2017
DOI: 10.1098/rsos.170024
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Mechanisms of vortices termination in the cardiac muscle

Abstract: We propose a solution to a long-standing problem: how to terminate multiple vortices in the heart, when the locations of their cores and their critical time windows are unknown. We scan the phases of all pinned vortices in parallel with electric field pulses (E-pulses). We specify a condition on pacing parameters that guarantees termination of one vortex. For more than one vortex with significantly different frequencies, the success of scanning depends on chance, and all vortices are terminated with a success … Show more

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Cited by 25 publications
(23 citation statements)
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“…In these papers, it was demonstrated that vortices that were assumed to be pinned at larger heterogeneities in cardiac tissue are best terminated if the pacing frequency in a LEAP procedure is set to be 80 -90% of the dominant frequency (the rotation frequency of the vortex around the pinning site). Such a choice of pacing frequency allows for an efficient scanning of the phase of the vortex in order to find the vulnerable window for vortex termination 27,28 . A simulation study in a realistic three-dimensional cardiac geometry demonstrated for selected examples that LEAP works for a pacing period of 88% of the VF cycle length, but often fails for much faster pacing with a period of 16% of the VF cycle length 29 .…”
Section: Introductionmentioning
confidence: 99%
“…In these papers, it was demonstrated that vortices that were assumed to be pinned at larger heterogeneities in cardiac tissue are best terminated if the pacing frequency in a LEAP procedure is set to be 80 -90% of the dominant frequency (the rotation frequency of the vortex around the pinning site). Such a choice of pacing frequency allows for an efficient scanning of the phase of the vortex in order to find the vulnerable window for vortex termination 27,28 . A simulation study in a realistic three-dimensional cardiac geometry demonstrated for selected examples that LEAP works for a pacing period of 88% of the VF cycle length, but often fails for much faster pacing with a period of 16% of the VF cycle length 29 .…”
Section: Introductionmentioning
confidence: 99%
“…The mechanism of arrhythmia termination was confirmed by optical mapping [13]. A deep understanding of how pinned 2-dimensional vortices can be terminated currently exists [10].…”
mentioning
confidence: 87%
“…These two waves annihilate and disappear, see e.g., Fig. 4d in [10]. This type of wave behavior is not possible in classical mechanics with the energy conservation law.…”
mentioning
confidence: 96%
“…In 2D, the interaction of the waves launched by the electric field with the rotating waves depends on the location of the rotating waves and where the waves are in their rotation when the electric field pulse is applied [6,7]. In contrast, in 3D, if a significant component of the electric field pulse is oriented along the axis of rotation of the rotating wave, then the result is, at some fundamental level, independent of where the wave is in its rotation [8,9].…”
Section: Motivation and Methodsmentioning
confidence: 99%