Phase 2 reentry as a mechanism of initiation of circus movement reentry in canine epicardium exposed to simulated ischemia

doi:10.1016/S0008-6363(96)00115-0

Cardiovascular Research 1996 32(3):593-603; doi:10.1016/S0008-6363(96)00115-0
© 1996 by European Society of Cardiology

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Phase 2 reentry as a mechanism of initiation of circus movement reentry in canine epicardium exposed to simulated ischemia

Anton Lukas^* and Charles Antzelevitch

Masonic Medical Research Laboratory, 2150 Bleecker Street, Utica, NY 13501-1787, USA

^* Corresponding author, present address: Division of Cardiovascular Sciences, St. Boniface General Hospital Research Centre, 351 Tache Avenue, Winnipeg, Manitoba, CanadaR2H 2A6. Tel.: (+1-204) 235-3521; fax: (+ 1-204) 233-6723. alukas{at}sbrc.umanitoba.ca

Objectives: Myocardial ischemia results in an early phase of arrhythmiasthat primarily involves reentrant mechanisms. However, the triggerthat initiates reentry remains unknown. We studied the initiationof reentry attending the development of electrical heterogeneityduring simulated ischemia in isolated canine right ventricularsubepicardium.Methods: Preparations consisted of thin epicardialsheets in which action potentials were recorded at 4 sites withintracellular microelectrodes. Tissues were superfused witha hyperkalemic, hypoxic and acidotic ‘ischemic’solution.Results: Simulated ischemia produced a 40–70%abbreviation of the action potential at some epicardial sitesbut not others, primarily by suppressing development of theaction potential plateau (or dome). This typically created amarked dispersion of repolarization within the preparation.Local re-excitation ensued when the action potential dome propagatedfrom sites where it was maintained to sites where it was abolished.This mechanism, termed ‘phase 2 reentry’, producedan extrasystole which then initiated one or more cycles of circusmovement reentry. Tachycardias consisting of repetitive reentryoccurred in larger tissues. The window for reentry occurredover a range of stimulation rates that shifted to faster ratesas ischemia progressed. The transient outward current blocker,4-aminopyridine, restored the dome at all sites by reversingthe ischemia-induced abbreviation of the action potential. Thus,block of the transient outward current restored electrical homogeneityand abolished all reentrant activity within the epicardial preparations.Conclusion:Our results implicate phase 2 reentry as a new mechanism forgenesis of extrasystoles during simulated ischemia and identifythis mechanism as a trigger of circus movement reentry. Validationof this hypothesis awaits the results of future studies usinghigh-resolution recording techniques.

KEYWORDS Dog ventricle; Myocardial ischemia; Potassium channel, transient outward; Epicardial mapping; Reentry; Tachycardia

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