Title :
Cellular automaton model of ventricular fibrillation
Author :
Mitchell, R.H. ; Bailey, A.H. ; Anderson, John
Author_Institution :
Dept. of Electr. & Electron. Eng., Ulster Univ., UK
fDate :
3/1/1992 12:00:00 AM
Abstract :
Ventricular fibrillation and the requirements for fibrillation are theoretically analyzed using a discrete element neighborhood (cellular automation) model of ventricular conduction. The model is configured as a 2500 element rectangular grid on the surface of a cylinder. It is shown that vulnerability to fibrillation is strongly influenced by excited state duration which primarily determines the nature of the underlying reentry activity. As excited state duration is increased fibrillation changes from ´coarse´ macroreentrant activity to the more chaotic ´fine´ fibrillation sustained by multiple wavelets of microreentry. In general, defibrillation is achieved by a stimulus strong enough to depolarize the majority of relative refractory elements. The threshold for defibrillation is increased for the more irregular microreentrant fibrillation.
Keywords :
cardiology; physiological models; cellular automaton model; chaotic fine fibrillation; coarse macroreentrant activity; cylinder surface; discrete element neighbourhood model; excited state duration; microreentry multiple wavelets; rectangular grid; reentry activity; relative refractory elements; ventricular fibrillation; Automata; Chaos; Circuits; Defibrillation; Dielectric constant; Electrodes; Fibrillation; Fractionation; Pacemakers; Performance analysis; Computer Simulation; Electric Countershock; Electrocardiography; Heart Conduction System; Humans; Models, Cardiovascular; Ventricular Fibrillation;
Journal_Title :
Biomedical Engineering, IEEE Transactions on
