Female college rugby players may have subtle brain changes even if they haven’t had a recent concussion, according a study published in Neurology, the medical journal of the American Academy of Neurology.
“There’s no longer a debate that when an athlete is diagnosed with a concussion caused by a sharp blow or a fall, there is a chance it may contribute to brain changes that could either be temporary or permanent,” says study author Ravi S. Menon, PhD, FRSC, of Western University in London, Canada.
“But what are the effects of the smaller jolts and impacts that come with playing a contact sport? Our study found they may lead to subtle changes in the brains of otherwise healthy, symptom-free athletes.”
The study compared rugby players to other female college athletes competing in the non-contact sports of swimming and rowing. It included 101 female college athletes, including 70 who played rugby and 31 who participated in either rowing or swimming. A subset of rugby players were followed for at least 2 years. Swimmers and rowers were followed for 1 year.
All athletes were concussion-free 6 months prior to the start of the study and during the study as well. However, some rugby players had a concussion history before the 6-month period while non-contact athletes had experienced none.
Some of the athletes wore devices to record head impacts, including 37 rugby players and nine rowers. Measurements from the devices found that while rowers did not experience any impacts, 70% of the rugby players experienced an average of three impacts during two practices and one pre-season game, a media release from the American Academy of Neurology explains.
MRI Reveals Concussion Signatures in Brains of Rugby Players
Concussion-Like Brain Changes Evident from a Regular Season of Rugby Play
“While we only looked at these impacts during a few events during the season, previous research has shown these kinds of subclinical impacts may accumulate over years of participation in contact sports,” Menon says.
Researchers used magnetic resonance imaging (MRI) to scan the brains of all the athletes during in- and off-season play. With the brain scans, researchers examined how water molecules moved throughout the white matter to determine if there were microstructural brain changes. They also investigated how different areas of the brain communicated with each other and whether there were any changes in how those areas worked together.
In rugby players, researchers found changes in the microstructure of the white matter, including in nerve fibers that connect areas of the brain that control basic emotions like fear, pleasure and anger. In some of the rugby players, the changes progressed over time. Researchers did not find changes in the brains of swimmers or rowers.
Researchers also found that for rugby players only, the microstructure of the brain changed between in- and off-seasons, specifically in the brain stem, which controls the flow of messages between the brain and body.
Differences were found in the functional organization of the brain too. When compared to swimmers and rowers, rugby players had changes in connectivity–how the brain communicates–between the areas of the brain that control memory retrieval and visual processing, the release continues.
“Even with no concussions, the repetitive impacts experienced by the rugby players clearly had effects on the brain,” Menon adds. “More research is needed to understand what these changes may mean and to what extent they reflect how the brain compensates for the injuries, repairs itself or degenerates so we can better understand the long-term health effects of playing a contact sport.”
A limitation of the study was that while the rugby athletes did not experience a diagnosed concussion, there may have been undiagnosed concussions that went unnoticed by the coaching staff or undetected by relatively insensitive clinical tools.
[Source(s): American Academy of Neurology, EurekAlert]