The authors create a modeling framework that treats the graft-host interface as a controllable boundary with specific conductance to investigate conditions under which spontaneous graft activity excites the host ventricular tissue.
The openCARP Simulation Environment for Cardiac Electrophysiology
2 Pith papers cite this work. Polarity classification is still indexing.
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UNVERDICTED 2representative citing papers
Physics-informed neural operators accurately reproduce cardiac electrophysiology dynamics over long horizons, generalize to unseen conditions and higher resolutions, and run faster than traditional numerical solvers.
citing papers explorer
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Modelling the electrophysiological interactions between human pluripotent cell-derived cardiomyocite grafts and host ventricular tissue
The authors create a modeling framework that treats the graft-host interface as a controllable boundary with specific conductance to investigate conditions under which spontaneous graft activity excites the host ventricular tissue.
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Physics-Informed Neural Operators for Cardiac Electrophysiology
Physics-informed neural operators accurately reproduce cardiac electrophysiology dynamics over long horizons, generalize to unseen conditions and higher resolutions, and run faster than traditional numerical solvers.