Title :
Magnetic techniques for evaluating peripheral nerve function
Author :
Wikswo, John P., Jr.
Author_Institution :
Dept. of Phys. & Aston., Vanderbilt Univ., Nashville, TN, USA
Abstract :
Experimental and theoretical studies of the magnetic field of isolated, giant nerve axons are being extended to the study of nerve bundles. The theoretical models use effective anisotropic conductivities that depend on the spatial and temporal frequencies of the transmembrane action potential to account for the effect of adjacent myelinated fibers on both the action current and the extracellular potential of a single axon off-axis in a sheathed nerve bundle. A convolution model is used to recreate the compound action signal from the fiber diameter histogram. A nonnegative least-squares algorithm is used for the deconvolution to obtain the histogram from measured signals, demonstrating the feasibility of magnetic determination of fiber diameter histograms. An openable toroidal probe is being developed to allow intraoperative assessment of damaged peripheral nerves in humans
Keywords :
biomagnetism; biomedical measurement; neurophysiology; action current; convolution model; damaged peripheral nerves; effective anisotropic conductivity; extracellular potential; intraoperative assessment; isolated giant nerve axons; magnetic techniques; nonnegative least-squares algorithm; openable toroidal probe; peripheral nerve function evaluation; sheathed nerve bundle; spatial frequency; transmembrane action potential; Anisotropic magnetoresistance; Conductivity; Convolution; Extracellular; Frequency; Histograms; Magnetic anisotropy; Nerve fibers; Perpendicular magnetic anisotropy; Toroidal magnetic fields;
Conference_Titel :
Biomedical Engineering., Proceedings of a Special Symposium on Maturing Technologies and Emerging Horizons in
Conference_Location :
New Orleans, LA
DOI :
10.1109/MTEHBE.1988.26381
