Development of a Novel Intrafascicular Nerve Electrode

Abstract: Artificial organs could be controlled using autonomic neural signals, because they exhibit rapid responses to physical needs similar to those of natural organs. A nerve electrode must satisfy many requirements to measure autonomous neural signals such as a long lifetime, high signal-to-noise ratio, multichannel recording, simple installation into a nerve fascicle, and good manufacturing productivity. The purpose of our study is to propose and evaluate a novel nerve electrode that satisfies these conditions, wh… Show more

“…In order to determine which device to use for a given physiological experiment or clinical application, the neural interface must meet the needs of both the desired physiological outcome and the constraints applied by the targeted neuroanatomy. Current peripheral nerve interfaces have electrodes that vary in their number of contacts, which can be separated by hundreds of micrometers [2,4,5,[11][12][13] or several millimeters [3,7,14]. Many of the devices have a low number of electrodes (<10) that are implanted interfascicularly (e.g.…”

A new high-density (25 electrodes/mm²) penetrating microelectrode array for recording and stimulating sub-millimeter neuroanatomical structures

“…In order to determine which device to use for a given physiological experiment or clinical application, the neural interface must meet the needs of both the desired physiological outcome and the constraints applied by the targeted neuroanatomy. Current peripheral nerve interfaces have electrodes that vary in their number of contacts, which can be separated by hundreds of micrometers [2,4,5,[11][12][13] or several millimeters [3,7,14]. Many of the devices have a low number of electrodes (<10) that are implanted interfascicularly (e.g.…”

A new high-density (25 electrodes/mm²) penetrating microelectrode array for recording and stimulating sub-millimeter neuroanatomical structures

“…Topographical patterning is also possible, which would provide anisotropic or directional growth for cells with regeneration of neural tissue and formation of neural networking 18. The patterning capability of the coating can be expanded to application for in vivo neural prosthetics, such as providing stable control for autonomic neural signals of an artificial organ and peripheral neural systems of artificial limbs 19, 20…”

Neurite outgrowth of PC12 cells on diX (parylene) family materials