OBJECTIVE: The purpose of this study is to ascertain the effects of spatially variable ACh distributions on arrhythmogenesis in a morphologically realistic computer model of canine atria. BACKGROUND: Vagal stimulation releases acetylcholine (ACh), which causes a dose-dependent reduction in action potential duration (APD) in the atria. Due to the nonuniform distribution of nerve endings, APD dispersion may result, which has been shown to play a role in the breakup of activity. METHODS: Reentry was initiated in a computationally efficient, morphologically realistic computer model of the atria. Discrete regions corresponding to ACh release sites, referred to as islands, were assigned shortened APDs in an ACh-dependent fashion. Island APD was varied as well as the basal APD. The window of vulnerability for ectopic beat-induction of sustained reentry was determined for both left atrial(LA) and right atrial (RA) stimulation. The resulting reentries were categorized based on type and location. RESULTS: 1) Atrial geometry severely restricts the formation of reentrant circuits. 2) Wave fractionation only occurred for large differences between island and basal APD. 3) Small ACh concentration differences produced stable figure-of-8 reentrant patterns. 4) Large islands displayed more wave breakup but could sometimes anchor reentries. CONCLUSIONS: Large APD gradients produced by ACh heterogeneity can lead to a breakdown of organized activity.
OBJECTIVE: The purpose of this study is to ascertain the effects of spatially variable ACh distributions on arrhythmogenesis in a morphologically realistic computer model of canine atria. BACKGROUND: Vagal stimulation releases acetylcholine (ACh), which causes a dose-dependent reduction in action potential duration (APD) in the atria. Due to the nonuniform distribution of nerve endings, APD dispersion may result, which has been shown to play a role in the breakup of activity. METHODS: Reentry was initiated in a computationally efficient, morphologically realistic computer model of the atria. Discrete regions corresponding to ACh release sites, referred to as islands, were assigned shortened APDs in an ACh-dependent fashion. Island APD was varied as well as the basal APD. The window of vulnerability for ectopic beat-induction of sustained reentry was determined for both left atrial(LA) and right atrial (RA) stimulation. The resulting reentries were categorized based on type and location. RESULTS: 1) Atrial geometry severely restricts the formation of reentrant circuits. 2) Wave fractionation only occurred for large differences between island and basal APD. 3) Small ACh concentration differences produced stable figure-of-8 reentrant patterns. 4) Large islands displayed more wave breakup but could sometimes anchor reentries. CONCLUSIONS: Large APD gradients produced by ACh heterogeneity can lead to a breakdown of organized activity.
Authors: M Zarzoso; L Such-Miquel; G Parra; L Brines-Ferrando; L Such; F J Chorro; J Guerrero; A Guill; J E O'Connor; A Alberola Journal: Eur J Appl Physiol Date: 2011-10-04 Impact factor: 3.078