Spatiotemporal Organization of Electromechanical Phase Singularities during High-Frequency Cardiac Arrhythmias

Abstract

Ventricular fibrillation (VF) is a lifethreatening electromechanical dysfunction of the heart associated with complex spatiotemporal dynamics of electrical excitation and mechanical contraction of the heart muscle. It has been hypothesized that VF is driven by three-dimensional (3D) rotating electrical scroll waves, which can be characterized by filament-like electrical phase singularities (EPS). Recently, it was shown that rotating excitation waves during VF are associated with rotating waves of mechanical deformation. 3D mechanical scroll waves and mechanical filaments describing their rotational core were observed in the ventricles by using high-resolution ultrasound. The findings suggest that the spatiotemporal organization of cardiac fibrillation may be assessed from waves of mechanical deformation. However, the complex relationship between excitation and mechanical waves during VF is currently not understood. Here, we study the fundamental nature of mechanical phase singularities (MPS), their spatiotemporal organization and relation with EPS. We demonstrate the existence of two fundamental types of MPS: "paired singularities", which are co-localized with EPS, and "unpaired singularities", which can form independently. We show that the unpaired singularities emerge due to the anisotropy of the active force field, generated by fiber anisotropy in cardiac tissue, and the non-locality of elastic interactions, which jointly induce strong spatiotemporal inhomogeneities in the strain fields. The inhomogeneities lead to the breakup of deformation waves and create MPS, even in the absence of EPS, which are typically associated with excitation wave break. We exploit these insights to develop an approach to discriminate paired and unpaired MPS. Our findings provide a fundamental understanding of the complex spatiotemporal organization of electromechanical waves in the heart.