Retrospective study reveals that younger brains take longer to heal

September 15, 2020

Science Daily/Henry Ford Health System

A recent study from the Henry Ford Sports Medicine Research team suggests that high school athletes competing, not only in football, but in soccer, hockey, basketball, swimming, cheerleading and other sports are not only at risk for concussions, but may need a longer recovery than first thought.

The study's results published by Orthopedics, a nationally recognized, peer-reviewed journal for orthopedic surgeons found that the most common sports for brain injuries were indeed football, hockey and soccer.

"We thought that concussion issues would be very short-lived," said Vasilios (Bill) Moutzouros, M.D., chief of Sports Medicine at Henry Ford and a study co-author, "That they wouldn't have as many attention issues, that they'd be able to recover for their sport much more quickly. Our study found just the opposite."

"The two sports, other than football, where concussions are common are soccer and hockey, although brain injuries can happen in any sport," said Meaghan Rourke, one of more than 30 Henry Ford athletic trainers who support sports programs at over 20 high schools, colleges and universities and professional teams in the tri-county area.

Michigan Gov. Gretchen Whitmer's latest executive order allows the high school football season to begin September 18. Football was reinstated by the Michigan High School Athletic Association (MHSAA) after initially being postponed until spring 2021. With football back in action with an adjusted six-game season, athletic trainers will once again be patrolling the sidelines and be on the lookout for signs of concussions. Other sports given the green light to compete this fall include soccer, volleyball, swimming and diving. These competitions will also present the potential for brain injuries from collisions, falls and impacts with the field of play.

"I went through a four-year period as an athletic trainer where I had at least one swimmer suffer a concussion. That's a sport you don't really think about in terms of concussions," said Rourke. She explained that in one instance a swimmer miscalculated her distance to the pool wall while doing the backstroke and bumped her head against the wall. As a result, the swimmer was out for more than a month with a concussion. Diving is another sport susceptible to brain injuries as the divers' heads impact the surface of the water at high speeds generated from their dives. In reality, all sports have the potential for concussions since athletics involve physical activity and competition.

"Competitive cheerleading is another sport where I've seen concussions happen. The kids get very high in the air, and if they slip and fall when they are coming down, they can suffer serious head injuries," said Rourke, "We usually have one or two athletes in that sport suffer concussions. Overall, I've probably had to deal with a concussion in every sport, including golf."

The retrospective study looked at Immediate Post-Concussion Assessment and Cognitive Testing (ImPACT) scores at baseline testing and following concussions performed by neuropsychologists. The study found that memory ImPACT scores increased as players suffered repeated concussions.

ImPACT is the brain injury testing protocol developed in the late 1990s at the University of Pittsburgh and released in the early 2000s. The testing protocol is the only FDA-approved tool for concussion assessment and is the national testing used by healthcare, educational and sports organizations to help assess and manage concussions. The protocol defines a concussion as "a disturbance in brain function that occurs following either a blow to the head or as a result of the violent shaking of the head." Symptoms of a concussion can include a combination of headaches, nausea, vomiting, balance problems, dizziness, fatigue, visual problems and a host of other brain-associated symptoms.

The study examined the records of 357 high school athletes who were treated for concussions at Henry Ford from 2013 to 2016. The athletes age averaged between 14-18 with nearly 62% being males. Football yielded the most concussions (27.7%), followed by hockey (21.8%), soccer (17%), basketball (9 %) and cheerleading (4.2%). From the study's participants, 72 played in "Other" sports and accounted for 20.3% of the total number of concussions. Overall, 14 % reported suffering from amnesia and 33 % reported a history of concussions.

Henry Ford athletic trainers use internationally approved guidelines to accurately diagnose concussions, appropriately manage the recovery process, and safely return athletes back to their game. They use sideline tools such as the Sports Concussion Assessment Tool 5 (SCAT5) to immediately evaluate cognitive function and, if needed, additional neuropsychological tests may be administered by a physician to track progression through the recovery process. SCAT5 is a standardized concussion assessment used by licensed healthcare providers when a concussion is suspected in athletes ages 12 and older.

