Role of Structural Barriers in the Mechanism of Alternans-Induced Reentry

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Circulation Research. 2000;87:1157-1163

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Integrative Physiology

Role of Structural Barriers in the Mechanism of Alternans-Induced Reentry

Joseph M. Pastore, David S. Rosenbaum

From the Heart and Vascular Research Center and Department of Biomedical Engineering, MetroHealth Campus, Case Western Reserve University, Cleveland, Ohio.

Correspondence to David S. Rosenbaum, MD, Director, Heart and Vascular Research Center, MetroHealth Campus, Case Western Reserve University, 2500 MetroHealth Dr, Hamman 322, Cleveland, OH 44109-1998. E-mail drosenbaum{at}metrohealth.org

Abstract—Previously, using an animal model of T-wave alternansin structurally normal myocardium, we demonstrated that repolarizationcan alternate with opposite phase between neighboring myocytes(ie, discordant alternans), causing spatial dispersions of repolarizationthat form the substrate for functional block and reentrant ventricularfibrillation (VF). However, the mechanisms responsible for cellulardiscordant alternans and its electrocardiographic manifestation(ie, T-wave alternans) in patients with structural heart diseaseare unknown. We hypothesize that electrotonic uncoupling betweenneighboring regions of cells by a structural barrier (SB) isa mechanism for discordant alternans. Using voltage-sensitivedyes, ventricular action potentials were recorded from 26 Langendorff-perfusedguinea pig hearts in the absence (ie, control) and presenceof an insulating SB produced by an epicardial laser lesion.Quantitative analysis of magnitude and phase of cellular alternansrevealed that in controls, action potential duration alternatedin phase at all ventricular sites above a critical heart rate(269±17 bpm), ie, concordant alternans. Also, above afaster critical heart rate threshold (335±24 bpm), actionpotential duration alternated with opposite phase between sites,ie, discordant alternans. In contrast, only discordant but notconcordant alternans was observed in 80% of hearts with theSB, and discordant alternans always occurred at a significantlyslower heart rate (by 68±28 bpm) compared with controls.Therefore, the SB had a major effect on the alternans–heart raterelation, which served to facilitate the development of discordant alternans.Whether a SB was present or not, discordant alternans producedconsiderable increases (by ${approx}$ 170%) in the maximum spatial gradientof repolarization, which in turn formed the substrate for unidirectionalblock and reentry. However, by providing a structural anchorfor stable reentry, discordant alternans in the presence ofa SB led most often to sustained monomorphic ventricular tachycardiarather than to VF, whereas in the absence of a SB discordantalternans caused VF. SBs facilitate development of discordantalternans between cells with different ionic properties by electrotonicallyuncoupling neighboring regions of myocardium. This may explainwhy arrhythmia-prone patients with structural heart diseaseexhibit T-wave alternans at lower heart rates. These data alsosuggest a singular mechanism by which T-wave alternans formsa substrate for initiation of both VF and sustained monomorphicventricular tachycardia.

Key Words: repolarization • reentry • alternans

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				A. A. Armoundas, G. F. Tomaselli, and H. D. Esperer Pathophysiological basis and clinical application of T-wave alternans J. Am. Coll. Cardiol., July 17, 2002; 40(2): 207 - 217. [Abstract] [Full Text] [PDF]

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				J. J. Fox, M. L. Riccio, F. Hua, E. Bodenschatz, and R. F. Gilmour Jr Spatiotemporal Transition to Conduction Block in Canine Ventricle Circ. Res., February 22, 2002; 90(3): 289 - 296. [Abstract] [Full Text] [PDF]

				R. D. Berger Repolarization Alternans : Toward a Unifying Theory of Reentrant Arrhythmia Induction Circ. Res., December 8, 2000; 87(12): 1083 - 1084. [Full Text] [PDF]

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