Termination of Reentry by a Long-Lasting AC Shock in a Slice of Canine Heart: A Computational Study

AC Cardioversion in a Canine Slice. Introduction: A heart in fibrillation can be entrained by long‐lasting alternating current (AC) stimuli, leading to defibrillation. To investigate the role entrainment plays in defibrillation, computer simulations of AC cardioversion in a three‐dimensional slice o...

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Bibliographic Details
Published in:Journal of cardiovascular electrophysiology 2002-12, Vol.13 (12), p.1253-1261
Main Authors: MEUNIER, JASON M., EASON, JAMES C., TRAYANOVA, NATALIA A.
Format: Article
Language:English
Subjects:
alternating current cardioversion
Animals
canine heart
Computer Simulation
Dogs
Electric Countershock - instrumentation
Electricity
Electrodes
Electrophysiology
Finite Element Analysis
Heart - physiopathology
In Vitro Techniques
Models, Cardiovascular
User-Computer Interface
virtual electrode polarization
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Summary:AC Cardioversion in a Canine Slice. Introduction: A heart in fibrillation can be entrained by long‐lasting alternating current (AC) stimuli, leading to defibrillation. To investigate the role entrainment plays in defibrillation, computer simulations of AC cardioversion in a three‐dimensional slice of the canine heart were performed. Methods and Results: A bidomain finite element model of a 1‐mm thick slice across the ventricles of a canine heart was used to simulate termination of transmural reentry with AC shocks. Cardioversion defibrillation thresholds (DFTs) were determined for 200‐msec (L) AC shocks at varying frequencies. At the DFT, the entire tissue is entrained by the AC shock. DFT decreases as the frequency of the long‐lasting AC shock increases. We hypothesize that this decrease is due to the short period of the high‐frequency AC waveform, leaving strong virtual electrode polarization (VEP) after the shock ends. To test this hypothesis, the end‐shock VEP were compared for different frequencies, demonstrating stronger polarization as frequency increased. To examine whether entrainment by the long‐lasting AC shock contributes to the VEP at the end of the shock, additional simulations were conducted using single‐period (Z) AC waveforms. Z waveform DFTs were higher than L waveform DFTs; the Z waveform VEP was weaker than the L waveform VEP at the same frequency. This indicates that entrainment contributes to the development of stronger VEP and, thus, to lower DFT at high frequencies. Conclusion: This study offers for the first time a mechanistic insight into cardioversion with long‐lasting AC shocks.
ISSN:1045-3873
1540-8167
DOI:10.1046/j.1540-8167.2002.01253.x