Effects of uniform anisotropy on wavelet fractionation and electrogram simulations in a computer model of fibrillation

Author

Sih, Haris J. ; Sahakian, Alan V. ; Baerman, Jeffrey M. ; Swiryn, Steven

Author_Institution

Northwestern Univ., Evanston, IL, USA

fYear

1990

fDate

23-26 Sep 1990

Firstpage

529

Lastpage

532

Abstract

Using a 10000-element modified Moe computer model of a fibrillating cardiac tissue sheet, cases of isotropic and uniformly anisotropic conduction were implemented and compared to determine how uniform anisotropy contributes to wavelet fractionation. In this model, a bipolar electrogram calculation based on the Ploney volume-conductor equations is implemented in several simple test cases and in a fibrillating, isotropic model sheet. It is shown that in this computer model, the role of uniform anisotropy in wavelet fractionation is less significant than effects due to overall velocity changes. Bipolar recordings in this model can approximate many characteristics in both the time and frequency domains of fibrillation cardiac tissue

Keywords

bioelectric phenomena; biology computing; cardiology; digital simulation; physiological models; Ploney volume-conductor equations; bipolar recordings; electrogram simulations; fibrillating cardiac tissue sheet; frequency domain; modified Moe computer model; overall velocity changes; time domain; uniform anisotropy; wavelet fractionation; Anisotropic magnetoresistance; Cardiac tissue; Computational modeling; Computer simulation; Conductors; Equations; Fractionation; Humans; Medical simulation; Testing;

fLanguage

English

Publisher

ieee

Conference_Titel

Computers in Cardiology 1990, Proceedings.

Conference_Location

Chicago, IL

Print_ISBN

0-8186-2225-3

Type

conf

DOI

10.1109/CIC.1990.144272

Filename

144272