of the normal ranges found in previous studies of long-term SCS outcomes.^15-17 One possible reason for the higher rate is that we did not differentiate based on the reason for the explant (ie, no benefit, further surgery needed for underlying medical condition, or SCS-specific complications). Another possible contributing factor to the higher than expected explant rate is the geographic location in the New Orleans metro area; New Orleans is considered to have one of the highest rates of obesity in the United States and obesity typically has other diseases associated with it such as hypertension and diabetes mellitus.

Limitations

Limitations of the study include the relatively low number of subjects, subjective nature of the interview questions, and the patients’ answers. Typically the POQ has been used as a prospective assessment of pain; whether it is valid in a retrospective analysis is not clear. While there was a statistically significant decrease of opioid use after getting SCS, this study can only show correlation, not causation. During the study period, there has been a drastic change in opioid prescribing patterns and efforts to decrease the amount of opioids prescribed.

Subjects also were asked to rate their pain and quality of life before SCS. Some subjects had SCS implantation up to 10 years prior to the phone interview. The variable amount of time between SCS implantation and interview likely affected subjects’ responses. Chronic pain is a moving target. Patients have good days and bad days that would likely change opinions on SCS benefits on a single phone interview. Some patients needed battery replacements at the time of the interview (battery life averaged about 3 to 5 years in our study population) and were asked to report current levels of pain from the perspective of when their batteries were still functional, further affecting results.

Conclusions

SCS was shown to improve the quality of life of US veterans at SLVHCS across a wide variety of metrics, including activities of daily living, as well as mental and physical health. For veterans with chronic intractable pain who have tried and failed more conservative treatments, SCS is a great treatment.

Lower back pain (LBP) affects an estimated 9.4% of the global population and has resulted in more years lived with disability than any other health condition.¹ LBP affects a wide range of populations, but US veterans have been shown to have significantly higher rates of back pain than nonveterans. The National Institutes of Health reports that 65.6% of veterans experience chronic pain; 9.1% of veterans experience severe, chronic pain.² Chronic back pain is treated by a range of methods, including medications, surgery, physical therapy (PT), patient education, and behavioral therapy.³ However, chronic neuropathic back pain has been shown to have limited responsiveness to medication.⁴

Neuropathic pain is caused by lesions in the somatosensory nervous system, resulting in spontaneous pain and amplified pain responses to both painful and nonpainful stimuli.⁵ The most common location for neuropathic pain is the back and legs. Between 10% and 40% of people who undergo lumbosacral spine surgery to treat neuropathic radicular pain will experience further neuropathic pain.⁶ This condition is referred to as failed back surgery syndrome or postlaminectomy syndrome (PLS). While neuropathic back pain has had limited responsiveness to medication and repeated lumbosacral spine surgery, spinal cord stimulation (SCS) has shown promise as an effective form of pain treatment for those experiencing PLS and other spine disorders.^7-10 In addition, SCS therapy has had a very low incidence of complications, which may be on the decline with recent technological advancements.¹¹ Patients with a diagnosis of PLS, LBP, or complex regional pain syndrome (CRPS) who have not responded to medications, therapy, and/or injections for ≥ 6 months were eligible for a trial of SCS therapy. Trial leads were placed via the percutaneous route with the battery strapped to the waistline for 3 to 5 days and were removed in clinic. Patients who experienced > 60% pain relief and functional improvement received a SCS implant.

The effectiveness of SCS has been demonstrated in a nonveteran population, but it has not been studied in a veteran population.¹² US Department of Veterans Affairs (VA) health care coverage is different from Medicare and private insurance in that it is classified as a benefit and not insurance. The goals of treatment at the VA may include considerations in addition to feeling better, and patient presentations may not align with those in the private sector.

We hypothesize that SCS is both a safe and beneficial treatment option for veterans with chronic intractable spine and/or extremity pain. The purpose of this study was to determine the efficacy and safety of SCS in a veteran population.

Methods

The efficacy and safety of SCS was determined via a retrospective study. Inclusion criteria for the study consisted of any Southeastern Louisiana Veterans Health Care System (SLVHCS) patient who had an SCS trial and/or implant from 2008 to 2020. Eligible veterans must have had chronic pain for at least 6 months and had previously tried multiple medications, PT, transcutaneous nerve stimulation, facet injections, epidural steroid injections, or surgery without success. For medication therapy to be considered unsuccessful, it must have included acetaminophen, nonsteroidal anti-inflammatory drugs, and ≥ 1 adjuvant medication (gabapentin, duloxetine, amitriptyline, lidocaine, and menthol). A diagnosis of chronic LBP, PLS, cervical or lumbar spondylosis with radiculopathy, complex regional pain syndrome, or chronic pain syndrome was required for eligibility. Patients whose pain decreased by > 60% and had functional improvement in a 3- to 5-day trial received SCS implantation with percutaneous leads by a pain physician or paddle lead by a neurosurgeon.

The SLVHCS Institutional Review Board approved this study. Electronic health records were reviewed to determine patient age, anthropometric data, and date of SCS implantation. Patients were then called and interviewed to complete a survey. After obtaining verbal consent to the study, subjects were surveyed regarding whether the patient would recommend the procedure to peers, adverse effects (AEs) or complications, and the ability to decrease opiates if applicable. A verbal Pain Outcome Questionnaire (POQ) assessment of activities of daily living also was given during the phone interview regarding pain levels before SCS and at the time of the phone interview.¹³ (eAppendix available at doi:10.12788/fp.0204) Following the survey, a chart review was performed to corroborate the given AEs or complications and opiate use information. Before and after results of the POQ were compared via a paired sample t test, and P values < .05 were considered significant. Analyses were performed by IBM SPSS, version 26.

The primary outcome measure for this study was whether veterans would recommend SCS to their peers; in our view, this categorical outcome measure seemed to be more valuable to share with future patients who might be candidates for SCS. Since VA health care coverage and goals of treatment may be different from a nonveteran population, we opted to use this primary measure to decrease the possibility of confounding variables.

Secondary outcome measures included changes in POC scores, improvements in activities of daily living, and decreases in use of opioid pain medications.

POQ responses were recorded during the telephone interviews (0 to 10 scale). A paired sample t test was conducted to compare pain levels before and after SCS implant. Pain levels were gathered in the single phone call. Patient opioid usage, if applicable, was assessed by converting medications to morphine milligram equivalent dosing (MMED). Since patients who were on chronic opioids took multiple formulations, we changed the total daily dose to all morphine; for this study, morphine was considered equivalent to hydrocodone, and oxycodone was 1.5x morphine.

Results

Of the 90 SLVHCS patients who received an SCS implant between 2008 and 2020, 76 were reached by telephone and 65 had their responses recorded in the study. Of the 11 patients who were not included, 5 had the SCS removed; it is unclear whether these veterans would have recommended the treatment. Four were unable to quantify pain and/or SCS effects, and 2 were excluded due to a dementia diagnosis years after the implant. The mean (SD) age of participants was 63.9 (10.3) years. Forty percent of patients had a diabetes mellitus diagnosis and 1 had prediabetes. Patients’ most common qualifying diagnosis for SCS was PLS (47.7%) followed by chronic LBP (26.2%). A percutaneous 2-lead technique was the most common type of SCS type used (60.0%) followed by 1-lead (21.5%). The most common SCS manufacturer was Boston Scientific (87.7%)(Table 1). Most veterans (76.9%) recommended SCS to their peers; 13.8% did not recommend SCS; 9.2% were undecided and stated that they were unable to recommend because they did not want to persuade a peer to get SCS (Figure).

There was a statistically significant decrease in opioid use for the 40 veterans for whom pain medication was converted (P < .001)(Table 2). Six patients reported using opioids at some point but could not remember their dose, and no records were found in their chart review, so they were not included in the MMED analysis. In that group, 4 patients reported using opioids before SCS but discontinued the opioid use after SCS implantation, and 2 patients noted using opioids before SCS and concomitantly. Eighteen subjects reported no opioid use at any point before or after SCS (Table 3).

There were few life-threatening complications of SCS. Three veterans developed skin dehiscence; 2 had dehiscence at the battery/generator site, and 1 had dehiscence at the lead anchor site. Two patients with dehiscence also had morbid obesity, and the third had postoperative malnourishment. The dehiscence occurred 3 and 8 months postoperation. All 3 patients with dehiscence had the SCS explanted, though they were eager to get a new SCS implanted as soon as possible because SCS was their most successful treatment to date.

