Athletic data depression: Gap in available neuroimaging data and technology limits understanding of effects of sports participation on the brain

There currently exists a limit to the available neuroimaging data and technologies on elite athletes. Our group has collected and analyzed data using the cloud-computing platform in order to accelerate sports participation and repetitive head impact/traumatic brain injury research.

Like Comment
Read more

Elite athletics, especially at the collegiate level, is a valuable industry in the States. The Division-1 American football and Basketball tournaments generate billions in revenue and draw in multi-millions to view their broadcasts. For most of these athletes, 14+ years of their lives have been dedicated to perfecting their minds and bodies to reach the pinnacle of their sport.

The demands placed on these elite athletes can provide a wealth of benefits, including improved cognition, well-being, and even increased integrity of brain tissue structure. However, the negative impacts on brain tissue structure may be just as prevalent but harder to detect. This is most prevalent in collision-sports athletes (eg. American football and ice hockey), where recent research has reported potentially damaging impacts of repetitive head impacts on brain tissue, which may last for years and contribute to later neurodegenerative disorders.

To fully understand the positive and negative effects of participating in athletics, science needs high-quality, openly shared datasets from elite athletes across the sports world broadly in addition to well-matched non-athletes. Despite recent efforts from multi-center concussion/mTBI focused studies, eg trackTBI, ENIGMA, and the CARE Consortium, there is almost no easily accessible data that can be openly used to separate detrimental and beneficial effects of sports. 

Even if there were a plethora of open data available, data is not enough. We need the resources and knowledge to implement useful science with data that is both reliable and reproducible. This is a much larger and more resource-consuming issue than just data availability, as noted by the current reproduction crises in psychology and neuroscience and the increased interest in Big Data analytics.

To address many of these issues, the National Science Foundation and Microsoft have supported developing an innovative cloud-resource called This resource allows for storing and processing brain data efficiently, reliably, and reproducibly. By connecting large-scale, publicly funded and private computing resources lowers entry barriers to effective brain data analysis. 

We combined this innovative technology with a data collection effort from varsity football players (collision), cross-country runners (non-collision), and age-matched non-athlete students at Indiana University. Our efforts have resulted in nearly 700GB worth of data and derivatives spanning magnetic resonance images, tractography, cortical maps, and structural networks ( The cutting-edge analysis pipelines implemented for this effort and the data have been thoroughly checked to assure the published data’s highest quality. We are excited about this effort and hope that other researchers will use it to accelerate discovery, and understanding of the effects of athletics on brain tissue.

Brad Caron

Neuroscience & Vision Sciences Ph.D. Student, Indiana University

I am a graduate student at Indiana University working with Franco Pestilli and Nicholas Port to identify the effects repetitive head impacts, traumatic brain injury, and sports participation have on brain tissue structural integrity properties using MRI. I am also interested in the effects of visual pathology on the structural properties of the underlying white matter tissue of the visual brain. Working on to develop efficient and reproducible neuroimaging analyses and pipelines to be used on large-scale datasets.

No comments yet.