Automatically generated‚ anatomically accurate Meshes for the Cardiac Bidomain Equations. by Trayanova, G

A bidomain model of the cardiac specialized conduction system of the heart. by Bordas, R, Gillow, K, Gavaghan, D, Rodriguez, B, Kay, D

Solving the coupled system improves computational efficiency of the bidomain equations. by Southern, J, Plank, G, Vigmond, E, Whiteley, J

“…The bidomain equations are frequently used to model the propagation of cardiac action potentials across cardiac tissue. …”

Solving the Coupled System Improves Computational Efficiency of the Bidomain Equations by Southern, J, Plank, G, Vigmond, E, Whiteley, J

“…The bidomain equations are frequently used to model the propagation of cardiac action potentials across cardiac tissue. …”

Computational and Numerical Methods for the Accurate and Efficient Solution of the Bidomain Equations by Whiteley, J

Solving the coupled system improves computational efficiency of the bidomain equations by Vigmond, J

Solving the Coupled System Improves Computational Efficiency of the Bidomain Equations by Southern, J, Plank, G, Vigmond, E, Whiteley, J

A Bidomain Model of the Ventricular Specialized Conduction System of the Heart. by Bordas, R, Gillow, K, Gavaghan, D, Rodríguez, B, Kay, D

“…An efficient bidomain model of electrical activity in cardiac specialized conduction system fibers is developed and applied to a geometric model of the specialized conduction system and the ventricles. …”

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

“…Simulation of cardiac electrical activity using the bidomain equations can be a massively computationally demanding problem. …”

A Bidomain Model of the Ventricular Specialized Conduction System of the Heart by Bordas, R, Gillow, K, Rodriguez, B, Gavaghan, D, Kay, D

Computational and Numerical Methods for the Efficient and Accurate Solution of the Bidomain Equations by 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

DERIVATION OF THE BIDOMAIN EQUATIONS FOR A BEATING HEART WITH A GENERAL MICROSTRUCTURE by Richardson, G, Chapman, S

“…The method is applied to a model of the electrical activity of cardiac myocytes and used to derive a version of the bidomain equations describing the macroscopic electrical activity of cardiac tissue. …”

Derivation of the bidomain equations for a beating heart with a general microstructure by Chapman, S

“…The method is applied to a model of the electrical activity of cardiac myocytes and used to derive a version of the bidomain equations describing the macroscopic electrical activity of cardiac tissue. …”

Stimulus protocol determines the most computationally−efficient preconditioner for the bidomain equations by Bernabeu, M, Pathmanathan, P, Pitt−Francis, J, Kay, D

Bidomain ECG Simulations Using an Augmented Monodomain Model for the Cardiac Source by Bishop, M, Plank, G

Stimulus protocol determines the most computationally−efficient preconditioner for the bidomain equations by Pitt−Francis, D

Stimulus protocol determines the most computationally efficient preconditioner for the bidomain equations. by Bernabeu, M, Pathmanathan, P, Pitt-Francis, J, Kay, D

“…The efficient solution of the bidomain equations is a fundamental tool in the field of cardiac electrophysiology. …”

Indentation of Anisotropic Tissue Using a Three-Dimensional Mechanical Bidomain Model by Dilmini Wijesinghe, Bradley J. Roth

“…Results of the tissue indentation analysis compared the spatial distribution of the magnitude of bidomain displacement for different anisotropy conditions between monodomain and bidomain models. …”
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Extended Bidomain Modeling of Defibrillation: Quantifying Virtual Electrode Strengths in Fibrotic Myocardium by Jean Bragard, Aparna C. Sankarankutty, Aparna C. Sankarankutty, Frank B. Sachse, Frank B. Sachse

“…Here, we shed light on defibrillation in the fibrotic heart. Using the extended bidomain model of electrical conduction in cardiac tissue, we assessed the influence of fibrosis on the strength of virtual electrodes caused by extracellular electrical current. …”
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