The significant effect of the choice of ionic current integration method in cardiac electro-physiological simulations

DOI10.1002/cnm.1438zbMath1242.92017OpenAlexW2056804845MaRDI QIDQ2892473

Jonathan P. Whiteley, Pras Pathmanathan, Gary R. Mirams, James A. Southern

Publication date: 18 June 2012

Published in: International Journal for Numerical Methods in Biomedical Engineering (Search for Journal in Brave)

Full work available at URL: https://doi.org/10.1002/cnm.1438

zbMATH Keywords

interpolation numerical methods ionic currents conduction velocity

Mathematics Subject Classification ID

Probabilistic models, generic numerical methods in probability and statistics (65C20) Biological applications of optics and electromagnetic theory (78A70) PDEs in connection with biology, chemistry and other natural sciences (35Q92) Finite element, Rayleigh-Ritz and Galerkin methods for boundary value problems involving PDEs (65N30) Biophysics (92C05) Physiology (general) (92C30)

Related Items (16)

A cardiac electromechanical model coupled with a lumped-parameter model for closed-loop blood circulation ⋮ An efficient isogeometric collocation approach to cardiac electrophysiology ⋮ The cardiovascular system: Mathematical modelling, numerical algorithms and clinical applications ⋮ Isogeometric mixed collocation of nearly-incompressible electromechanics in finite deformations for cardiac muscle simulations ⋮ Operator splitting for the bidomain model revisited ⋮ A stable loosely-coupled scheme for cardiac electro-fluid-structure interaction ⋮ Preserving the positivity of the deformation gradient determinant in intergrid interpolation by combining RBFs and SVD: Application to cardiac electromechanics ⋮ Key aspects for effective mathematical modelling of fractional-diffusion in cardiac electrophysiology: a quantitative study ⋮ An intergrid transfer operator using radial basis functions with application to cardiac electromechanics ⋮ High-Order Operator Splitting for the Bidomain and Monodomain Models ⋮ Modelling the effect of gap junctions on tissue-level cardiac electrophysiology ⋮ A curvilinear isogeometric framework for the electromechanical activation of thin muscular tissues ⋮ Incorporating inductances in tissue-scale models of cardiac electrophysiology ⋮ Multipatch isogeometric analysis for electrophysiology: simulation in a human heart ⋮ Integrated heart -- coupling multiscale and multiphysics models for the simulation of the cardiac function ⋮ Finite element and finite volume-element simulation of pseudo-ECGs and cardiac alternans

Uses Software

Chaste

Cites Work

This page was built for publication: The significant effect of the choice of ionic current integration method in cardiac electro-physiological simulations