Electromechanics of the heart: a unified approach to the strongly coupled excitation–contraction problem

This manuscript is concerned with a novel, unified finite element approach to fully coupled cardiac electromechanics. The intrinsic coupling arises from both the excitation-induced contraction of cardiac cells and the deformation-induced generation of current due to the opening of ion channels. In contrast to the existing numerical approaches suggested in the literature, which devise staggered algorithms through distinct numerical methods for the respective electrical and mechanical problems, we propose a fully implicit, entirely finite element-based modular approach. To this end, the governing differential equations that are coupled through constitutive equations are recast into the corresponding weak forms through the conventional isoparametric Galerkin method. The resultant non-linear weighted residual terms are then consistently linearized. The system of coupled algebraic equations obtained through discretization is solved monolithically. The put-forward modular algorithmic setting leads to an unconditionally stable and geometrically flexible framework that lays a firm foundation for the extension of constitutive equations towards more complex ionic models of cardiac electrophysiology and the strain energy functions of cardiac mechanics. The performance of the proposed approach is demonstrated through three-dimensional illustrative initial boundary-value problems that include a coupled electromechanical analysis of a biventricular generic heart model.

[1]  A. Hodgkin,et al.  A quantitative description of membrane current and its application to conduction and excitation in nerve , 1952, The Journal of physiology.

[2]  R. FitzHugh Impulses and Physiological States in Theoretical Models of Nerve Membrane. , 1961, Biophysical journal.

[3]  D. Noble A modification of the Hodgkin—Huxley equations applicable to Purkinje fibre action and pacemaker potentials , 1962, The Journal of physiology.

[4]  A.J.M. Spencer,et al.  Theory of invariants , 1971 .

[5]  G. W. Beeler,et al.  Reconstruction of the action potential of ventricular myocardial fibres , 1977, The Journal of physiology.

[6]  J J Heger,et al.  Sudden cardiac death. , 1998, Circulation.

[7]  P. Hunter,et al.  Mathematical model of geometry and fibrous structure of the heart. , 1991, The American journal of physiology.

[8]  C. Luo,et al.  A model of the ventricular cardiac action potential. Depolarization, repolarization, and their interaction. , 1991, Circulation research.

[9]  A. McCulloch,et al.  Nonuniform Muscle Fiber Orientation Causes Spiral Wave Drift in a Finite Element Model of Cardiac Action Potential Propagation , 1994, Journal of cardiovascular electrophysiology.

[10]  R. Aliev,et al.  A simple two-variable model of cardiac excitation , 1996 .

[11]  R. Judd,et al.  Compressibility of perfused passive myocardium. , 1996, The American journal of physiology.

[12]  F. Fenton,et al.  Vortex dynamics in three-dimensional continuous myocardium with fiber rotation: Filament instability and fibrillation. , 1998, Chaos.

[13]  Lionel H. Opie,et al.  Heart Physiology: From Cell to Circulation , 2003 .

[14]  James P. Keener,et al.  Mathematical physiology , 1998 .

[15]  P. Hunter,et al.  Stretch-induced changes in heart rate and rhythm: clinical observations, experiments and mathematical models. , 1999, Progress in biophysics and molecular biology.

[16]  P. Hunter,et al.  Computational Mechanics of the Heart , 2000 .

[17]  P. Hunter,et al.  Computational mechanics of the heart : From tissue structure to ventricular function , 2000 .

[18]  George A. Mensah,et al.  Sudden Cardiac Death in the United States, 1989 to 1998 , 2001, Circulation.

[19]  D. Bers Cardiac excitation–contraction coupling , 2002, Nature.

[20]  A. McCulloch,et al.  Computational model of three-dimensional cardiac electromechanics , 2002 .

[21]  J. Rogers Wave front fragmentation due to ventricular geometry in a model of the rabbit heart. , 2002, Chaos.

[22]  F. Fenton,et al.  Multiple mechanisms of spiral wave breakup in a model of cardiac electrical activity. , 2002, Chaos.

[23]  Frank B. Sachse,et al.  Computational Cardiology , 2004, Lecture Notes in Computer Science.

[24]  M. Nash,et al.  Electromechanical model of excitable tissue to study reentrant cardiac arrhythmias. , 2004, Progress in biophysics and molecular biology.

[25]  M P Nash,et al.  Self-organized pacemakers in a coupled reaction-diffusion-mechanics system. , 2005, Physical review letters.

[26]  P. Hunter,et al.  New developments in a strongly coupled cardiac electromechanical model. , 2005, Europace : European pacing, arrhythmias, and cardiac electrophysiology : journal of the working groups on cardiac pacing, arrhythmias, and cardiac cellular electrophysiology of the European Society of Cardiology.

[27]  Hervé Delingette,et al.  Simulation of cardiac pathologies using an electromechanical biventricular model and XMR interventional imaging , 2005, Medical Image Anal..

[28]  D. Chapelle,et al.  MODELING AND ESTIMATION OF THE CARDIAC ELECTROMECHANICAL ACTIVITY , 2006 .

[29]  Peter J. Hunter,et al.  Computational multiscale modeling in the IUPS Physiome Project: Modeling cardiac electromechanics , 2006, IBM J. Res. Dev..

[30]  Roy C. P. Kerckhoffs,et al.  Computational Methods for Cardiac Electromechanics , 2006, Proceedings of the IEEE.

[31]  J. NAGUMOt,et al.  An Active Pulse Transmission Line Simulating Nerve Axon , 2006 .

[32]  M P Nash,et al.  Drift and breakup of spiral waves in reaction–diffusion–mechanics systems , 2007, Proceedings of the National Academy of Sciences.

[33]  Damien Rohmer,et al.  Reconstruction and Visualization of Fiber and Laminar Structure in the Normal Human Heart from Ex Vivo Diffusion Tensor Magnetic Resonance Imaging (DTMRI) Data , 2007, Investigative radiology.

[34]  Martyn P. Nash,et al.  Pacemakers in a Reaction-Diffusion Mechanics System , 2007 .

[35]  S. Niederer,et al.  An improved numerical method for strong coupling of excitation and contraction models in the heart. , 2008, Progress in biophysics and molecular biology.

[36]  A V Panfilov,et al.  A guide to modelling cardiac electrical activity in anatomically detailed ventricles. , 2008, Progress in biophysics and molecular biology.

[37]  Gregory B. Sands,et al.  Three-dimensional transmural organization of perimysial collagen in the heart , 2008, American journal of physiology. Heart and circulatory physiology.

[38]  A. Panfilov,et al.  Modelling of the ventricular conduction system. , 2008, Progress in biophysics and molecular biology.

[39]  Gerhard A Holzapfel,et al.  Constitutive modelling of passive myocardium: a structurally based framework for material characterization , 2009, Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences.

[40]  David Gavaghan,et al.  Generation of histo-anatomically representative models of the individual heart: tools and application , 2009, Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences.

[41]  S. Göktepe,et al.  Computational modeling of cardiac electrophysiology: A novel finite element approach , 2009 .

[42]  S. Göktepe,et al.  Computational modeling of electrocardiograms: A finite element approach toward cardiac excitation , 2010 .

[43]  S. Göktepe,et al.  Atrial and ventricular fibrillation: computational simulation of spiral waves in cardiac tissue , 2010 .

[44]  R. Klabunde,et al.  Comprar Cardiovascular Physiology Concepts | Richard E. Klabunde | 9781451113846 | Lippincott Williams & Wilkins , 2011 .