Title :
Efficient Computational Methods for Strongly Coupled Cardiac Electromechanics
Author :
Land, Sander ; Niederer, Steven A. ; Smith, Nicolas P.
Author_Institution :
Comput. Lab., Univ. of Oxford, Oxford, UK
fDate :
5/1/2012 12:00:00 AM
Abstract :
Strongly coupled cardiac electromechanical models can further our understanding of the relative importance of feedback mechanisms in the heart, but computational challenges currently remain a major obstacle, which limit their widespread use. To address this issue, we present a set of efficient computational methods including an efficient adaptive cell model integration scheme and a solution method for the monodomain equations that maintains high conduction velocity for time steps greater than 0.1 ms. We also present a novel method for increasing the efficiency of simulating electromechanical coupling, which shows a significant reduction in computational cost of the mechanical component on a personalized left ventricular geometry with an active contraction cell model reparametrized for human cells.
Keywords :
bioelectric potentials; cardiology; cellular biophysics; electromechanical effects; integration; computational methods; conduction velocity; efficient adaptive cell model integration scheme; electromechanical coupling; feedback mechanisms; heart; human cells; monodomain equations; personalized left ventricular geometry; solution method; strongly coupled cardiac electromechanics; Adaptation model; Computational modeling; Deformable models; Equations; Logic gates; Mathematical model; Numerical models; Human electromechanical model; monodomain; numerical methods; solid mechanics; Heart; Heart Conduction System; Heart Ventricles; Humans; Models, Cardiovascular; Myocardial Contraction; Ventricular Function, Left;
Journal_Title :
Biomedical Engineering, IEEE Transactions on
DOI :
10.1109/TBME.2011.2112359
