Title :
A model study of the effects of anisotropy on the stability of cardiac reentrant activity
Author :
Leon, L.Joshua ; Nour, C.A. ; Roberge, Fernand A.
Author_Institution :
Inst. de Genie Biomed., Montreal Univ., Que., Canada
fDate :
31 Oct-3 Nov 1996
Abstract :
A two-dimensional parallel-cable sheet model of cardiac tissue, with a brick-wall arrangement of resistive transverse interconnections, was used to study the effects of tissue anisotropy on reentry. Reentrant activity was induced using a modified cross-shock protocol. A sheet with a low anisotropy ratio (<6.0) could be rescaled in the transverse direction so that the reentrant activity had the same basic characteristics as those observed in the nominal sheet. Once the anisotropy ratio passed 6.0 the similarity was lost. Reentry in the high anisotropy sheet had a longer cycle length and propagation tended to be blocked more easily, which led to wave breakup and the appearance of multiple wavefronts. These results suggest a fundamental difference between reentrant activity in low anisotropy tissue, typical of ventricular myocardium, and high anisotropy tissue typical of the atria
Keywords :
bioelectric phenomena; cardiology; physiological models; anisotropy effects; atria; brick-wall arrangement; cardiac electrophysiology model; cardiac reentrant activity stability; cardiac tissue; high anisotropy tissue; low anisotropy tissue; modified cross-shock protocol; multiple wavefronts appearance; resistive transverse interconnections; transverse direction; two-dimensional parallel-cable sheet model; ventricular myocardium; wave breakup; Anisotropic magnetoresistance; Cables; Cardiac tissue; Electronic waste; Myocardium; Protocols; Resistors; Safety; Stability; Thyristors;
Conference_Titel :
Engineering in Medicine and Biology Society, 1996. Bridging Disciplines for Biomedicine. Proceedings of the 18th Annual International Conference of the IEEE
Conference_Location :
Amsterdam
Print_ISBN :
0-7803-3811-1
DOI :
10.1109/IEMBS.1996.652796
