Premature Beats Elicit a Phase Reversal of Mechanoelectrical Alternans in Cat Ventricular Myocytes : A Possible Mechanism for Reentrant Arrhythmias

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Circulation. 1995;91:201-214

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(Circulation. 1995;91:201-214.)
© 1995 American Heart Association, Inc.

Articles

Premature Beats Elicit a Phase Reversal of Mechanoelectrical Alternans in Cat Ventricular Myocytes

A Possible Mechanism for Reentrant Arrhythmias

Donald S. Rubenstein, MD, PhD; Stephen L. Lipsius, PhD

From the Department of Cardiology (D.S.R.) and the Department of Physiology (S.L.L.), Loyola University of Chicago, Maywood, Ill.

Correspondence to Donald S. Rubenstein, MD, PhD, Department of Cardiology, Loyola University of Chicago, 2160 S First Ave, Maywood, IL 60153.

Background Alternans of the ST segment of the ECG is an importantrisk factor for sudden cardiac death. Premature beats during alternansand the development of discordant alternans are associated withthe onset of ventricular tachycardia and ventricular fibrillation. Moreover,premature beats can switch the pattern of alternans from discordantto concordant alternans. The mechanisms of how a premature beatcan elicit a pattern shift in alternans and develop malignant ventriculararrhythmias are not clear. The purpose of this cellular studywas to determine the electrical and mechanical restitution propertiesduring cycle length–induced alternans and to determinehow premature and delayed beats affect the resultant phase of alternans.

Methods and Results A perforated patch recording method andvideo-based edge detector were used to record action potentialsand contractions, respectively, from single ventricular myocytesenzymatically isolated from the cat heart. Electrical and mechanicalrestitution curves were determined by programmed test beats deliveredat different cycle lengths during mechanoelectrical alternans.At 35°C, 97.8% of cells exhibited concordant cellular alternans(action potentials with the larger action potential duration [APD]were associated with the larger contraction, and action potentialswith the smaller APD exhibited the smaller contraction). The sequenceor phase of concordant cellular alternans could be systematicallyreversed by (1) early premature beats that followed only actionpotentials with the shorter APD and smaller contraction (type1 phase reversal; n=34) or (2) late delayed beats that followedonly action potentials with the longer duration and the largercontraction (type 2 phase reversal; n=14). A phase reversalpoint was defined as a threshold time interval that resultedin switching the sequence of the alternating beats. A test stimulusat the phase reversal point caused temporary suppression ofmechanoelectrical alternans. Lower temperatures (32°C) ordecreases in the basic cycle length induced larger beat-to-beatchanges in the magnitude of alternans (APD or contraction) andsignificantly shifted the phase reversal point to earlier prematureintervals for type 1 phase reversal. The interval of the phasereversal point was a function of the contractile ratio (the magnitudeof the larger contraction/smaller contraction for two consecutivebeats, r=.93) and not the APD ratio (longer APD/shorter APD;r=.501). In cells stimulated at cycle lengths longer than thethreshold of alternans, a single premature beat could elicita damped form of concordant mechanoelectrical alternans. A criticallytimed second premature beat reversed the phase of the damped alternans.

Conclusions Properly timed premature or delayed beats duringcycle length–induced alternans consistently reversed thephase of cellular mechanoelectrical alternans. Reversal of thephase of alternans was dependent on recovery of mechanical activity,not electrical activity. The premature stimulus interval atthe phase reversal point can be predicted by the magnitude ofmechanical alternans. Thus, during cycle length–inducedalternans, mechanical alternans governs the phase of electricalalternans. From the present results, a multicellular model isproposed that may explain how critically timed premature beatscause a regional change in the phase of mechanical alternansand thereby result in discordant electrical alternans or dispersionof refractoriness. Premature beats that induce phase reversalin mechanoelectrical alternans may contribute to the developmentof reentrant arrhythmias.

Key Words: alternans • potentials • electrophysiology • reentry • arrhythmia

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				J. M. Pastore, S. D. Girouard, K. R. Laurita, F. G. Akar, and D. S. Rosenbaum Mechanism Linking T-Wave Alternans to the Genesis of Cardiac Fibrillation Circulation, March 16, 1999; 99(10): 1385 - 1394. [Abstract] [Full Text] [PDF]

				M. J. Burgess, A. E. Pollard, K. W. Spitzer, and L. Yang Effects of Premature Beats on Repolarization of Postextrasystolic Beats Circulation, October 1, 1995; 92(7): 1969 - 1980. [Abstract] [Full Text]