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

Reproducible model development in the cardiac electrophysiology Web Lab by Daly, A, Clerx, M, Beattie, K, Cooper, J, Gavaghan, D, Mirams, G

“…We developed a fully-open online repository (which we termed the Cardiac Electrophysiology Web Lab) which allows users to store and compare the results of applying the same experimental protocol to competing models. …”

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

Utility and limitations of cardiac tissue slices for the study of cardiac electrophysiology by Wang, K

“…</p> <p>We conclude that the cardiac tissue slice preparation preserves some key functional parameters of the whole heart and is a promising model to study cardiac electrophysiology.</p> …”

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. …”

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. …”

Rabbit−specific ventricular model of cardiac electrophysiological function including specialized conduction system by Bordas, R, Gillow, K, Lou, Q, Efimov, I, Gavaghan, D, Kohl, P, Grau, V, Rodriguez, B

Rabbit-specific ventricular model of cardiac electrophysiological function including specialized conduction system by Bordas, R, Gillow, K, Lou, Q, Efimov, I, Gavaghan, D, Kohl, P, Grau, V, Rodriguez, B

Computational modelling of cardiac electrophysiology: Explanation of the variability of results from different numerical solvers by Pathmanathan, P, Bernabeu, M, Niederer, SA, Gavaghan, D, Kay, D

“…A recent verification study compared 11 large-scale cardiac electrophysiology solvers on an unambiguously defined common problem. …”

Computational modelling of cardiac electrophysiology: explanation of the variability of results from different numerical solvers. by Pathmanathan, P, Bernabeu, M, Niederer, SA, Gavaghan, D, Kay, D

“…A recent verification study compared 11 large-scale cardiac electrophysiology solvers on an unambiguously defined common problem. …”

Rabbit-specific ventricular model of cardiac electrophysiological function including specialized conduction system. by Bordas, R, Gillow, K, Lou, Q, Efimov, I, Gavaghan, D, Kohl, P, Grau, V, Rodriguez, B

Considerations for the use of cellular electrophysiology models within cardiac tissue simulations. by Cooper, J, Corrias, A, Gavaghan, D, Noble, D

“…The use of mathematical models to study cardiac electrophysiology has a long history, and numerous cellular scale models are now available, covering a range of species and cell types. …”

Uncertainty and variability in models of the cardiac action potential: Can we build trustworthy models? by Johnstone, R, Chang, E, Bardenet, R, de Boer, T, Gavaghan, D, Pathmanathan, P, Clayton, R, Mirams, G

“…<p>Cardiac electrophysiology models have been developed for over 50 years, and now include detailed descriptions of individual ion currents and sub-cellular calcium handling. …”

Chaste: an open source C++ library for computational physiology and biology by Mirams, G, Arthurs, C, Bernabeu, M, Bordas, R, Cooper, J, Corrias, A, Davit, Y, Dunn, S, Fletcher, A, Harvey, D, Marsh, M, Osborne, J, Pathmanathan, P, Pitt−Francis, J, Southern, J, Zemzemi, N, Gavaghan, D

“…Code development has been driven by two initial applications: cardiac electrophysiology and cancer development. A large number of cardiac electrophysiology studies have been enabled and performed, including high-performance computational investigations of defibrillation on realistic human cardiac geometries. …”

Chaste: an open source C++ library for computational physiology and biology by Mirams, G, Arthurs, C, Bernabeu, M, Bordas, R, Cooper, J, Corrias, A, Davit, Y, Dunn, S, Fletcher, A, Harvey, D, Marsh, M, Osborne, J, Pathmanathan, P, Pitt-Francis, J, Southern, J, Zemzem, N, Gavaghan, D

“…Code development has been driven by two initial applications: cardiac electrophysiology and cancer development. A large number of cardiac electrophysiology studies have been enabled and performed, including high-performance computational investigations of defibrillation on realistic human cardiac geometries. …”

Chaste: an open source C++ library for computational physiology and biology by Mirams, G, Arthurs, C, Bernabeu, M, Bordas, R, Cooper, J, Corrias, A, Davit, Y, Dunn, S, Fletcher, A, Harvey, D, Marsh, M, Osborne, J, Pathmanathan, P, Pitt-Francis, J, Southern, J, Zemzemi, N, Gavaghan, D

“…Code development has been driven by two initial applications: cardiac electrophysiology and cancer development. A large number of cardiac electrophysiology studies have been enabled and performed, including high-performance computational investigations of defibrillation on realistic human cardiac geometries. …”