Title :
A fast model for simulating reentry in three dimensions with fiber rotation
Author :
Vigmond, Edward J. ; Leon, L.Joshua
Author_Institution :
Inst. de Genie Biomed., Montreal Univ., Que., Canada
fDate :
29 Oct-1 Nov 1998
Abstract :
Transmural rotation of cardiac fibers may have a large influence on reentry in the heart. However, modeling reentry is computationally challenging since the tissue modeled must be large enough to sustain reentry and this leads to a system of with millions of variables. A method is presented which decreases computation time due to its use of a discrete cable model which allows for system order reduction, and because it tracks the activation wavefront and only integrates the neighborhood of the front with a small time step. Simulations of approximately 1.8×106 cells in a block measuring 2×4×0.29 cm were possible in a reasonable amount of time. The effect on speed and accuracy of model parameters is discussed. It is also demonstrated that the method lends itself well to parallel computation. The effect of fiber rotation can be clearly seen during reentry
Keywords :
bioelectric phenomena; biological tissues; cardiology; finite difference methods; physiological models; 3D reentry simulation; activation wavefront; cardiac fibers; cardiac tissue; computation time; discrete cable model; fast model; finite difference; heart; ionic currents; parallel computation; system order reduction; transmural rotation; Anisotropic magnetoresistance; Cardiac tissue; Computational modeling; Concurrent computing; Finite difference methods; Heart; Muscles; Optical fiber cables; Pathology; Time measurement;
Conference_Titel :
Engineering in Medicine and Biology Society, 1998. Proceedings of the 20th Annual International Conference of the IEEE
Conference_Location :
Hong Kong
Print_ISBN :
0-7803-5164-9
DOI :
10.1109/IEMBS.1998.745814
