A model for human ventricular tissue KHWJ Ten Tusscher, D Noble, PJ Noble, AV Panfilov American Journal of Physiology-Heart and Circulatory Physiology 286 (4 …, 2004 | 1808 | 2004 |
Alternans and spiral breakup in a human ventricular tissue model KHWJ Ten Tusscher, AV Panfilov American Journal of Physiology-Heart and Circulatory Physiology 291 (3 …, 2006 | 1327 | 2006 |
A simple two-variable model of cardiac excitation RR Aliev, AV Panfilov Chaos, Solitons & Fractals 7 (3), 293-301, 1996 | 1066 | 1996 |
Models of cardiac tissue electrophysiology: progress, challenges and open questions RH Clayton, O Bernus, EM Cherry, H Dierckx, FH Fenton, L Mirabella, ... Progress in biophysics and molecular biology 104 (1-3), 22-48, 2011 | 711 | 2011 |
Mechanisms of cardiac fibrillation RA Gray, J Jalife, AV Panfilov, WT Baxter, C Cabo, JM Davidenko, ... Science 270 (5239), 1222-1223, 1995 | 589 | 1995 |
Electromechanical model of excitable tissue to study reentrant cardiac arrhythmias MP Nash, AV Panfilov Progress in biophysics and molecular biology 85 (2-3), 501-522, 2004 | 512 | 2004 |
Nonstationary vortex like reentrant activity as a mechanism of polymorphic ventricular tachycardia in the isolated rabbit heart J Jalife, A Panfilov Circulation 91, 2454-2469, 1995 | 375 | 1995 |
Spiral breakup as a model of ventricular fibrillation AV Panfilov Chaos: An Interdisciplinary Journal of Nonlinear Science 8 (1), 57-64, 1998 | 283 | 1998 |
A guide to modelling cardiac electrical activity in anatomically detailed ventricles RH Clayton, AV Panfilov Progress in biophysics and molecular biology 96 (1-3), 19-43, 2008 | 260 | 2008 |
Cell model for efficient simulation of wave propagation in human ventricular tissue under normal and pathological conditions KHWJ Ten Tusscher, AV Panfilov Physics in Medicine & Biology 51 (23), 6141, 2006 | 248 | 2006 |
Computational biology of the heart AV Panfilov, AV Holden (No Title), 1997 | 222 | 1997 |
Organization of ventricular fibrillation in the human heart KHWJ Ten Tusscher, R Hren, AV Panfilov Circulation research 100 (12), e87-e101, 2007 | 212 | 2007 |
A computationally efficient electrophysiological model of human ventricular cells O Bernus, R Wilders, CW Zemlin, H Verschelde, AV Panfilov American Journal of Physiology-Heart and Circulatory Physiology 282 (6 …, 2002 | 211 | 2002 |
Spiral breakup in a modified FitzHugh-Nagumo model A Panfilov, P Hogeweg Physics Letters A 176 (5), 295-299, 1993 | 203 | 1993 |
Rotating spiral waves created by geometry K Agladze, JP Keener, SC Müller, A Panfilov Science 264 (5166), 1746-1748, 1994 | 189 | 1994 |
Influence of diffuse fibrosis on wave propagation in human ventricular tissue KHWJ Ten Tusscher, AV Panfilov Europace 9 (suppl_6), vi38-vi45, 2007 | 167 | 2007 |
Modelling of the ventricular conduction system K Ten Tusscher, AV Panfilov Progress in biophysics and molecular biology 96 (1-3), 152-170, 2008 | 163 | 2008 |
Comparison of electrophysiological models for human ventricular cells and tissues KHWJ Ten Tusscher, O Bernus, AV Panfilov Progress in biophysics and molecular biology 90 (1-3), 326-345, 2006 | 151 | 2006 |
Rotating spiral waves in a modified Fitz-Hugh-Nagumo model AM Pertsov, EA Ermakova, AV Panfilov Physica D: Nonlinear Phenomena 14 (1), 117-124, 1984 | 139 | 1984 |
Drift and breakup of spiral waves in reaction–diffusion–mechanics systems AV Panfilov, RH Keldermann, MP Nash Proceedings of the National Academy of Sciences 104 (19), 7922-7926, 2007 | 136 | 2007 |