Current MHSAA protocols call for a player showing concussion symptoms to be sidelined for at least 24 hours. Athletes at high schools staffed with a Henry Ford athletic trainer are sidelined for at least five days and follow a strict return to play protocol, "We're going to slowly bring them back," said Rourke. "We don't want to just throw them out there where they're going to get hit again, and then they're dealing with prolonged symptoms."

The Henry Ford research team found that athletes with only one concussion required at least 30 days of recovery prior to returning to their sport while others who reported a second or more concussions required more recovery time. They also learned that visual motor speed and reaction time scores decreased with recurrent concussions, and that male and female athletes with a previous history of concussion, and those with delayed diagnosis, required more time before returning to competition.

The study team hopes that the results help start the conversation on how to more safely return student athletes to their sport after a brain injury. "When you recognize that it can be up to 30 days to get a young student athlete back, you're going to change your mind-set on how you advance them, in terms of how you push them, in terms of how you test them," said Dr. Moutzouros.

Previously, it was believed that brain injuries were related to a player's age. The younger the player, the shorter the recovery time. "We need more studies on the younger athletes," said Dr. Moutzouros, "Many of us have children. We're all worried about them and we want them to be safe. So, we need to recognize that this is a problem for the youth athlete."

https://www.sciencedaily.com/releases/2020/09/200915110014.htm

July 22, 2020

Science Daily/University of Texas Health Science Center at Houston

Concussions can have a compounding effect on children, leading to long-term cognitive, behavioral, and emotional health consequences, according to researchers at The University of Texas Health Science Center at Houston (UTHealth), who published their findings in the American Journal of Sports Medicine.

In 2017, approximately 2.5 million high school students in the United States reported suffering at least one concussion related to sports or physical activity in the last 12 months, according to information from the U.S. Centers for Disease Control and Prevention (CDC).

The UTHealth researchers analyzed survey data from more than 13,000 high school students in the United States. According to the authors, it is the first study to report on the association between sports-related concussions and negative health implications based on a representative sample of U.S. high school students.

"We have previously speculated that children who suffer a concussion have more behavioral problems, so this study was able to provide a more comprehensive analysis on the various cognitive and behavioral health issues that this population faces in connection with this type of brain injury," said Gregory Knell, PhD, the study's first and corresponding author. Knell is an assistant professor at UTHealth School of Public Health in Dallas and is research faculty at Children's Health Andrews Institute for Orthopaedics and Sports Medicine.

A concussion is the most common form of traumatic brain injury, caused by a mild blow to the head. Common symptoms include a headache, ringing in the ears, nausea, vomiting, fatigue, drowsiness, and blurry vision.

Participants were asked how many times they had suffered a concussion from playing a sport or during physical activity in the last 12 months. Students were also surveyed on relevant cognitive, emotional, and behavioral factors and related health outcomes, including questions on topics such as academics, suicidal ideation, and substance abuse.

The study revealed that 14.5% of female high school athletes and 18.1% of male high school athletes reported experiencing at least one concussion the previous year. These students also reported at least one factor associated to their behavioral, cognitive, and emotional health. The questions covered topics such as difficulty concentrating, poor grades, drinking and driving, carrying a weapon, getting into a physical altercation, using tobacco or marijuana, binge drinking, feeling depressed, and having suicidal thoughts or actions.

Of the male participants who suffered at least one concussion, 33.8% reported they drank and drove in the last 30 days. For the female athletes who reported suffering more than one concussion, 19% stated they had used marijuana at least once in the last 30 days. Both male and female participants who answered that they had been in at least one physical fight in the last year were significantly more likely to have reported having at least one concussion in that same timeframe.

Other associated factors that were significantly more likely in male students who reported a prior concussion included difficulty concentrating, tobacco/e-cigarette use, and binge drinking. Female students who reported prior concussions were more likely to ride in a car with a driver who had been drinking, and have suicidal thoughts or actions.

