Computational simulations of idealized infarct geometries demonstrated that the choice of scar representation (insulator vs passive tissue) significantly alters action potential duration and focal ERP.
The choice of computational representation for myocardial infarct scars significantly impacts simulated electrophysiological properties and arrhythmogenesis mechanisms.
Image-based computational modeling is becoming an increasingly used clinical tool to provide insight into the mechanisms of reentrant arrhythmias. In the context of ischemic heart disease, faithful representation of the electrophysiological properties of the infarct region within models is essential, due to the scars known for arrhythmic properties. Here, we review the different computational representations of the infarcted region, summarizing the experimental measurements upon which they are based. We then focus on the two most common representations of the scar core (complete insulator or electrically passive tissue) and perform simulations of electrical propagation around idealized infarct geometries. Our simulations highlight significant differences in action potential duration and focal effective refractory period (ERP) around the scar, driven by differences in electrotonic loading, depending on the choice of scar representation. Finally, a novel mechanism for arrhythmia induction, following a focal ectopic beat, is demonstrated, which relies on localized gradients in ERP directly caused by the electrotonic sink effects of the neighboring passive scar.
Connolly et al. (Fri,) conducted a review in Ischemic heart disease with myocardial infarct scars. Computational representations of the scar core (complete insulator vs electrically passive tissue) was evaluated on Action potential duration and focal effective refractory period (ERP) around the scar. Computational simulations of idealized infarct geometries demonstrated that the choice of scar representation (insulator vs passive tissue) significantly alters action potential duration and focal ERP.