Chronically-Implantable Multisite Microelectrode Arrays
Han, Martin   
Huntington Medical Research Institutes, Pasadena, CA, United States

We are requesting funding for an essential need in neuroscience, supporting researchers with chronically-implantable multisite microelectrode arrays. Microelectrode arrays are an important tool for neural prostheses and brain machine interfaces as well as for basic neuroscience. Clinical applications now under development include central auditory prostheses that utilize electrical neural stimulation to overcome hearing loss, visual prostheses employing microstimulation in the cerebral cortex, and closed-loop deep brain stimulation to relieve the motor symptoms of Parkinson's disease and other disorders. While there are commercial vendors providing microwire arrays and silicon arrays suitable for chronic implantation, there is an unmet need for custom-assembled silicon-based 3D multisite microelectrode arrays. This resource center will design, fabricate, and assemble customized microelectrode arrays for long-term neural stimulation and recording in-vivo. The proposed devices will be fabricated from custom-designed multisite silicon-based arrays that can be inserted into targets in the sulci of the cerebral cortex, deep brain, brainstems, and spinal cord or spinal nerves. The devices will be mechanically sturdy for reliable insertion into the target tissues, and will have long flexible cables to meet users' requirements. The arrays are intended to be used in animal models such as rats, cats, and non-human primates, and are designed to facilitate clinical translation.

Public Health Relevance

State-of-the-art microelectrode arrays are the basis of a new generation of neural prostheses for replacing lost neural functions. The proposed research resources could have a profound impact on the treatment of many neurological diseases. For instances, multisite microelectrode arrays can be used in auditory prostheses by accessing the tonotopic organization in the auditory brainstem, or in a deep-brain array that can deliver spatially-focused stimulation and also record neuronal activity for closed-loop control of the stimulation in order to ameliorate the symptoms of a neurological disorder.