Mechanistic inquiry into decrease in probability of defibrillation success with increase in complexity of preshock reentrant activity

doi:10.1152/ajpheart.00492.2003

Mechanistic inquiry into decrease in probability of defibrillation success with increase in complexity of preshock reentrant activity

Matthew G. Hillebrenner, James C. Eason, and Natalia A. Trayanova

Department of Biomedical Engineering, Tulane University, New Orleans, Louisiana 70118

Submitted 28 May 2003 ; accepted in final form 31 October 2003

Energy requirements for successful antiarrhythmia shocks arearrhythmia specific. However, it remains unclear why the probabilityof shock success decreases with increasing arrhythmia complexity.The goal of this research was to determine whether a diminishedprobability of shock success results from an increased numberof functional reentrant circuits in the myocardium, and if so,to identify the responsible mechanisms. To achieve this goal,we assessed shock efficacy in a bidomain defibrillation modelof a 4-mm-thick slice of canine ventricles. Shocks were appliedbetween a right ventricular cathode and a distant anode to terminateeither a single scroll wave (SSW) or multiple scroll waves (MSWs).From the 160 simulations conducted, dose-response curves wereconstructed for shocks given to SSWs and MSWs. The shock strengththat yielded a 50% probability of success (ED₅₀) for SSWs wasfound to be 13% less than that for MSWs, which indicates thata larger number of functional reentries results in an increaseddefibrillation threshold. The results also demonstrate thatan isoelectric window exists after both failed and successfulshocks; however, shocks of strength near the ED₅₀ value thatwere given to SSWs resulted in 16.3% longer isoelectric windowdurations than the same shocks delivered to MSWs. Mechanisticinquiry into these findings reveals that the two main factorsunderlying the observed relationships are 1) smaller virtualelectrode polarizations in the tissue depth, and 2) differencesin preshock tissue state. As a result of these factors, intramuralexcitable pathways leading to delayed breakthrough on the surfacewere formed earlier after shocks given to MSWs compared withSSWs and thus resulted in a lower defibrillation threshold forshocks given to SSWs.

scroll waves; isoelectric window; postshock activation; bidomain model

Address for reprint requests and other correspondence: N. Trayanova, Dept. of Biomedical Engineering, 500 Lindy Boggs Center, Suite 500, Tulane Univ., New Orleans, LA 70118 (E-mail: nataliat{at}tulane.edu).

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