Trapped re-entry challenges the binary view on cardiac arrhythmias

Abstract

Abstract Background There is currently a binary view on cardiac arrhythmias: (1) arrhythmias are present and thereby affect the atria or ventricles as a whole, or (2) they are not present and therefore the heart is in sinus rhythm. However, complex fractionated atrial electrograms (CFAEs) under sinus rhythm (SR) are observed in patients with atrial fibrillation (AF), raising the question whether both cardiac states (arrhythmia and SR) could coexist. Although CFAEs in AF patients have been associated with functional and structural heterogeneities (e.g. dense fibrotic regions), the underlying mechanisms of fractionation under SR remain incompletely understood. Purpose To test the hypothesis that an arrhythmia can exist locally with the majority of cardiac tissue in sinus rhythm, made possible through dense local fibrotic regions forming a small electrically isolated re-entrant circuit that can "trap" excitation waves, which can only be "released" under dynamic tissue changes at an isthmus connected to the bulk of the tissue. Methods By harnessing the unique possibilities of light-gated depolarizing ion channels (CatCh) to precisely control in vitro cardiac excitability in time and space, complemented with advanced computational modelling of whole human atria, we explored the geometry of such an electrically isolated circuit and assessed its clinical relevance. Results Optical mapping studies, in monolayers of CatCh-activated neonatal rat atrial cardiomyocytes (n=8), revealed that re-entry can be established and trapped by creating an electrically isolated pathway with a bulk-connecting isthmus causing source-sink mismatch. A tachyarrhythmia was shown to exist locally with SR prevailing in the bulk of the monolayer. Next, conditions were found under which re-entry could escape this pathway, thereby converting a local dormant arrhythmic source into an active driver with global impact. Escape could be established by overcoming the source-sink mismatch through widening of the isthmus or a reduction of the gap junctional coupling. In a digital twin of the human atria, it was revealed that the conditions for "trapped re-entry" and its release can be realized as well. Unipolar pseudo-electrograms derived from these complementary computational 3D studies showed CFAEs at the site of "trapped re-entry" in coexistence with normal electrograms of SR in the bulk of the atria. Upon release of the re-entry, acute arrhythmia onset occurred, affecting the complete atria as evidenced by wave front and electrogram visualization. Conclusion Through the concept of "trapped re-entry", we not only present a new mechanism of acute manifestation of focal tachyarrhythmias, but also provide novel insight into the origin of fractionated electrograms. This insight may provide new rationales for treatment of cardiac arrhythmias, especially for ablation by site-directed targeting.Trapped re-entry in vitro and in silico