Ultrathin, Foldable Sensors Probe Secrets Of The Brain
New ultra-thin, flexible sensors can deliver unprecedented views of the brain while dramatically reducing the invasiveness of brain implant devices.
Using the new sensors, researchers have already recorded previously unknown details of sleep patterns and brain activity during epileptic seizures in animals. They hope the new technology will help control seizures and sleep disorders and lead to new understandings of learning, vision, memory, depression, chronic pain and other neurological disorders. Ultimately, they hope to apply the new technology to other implantable devices such as cardiac pacemakers and defibrillators, cochlear and retinal implants and motor prosthetic systems.
The breakthrough technology packs ultrathin, foldable, silicon transistors into dense arrays of thousands of multiplexed sensors, and it uses just a tenth of the wires required by today's technology. The new sensors deliver unprecedented resolution — more than 400 times the current level.
Current implants that record or stimulate brain activity require wires for each individual sensor. The combination of the mass of today's sensors and wires preclude them from important areas of the brain that the new sensors can monitor for the first time, including inside sulci and fissures and even between the cortical hemispheres.
The new arrays cover a much larger brain area with significantly higher resolution, and the surgery to implant them is much less invasive.
The researchers' findings were published in the December issue of Nature Neuroscience. Lead authors are Brian Litt of the University of Pennsylvania and Jonathan Viventi, assistant professor of electrical and computer engineering at Polytechnic Institute of New York University and at the Center for Neural Science at New York University. John Rogers of the University of Illinois Urbana-Champaign and Dae-Hyeong Kim of Seoul National University, in South Korea are also part of the team that conceived and built the array.
The research was conducted with support from the U.S. National Institutes of Health's National Institute of Neurological Disorders and Stroke and National Heart, Lung, and Blood Institute, the National Science Foundation, the U.S. Department of Energy Division of Materials Sciences and Engineering, Citizens United for Research in Epilepsy, and the Dr. Michel and Mrs. Anna Mirowski Discovery Fund for Epilepsy Research.
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