Neural stimulation with magnetic fields: analysis of induced electric fields

Author

Esselle, Karu P. ; Stuchly, Maria A.

Author_Institution

Health & Welfare Canada, Ottawa, Ont., Canada

Volume

39

Issue

7

fYear

1992

fDate

7/1/1992 12:00:00 AM

Firstpage

693

Lastpage

700

Abstract

Spatial distribution of the derivative of the electric field induced in a planar semi-infinite tissue model by various current-carrying coils and their utility in neural stimulation are evaluated. Analytical expressions are obtained for the electric field and its spatial derivatives produced by an infinitely short current element. Fields and their derivatives for an arbitrarily shaped coil are then obtained by numerical summation of contributions from all the elements forming the coil. The simplicity of the solution and a very short computation time make this method particularly attractive for gaining a physical insight into the spatial behavior of the stimulating parameter and for the optimization of coils. Such analysis is useful as the first step before undertaking a more complex numerical analysis of a model more closely representing the tissue geometry and heterogeneity.

Keywords

bioelectric phenomena; biological effects of fields; biomagnetism; neurophysiology; physiological models; analytical expressions; arbitrarily shaped coil; coil optimization; computation time; current-carrying coils; electric field derivative; induced electric fields; numerical analysis; planar semi-infinite tissue model; tissue geometry; tissue heterogeneity; Coils; Geometry; Magnetic analysis; Magnetic fields; Magnetic stimulation; Medical diagnostic imaging; Nerve fibers; Neurons; Optimization methods; Physics computing; Computer Simulation; Electricity; Humans; Magnetics; Motor Neurons;

fLanguage

English

Journal_Title

Biomedical Engineering, IEEE Transactions on

Publisher

ieee

ISSN

0018-9294

Type

jour

DOI

10.1109/10.142644

Filename

142644