"Parents need to understand that a concussion is a very serious brain injury, one which requires treatment every time a concussion is sustained. This study has revealed this type of traumatic brain injury can have a compounding effect on children that could lead to more aggressive behavior, academic problems, and social issues," said study co-author Scott Burkhart, PsyD, a neuropsychologist at Children's Health Andrews Institute for Orthopaedics and Sports Medicine.

The research team encourages future studies to continue the surveillance on the prevalence of concussions among student athletes, as well as the severity of these injuries.

https://www.sciencedaily.com/releases/2020/07/200722163225.htm

Traumatic brain injury with no symptoms can cause wear and tear over time

August 26, 2019

Science Daily/Orlando Health

In one of the largest studies of its kind, researchers at Orlando Health are making new progress in finding ways to detect a traumatic yet sinister brain injury -- and getting closer to preventing further damage.

Subconcussive injuries often show no symptoms or immediate effects, but can cause wear and tear on the brain over time with repeated injuries. The latest study, published in the journal BMJ Paediatrics Open, includes more than 700 emergency room patients -- children and adults. The study gets us closer to developing a standard blood test to spot these injuries as early as possible.

"A unique feature of this study is that it includes patients who hit their heads but have no symptoms," said Linda Papa, MD, lead author of the study and emergency medicine doctor at Orlando Health. "This group is rarely -- if ever -- included in biomarker studies."

The blood test looks for two proteins (GFAP and UCH-L1) found in our brains and released into blood after an injury -- higher levels of which could indicate a concussion or subconcussive injury. Dr. Papa has been studying these biomarkers for more than a decade. Some of her previous studies have focused on athletes, but now she's expanding her research on subconcussive injuries to the general population and all age groups.

Historically, people who suffer head trauma without concussion symptoms may have been classified as having "no injury." Plus, there are very few studies addressing the impact of subconcussive injuries following head trauma in the civilian population, as opposed to military members or athletes.

"It is estimated that up to 3.8 million concussions occur in the U.S. annually from organized and recreational sports -- and there are more than 2 million ER visits for traumatic brain injuries and concussions," said Papa. "It is a significant health problem in both athletes and non-athletes."

The study looked at patients with concussions, those with head trauma without overt signs of concussion and those with body trauma without head trauma or concussion. Elevated levels of both biomarkers were found in patients with nonconcussive head trauma, potentially signaling a subconcussive brain injury.

Furthermore, this blood test goes even deeper than a routine CT scan. Previous studies using the two biomarkers have focused on detecting brain lesions, but subconcussive injuries don't necessarily result in lesions -- and even the vast majority of patients with concussions tend to have a normal CT scan.

"The study includes an array of patients with different injury mechanisms, including car crashes, falls and bicycle accidents in addition to recreational and sports injuries," said Papa. "It is not limited to just one group of injury types."

A number of companies are now working on developing a bench-top device for the hospital lab -- along with a point-of-care handheld device that can be used to detect subconcussive injuries in a variety of settings -- including sporting events, in the ambulance, at the scene of car crashes, in military settings or even after a simple bump to the head.

"The technology is only a year or two away," said Papa.

https://www.sciencedaily.com/releases/2019/08/190826092315.htm

August 7, 2019

Science Daily/Carnegie Mellon University

New research led by Carnegie Mellon University and the University of Rochester Medical Center indicates that concussions aren't the sole cause of damage to the brain in contact sports. A study of college football players found that typical hits sustained from playing just one season cause structural changes to the brain.

The researchers studied 38 University of Rochester players, putting accelerometers -- devices that measures accelerative force -- in their helmets for every practice and game. The players' brains were scanned in an MRI machine before and after a season of play.

While only two players suffered clinically diagnosed concussions during the time they were followed in the study, the comparison of the post- and pre-season MRIs showed greater than two-thirds of the players experienced a decrease in the structural integrity of their brain. Specifically, the researchers found reduced white matter integrity in the midbrain after the season compared to before the season. Furthermore, and indicating the injury was specifically related to playing football, the researchers found the amount of white matter damage was correlated with the number of hits to the head players sustained.

The study is published in the journal Science Advances.