Discussion

In this nonrandomized retrospective review, SCS was shown to be an effective treatment for intractable spine and/or extremity pain. Veterans’ pain levels were significantly reduced following SCS implantation, and more than three-fourths of veterans recommended SCS to their peers. We used the recommendation of SCS to peers as the most important metric regarding the effectiveness of SCS, as this measure was felt to be more valuable to share with future patients; furthermore, categorical analysis has been shown to be more valuable than ordinal pain scales to measure pain.¹⁴ In addition to wanting to expand the available research to the general public, we wanted a measure that we could easily relay to our patient population regarding SCS.

The explant rate of 14.5% among surveyed veterans falls at the higher end of the normal ranges found in previous studies of long-term SCS outcomes.^15-17 One possible reason for the higher rate is that we did not differentiate based on the reason for the explant (ie, no benefit, further surgery needed for underlying medical condition, or SCS-specific complications). Another possible contributing factor to the higher than expected explant rate is the geographic location in the New Orleans metro area; New Orleans is considered to have one of the highest rates of obesity in the United States and obesity typically has other diseases associated with it such as hypertension and diabetes mellitus.

Limitations

Limitations of the study include the relatively low number of subjects, subjective nature of the interview questions, and the patients’ answers. Typically the POQ has been used as a prospective assessment of pain; whether it is valid in a retrospective analysis is not clear. While there was a statistically significant decrease of opioid use after getting SCS, this study can only show correlation, not causation. During the study period, there has been a drastic change in opioid prescribing patterns and efforts to decrease the amount of opioids prescribed.

Subjects also were asked to rate their pain and quality of life before SCS. Some subjects had SCS implantation up to 10 years prior to the phone interview. The variable amount of time between SCS implantation and interview likely affected subjects’ responses. Chronic pain is a moving target. Patients have good days and bad days that would likely change opinions on SCS benefits on a single phone interview. Some patients needed battery replacements at the time of the interview (battery life averaged about 3 to 5 years in our study population) and were asked to report current levels of pain from the perspective of when their batteries were still functional, further affecting results.

Conclusions

SCS was shown to improve the quality of life of US veterans at SLVHCS across a wide variety of metrics, including activities of daily living, as well as mental and physical health. For veterans with chronic intractable pain who have tried and failed more conservative treatments, SCS is a great treatment.

Lower back pain (LBP) affects an estimated 9.4% of the global population and has resulted in more years lived with disability than any other health condition.¹ LBP affects a wide range of populations, but US veterans have been shown to have significantly higher rates of back pain than nonveterans. The National Institutes of Health reports that 65.6% of veterans experience chronic pain; 9.1% of veterans experience severe, chronic pain.² Chronic back pain is treated by a range of methods, including medications, surgery, physical therapy (PT), patient education, and behavioral therapy.³ However, chronic neuropathic back pain has been shown to have limited responsiveness to medication.⁴

Neuropathic pain is caused by lesions in the somatosensory nervous system, resulting in spontaneous pain and amplified pain responses to both painful and nonpainful stimuli.⁵ The most common location for neuropathic pain is the back and legs. Between 10% and 40% of people who undergo lumbosacral spine surgery to treat neuropathic radicular pain will experience further neuropathic pain.⁶ This condition is referred to as failed back surgery syndrome or postlaminectomy syndrome (PLS). While neuropathic back pain has had limited responsiveness to medication and repeated lumbosacral spine surgery, spinal cord stimulation (SCS) has shown promise as an effective form of pain treatment for those experiencing PLS and other spine disorders.^7-10 In addition, SCS therapy has had a very low incidence of complications, which may be on the decline with recent technological advancements.¹¹ Patients with a diagnosis of PLS, LBP, or complex regional pain syndrome (CRPS) who have not responded to medications, therapy, and/or injections for ≥ 6 months were eligible for a trial of SCS therapy. Trial leads were placed via the percutaneous route with the battery strapped to the waistline for 3 to 5 days and were removed in clinic. Patients who experienced > 60% pain relief and functional improvement received a SCS implant.

The effectiveness of SCS has been demonstrated in a nonveteran population, but it has not been studied in a veteran population.¹² US Department of Veterans Affairs (VA) health care coverage is different from Medicare and private insurance in that it is classified as a benefit and not insurance. The goals of treatment at the VA may include considerations in addition to feeling better, and patient presentations may not align with those in the private sector.

We hypothesize that SCS is both a safe and beneficial treatment option for veterans with chronic intractable spine and/or extremity pain. The purpose of this study was to determine the efficacy and safety of SCS in a veteran population.

Methods

The efficacy and safety of SCS was determined via a retrospective study. Inclusion criteria for the study consisted of any Southeastern Louisiana Veterans Health Care System (SLVHCS) patient who had an SCS trial and/or implant from 2008 to 2020. Eligible veterans must have had chronic pain for at least 6 months and had previously tried multiple medications, PT, transcutaneous nerve stimulation, facet injections, epidural steroid injections, or surgery without success. For medication therapy to be considered unsuccessful, it must have included acetaminophen, nonsteroidal anti-inflammatory drugs, and ≥ 1 adjuvant medication (gabapentin, duloxetine, amitriptyline, lidocaine, and menthol). A diagnosis of chronic LBP, PLS, cervical or lumbar spondylosis with radiculopathy, complex regional pain syndrome, or chronic pain syndrome was required for eligibility. Patients whose pain decreased by > 60% and had functional improvement in a 3- to 5-day trial received SCS implantation with percutaneous leads by a pain physician or paddle lead by a neurosurgeon.

The SLVHCS Institutional Review Board approved this study. Electronic health records were reviewed to determine patient age, anthropometric data, and date of SCS implantation. Patients were then called and interviewed to complete a survey. After obtaining verbal consent to the study, subjects were surveyed regarding whether the patient would recommend the procedure to peers, adverse effects (AEs) or complications, and the ability to decrease opiates if applicable. A verbal Pain Outcome Questionnaire (POQ) assessment of activities of daily living also was given during the phone interview regarding pain levels before SCS and at the time of the phone interview.¹³ (eAppendix available at doi:10.12788/fp.0204) Following the survey, a chart review was performed to corroborate the given AEs or complications and opiate use information. Before and after results of the POQ were compared via a paired sample t test, and P values < .05 were considered significant. Analyses were performed by IBM SPSS, version 26.

The primary outcome measure for this study was whether veterans would recommend SCS to their peers; in our view, this categorical outcome measure seemed to be more valuable to share with future patients who might be candidates for SCS. Since VA health care coverage and goals of treatment may be different from a nonveteran population, we opted to use this primary measure to decrease the possibility of confounding variables.

Secondary outcome measures included changes in POC scores, improvements in activities of daily living, and decreases in use of opioid pain medications.

POQ responses were recorded during the telephone interviews (0 to 10 scale). A paired sample t test was conducted to compare pain levels before and after SCS implant. Pain levels were gathered in the single phone call. Patient opioid usage, if applicable, was assessed by converting medications to morphine milligram equivalent dosing (MMED). Since patients who were on chronic opioids took multiple formulations, we changed the total daily dose to all morphine; for this study, morphine was considered equivalent to hydrocodone, and oxycodone was 1.5x morphine.

Results

Of the 90 SLVHCS patients who received an SCS implant between 2008 and 2020, 76 were reached by telephone and 65 had their responses recorded in the study. Of the 11 patients who were not included, 5 had the SCS removed; it is unclear whether these veterans would have recommended the treatment. Four were unable to quantify pain and/or SCS effects, and 2 were excluded due to a dementia diagnosis years after the implant. The mean (SD) age of participants was 63.9 (10.3) years. Forty percent of patients had a diabetes mellitus diagnosis and 1 had prediabetes. Patients’ most common qualifying diagnosis for SCS was PLS (47.7%) followed by chronic LBP (26.2%). A percutaneous 2-lead technique was the most common type of SCS type used (60.0%) followed by 1-lead (21.5%). The most common SCS manufacturer was Boston Scientific (87.7%)(Table 1). Most veterans (76.9%) recommended SCS to their peers; 13.8% did not recommend SCS; 9.2% were undecided and stated that they were unable to recommend because they did not want to persuade a peer to get SCS (Figure).

