DocumentCode
1148342
Title
Microchannel Electrodes for Recording and Stimulation: In Vitro Evaluation
Author
Fitzgerald, James J. ; Lacour, Stéphanie P. ; McMahon, Stephen B. ; Fawcett, James W.
Author_Institution
Cambridge Centre for Brain Repair, Univ. of Cambridge, Cambridge
Volume
56
Issue
5
fYear
2009
fDate
5/1/2009 12:00:00 AM
Firstpage
1524
Lastpage
1534
Abstract
Previously we reported a finite-element model that predicted that microchannels could be sensitive recording devices, amplifying the extracellular signal as action potentials pass through them, and making recording independent of node of Ranvier location. Here, we present an in vitro experimental study that validates these predictions and also demonstrates that microchannel electrodes can be highly efficient stimulators. Several aspects of whole-nerve cuff technology, including noise-reduction techniques and unidirectional stimulation methods, are readily transferable to this small scale. If axons can be persuaded to regenerate in large numbers through narrow channels, the results presented here suggest that a regenerative microchannel array could be used to produce an in vivo peripheral nerve interface with a high-resolution for both recording and stimulation.
Keywords
amplification; biomedical electrodes; finite element analysis; medical signal processing; microelectrodes; neurophysiology; recorders; Ranvier location; action potentials; extracellular signal; extracellular signal amplification; finite-element model; in vivo peripheral nerve interface; microchannel electrodes; noise-reduction techniques; recording; regenerative microchannel array; sensitive recording devices; unidirectional stimulation methods; whole-nerve cuff technology; Conductors; Councils; Electrodes; Extracellular; Finite element methods; Impedance; In vitro; Materials science and technology; Microchannel; Nerve fibers; Noise reduction; Predictive models; Electrophysiology; neural interfaces; peripheral nerve; recording; stimulation; Action Potentials; Amplifiers, Electronic; Animals; Electric Impedance; Electric Stimulation; Electrodes, Implanted; Microelectrodes; Microtechnology; Peripheral Nerves; Rats; Rats, Sprague-Dawley;
fLanguage
English
Journal_Title
Biomedical Engineering, IEEE Transactions on
Publisher
ieee
ISSN
0018-9294
Type
jour
DOI
10.1109/TBME.2009.2013960
Filename
4776459
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