Abstract
Cardiac tissue is an excitable system that can support complex spatiotemporal dynamics, including instabilities (arrhythmias) with lethal consequences. While over the last two decades optical mapping of excitation (voltage and calcium dynamics) has facilitated the detailed characterization of such arrhythmia events, until recently, no precise tools existed to actively interrogate cardiac dynamics in space and time. In this work, we discuss the combined use of new methods for space- and time-resolved optogenetic actuation and simultaneous fast, high resolution optical imaging of cardiac excitation waves. First, the mechanisms, limitations and unique features of optically-induced responses in cardiomyocytes are outlined. These include ability to bi-directionally control the membrane potential using depolarizing and hyperpolarizing opsins, and the ability to induce prolonged sustained voltage changes, control refractoriness and the shape the cardiac action potential. At the syncytial tissue level, we discuss optogenetically-enabled experimentation on cell-cell coupling, alteration of conduction properties and termination of propagating waves by light. Specific attention is given to space- and time-resolved application of optical stimulation using dynamic light patterns to perturb ongoing activation and to probe electrophysiological properties at desired tissue locations. The combined use of optical methods to perturb and to observe the system can offer new tools for precise feedback control of cardiac electrical activity, not available previously with pharmacological and electrical stimulation. These new experimental tools for all-optical electrophysiology allow for level of precise manipulation and quantification of cardiac dynamics, comparable in robustness to the computational setting, and can provide new insights into pacemaking, arrhythmogenesis and suppression/cardioversion.
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