There was a statistically significant decrease in opioid use for the 40 veterans for whom pain medication was converted (P < .001)(Table 2). Six patients reported using opioids at some point but could not remember their dose, and no records were found in their chart review, so they were not included in the MMED analysis. In that group, 4 patients reported using opioids before SCS but discontinued the opioid use after SCS implantation, and 2 patients noted using opioids before SCS and concomitantly. Eighteen subjects reported no opioid use at any point before or after SCS (Table 3).

There were few life-threatening complications of SCS. Three veterans developed skin dehiscence; 2 had dehiscence at the battery/generator site, and 1 had dehiscence at the lead anchor site. Two patients with dehiscence also had morbid obesity, and the third had postoperative malnourishment. The dehiscence occurred 3 and 8 months postoperation. All 3 patients with dehiscence had the SCS explanted, though they were eager to get a new SCS implanted as soon as possible because SCS was their most successful treatment to date.

Discussion

In this nonrandomized retrospective review, SCS was shown to be an effective treatment for intractable spine and/or extremity pain. Veterans’ pain levels were significantly reduced following SCS implantation, and more than three-fourths of veterans recommended SCS to their peers. We used the recommendation of SCS to peers as the most important metric regarding the effectiveness of SCS, as this measure was felt to be more valuable to share with future patients; furthermore, categorical analysis has been shown to be more valuable than ordinal pain scales to measure pain.¹⁴ In addition to wanting to expand the available research to the general public, we wanted a measure that we could easily relay to our patient population regarding SCS.

The explant rate of 14.5% among surveyed veterans falls at the higher end of the normal ranges found in previous studies of long-term SCS outcomes.^15-17 One possible reason for the higher rate is that we did not differentiate based on the reason for the explant (ie, no benefit, further surgery needed for underlying medical condition, or SCS-specific complications). Another possible contributing factor to the higher than expected explant rate is the geographic location in the New Orleans metro area; New Orleans is considered to have one of the highest rates of obesity in the United States and obesity typically has other diseases associated with it such as hypertension and diabetes mellitus.

Limitations

Limitations of the study include the relatively low number of subjects, subjective nature of the interview questions, and the patients’ answers. Typically the POQ has been used as a prospective assessment of pain; whether it is valid in a retrospective analysis is not clear. While there was a statistically significant decrease of opioid use after getting SCS, this study can only show correlation, not causation. During the study period, there has been a drastic change in opioid prescribing patterns and efforts to decrease the amount of opioids prescribed.

Subjects also were asked to rate their pain and quality of life before SCS. Some subjects had SCS implantation up to 10 years prior to the phone interview. The variable amount of time between SCS implantation and interview likely affected subjects’ responses. Chronic pain is a moving target. Patients have good days and bad days that would likely change opinions on SCS benefits on a single phone interview. Some patients needed battery replacements at the time of the interview (battery life averaged about 3 to 5 years in our study population) and were asked to report current levels of pain from the perspective of when their batteries were still functional, further affecting results.

Conclusions

SCS was shown to improve the quality of life of US veterans at SLVHCS across a wide variety of metrics, including activities of daily living, as well as mental and physical health. For veterans with chronic intractable pain who have tried and failed more conservative treatments, SCS is a great treatment.

Baby-wearing – carrying a child against your body in a sling, soft carrier, or other device – is associated with benefits like reduced crying and increased breastfeeding, studies have shown.

But this practice also entails risks. Babies can fall out of carriers, or be injured when an adult carrying them falls, for example.

In the past decade, thousands of children were seen at EDs in the United States with injuries related to baby-wearing products, researchers estimated in a study presented at the annual meeting of the American Academy of Pediatrics.

To characterize the epidemiology of these injuries, Samantha J. Rowe, MD, chief resident physician at Walter Reed National Military Medical Center in Bethesda, Md., and colleagues analyzed data from the National Electronic Injury Surveillance System between 2011 and 2020.

They included in their analysis data from patients aged 5 years and younger who sustained an injury associated with a baby-wearing product. Baby harnesses, carriers, slings, framed baby carriers, and soft baby carriers were among the devices included in the study. The researchers used 601 cases to generate national estimates.

An estimated 14,024 patients presented to EDs because of baby-wearing injuries, and 52% of the injuries occurred when a patient fell from the product.

Most injuries (61%) occurred in children aged 5 months and younger; 19.3% of these infants required hospitalization, most often for head injuries.

The investigators found that about 22% of the injuries were associated with a caregiver falling, noted Rachel Y. Moon, MD, who was not involved in the study.

“Carrying a baby changes your center of gravity – and can also obscure your vision of where you’re walking, so adults who use these devices should be cognizant of this,” said Dr. Moon, with the University of Virginia, Charlottesville.

Dr. Rowe often practiced baby-wearing with her daughter, and found that it was beneficial. And studies have demonstrated various benefits of baby-wearing, including improved thermoregulation and glycemic control.

Still, the new analysis illustrates the potential for baby-wearing products “to cause serious injury, especially in infants 5 months and younger,” Dr. Rowe said. “We need to provide more education to caregivers on safe baby-wearing and continue to improve our safety standards for baby-wearing products.”

Study coauthor Patrick T. Reeves, MD, with the Naval Medical Center at San Diego, offered additional guidance in a news release: “Like when buying a new pair of shoes, parents must be educated on the proper sizing, selection, and wear of baby carriers to prevent injury to themselves and their child.”

Parents also need to ensure that the child’s nose and mouth are not obstructed, Dr. Moon

In a recent article discussing the possible benefits of baby-wearing in terms of helping with breastfeeding, Dr. Moon also pointed out further safety considerations: “No matter which carrier is used, for safety reasons, we need to remind parents that the baby should be positioned so that the head is upright and the nose and mouth are not obstructed.”

The researchers and Dr. Moon had no relevant financial disclosures.

[email protected]

Baby-wearing – carrying a child against your body in a sling, soft carrier, or other device – is associated with benefits like reduced crying and increased breastfeeding, studies have shown.

But this practice also entails risks. Babies can fall out of carriers, or be injured when an adult carrying them falls, for example.

In the past decade, thousands of children were seen at EDs in the United States with injuries related to baby-wearing products, researchers estimated in a study presented at the annual meeting of the American Academy of Pediatrics.

To characterize the epidemiology of these injuries, Samantha J. Rowe, MD, chief resident physician at Walter Reed National Military Medical Center in Bethesda, Md., and colleagues analyzed data from the National Electronic Injury Surveillance System between 2011 and 2020.

They included in their analysis data from patients aged 5 years and younger who sustained an injury associated with a baby-wearing product. Baby harnesses, carriers, slings, framed baby carriers, and soft baby carriers were among the devices included in the study. The researchers used 601 cases to generate national estimates.

An estimated 14,024 patients presented to EDs because of baby-wearing injuries, and 52% of the injuries occurred when a patient fell from the product.

Most injuries (61%) occurred in children aged 5 months and younger; 19.3% of these infants required hospitalization, most often for head injuries.

The investigators found that about 22% of the injuries were associated with a caregiver falling, noted Rachel Y. Moon, MD, who was not involved in the study.

“Carrying a baby changes your center of gravity – and can also obscure your vision of where you’re walking, so adults who use these devices should be cognizant of this,” said Dr. Moon, with the University of Virginia, Charlottesville.

Dr. Rowe often practiced baby-wearing with her daughter, and found that it was beneficial. And studies have demonstrated various benefits of baby-wearing, including improved thermoregulation and glycemic control.

Still, the new analysis illustrates the potential for baby-wearing products “to cause serious injury, especially in infants 5 months and younger,” Dr. Rowe said. “We need to provide more education to caregivers on safe baby-wearing and continue to improve our safety standards for baby-wearing products.”

Study coauthor Patrick T. Reeves, MD, with the Naval Medical Center at San Diego, offered additional guidance in a news release: “Like when buying a new pair of shoes, parents must be educated on the proper sizing, selection, and wear of baby carriers to prevent injury to themselves and their child.”

Parents also need to ensure that the child’s nose and mouth are not obstructed, Dr. Moon

In a recent article discussing the possible benefits of baby-wearing in terms of helping with breastfeeding, Dr. Moon also pointed out further safety considerations: “No matter which carrier is used, for safety reasons, we need to remind parents that the baby should be positioned so that the head is upright and the nose and mouth are not obstructed.”

