News Release

High-resolution brain imaging could improve detection of concussions

New machine learning approach uses brain scans to accurately detect mild traumatic brain injury

Peer-Reviewed Publication


High-Resolution Brain Imaging Could Improve Detection of Concussions

image: High-resolution brain imaging could improve detection of concussions. view more 

Credit: Vakorin et al.

High-resolution brain scans analyzed by machine learning algorithms could determine whether a patient has a concussion, according to a new study published in PLOS Computational Biology.

Currently, doctors diagnose concussions according to patient-reported symptoms, which can be challenging and inefficient. Previous studies have used high-resolution imaging to show that concussions cause changes in communication between different brain areas. However, these studies have typically only looked at average changes across groups of patients.

Vasily Vakorin, now of Simon Fraser University, British Columbia, and colleagues (from the Hospital for Sick Children, Toronto and Defense Research and Development Canada) investigated whether high-resolution imaging could be combined with machine learning algorithms to detect concussions in the brains of individual patients.

The researchers scanned the brains of men with and without concussion using magnetoencephalography (MEG), which records brain activity at fast time scales. MEG imaging showed that patients with concussions had distinctive changes in communication among areas of their brains.

Then, by employing machine learning algorithms, the scientists were able to use individual brain scans to work backwards and predict whether a given patient had a concussion or not. They were able to detect concussions with 88% accuracy. This approach also accurately predicted the severity of symptoms reported by individual patients.

"Changes in communication between brain areas, as detected by magnetoencephalography, allowed us to detect concussion from individual scans, in situations wherein typical clinical imaging tools such as MRI or CT fail," says study coauthor Sam Doesburg.

Future research could refine understanding of the specific neural changes associated with concussions in order to improve detection, inform treatment, and monitor recovery.


In your coverage please use this URL to provide access to the freely available article in PLOS Computational Biology:

Citation: Vakorin VA, Doesburg SM, da Costa L, Jetly R, Pang EW, Taylor MJ (2016) Detecting Mild Traumatic Brain Injury Using Resting State Magnetoencephalographic Connectivity. PLoS Comput Biol 12(11): e1004914. doi:10.1371/journal.pcbi.1004914

Funding: This work was supported by the Canadian Forces Health Services and funding from Defence Research and Development Canada (DRDC) (contract # W7719-135182/001/TOR) to MJT and EWP. The funders had no role in study.

Competing Interests: The authors have declared that no competing interests exist.

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