Carbon Fiber Microelectrode Arrays for Neuroprosthetic and Neuroscience Applications.

Abstract

The aim of this work is to develop, validate, and characterize the insertion mechanism, tissue response, and recording longevity of a new high-density carbon fiber microelectrode array. This technology was designed to significantly improve the field of penetrating microelectrodes while simultaneously accommodating the variable needs of both neuroscientists and neural engineers. The first study presents the fabrication and insertion dynamics of a high-density carbon fiber electrode array using a dual sided printed circuit board platform. The use of this platform has pushed electrode density to limits not seen in other works. This necessitated the use of an encapsulation method that served to temporarily stiffen the fibers during insertion, but did not enter the brain as many other shuttles do for other probe designs. The initial findings in this work informed the development of an even higher density array using a silicon support structure as a backbone. The second study reports on the tissue reaction of chronically implanted carbon fiber electrode arrays as compared to silicon electrodes. Due to their smaller footprint, the reactive response to carbon fibers should be greatly attenuated, if not non-existent. Results show a scarring response to the implanted silicon electrode with elevated astrocyte and microglia activity coupled to a local decrease in neuronal density. The area implanted with the carbon fiber electrodes showed a varied response, from no detectable increase in astrocytic or microglial activity to an elevated activation of both cell types, but with no detectable scars. Neuronal density in the carbon fiber implant region was unaffected. The data demonstrates that the small carbon fiber profile, even in an array configuration, shows an attenuated reactive response with no visible scaring. The final study reports on the viability of chronically implanted high-density carbon fiber arrays as compared to more traditional silicon planar arrays with comparable site sizes. While most new probe technologies or designs are able to demonstrate proof of concept functionality in acute preparations, very few show the ability to record chronic unit activity. This study aims to provide a comprehensive analysis of electrophysiology data collected over implant durations ranging from 3 – 5 months.