The researchers and Dr. Moon had no relevant financial disclosures.

[email protected]

Baby-wearing – carrying a child against your body in a sling, soft carrier, or other device – is associated with benefits like reduced crying and increased breastfeeding, studies have shown.

But this practice also entails risks. Babies can fall out of carriers, or be injured when an adult carrying them falls, for example.

In the past decade, thousands of children were seen at EDs in the United States with injuries related to baby-wearing products, researchers estimated in a study presented at the annual meeting of the American Academy of Pediatrics.

To characterize the epidemiology of these injuries, Samantha J. Rowe, MD, chief resident physician at Walter Reed National Military Medical Center in Bethesda, Md., and colleagues analyzed data from the National Electronic Injury Surveillance System between 2011 and 2020.

They included in their analysis data from patients aged 5 years and younger who sustained an injury associated with a baby-wearing product. Baby harnesses, carriers, slings, framed baby carriers, and soft baby carriers were among the devices included in the study. The researchers used 601 cases to generate national estimates.

An estimated 14,024 patients presented to EDs because of baby-wearing injuries, and 52% of the injuries occurred when a patient fell from the product.

Most injuries (61%) occurred in children aged 5 months and younger; 19.3% of these infants required hospitalization, most often for head injuries.

The investigators found that about 22% of the injuries were associated with a caregiver falling, noted Rachel Y. Moon, MD, who was not involved in the study.

“Carrying a baby changes your center of gravity – and can also obscure your vision of where you’re walking, so adults who use these devices should be cognizant of this,” said Dr. Moon, with the University of Virginia, Charlottesville.

Dr. Rowe often practiced baby-wearing with her daughter, and found that it was beneficial. And studies have demonstrated various benefits of baby-wearing, including improved thermoregulation and glycemic control.

Still, the new analysis illustrates the potential for baby-wearing products “to cause serious injury, especially in infants 5 months and younger,” Dr. Rowe said. “We need to provide more education to caregivers on safe baby-wearing and continue to improve our safety standards for baby-wearing products.”

Study coauthor Patrick T. Reeves, MD, with the Naval Medical Center at San Diego, offered additional guidance in a news release: “Like when buying a new pair of shoes, parents must be educated on the proper sizing, selection, and wear of baby carriers to prevent injury to themselves and their child.”

Parents also need to ensure that the child’s nose and mouth are not obstructed, Dr. Moon

In a recent article discussing the possible benefits of baby-wearing in terms of helping with breastfeeding, Dr. Moon also pointed out further safety considerations: “No matter which carrier is used, for safety reasons, we need to remind parents that the baby should be positioned so that the head is upright and the nose and mouth are not obstructed.”

The researchers and Dr. Moon had no relevant financial disclosures.

[email protected]

When pediatricians and other pediatric providers are given training and resource materials, levels of firearm screenings and anticipatory guidance about firearm safety increase significantly, according to two new studies presented at the annual meeting of the American Academy of Pediatrics.

“With the rise in firearm sales and injuries during the COVID-19 pandemic, it is more important than ever that pediatricians address the firearm epidemic,” said Alexandra Byrne, MD, a pediatric resident at the University of Florida in Gainesville, who presented one of the studies.

There were 4.3 million more firearms purchased from March through July 2020 than expected, a recent study estimates, and 4,075 more firearm injuries than expected from April through July 2020.

In states with more excess purchases, firearm injuries related to domestic violence increased in April (rate ratio, 2.60; 95% CI, 1.32-5.93) and May (RR, 1.79; 95% CI, 1.19-2.91) 2020. However, excess gun purchases had no effect on rates of firearm violence outside the home.

In addition to the link between firearms in the home and domestic violence, they are also linked to a three- to fourfold greater risk for teen suicide, and both depression and suicidal thoughts have risen in teens during the pandemic.

“The data are pretty clear that if you have an unlocked, loaded weapon in your home, and you have a kid who’s depressed or anxious or dysregulated or doing maladaptive things for the pandemic, they’re much more likely to inadvertently take their own or someone else’s life by grabbing [a gun],” said Cora Breuner, MD, MPH, professor of pediatrics at Seattle Children’s Hospital.

However, there is no difference in gun ownership or gun-safety measures between homes with and without at-risk children, previous research shows.
 

Training, guidance, and locks

Previous research has also shown that there has been a reluctance by pediatricians to conduct firearm screenings and counsel parents about gun safety in the home.

For their two-step program, Dr. Byrne’s team used a plan-do-study-act approach. They started by providing training on firearm safety, evidence-based recommendations for firearm screening, and anticipatory guidance regarding safe firearm storage to members of the general pediatrics division at the University of Florida. And they supplied clinics with free firearm locks.

Next they supplied clinics with posters and educational cards from the Be SMART campaign, an initiative of the Everytown for Gun Safety Support Fund, which provides materials for anyone, including physicians, to use.

During their study, the researchers sent three anonymous six-question online surveys – at baseline and 3 to 4 months after each of the two steps – to pediatric residents, physician assistants, advanced practice registered nurses, and attendings to assess the project. There were 52 responses to the first survey, for a response rate of 58.4%, 42 responses to the second survey, for a response rate of 47.2%, and 23 responses to the third survey, for a rate of response 25.8%.

The program nearly doubled screenings during well-child visits and dramatically increased the proportion of families who received a firearm lock when they told providers they had a firearm at home.

Adding a social-history component

A program to increase firearm screening was also presented at the AAP conference.

After random review of medical records from 30 patients admitted to the hospital documented zero firearm screenings, Marjorie Farrington, MD, and Samantha Gunkelman, MD, from Akron Children’s Hospital in Ohio, implemented a program that they hope will increase firearm screenings during inpatient admissions to at least 50%.

They started their ongoing program in April 2020 by adding a social-history component to the history and physical (H&P) exam template and educating residents on how to screen and included guidance on safe firearm storage.

They also had physicians with firearm expertise give gun-safety lectures, and they plan to involve the Family Resource Center at their hospital in the creation of resources that can be incorporated into discharge instructions.

From April 2020 to June 2021, after the addition to the H&P template, 63% of the 5196 patients admitted to the hospital underwent a firearm screening. Of the 25% of patients who reported guns at home, 3% were not storing their firearms safely.

The pair used the “Store It Safe” Physician Handout provided by the Ohio chapter of the AAP.

Many pediatricians and pediatric trainees are not comfortable counseling on firearm safety, often a result of inadequate training on the topic.

The BulletPoints Project — developed by the Violence Prevention Research Program at the University of California, Davis — can also help physicians talk to patients about guns.

“Many pediatricians and pediatric trainees are not comfortable counseling on firearm safety, often a result of inadequate training on the topic,” Dr. Byrne said in an interview. “Additionally, it is a challenging topic that can often be met with resistance from patients and families. Lack of time during visits is also a huge barrier.”

Lack of training is an obstacle to greater firearm screenings, Dr. Greeley agreed, as are the feeling that guidance simply won’t make a difference and concerns about political pressure and divineness. The lack of research on firearm injuries and the impact of firearm screenings and anticipatory guidance is a challenge, he added, although that is starting to change.

Pediatricians need education on how to make a difference when it comes to firearm safety, and should follow AAP guidelines, Dr. Greeley said.

Counseling on firearm safety is in the same category as immunizations, seatbelts, substance use, helmets, and other public-health issues that are important to address at visits, regardless of how difficult it might be, Dr. Breuner told this news organization.

“It is our mission, as pediatricians, to provide every ounce of prevention in our well-child and anticipatory guidance visits,” she said. “It’s our job, so we shouldn’t shy away from it even though it’s hard.”

Doctors are more comfortable discussing firearm safety if they are firearm owners, previous research has shown, so she advises pediatricians who feel unqualified to discuss firearms to seek guidance from their peers on how to approach screenings and anticipatory guidance, she noted.

The firearm study being done in an academic center gives me great pause. The populations are often very different than private practice.

Both of these studies were conducted at single institutions and might not reflect what would work in private clinics.

“The firearm study being done in an academic center gives me great pause,” Dr. Greeley said. “The populations are often very different than private practice. I think that there is still a lot that remains unknown about decreasing household firearm injury and death.”

And the degree to which findings from these two gun-safety programs can be generalized to other academic centers or children’s hospitals is unclear.

