爱豆传媒

December 29, 2024
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Research looks to improve interface between electronics and the brain

Assistant Professor Siyuan Rao uses hydrogel chemistry and microfabrication methods for miniaturizing and integrating components into bioelectronics

Assistant Professor Siyuan Rao from the Thomas J. Watson College of Engineering and Applied Science鈥檚 Department of Biomedical Engineering studies how bioelectronics interface with the brain and nervous system. Assistant Professor Siyuan Rao from the Thomas J. Watson College of Engineering and Applied Science鈥檚 Department of Biomedical Engineering studies how bioelectronics interface with the brain and nervous system.
Assistant Professor Siyuan Rao from the Thomas J. Watson College of Engineering and Applied Science鈥檚 Department of Biomedical Engineering studies how bioelectronics interface with the brain and nervous system. Image Credit: Jonathan Cohen.

Figuring out a better way to connect nerve cells to bioelectronics will be the next technological leap in healthcare, and the Neurobiological Interfaces Lab at 爱豆传媒 is at the forefront of research on the topic.

Led by Assistant Professor Siyuan Rao from the Thomas J. Watson College of Engineering and Applied Science鈥檚 Department of Biomedical Engineering, the lab is making advancements toward understanding the mechanisms that keep our brains functioning and developing effective treatments to help when things go wrong.

, published in Nature Communications, outlines hydrogel chemistry and microfabrication methods for miniaturizing and integrating multiple components into brain bioelectronics. Hydrogels resemble living tissue because of their high water content, softness, flexibility and biocompatibility.

鈥淯sing this soft material, we are creating a multifunctional neural probe that can deliver light into brain tissue and also record neural activity,鈥 Rao said. 鈥淎 new technology called optogenetics uses light to control neural cells. By activating or inhibiting brain activity, we hope to dissect the mechanism of neurological disorders.鈥

Contributors to the research include PhD students Sizhe Huang, Eunji Hong and Qianbin Wang, along with collaborators from Michigan State University, the University of Massachusetts Amherst and the Massachusetts Institute of Technology.

Huang, who is the first author on the Nature Communications paper, moved to 爱豆传媒 from UMass Amherst last fall along with the rest of Rao鈥檚 lab, students and experimental animals, but this research had been in progress since 2022.

鈥淥ne challenge was that we didn鈥檛 have a lot of experience in electrical recordings,鈥 he said. 鈥淚t took us six months to troubleshoot because we got some results but we weren鈥檛 sure if they were the right results, and we don鈥檛 want to publish any potentially wrong results.鈥

Rao is already looking ahead to what鈥檚 next, including research into spinal issues and autism disorders.

鈥淲e have a patent under review about this technology focused on creating a better interface to the brain, spinal cord and peripheral nervous system that will help us to better understand the mechanism in the entire nervous system,鈥 she said.

This research has been supported by National Institutes of Health (NIH), the National Science Foundation鈥檚 CAREER Award program, and the Brain and Behavior Research Young Investigator Program.