The BrainGate collaboration plans to embark on the preclinical testing of its first wireless sensor intended for human use. The researchers realize that benchtop preclinical testing is still needed before the technology can be considered for use in a clinical trial, and that testing is now beginning in collaboration with neuroscience technology firm Blackrock Microsystems (Salt Lake City, UT), the manufacturer that has licensed the Brown technology.
"After years of development led by Professor Arto Nurmikko at Brown University, we have created a low-profile, high-bandwidth wireless device, but translating it to use in people requires specific testing," said BrainGate investigator John Simeral, assistant professor of engineering (research) at Brown University and research biomedical engineer at the Providence Veterans Affairs Medical Center (PVAMC), who is the principal investigator for this new grant. "This project will support that testing as a critical step toward use by people with spinal cord injury and others with tetraplegia or locked-in syndrome."
The work will begin with the support of a $50,000 grant as part of stage 1 of the Conquer Paralysis Now Challenge. The nonprofit organization's competition to cure paralysis in the next 10 years will ultimately award a $10-million grand prize to the first team that can reach unprecedented improvement in every day functions of people living with chronic spinal injury.
The BrainGate Neural Interface System is an investigational assistive neurotechnology under development for years by a multi-institution collaboration. The goal is to replace or restore lost function and enhance independence for people with paralysis. Dr. Leigh Hochberg, professor of engineering at Brown and director of the VA Center for Neurorestoration and Neurotechnology, directs the BrainGate pilot clinical trials.
The initial proofs of concept resulted from the research of John Donoghue, the Henry Merritt Wriston Professor of Neuroscience. As an individual attempts to make arm and hand movements, BrainGate records movement-related activity from tiny electrodes in the surface of the brain and translates that