“There are states where, I suspect, firearm screening is much more common. Some states have very pro-firearm cultures and others are anti-firearm,” Dr. Greeley said. “There are also likely differences within states,” particularly between urban and rural regions.

“Firearms are often a very personal issue for families, and pediatricians in ‘pro-firearm’ communities may have greater resistance to working on this,” he pointed out.

Nevertheless, Dr. Greeley said, “this is a promising strategy that could be part of a broad injury prevention initiative.”

Neither study noted any external funding. Dr. Byrne is a member of the Moms Demand Action Gainesville Chapter, which donated the firearm locks for the project. Dr. Breuner, Dr. Greeley, and Dr. Farrington have disclosed no relevant financial relationships.

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

When pediatricians and other pediatric providers are given training and resource materials, levels of firearm screenings and anticipatory guidance about firearm safety increase significantly, according to two new studies presented at the annual meeting of the American Academy of Pediatrics.

“With the rise in firearm sales and injuries during the COVID-19 pandemic, it is more important than ever that pediatricians address the firearm epidemic,” said Alexandra Byrne, MD, a pediatric resident at the University of Florida in Gainesville, who presented one of the studies.

There were 4.3 million more firearms purchased from March through July 2020 than expected, a recent study estimates, and 4,075 more firearm injuries than expected from April through July 2020.

In states with more excess purchases, firearm injuries related to domestic violence increased in April (rate ratio, 2.60; 95% CI, 1.32-5.93) and May (RR, 1.79; 95% CI, 1.19-2.91) 2020. However, excess gun purchases had no effect on rates of firearm violence outside the home.

In addition to the link between firearms in the home and domestic violence, they are also linked to a three- to fourfold greater risk for teen suicide, and both depression and suicidal thoughts have risen in teens during the pandemic.

“The data are pretty clear that if you have an unlocked, loaded weapon in your home, and you have a kid who’s depressed or anxious or dysregulated or doing maladaptive things for the pandemic, they’re much more likely to inadvertently take their own or someone else’s life by grabbing [a gun],” said Cora Breuner, MD, MPH, professor of pediatrics at Seattle Children’s Hospital.

However, there is no difference in gun ownership or gun-safety measures between homes with and without at-risk children, previous research shows.
 

Training, guidance, and locks

Previous research has also shown that there has been a reluctance by pediatricians to conduct firearm screenings and counsel parents about gun safety in the home.

For their two-step program, Dr. Byrne’s team used a plan-do-study-act approach. They started by providing training on firearm safety, evidence-based recommendations for firearm screening, and anticipatory guidance regarding safe firearm storage to members of the general pediatrics division at the University of Florida. And they supplied clinics with free firearm locks.

Next they supplied clinics with posters and educational cards from the Be SMART campaign, an initiative of the Everytown for Gun Safety Support Fund, which provides materials for anyone, including physicians, to use.

During their study, the researchers sent three anonymous six-question online surveys – at baseline and 3 to 4 months after each of the two steps – to pediatric residents, physician assistants, advanced practice registered nurses, and attendings to assess the project. There were 52 responses to the first survey, for a response rate of 58.4%, 42 responses to the second survey, for a response rate of 47.2%, and 23 responses to the third survey, for a rate of response 25.8%.

The program nearly doubled screenings during well-child visits and dramatically increased the proportion of families who received a firearm lock when they told providers they had a firearm at home.

Adding a social-history component

A program to increase firearm screening was also presented at the AAP conference.

After random review of medical records from 30 patients admitted to the hospital documented zero firearm screenings, Marjorie Farrington, MD, and Samantha Gunkelman, MD, from Akron Children’s Hospital in Ohio, implemented a program that they hope will increase firearm screenings during inpatient admissions to at least 50%.

They started their ongoing program in April 2020 by adding a social-history component to the history and physical (H&P) exam template and educating residents on how to screen and included guidance on safe firearm storage.

They also had physicians with firearm expertise give gun-safety lectures, and they plan to involve the Family Resource Center at their hospital in the creation of resources that can be incorporated into discharge instructions.

From April 2020 to June 2021, after the addition to the H&P template, 63% of the 5196 patients admitted to the hospital underwent a firearm screening. Of the 25% of patients who reported guns at home, 3% were not storing their firearms safely.

The pair used the “Store It Safe” Physician Handout provided by the Ohio chapter of the AAP.

Many pediatricians and pediatric trainees are not comfortable counseling on firearm safety, often a result of inadequate training on the topic.

The BulletPoints Project — developed by the Violence Prevention Research Program at the University of California, Davis — can also help physicians talk to patients about guns.

“Many pediatricians and pediatric trainees are not comfortable counseling on firearm safety, often a result of inadequate training on the topic,” Dr. Byrne said in an interview. “Additionally, it is a challenging topic that can often be met with resistance from patients and families. Lack of time during visits is also a huge barrier.”

Lack of training is an obstacle to greater firearm screenings, Dr. Greeley agreed, as are the feeling that guidance simply won’t make a difference and concerns about political pressure and divineness. The lack of research on firearm injuries and the impact of firearm screenings and anticipatory guidance is a challenge, he added, although that is starting to change.

Pediatricians need education on how to make a difference when it comes to firearm safety, and should follow AAP guidelines, Dr. Greeley said.

Counseling on firearm safety is in the same category as immunizations, seatbelts, substance use, helmets, and other public-health issues that are important to address at visits, regardless of how difficult it might be, Dr. Breuner told this news organization.

“It is our mission, as pediatricians, to provide every ounce of prevention in our well-child and anticipatory guidance visits,” she said. “It’s our job, so we shouldn’t shy away from it even though it’s hard.”

Doctors are more comfortable discussing firearm safety if they are firearm owners, previous research has shown, so she advises pediatricians who feel unqualified to discuss firearms to seek guidance from their peers on how to approach screenings and anticipatory guidance, she noted.

The firearm study being done in an academic center gives me great pause. The populations are often very different than private practice.

Both of these studies were conducted at single institutions and might not reflect what would work in private clinics.

“The firearm study being done in an academic center gives me great pause,” Dr. Greeley said. “The populations are often very different than private practice. I think that there is still a lot that remains unknown about decreasing household firearm injury and death.”

And the degree to which findings from these two gun-safety programs can be generalized to other academic centers or children’s hospitals is unclear.

“There are states where, I suspect, firearm screening is much more common. Some states have very pro-firearm cultures and others are anti-firearm,” Dr. Greeley said. “There are also likely differences within states,” particularly between urban and rural regions.

“Firearms are often a very personal issue for families, and pediatricians in ‘pro-firearm’ communities may have greater resistance to working on this,” he pointed out.

Nevertheless, Dr. Greeley said, “this is a promising strategy that could be part of a broad injury prevention initiative.”

Neither study noted any external funding. Dr. Byrne is a member of the Moms Demand Action Gainesville Chapter, which donated the firearm locks for the project. Dr. Breuner, Dr. Greeley, and Dr. Farrington have disclosed no relevant financial relationships.

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

When pediatricians and other pediatric providers are given training and resource materials, levels of firearm screenings and anticipatory guidance about firearm safety increase significantly, according to two new studies presented at the annual meeting of the American Academy of Pediatrics.

“With the rise in firearm sales and injuries during the COVID-19 pandemic, it is more important than ever that pediatricians address the firearm epidemic,” said Alexandra Byrne, MD, a pediatric resident at the University of Florida in Gainesville, who presented one of the studies.

There were 4.3 million more firearms purchased from March through July 2020 than expected, a recent study estimates, and 4,075 more firearm injuries than expected from April through July 2020.

In states with more excess purchases, firearm injuries related to domestic violence increased in April (rate ratio, 2.60; 95% CI, 1.32-5.93) and May (RR, 1.79; 95% CI, 1.19-2.91) 2020. However, excess gun purchases had no effect on rates of firearm violence outside the home.

In addition to the link between firearms in the home and domestic violence, they are also linked to a three- to fourfold greater risk for teen suicide, and both depression and suicidal thoughts have risen in teens during the pandemic.

“The data are pretty clear that if you have an unlocked, loaded weapon in your home, and you have a kid who’s depressed or anxious or dysregulated or doing maladaptive things for the pandemic, they’re much more likely to inadvertently take their own or someone else’s life by grabbing [a gun],” said Cora Breuner, MD, MPH, professor of pediatrics at Seattle Children’s Hospital.

