Title :
Limitations of approximate solutions for computing the extracellular potential of single fibers and bundle equivalents
Author :
Trayanova, Natalia A. ; Henriquez, Craig S. ; Plonsey, Robert
Author_Institution :
Dept. of Biomed. Eng., Duke Univ., Durnham, NC, USA
Abstract :
An examination and comparison are made of the rigorous and conventional approximate solutions of Laplace´s equation used to evaluate the extracellular potential of a single, cylindrical fiber. The single fiber is considered as both a prototypical element (such as a nerve or muscle fiber) and an elementary model of an entire multicellular preparation (e.g. nerve bundle or Purkinje strand). The effects of the fiber radius, the intracellular and extracellular conductiveness, and the shape and extent of the source function (either the transmembrane potential or the intracellular potential) on the solutions are discussed. The results show that, in general, the approximate solutions are unsatisfactory for computing the surface extracellular potential when the single fiber is used to represent a large bundle (>300 mu m).
Keywords :
Laplace transforms; bioelectric potentials; electrical conductivity; muscle; neurophysiology; physiological models; 300 micron; Laplace equation solutions; Laplace´s equation; Purkinje strand; approximate solutions; bundle equivalents; cylindrical fiber; extracellular conductiveness; extracellular potential; fiber radius; intracellular conductiveness; intracellular potential; multicellular preparation; muscle fiber; nerve; nerve bundle; prototypical element; single fibers; surface extracellular potential; transmembrane potential; Bioelectric phenomena; Biomedical engineering; Conductivity; Conductors; Electric potential; Extracellular; Laplace equations; Muscles; Prototypes; Shape; Fourier Analysis; Membrane Potentials; Models, Biological; Models, Neurological; Muscles; Nerve Fibers; Synaptic Transmission;
Journal_Title :
Biomedical Engineering, IEEE Transactions on
