Regional wall mechanics in the ischemic left ventricle: numerical modeling and dog experiments
01 Jan 1996-American Journal of Physiology-heart and Circulatory Physiology (American Physiological Society)-Vol. 270, Iss: 1
TL;DR: The mechanics of the ischemic left ventricle during a complete cardiac cycle were simulated using a finite-element model accounting for the thick-walled ventricular geometry, the fibrous nature of the myocardial tissue, and the dependency of active muscle fiber stress on time, strain, and strain rate.
Abstract: The mechanics of the ischemic left ventricle during a complete cardiac cycle were simulated using a finite-element model accounting for the thick-walled ventricular geometry, the fibrous nature of the myocardial tissue, and the dependency of active muscle fiber stress on time, strain, and strain rate. Ischemia was modeled by disabling the generation of active stress in a region comprising approximately 12% of total wall volume. In the model simulations, the approximately 12% reduction in the amount of normally contracting tissue resulted in an approximately 25% reduction in stroke work compared with the normal situation. The more-than-proportional loss of stroke work may partly be attributed to storage of elastic energy in the bulging ischemic region. Furthermore the mechanical performance in the nonischemic border zone deteriorated because of reduced systolic fiber stress (if fibers were in series with those in the ischemic region) or reduced fiber shortening (if fibers were parallel). The deformation pattern of the ventricle was asymmetric with respect to the ischemic region because of the anisotropy of the myocardial tissue. Epicardial fiber shortening in and around the ischemic region, as predicted from the model simulations, was in qualitative agreement with shortening, as measured in four dogs in which ischemia was induced by occlusion of the distal part of the left anterior interventricular coronary artery.
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TL;DR: The potential for modeling patient-specific electromechanic during ventricular pacing by means of the extension of an existing three-dimensional finite-element model of LV electromechanics with the right ventricle is demonstrated by inserting a ventricular geometry obtained from non-invasively measured short axis MR images.
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53 citations
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Cites background from "Regional wall mechanics in the isch..."
...To further elucidate the relation between myofiber mechanics and pump function, numerical models of cardiac mechanics have been designed (Vetter and McCulloch, 2000; Bovendeerd et al., 1996)....
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...Recent models of cardiac mechanics most often use finite element analysis (Vetter and McCulloch, 2000; Bovendeerd et al., 1996)....
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TL;DR: This work tested the hypothesis that infarcted myocardium must contain contracting myocytes to be akinetic and not dyskinetic, and sought to better define the contributions of passive material properties (stiffness) and active properties (contracting myocytes) to infarCT thickening.
Abstract: Infarcted segments of myocardium demonstrate functional impairment ranging in severity from hypokinesis to dyskinesis. We sought to better define the contributions of passive material properties (s...
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Cites background from "Regional wall mechanics in the isch..."
...(3) previously described a FE model of the LV with ischemic anterior wall....
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...(3) made no attempt to vary material parameters so that model-derived and experimentally measured strains were in the best possible agreement....
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TL;DR: In this article, the authors tested the hypothesis that regional end-systolic left ventricular (ESLV) wall stress is associated with extracellular matrix remodeling activity after myocardial infarction.
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Cites background from "Regional wall mechanics in the isch..."
...Local perturbations, such as ischemia or infarction, have een shown by numerous investigators to affect epicardial eformation gradients [5,6]....
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...[5] Bovendeerd PH, Arts T, Delhaas T, Huyghe JM, van Campen DH,...
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