 "Public perception is that the big hits are the only ones that matter. It's what people talk about and what we often see being replayed on TV," said senior study author Brad Mahon, an associate professor of psychology at Carnegie Mellon and scientific director of the Program for Translational Brain Mapping at the University of Rochester. "The big hits are definitely bad, but with the focus on the big hits, the public is missing what's likely causing the long-term damage in players' brains. It's not just the concussions. It's everyday hits, too."

The midbrain, located in the center of the head and just beneath the cerebral cortex, is part of a larger stalk-like rigid structure that includes the brain stem and the thalamus. The relative rigidity of the midbrain means it absorbs forces differently than surrounding softer tissues, making it biomechanically susceptible to the forces caused by head hits. The midbrain supports functions like eye movements, which are impacted by concussions and hits to the head. While head hits are known to affect many parts of the brain simultaneously, the researchers decided to focus the study on the midbrain, hypothesizing that this structure would be the "canary in the coal mine" for sub-concussive hits.

"We hypothesized and found that the midbrain is a key structure that can serve as an index of injury in both clinically defined concussions and repetitive head hits," said Adnan Hirad, an M.D./Ph.D. candidate at the University of Rochester's Medical Scientist Training Program and lead author of the study. "What we cataloged in our study are things that can't be observed simply by looking at or behaviorally testing a player, on or off the field. These are 'clinically silent' brain injuries."

Each player in the study received an MRI scan within two weeks of the start of each season and within one week at the end. The helmet accelerometers measured linear and rotational acceleration during all practices and games, recording all contact that produced forces of 10 gs or greater. Astronauts on the space shuttle experienced 3 gs during lift-off. Race car drivers feel the effects of 6 gs, and car crashes can produce brief forces of more than 100 gs.

The 38 NCAA Division III players experienced nearly 20,000 hits across all practices and games. Of those hits, the median force was around 25 gs, with half of the hits exceeding that amount. Only two of the nearly 20,000 hits resulted in concussions.

"We measured the linear acceleration, rotational acceleration and direction of impact of every hit the players sustained. This allowed us to create a three-dimensional map of all of the forces their brains sustained," Hirad said.

The MRI scans measured structural changes in the brain that took place over the course of each season. They found that rotational acceleration (impact causing the head to twist) more so than linear acceleration (head-on impact) is correlated with the observed changes in the structural integrity of white matter in the midbrain.

"This study suggests that midbrain imaging using diffusion MRI might be a way in the future to diagnose injury from a single concussive head hit and/or from repetitive sub-concussive head hits," said Dr. Jeffrey Bazarian, professor of Emergency Medicine, Neurology, Neurosurgery and Public Health Sciences at the University of Rochester Medical Center and a co-author of the study.

The second part of the study served as an independent means to validate the researchers' approach to the football cohort. This group included 29 athletes from various other contact sports who had a clinically defined concussion and 58 who didn't.

The concussed participants underwent MRI scans and offered blood samples within 72 hours of injury. Like the football cohort, those players exhibited reduced structural integrity in the midbrain. In addition, they exhibited increased tau, a protein, in their blood. As structural integrity in the brain decreases, tau increases.

"Tau is an important marker of acute changes in the brain and is thought to be, in the long term, implicated in neurodegenerative diseases like chronic traumatic encephalopathy, also known as CTE," Hirad said.

Given this new insight on repetitive head hits, what should we do?

"Our research, in the context of prior research over the past several years, is beginning to indicate that the accumulation of many sub-concussive hits is instrumental in driving long-term damage in football players' brains," Mahon said. "Future research will be required in order to translate our findings into concrete directives that are relevant to public health. An important direction for future research will be to carry out larger-scale longitudinal studies of contact sports athletes in various ages groups."

"We also need to re-evaluate how we make return-to-play decisions," Hirad said. "Right now, those decisions are made based on whether or not a player is exhibiting symptoms of a concussion like dizziness or loss of consciousness. Even without a concussion, the hits players are taking in practice and games appear to cause brain damage over time."

https://www.sciencedaily.com/releases/2019/08/190807142249.htm