Technology for Bioelectronic Medicine
Bioelectronic medicine provides a new means of addressing disease via the electrical stimulation of tissues: Deep brain stimulation, for example, has shown exceptional promise in the treatment of neurological and neuropsychiatric disorders, while stimulation of peripheral nerves is being explored to treat autoimmune disorders. To bring these technologies to patients at scale, however, significant challenges remain to be addressed. Key among these is our ability to establish stable and efficient interfaces between electronics and the human body. I will show examples of how this can be achieved using new electronic materials and devices engineered to communicate with the body and evolve with it.
Department of Engineering Electrical Engineering Division, University of Cambridge
George Malliaras is the Prince Philip Professor of Technology at the University of Cambridge. He received a PhD from the University of Groningen and did a postdoc at the IBM Almaden Research Center. Before joining Cambridge, he was a faculty member at Ecole des Mines de St. Etienne and at Cornell University, and served as the Director of the Cornell NanoScale Facility. His research has been recognized with awards from the New York Academy of Sciences, the US National Science Foundation, and DuPont. He is a Fellow of the Materials Research Society and of the Royal Society of Chemistry. Prof. Malliaras' research is on bioelectronics. He leads a group of scientists, engineers and clinicians who study the fundamental processes that take place at the abiotic/biotic interface and develop better tools for healthcare. Research themes include the development and translation of implantable and wearable devices that interface with electrically active tissues, with applications in neurological disorders and brain cancer.
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