However, there is no difference in gun ownership or gun-safety measures between homes with and without at-risk children, previous research shows.
 

Training, guidance, and locks

Previous research has also shown that there has been a reluctance by pediatricians to conduct firearm screenings and counsel parents about gun safety in the home.

For their two-step program, Dr. Byrne’s team used a plan-do-study-act approach. They started by providing training on firearm safety, evidence-based recommendations for firearm screening, and anticipatory guidance regarding safe firearm storage to members of the general pediatrics division at the University of Florida. And they supplied clinics with free firearm locks.

Next they supplied clinics with posters and educational cards from the Be SMART campaign, an initiative of the Everytown for Gun Safety Support Fund, which provides materials for anyone, including physicians, to use.

During their study, the researchers sent three anonymous six-question online surveys – at baseline and 3 to 4 months after each of the two steps – to pediatric residents, physician assistants, advanced practice registered nurses, and attendings to assess the project. There were 52 responses to the first survey, for a response rate of 58.4%, 42 responses to the second survey, for a response rate of 47.2%, and 23 responses to the third survey, for a rate of response 25.8%.

The program nearly doubled screenings during well-child visits and dramatically increased the proportion of families who received a firearm lock when they told providers they had a firearm at home.

Adding a social-history component

A program to increase firearm screening was also presented at the AAP conference.

After random review of medical records from 30 patients admitted to the hospital documented zero firearm screenings, Marjorie Farrington, MD, and Samantha Gunkelman, MD, from Akron Children’s Hospital in Ohio, implemented a program that they hope will increase firearm screenings during inpatient admissions to at least 50%.

They started their ongoing program in April 2020 by adding a social-history component to the history and physical (H&P) exam template and educating residents on how to screen and included guidance on safe firearm storage.

They also had physicians with firearm expertise give gun-safety lectures, and they plan to involve the Family Resource Center at their hospital in the creation of resources that can be incorporated into discharge instructions.

From April 2020 to June 2021, after the addition to the H&P template, 63% of the 5196 patients admitted to the hospital underwent a firearm screening. Of the 25% of patients who reported guns at home, 3% were not storing their firearms safely.

The pair used the “Store It Safe” Physician Handout provided by the Ohio chapter of the AAP.

Many pediatricians and pediatric trainees are not comfortable counseling on firearm safety, often a result of inadequate training on the topic.

The BulletPoints Project — developed by the Violence Prevention Research Program at the University of California, Davis — can also help physicians talk to patients about guns.

“Many pediatricians and pediatric trainees are not comfortable counseling on firearm safety, often a result of inadequate training on the topic,” Dr. Byrne said in an interview. “Additionally, it is a challenging topic that can often be met with resistance from patients and families. Lack of time during visits is also a huge barrier.”

Lack of training is an obstacle to greater firearm screenings, Dr. Greeley agreed, as are the feeling that guidance simply won’t make a difference and concerns about political pressure and divineness. The lack of research on firearm injuries and the impact of firearm screenings and anticipatory guidance is a challenge, he added, although that is starting to change.

Pediatricians need education on how to make a difference when it comes to firearm safety, and should follow AAP guidelines, Dr. Greeley said.

Counseling on firearm safety is in the same category as immunizations, seatbelts, substance use, helmets, and other public-health issues that are important to address at visits, regardless of how difficult it might be, Dr. Breuner told this news organization.

“It is our mission, as pediatricians, to provide every ounce of prevention in our well-child and anticipatory guidance visits,” she said. “It’s our job, so we shouldn’t shy away from it even though it’s hard.”

Doctors are more comfortable discussing firearm safety if they are firearm owners, previous research has shown, so she advises pediatricians who feel unqualified to discuss firearms to seek guidance from their peers on how to approach screenings and anticipatory guidance, she noted.

The firearm study being done in an academic center gives me great pause. The populations are often very different than private practice.

Both of these studies were conducted at single institutions and might not reflect what would work in private clinics.

“The firearm study being done in an academic center gives me great pause,” Dr. Greeley said. “The populations are often very different than private practice. I think that there is still a lot that remains unknown about decreasing household firearm injury and death.”

And the degree to which findings from these two gun-safety programs can be generalized to other academic centers or children’s hospitals is unclear.

“There are states where, I suspect, firearm screening is much more common. Some states have very pro-firearm cultures and others are anti-firearm,” Dr. Greeley said. “There are also likely differences within states,” particularly between urban and rural regions.

“Firearms are often a very personal issue for families, and pediatricians in ‘pro-firearm’ communities may have greater resistance to working on this,” he pointed out.

Nevertheless, Dr. Greeley said, “this is a promising strategy that could be part of a broad injury prevention initiative.”

Neither study noted any external funding. Dr. Byrne is a member of the Moms Demand Action Gainesville Chapter, which donated the firearm locks for the project. Dr. Breuner, Dr. Greeley, and Dr. Farrington have disclosed no relevant financial relationships.

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

Third-year medical student Liz Groesbeck was like other excited Las Vegas Raiders fans recently headed to the first full-capacity game in the new Allegiant Stadium since the team moved to “Sin City.” She was in an Uber on a first date just blocks from the game that would pit her Raiders against the Seattle Seahawks when she saw a man on the ground and people gathered around him.

Abandoning her keys, cellphone, and date in the Uber, Ms. Groesbeck popped out to see if she could help. The Uber had been stuck in traffic, so Ms. Groesbeck thought she’d still be able to jump back in the car if she wasn’t needed. 

Then she heard screams. “That didn’t concern me. People scream whenever anything unexpected happens,” said the 28-year-old student from the Kirk Kerkorian School of Medicine at the University of Nevada, Las Vegas (UNLV). But the screams were only a small indication of what she would discover on closer inspection. The arm of the middle-aged man lying on the ground was detached. An abandoned gold SUV remained on the curb nearby. It would turn out to be a hit-and-run of pedestrians by a driver later charged by police with DUI. 

“I was one of the first people there,” Ms. Groesbeck recounted for this news organization. “I knew this guy did not just fall. I told someone to call EMS and I got someone to take his wife somewhere else [away from the bloody scene]. She was obviously very distraught. …At a couple of points she was hysterical.” 

Next, Ms. Groesbeck, who, ironically, had finished her emergency general surgery rotation the day before, focused on the patient. Kneeling beside him, she determined that the immediate priorities were to stop the bleeding and clear his airway. “He was barely breathing,” she recounted. Another student who Ms. Groesbeck believes was pursuing a medical degree — there wasn’t time for formal introductions — offered to help, along with bystanders headed to the game. 

“The crowd was very energetic. It was a beautiful thing.” Ms. Groesbeck cited the spirit of saving lives that developed from the October 1, 2017, Las Vegas country music festival shooting. “People are very willing to try to help others in any way they can.” 

MS. Groesbeck, leading the effort, asked for belts, “and bystanders immediately provided that,” and the other student followed Ms. Groesbeck’s directions to apply tourniquets with the help of those around her. With the blood loss being stemmed, Ms. Groesbeck’s next priority was making sure the patient could breathe. 

Appealing for clothing to clear the man’s airway, “five shirts were handed in a circle to me.” She only needed one jersey to scoop the blood out of his mouth manually to free his airway. 

She overruled well-meaning suggestions to lay the man on his side — which she was concerned could paralyze him — or use a straw to help him breathe. “I did not want to stick anything down his throat.” Meanwhile, there was so much traffic that night around Allegiant Stadium that when the ambulance couldn’t get any closer the firefighters and paramedics exited the vehicle and ran to the scene. 
 

From training to practice

The decisions Ms. Groesbeck made until they could arrive called upon her years of training to be a doctor, and specifically an EMT certification course she had to pass before beginning medical school, she said.

She credits the life-saving methods she learned in that course to Douglas Fraser, MD, FACS, associate professor of surgery at UNLV and University Medical Center (UMC) trauma medical director. He happened to be the attending physician when the accident victim was admitted to the hospital that night in critical condition. The man’s wife also was injured, but not to the extent of her husband.

Dr. Fraser said he didn’t know at the time that his student had been involved in saving the man’s life until Ms. Groesbeck reached out to say thanks for teaching her what to do in an emergency. “I [first] was overly impressed that she did that. Students are so busy; they move after they graduate or finish their rotations. You don’t get to see them time and time again; your short time with them could have a lasting impact and that is my goal,” Dr. Fraser told this news organization.

