“We want to know how much force inside the brain is too much for cells,” Franck said. “That gives us a baseline for understanding exactly what kinds of forces are involved in TBI at the cellular level.”

Diane Hoffman-KimDiane Hoffman-KimThe lab of Hoffman-Kim, an associate professor of medical science and of engineering at Brown, works with mini-brains, or neuron bundles that model basic properties of living brains. The mini-brains offer a more complex cell culture than those Franck has worked with previously, which enables the researchers to better recreate the actual brain environment in which neurons operate.

The information gleaned from the cellular level will be combined with results of studies designed to better understand the forces on a helmeted head generated by typical blunt impacts and blast waves. To do that, the research team will work with Team Wendy to develop a sensor system that can be fitted to existing helmets used in combat and athletics. In 2013, Franck and Team Wendy developed a simple but fully functional impact acceleration measuring combat helmet system, which served as a proof of principle for the current grant.

The team will build upon that initial sensor design, then they’ll use facilities at Drexel and Team Wendy to test the response of helmets to a wide variety of forces, and how those forces are transmitted to the skull.

To complete the picture of how forces transmitted by a helmet are distributed through the brain to individual cells, Franck will work with researchers at Sandia National Laboratory. The Sandia team who has developed models of the head and neck based on thousands of CT scans. Those models are able to provide insights into how forces are transmitted through soft tissue.

“We want put all these pieces together from the macroscopic level of helmets to the microscopic level of cells to get a complete picture of how these injuries occur,” Franck said. “Once we have that, we can start to think about new methods of diagnosis and prevention.”

Based on the injury model developed during this project, the researchers aim to deploy a version of their sensor system in combat theaters and playing fields.

“The idea is that when someone experiences a blow to the head, the helmet transmits the force data to a computer,” Franck said. “A first responder could then look at that data and determine if TBI is likely and how severe it might be.”

Ultimately, the team hopes the data generated by the research can be used to devise a new testing standard for helmets and a new helmet prototype. In developing the prototype, Franck will work closely with Team Wendy and his colleague in the School of Engineering, Haseesh Kesari, who studies the mechanical properties of solid materials.

“What’s exciting to me about this is that it spans the microscale to macroscale,” Franck said. “We’re not aware of any other project that has taken such a comprehensive and tightly integrated approach to understanding how to better prevent these kinds of injuries.”