Shock-Induced Depolarization of Refractory Myocardium Prevents Wave-Front Propagation in Defibrillation

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Circulation Research. 1996;79:957-973

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(Circulation Research. 1996;79:957-973.)
© 1996 American Heart Association, Inc.

Articles

Shock-Induced Depolarization of Refractory Myocardium Prevents Wave-Front Propagation in Defibrillation

Kevin F. Kwaku, Stephen M. Dillon

the Department of Pharmacology (K.F.K.), College of Physicians and Surgeons, Columbia University, New York, NY, and Philadelphia Heart Institute (S.M.D.), Sidney Kimmel Cardiovascular Research Center, Presbyterian Medical Center, Philadelphia, Pa.

Correspondence to Stephen M. Dillon, PhD, Allegheny University of the Health Sciences, Division of Cardiology, mail stop 429, Broad and Vine, Philadelphia, PA 19102-1192. E-mail sdillon@ix.netcom.com.

The elimination of most, if not all, propagating wave frontsof electrical activation by a shock constitutes a minimum prerequisitefor successful defibrillation. However, the factors responsiblefor the prevention of postshock propagating activity are unknown.We investigated the determinants of this effect of defibrillationshocks in 23 Langendorff-perfused rabbit hearts by opticallymapping cardiac cellular electrical activity by means of laserscanning. The optical action potentials obtained by this methodwere continuously recorded from 100 ventricular epicardial sitesbefore, during, and after shock delivery during fibrillation.Analysis of activation maps showed that postshock propagatingactivity arose from areas depolarized by the shock. In 273 shockepisodes, 898 sites at the border of shock-depolarized areas(BSDAs) from which wave-front propagation could have arisenwere identified. The incidence of postshock propagation fromBSDA sites was inversely related to refractoriness, as indexedby coupling interval (CI) or the optical takeoff potential (V_m).Specifically, there was a near-zero probability of postshockpropagation if the shock caused depolarization at CIs <50%of the fibrillation cycle length or from myocardium still depolarizedto $>=$ 60% of the amplitude of a paced action potential (APA). Furthermore,incidences of wave-front propagation following shocks were consistentlylower than the propagation incidences of naturally occurringunshocked fibrillation wave fronts, at comparable CIs and V_ms.We conclude that the incidence of postshock wave-front propagationdecreases with increasing refractoriness at the BSDA and thatshock-induced depolarization of effectively refractory myocardium(ie, depolarized to $>=$ 60% APA) is required to guarantee the cessationof continued wave-front propagation in defibrillation.

Key Words: defibrillation • ventricular fibrillation • refractoriness • optical mapping • rabbit heart

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				J. J. Sims, A. W. Miller, and M. R. Ujhelyi Disparate effects of biphasic and monophasic shocks on postshock refractory period dispersion Am J Physiol Heart Circ Physiol, June 1, 1998; 274(6): H1943 - H1949. [Abstract] [Full Text] [PDF]

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