“They rarely thank you or reflect back. It renewed my sense that I want to teach more, to see the positive impact it had on Elizabeth” and other students, he said.

In terms of the emergency situation she navigated, Dr. Fraser said he was very proud of his student, but was also concerned she could have gotten hurt herself in the middle of a busy intersection. “She was selfless and put herself in harm’s way to help someone.” He also noted it was the first time he knew of a student putting her skills to the test so soon after learning them. “It was a good outcome and she truly provided lifesaving care to this victim.”

He attributed her training to the Stop the Bleed program, which began after the Sandy Hook tragedy in 2012. UNLV requires new med students to complete the American College of Surgeons’ first aid program to learn how to stop the bleeding of a severely injured person by applying tourniquets and pressure. “You have to stop the bleeding right away…and look to see whether their airway is open and if it’s not, open their airway or you won’t have a patient very long. I know she did that. These are the two most important lifesaving skills that she did.” 

Medical students are often called upon as doctors by their family and friends, Dr. Fraser continued. “Everyone looks to you. It can happen on an airplane; you can be anywhere. She heard a person was in need and jumped to action and was able to use the training her school provided and was able to put it to good use.” 
 

Not her first call to action

Just the week before the incident, Ms. Groesbeck was on clinical rotations at UMC helping in the emergency and operating rooms. “She was always very engaged and mature beyond her years,” Dr. Fraser said. “She definitely had that ‘it’ factor. She was sincere with patients and their families and performed well in the operating room. …She was very comfortable around the patients; very comfortable in stressful situations.” 

He added, “I look forward to her participating in trauma surgery rotations in the near future.”

In the meantime, Ms. Groesbeck was pleased to learn that the man she saved survived and thrilled to be part of that effort. As of press time, he had not contacted her. Nor has the other student who helped save his life. 

“A lot of people stepped up and donated their time to help. He got lucky on a very unlucky day,” Ms. Groesbeck said.

She recalled a previous accident victim years ago who wasn’t as lucky. On the way to pick up her white coat for the ceremony before her first year of medical school, she came upon a car that had flipped upside down. “It sheared the roof away. I checked on the restrained passenger. He was partially scalped. The windows were broken and I climbed in next to him.” This time, she used her own shirt to hold pressure on the wound. “He, unfortunately did not make it.” There was nothing she could have done, she was told. 

“That one got me mentally. Very graphic imaging was stuck in my head,” Ms. Groesbeck said. With a masters in neuroscience, she was accustomed to seeing the brain, “but not like this. I felt sad he passed in such a violent way.” So the more recent life-saving experience was redemptive, she said. “I’ve been through hell and back.”

And she’s still on track to become the doctor she envisioned as a child, mummifying her cats with gauze wraps and covering her little sister with adhesive bandages. “It felt good knowing what I could do,” Ms. Groesbeck said. “I’m glad this [man] made it. He got lucky and he could go home to his family. I was not positive when he left in the ambulance. It was a huge relief.” 

Of her role in the episode and her future career ambitions, Ms. Groesbeck noted: “We are studying all the time. It’s not very rewarding. But this, not thinking but having sprung into action, doing the right thing and he could go home to his family a week later. It’s things like this that make the endless hours of studying worth it. I feel like I accomplished something.”

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

Third-year medical student Liz Groesbeck was like other excited Las Vegas Raiders fans recently headed to the first full-capacity game in the new Allegiant Stadium since the team moved to “Sin City.” She was in an Uber on a first date just blocks from the game that would pit her Raiders against the Seattle Seahawks when she saw a man on the ground and people gathered around him.

Abandoning her keys, cellphone, and date in the Uber, Ms. Groesbeck popped out to see if she could help. The Uber had been stuck in traffic, so Ms. Groesbeck thought she’d still be able to jump back in the car if she wasn’t needed. 

Then she heard screams. “That didn’t concern me. People scream whenever anything unexpected happens,” said the 28-year-old student from the Kirk Kerkorian School of Medicine at the University of Nevada, Las Vegas (UNLV). But the screams were only a small indication of what she would discover on closer inspection. The arm of the middle-aged man lying on the ground was detached. An abandoned gold SUV remained on the curb nearby. It would turn out to be a hit-and-run of pedestrians by a driver later charged by police with DUI. 

“I was one of the first people there,” Ms. Groesbeck recounted for this news organization. “I knew this guy did not just fall. I told someone to call EMS and I got someone to take his wife somewhere else [away from the bloody scene]. She was obviously very distraught. …At a couple of points she was hysterical.” 

Next, Ms. Groesbeck, who, ironically, had finished her emergency general surgery rotation the day before, focused on the patient. Kneeling beside him, she determined that the immediate priorities were to stop the bleeding and clear his airway. “He was barely breathing,” she recounted. Another student who Ms. Groesbeck believes was pursuing a medical degree — there wasn’t time for formal introductions — offered to help, along with bystanders headed to the game. 

“The crowd was very energetic. It was a beautiful thing.” Ms. Groesbeck cited the spirit of saving lives that developed from the October 1, 2017, Las Vegas country music festival shooting. “People are very willing to try to help others in any way they can.” 

MS. Groesbeck, leading the effort, asked for belts, “and bystanders immediately provided that,” and the other student followed Ms. Groesbeck’s directions to apply tourniquets with the help of those around her. With the blood loss being stemmed, Ms. Groesbeck’s next priority was making sure the patient could breathe. 

Appealing for clothing to clear the man’s airway, “five shirts were handed in a circle to me.” She only needed one jersey to scoop the blood out of his mouth manually to free his airway. 

She overruled well-meaning suggestions to lay the man on his side — which she was concerned could paralyze him — or use a straw to help him breathe. “I did not want to stick anything down his throat.” Meanwhile, there was so much traffic that night around Allegiant Stadium that when the ambulance couldn’t get any closer the firefighters and paramedics exited the vehicle and ran to the scene. 
 

From training to practice

The decisions Ms. Groesbeck made until they could arrive called upon her years of training to be a doctor, and specifically an EMT certification course she had to pass before beginning medical school, she said.

She credits the life-saving methods she learned in that course to Douglas Fraser, MD, FACS, associate professor of surgery at UNLV and University Medical Center (UMC) trauma medical director. He happened to be the attending physician when the accident victim was admitted to the hospital that night in critical condition. The man’s wife also was injured, but not to the extent of her husband.

Dr. Fraser said he didn’t know at the time that his student had been involved in saving the man’s life until Ms. Groesbeck reached out to say thanks for teaching her what to do in an emergency. “I [first] was overly impressed that she did that. Students are so busy; they move after they graduate or finish their rotations. You don’t get to see them time and time again; your short time with them could have a lasting impact and that is my goal,” Dr. Fraser told this news organization.

“They rarely thank you or reflect back. It renewed my sense that I want to teach more, to see the positive impact it had on Elizabeth” and other students, he said.

In terms of the emergency situation she navigated, Dr. Fraser said he was very proud of his student, but was also concerned she could have gotten hurt herself in the middle of a busy intersection. “She was selfless and put herself in harm’s way to help someone.” He also noted it was the first time he knew of a student putting her skills to the test so soon after learning them. “It was a good outcome and she truly provided lifesaving care to this victim.”

He attributed her training to the Stop the Bleed program, which began after the Sandy Hook tragedy in 2012. UNLV requires new med students to complete the American College of Surgeons’ first aid program to learn how to stop the bleeding of a severely injured person by applying tourniquets and pressure. “You have to stop the bleeding right away…and look to see whether their airway is open and if it’s not, open their airway or you won’t have a patient very long. I know she did that. These are the two most important lifesaving skills that she did.” 

Medical students are often called upon as doctors by their family and friends, Dr. Fraser continued. “Everyone looks to you. It can happen on an airplane; you can be anywhere. She heard a person was in need and jumped to action and was able to use the training her school provided and was able to put it to good use.” 
 

Not her first call to action

Just the week before the incident, Ms. Groesbeck was on clinical rotations at UMC helping in the emergency and operating rooms. “She was always very engaged and mature beyond her years,” Dr. Fraser said. “She definitely had that ‘it’ factor. She was sincere with patients and their families and performed well in the operating room. …She was very comfortable around the patients; very comfortable in stressful situations.” 

He added, “I look forward to her participating in trauma surgery rotations in the near future.”

