INTRODUCTION: Reflection is a special type of reentry in which an electrical wave front travels in a forward direction through tissue that is then re-excited by a wave front that propagates backward. This type of reentry has been studied computationally in 1-dimensional fibers and verified experimentally. Different hypotheses explaining reflected reentry have been proposed based on the structure and heterogeneity of the tissue properties, but the mechanism remains uncertain. METHODS AND RESULTS: We used the bidomain model to represent cardiac tissue and the Luo-Rudy model to describe the active membrane properties. We consider an ischemic region in a volume of ventricular myocardium. Our results show that a slow depolarization in the ischemic border zone caused by electrotonic coupling to depolarized tissue in the normal region creates a delay between proximal and distal regions that produces enough electrotonic current in the distal region to re-excite the proximal region. CONCLUSION: Our simulation shows that an early afterdepolarization (EAD) is not the source of the reflection. It depends on the pacing interval and stimulus strength necessary to maintain enough time delay between proximal and distal regions.
INTRODUCTION: Reflection is a special type of reentry in which an electrical wave front travels in a forward direction through tissue that is then re-excited by a wave front that propagates backward. This type of reentry has been studied computationally in 1-dimensional fibers and verified experimentally. Different hypotheses explaining reflected reentry have been proposed based on the structure and heterogeneity of the tissue properties, but the mechanism remains uncertain. METHODS AND RESULTS: We used the bidomain model to represent cardiac tissue and the Luo-Rudy model to describe the active membrane properties. We consider an ischemic region in a volume of ventricular myocardium. Our results show that a slow depolarization in the ischemic border zone caused by electrotonic coupling to depolarized tissue in the normal region creates a delay between proximal and distal regions that produces enough electrotonic current in the distal region to re-excite the proximal region. CONCLUSION: Our simulation shows that an early afterdepolarization (EAD) is not the source of the reflection. It depends on the pacing interval and stimulus strength necessary to maintain enough time delay between proximal and distal regions.
Authors: M J Janse; F J van Capelle; H Morsink; A G Kléber; F Wilms-Schopman; R Cardinal; C N d'Alnoncourt; D Durrer Journal: Circ Res Date: 1980-08 Impact factor: 17.367
Authors: Kornél Kistamás; Roland Veress; Balázs Horváth; Tamás Bányász; Péter P Nánási; David A Eisner Journal: Front Pharmacol Date: 2020-02-25 Impact factor: 5.810
Authors: Richard D Walton; Ali Pashaei; Marine E Martinez; Marion Constantin; Josselin Duchateau; Laura Bear; Caroline Cros; Caroline Pascarel-Auclerc; Yunbo Guo; David Benoist; Virginie Dubes; Ndeye Rokhaya Faye; Sebastien Chaigne; Sebastien Dupuis; Dominique Détaille; Line Pourtau; Philippe Pasdois; Fabien Brette; Julien Rogier; Louis Labrousse; Mélèze Hocini; Edward J Vigmond; Michel Haïssaguerre; Olivier Bernus Journal: Circ Arrhythm Electrophysiol Date: 2018-08