Title :
Analysis of monophasic and biphasic electrical stimulation of nerve
Author :
Rubinstein, Jay T. ; Miller, Charles A. ; Mino, Hiroyuki ; Abbas, Paul J.
Author_Institution :
Dept. of Otolaryngology, Physiol. & Biophys. & Biomed. Eng., Iowa Univ., Iowa City, IA, USA
Abstract :
In an earlier study, biphasic and monophasic electrical stimulation of the auditory nerve was performed in cats with a cochlear implant. Single-unit recordings demonstrated that spikes resulting from monophasic and biphasic stimuli have different thresholds and latencies. Monophasic thresholds are lower and latencies are shorter under cathodic stimulation. Results from stochastic simulations of a biophysical model of electrical stimulation are similar. A simple analysis of a linear, "integrate to threshold" membrane model accounts for the threshold and latency differences observed experimentally and computationally. Since biphasic stimuli are used extensively in functional electrical stimulation, this analysis greatly simplifies the biophysical interpretation of responses to clinically relevant stimuli by relating them to the responses obtained with monophasic stimuli.
Keywords :
auditory evoked potentials; hearing aids; neurophysiology; physiological models; prosthetics; action potentials; auditory nerve; biophysical model; biphasic electrical stimulation; cathodic stimulation; cats; cochlear implant; functional electrical stimulation; latency differences; linear integrate to threshold membrane model; monophasic electrical stimulation; single-unit recordings; stochastic simulations; threshold differences; Biomembranes; Cats; Cities and towns; Cochlear implants; Computational modeling; Delay; Electrical stimulation; Nerve fibers; Neuromuscular stimulation; Stochastic processes; Action Potentials; Animals; Auditory Threshold; Cats; Electric Stimulation; Models, Neurological; Nerve Fibers; Reaction Time; Stochastic Processes; Vestibulocochlear Nerve;
Journal_Title :
Biomedical Engineering, IEEE Transactions on