In the meantime, Ms. Groesbeck was pleased to learn that the man she saved survived and thrilled to be part of that effort. As of press time, he had not contacted her. Nor has the other student who helped save his life. 

“A lot of people stepped up and donated their time to help. He got lucky on a very unlucky day,” Ms. Groesbeck said.

She recalled a previous accident victim years ago who wasn’t as lucky. On the way to pick up her white coat for the ceremony before her first year of medical school, she came upon a car that had flipped upside down. “It sheared the roof away. I checked on the restrained passenger. He was partially scalped. The windows were broken and I climbed in next to him.” This time, she used her own shirt to hold pressure on the wound. “He, unfortunately did not make it.” There was nothing she could have done, she was told. 

“That one got me mentally. Very graphic imaging was stuck in my head,” Ms. Groesbeck said. With a masters in neuroscience, she was accustomed to seeing the brain, “but not like this. I felt sad he passed in such a violent way.” So the more recent life-saving experience was redemptive, she said. “I’ve been through hell and back.”

And she’s still on track to become the doctor she envisioned as a child, mummifying her cats with gauze wraps and covering her little sister with adhesive bandages. “It felt good knowing what I could do,” Ms. Groesbeck said. “I’m glad this [man] made it. He got lucky and he could go home to his family. I was not positive when he left in the ambulance. It was a huge relief.” 

Of her role in the episode and her future career ambitions, Ms. Groesbeck noted: “We are studying all the time. It’s not very rewarding. But this, not thinking but having sprung into action, doing the right thing and he could go home to his family a week later. It’s things like this that make the endless hours of studying worth it. I feel like I accomplished something.”

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

Third-year medical student Liz Groesbeck was like other excited Las Vegas Raiders fans recently headed to the first full-capacity game in the new Allegiant Stadium since the team moved to “Sin City.” She was in an Uber on a first date just blocks from the game that would pit her Raiders against the Seattle Seahawks when she saw a man on the ground and people gathered around him.

Abandoning her keys, cellphone, and date in the Uber, Ms. Groesbeck popped out to see if she could help. The Uber had been stuck in traffic, so Ms. Groesbeck thought she’d still be able to jump back in the car if she wasn’t needed. 

Then she heard screams. “That didn’t concern me. People scream whenever anything unexpected happens,” said the 28-year-old student from the Kirk Kerkorian School of Medicine at the University of Nevada, Las Vegas (UNLV). But the screams were only a small indication of what she would discover on closer inspection. The arm of the middle-aged man lying on the ground was detached. An abandoned gold SUV remained on the curb nearby. It would turn out to be a hit-and-run of pedestrians by a driver later charged by police with DUI. 

“I was one of the first people there,” Ms. Groesbeck recounted for this news organization. “I knew this guy did not just fall. I told someone to call EMS and I got someone to take his wife somewhere else [away from the bloody scene]. She was obviously very distraught. …At a couple of points she was hysterical.” 

Next, Ms. Groesbeck, who, ironically, had finished her emergency general surgery rotation the day before, focused on the patient. Kneeling beside him, she determined that the immediate priorities were to stop the bleeding and clear his airway. “He was barely breathing,” she recounted. Another student who Ms. Groesbeck believes was pursuing a medical degree — there wasn’t time for formal introductions — offered to help, along with bystanders headed to the game. 

“The crowd was very energetic. It was a beautiful thing.” Ms. Groesbeck cited the spirit of saving lives that developed from the October 1, 2017, Las Vegas country music festival shooting. “People are very willing to try to help others in any way they can.” 

MS. Groesbeck, leading the effort, asked for belts, “and bystanders immediately provided that,” and the other student followed Ms. Groesbeck’s directions to apply tourniquets with the help of those around her. With the blood loss being stemmed, Ms. Groesbeck’s next priority was making sure the patient could breathe. 

Appealing for clothing to clear the man’s airway, “five shirts were handed in a circle to me.” She only needed one jersey to scoop the blood out of his mouth manually to free his airway. 

She overruled well-meaning suggestions to lay the man on his side — which she was concerned could paralyze him — or use a straw to help him breathe. “I did not want to stick anything down his throat.” Meanwhile, there was so much traffic that night around Allegiant Stadium that when the ambulance couldn’t get any closer the firefighters and paramedics exited the vehicle and ran to the scene. 
 

From training to practice

The decisions Ms. Groesbeck made until they could arrive called upon her years of training to be a doctor, and specifically an EMT certification course she had to pass before beginning medical school, she said.

She credits the life-saving methods she learned in that course to Douglas Fraser, MD, FACS, associate professor of surgery at UNLV and University Medical Center (UMC) trauma medical director. He happened to be the attending physician when the accident victim was admitted to the hospital that night in critical condition. The man’s wife also was injured, but not to the extent of her husband.

Dr. Fraser said he didn’t know at the time that his student had been involved in saving the man’s life until Ms. Groesbeck reached out to say thanks for teaching her what to do in an emergency. “I [first] was overly impressed that she did that. Students are so busy; they move after they graduate or finish their rotations. You don’t get to see them time and time again; your short time with them could have a lasting impact and that is my goal,” Dr. Fraser told this news organization.

“They rarely thank you or reflect back. It renewed my sense that I want to teach more, to see the positive impact it had on Elizabeth” and other students, he said.

In terms of the emergency situation she navigated, Dr. Fraser said he was very proud of his student, but was also concerned she could have gotten hurt herself in the middle of a busy intersection. “She was selfless and put herself in harm’s way to help someone.” He also noted it was the first time he knew of a student putting her skills to the test so soon after learning them. “It was a good outcome and she truly provided lifesaving care to this victim.”

He attributed her training to the Stop the Bleed program, which began after the Sandy Hook tragedy in 2012. UNLV requires new med students to complete the American College of Surgeons’ first aid program to learn how to stop the bleeding of a severely injured person by applying tourniquets and pressure. “You have to stop the bleeding right away…and look to see whether their airway is open and if it’s not, open their airway or you won’t have a patient very long. I know she did that. These are the two most important lifesaving skills that she did.” 

Medical students are often called upon as doctors by their family and friends, Dr. Fraser continued. “Everyone looks to you. It can happen on an airplane; you can be anywhere. She heard a person was in need and jumped to action and was able to use the training her school provided and was able to put it to good use.” 
 

Not her first call to action

Just the week before the incident, Ms. Groesbeck was on clinical rotations at UMC helping in the emergency and operating rooms. “She was always very engaged and mature beyond her years,” Dr. Fraser said. “She definitely had that ‘it’ factor. She was sincere with patients and their families and performed well in the operating room. …She was very comfortable around the patients; very comfortable in stressful situations.” 

He added, “I look forward to her participating in trauma surgery rotations in the near future.”

In the meantime, Ms. Groesbeck was pleased to learn that the man she saved survived and thrilled to be part of that effort. As of press time, he had not contacted her. Nor has the other student who helped save his life. 

“A lot of people stepped up and donated their time to help. He got lucky on a very unlucky day,” Ms. Groesbeck said.

She recalled a previous accident victim years ago who wasn’t as lucky. On the way to pick up her white coat for the ceremony before her first year of medical school, she came upon a car that had flipped upside down. “It sheared the roof away. I checked on the restrained passenger. He was partially scalped. The windows were broken and I climbed in next to him.” This time, she used her own shirt to hold pressure on the wound. “He, unfortunately did not make it.” There was nothing she could have done, she was told. 

“That one got me mentally. Very graphic imaging was stuck in my head,” Ms. Groesbeck said. With a masters in neuroscience, she was accustomed to seeing the brain, “but not like this. I felt sad he passed in such a violent way.” So the more recent life-saving experience was redemptive, she said. “I’ve been through hell and back.”

And she’s still on track to become the doctor she envisioned as a child, mummifying her cats with gauze wraps and covering her little sister with adhesive bandages. “It felt good knowing what I could do,” Ms. Groesbeck said. “I’m glad this [man] made it. He got lucky and he could go home to his family. I was not positive when he left in the ambulance. It was a huge relief.” 

Of her role in the episode and her future career ambitions, Ms. Groesbeck noted: “We are studying all the time. It’s not very rewarding. But this, not thinking but having sprung into action, doing the right thing and he could go home to his family a week later. It’s things like this that make the endless hours of studying worth it. I feel like I accomplished something.”

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