Routine
hits playing football cause damage to the brain
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.
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 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."
"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.
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."
