Electrical remodeling of the epicardial border zone in the canine infarcted heart: a computational analysis

doi:10.1152/ajpheart.00512.2002

Electrical remodeling of the epicardial border zone in the canine infarcted heart: a computational analysis

Candido Cabo¹^,²^,³ and Penelope A. Boyden¹^,²

¹ Department of Pharmacology and ² Center for Molecular Therapeutics, College of Physicians and Surgeons of Columbia University, New York 10032; and ³ Department of Computer Systems, New York City College of Technology, City University of New York, New York, New York 11201

The density and kinetics of several ionic currents of cells isolated from the epicardial border zone of the infarcted heart(IZs) are markedly different from cells from the noninfarctedcanine epicardium (NZs). To understand how these changes in channelfunction affect the action potential of the IZ cell as well asits response to antiarrhythmic agents, we developed a new ionicmodel of the action potential of a cell that survives in the infarct(IZ) and one of a normal epicardial cell (NZ) using formulationsbased on experimental measurements. The difference in action potentialduration (APD) between NZ and IZ cells during steady-state stimulation(basic cycle length = 250 ms) was 6 ms (156 ms in NZ and 162 msin IZ). However, because IZs exhibit postrepolarization refractoriness,the difference in the effective refractory period (ERP), calculatedusing a propagation model of a single fiber of 100 cells, was43 ms (156 ms in NZ and 199 ms in IZ). Either an increase in L-typeCa²⁺ current (to simulate the effects of BAY Y5959) or a decreaseof both or either delayed rectifier currents (e.g., to simulatethe effects of azimilide, sotalol, and chromanol) had significanteffects on NZ ERP. In contrast, the effects of these agents inIZs were minor, in agreement with measurements in the in situcanine infarcted heart. Therefore 1) because IZs exhibit postrepolarizationrefractoriness, conclusions drawn from APD measurements cannotbe extrapolated directly to ERPs; 2) ionic currents that are themajor determinants of APD and the ERP in NZs are less importantin IZs; and 3) differential effects of either BAY Y5959 or azimilidein NZs versus IZs are predicted to decrease ERP dispersion andin so doing prevent initiation of arrhythmias in a substrate ofinhomogeneous APD/ERPs.

computer model; infarction; postrepolarization refractoriness; antiarrhythmic drugs

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