A comparison of discrete and continuum models of cardiac electrophysiology by Bruce, D

Subjects: “…Cardiac Electrophysiology…”

numerical guide to the solution of the bidomain equations of cardiac electrophysiology by Pathmanathan, P, Bernabeu, M, Bordas, R, Cooper, J, Garny, A, Pitt−Francis, J, Whiteley, J, Gavaghan, D

Modelling the effect of gap junctions on tissue−level cardiac electrophysiology by Bruce, D, Pathmanathan, P, Whiteley, J

Modelling the effect of gap junctions on tissue–level cardiac electrophysiology by Bruce, D, Pathmanathan, P, Whiteley, J

A numerical guide to the solution of the bidomain equations of cardiac electrophysiology by Pathmanathan, P, Bernabeu, M, Bordas, R, Cooper, J, Garny, A, Pitt-Francis, J, Whiteley, J, Gavaghan, D

A numerical guide to the solution of the bidomain equations of cardiac electrophysiology by Pathmanathan, P, Bernabeu, M, Bordas, R, Cooper, J, Garny, A, Pitt−Francis, J, Whiteley, J, Gavaghan, D

POSTERIORI ERROR ANALYSIS FOR THE USE OF LOOKUP TABLES IN CARDIAC ELECTROPHYSIOLOGY SIMULATIONS by Cooper, J, Whiteley, J, Gavaghan, D

“…A common example is the use of lookup tables to approximate computationally intensive expressions in cardiac electrophysiology cell models, which are given mathematically as systems of ordinary differential equations. …”

A numerical guide to the solution of the bi-domain equations of cardiac electrophysiology. by Pathmanathan, P, Bernabeu, M, Bordas, R, Cooper, J, Garny, A, Pitt-Francis, J, Whiteley, J, Gavaghan, D

Representation of multiple cellular phenotypes within tissue-level simulations of cardiac electrophysiology by Gavaghan, D, Bowler, L, Mirams, G, Whiteley, J

“…The usual approach when simulating the cardiac electrophysiology of tissue that includes different cell types is to model the different cell types as occupying spatially distinct yet coupled regions. …”

The significant effect of the choice of ionic current integration method in cardiac electrophysiological simulations by Southern, P, Whiteley, J

A posteriori error analysis for the use of lookup tables in cardiac electrophysiology simulations by Cooper, J, Whiteley, J, Gavaghan, D

A POSTERIORI ERROR ANALYSIS FOR THE USE OF LOOKUP TABLES IN CARDIAC ELECTROPHYSIOLOGY SIMULATIONS by Cooper, J, Whiteley, J, Gavaghan, D

“…A common example is the use of lookup tables to approximate computationally intensive expressions in cardiac electrophysiology cell models, which are given mathematically as systems of ordinary differential equations. …”

A Numerical Method for Coupled Cardiac Electro-Mechanical Simulations by Whiteley, J, Pathmanathan, P, Simos, T

“…This tension is a result of biochemical reactions that occur as part of cardiac electrophysiology. This coupled electro-mechanical system is usually modelled by coupling a model of tissue deformation with a tissue level model of cardiac electrophysiology such as the bidomain equations [1]. …”

A numerical method for cardiac mechanoelectric simulations. by Pathmanathan, P, Whiteley, J

“…Much effort has been devoted to developing numerical techniques for solving the equations that describe cardiac electrophysiology, namely the monodomain equations and bidomain equations. …”

A Numerical Method for Cardiac Mechanoelectric Simulations by Pathmanathan, P, Whiteley, J

“…Much effort has been devoted to developing numerical techniques for solving the equations that describe cardiac electrophysiology, namely the monodomain equations and bidomain equations. …”

CARDIAC ELECTROMECHANICS: THE EFFECT OF CONTRACTION MODEL ON THE MATHEMATICAL PROBLEM AND ACCURACY OF THE NUMERICAL SCHEME by Pathmanathan, P, Chapman, S, Gavaghan, D, Whiteley, J

“…All contraction models are dependent on cardiac electrophysiology but can also be dependent on the stretch and stretch rate in the fibre direction. …”

Model reduction using a posteriori analysis by Whiteley, J

“…The technique presented is demonstrated by application to a model problem, and then to automatically deduce known results from a cell–level cardiac electrophysiology model.…”

Model reduction using a posteriori analysis. by Whiteley, J

“…The technique presented is demonstrated by application to a model problem, and then to automatically deduce known results from a cell-level cardiac electrophysiology model.…”

Model reduction for initial value ODEs by Ambuehl, A, Whiteley, J

“…These extensions are illustrated using examples drawn from enzyme kinetics and cardiac electrophysiology.…”

CARDIAC ELECTROMECHANICS: THE EFFECT OF CONTRACTION MODEL ON THE MATHEMATICAL PROBLEM AND ACCURACY OF THE NUMERICAL SCHEME by Pathmanathan, P, Chapman, S, Gavaghan, D, Whiteley, J

“…All contraction models are dependent on cardiac electrophysiology but can also be dependent on the stretch and stretch rate in the fibre direction. …”