Control of Action Potential Duration Alternans in Canine Cardiac Ventricular Tissue

Cardiac electrical alternans, characterized by a beat-to-beat alternation in action potential waveform, is a naturally occurring phenomenon, which can occur at sufficiently fast pacing rates. Its presence has been putatively linked to the onset of cardiac reentry, which is a precursor to ventricular fibrillation. Previous studies have shown that closed-loop alternans control techniques that apply a succession of externally administered cycle perturbations at a single site provide limited spatially-extended alternans elimination in sufficiently large cardiac substrates. However, detailed experimental investigations into the spatial dynamics of alternans control have been restricted to Purkinje fiber studies. A complete understanding of alternans control in the more clinically relevant ventricular tissue is needed. In this paper, we study the spatial dynamics of alternans and alternans control in arterially perfused canine right ventricular preparations using an optical mapping system capable of high-resolution fluorescence imaging. Specifically, we quantify the spatial efficacy of alternans control along 2.5 cm of tissue, focusing on differences in spatial control between different subregions of tissue. We demonstrate effective control of spatially-extended alternans up to 2.0 cm, with control efficacy attenuating as a function of distance. Our results provide a basis for future investigations into electrode-based control interventions of alternans in cardiac tissue.

[1]  D. Connelly Implantable cardioverter-defibrillators , 2001, Heart.

[2]  R A Bassani,et al.  Temperature and relative contributions of Ca transport systems in cardiac myocyte relaxation. , 1996, The American journal of physiology.

[3]  M R Gold,et al.  A comparison of T-wave alternans, signal averaged electrocardiography and programmed ventricular stimulation for arrhythmia risk stratification. , 2000, Journal of the American College of Cardiology.

[4]  Eberhard Bodenschatz,et al.  Spatiotemporal Transition to Conduction Block in Canine Ventricle , 2002, Circulation research.

[5]  D. Rosenbaum,et al.  Role of Structural Barriers in the Mechanism of Alternans-Induced Reentry , 2000, Circulation research.

[6]  H M Hastings,et al.  Mechanisms for Discordant Alternans , 2001, Journal of cardiovascular electrophysiology.

[7]  Daniel J. Gauthier,et al.  Comment on ``Dynamic Control of Cardiac Alternans'' , 1997 .

[8]  D. Rosenbaum,et al.  Modulation of ventricular repolarization by a premature stimulus. Role of epicardial dispersion of repolarization kinetics demonstrated by optical mapping of the intact guinea pig heart. , 1996, Circulation research.

[9]  A. Karma Electrical alternans and spiral wave breakup in cardiac tissue. , 1994, Chaos.

[10]  Gil Bub,et al.  Dynamical Mechanism for Subcellular Alternans in Cardiac Myocytes , 2009, Circulation research.

[11]  I. Efimov,et al.  Application of blebbistatin as an excitation-contraction uncoupler for electrophysiologic study of rat and rabbit hearts. , 2007, Heart rhythm.

[12]  J. Goldberger Treatment and prevention of sudden cardiac death: effect of recent clinical trials. , 1999, Archives of internal medicine.

[13]  J. Ruskin,et al.  Electrical alternans and vulnerability to ventricular arrhythmias. , 1994, The New England journal of medicine.

[14]  R J Cohen,et al.  T-wave alternans and dispersion of the QT interval as risk stratification markers in patients susceptible to sustained ventricular arrhythmias. , 1998, The American journal of cardiology.

[15]  R J Cohen,et al.  T Wave Alternans as a Predictor of Recurrent Ventricular Tachyarrhythmias in ICD Recipients: Prospective Comparison with Conventional Risk Markers , 1998, Journal of cardiovascular electrophysiology.

[16]  Edward Ott,et al.  Controlling chaos , 2006, Scholarpedia.

[17]  Harold Bien,et al.  Macroscopic optical mapping of excitation in cardiac cell networks with ultra-high spatiotemporal resolution. , 2006, Progress in biophysics and molecular biology.

[18]  Ying-Cheng Lai,et al.  Controlling chaos , 1994 .

[19]  J. Nolasco,et al.  A graphic method for the study of alternation in cardiac action potentials. , 1968, Journal of applied physiology.

[20]  A. M. Scher,et al.  Effect of Tissue Anisotropy on Extracellular Potential Fields in Canine Myocardium in Situ , 1982, Circulation research.

[21]  D. Roden,et al.  Virtual cathode effects during stimulation of cardiac muscle. Two-dimensional in vivo experiments. , 1991, Circulation research.

[22]  G. Salama,et al.  Optical Imaging of the Heart , 2004, Circulation research.

[23]  Robert F Gilmour,et al.  Control of electrical alternans in canine cardiac purkinje fibers. , 2006, Physical review letters.

[24]  L A Geddes,et al.  Therapeutic indices for transchest defibrillator shocks: effective, damaging, and lethal electrical doses. , 1980, American heart journal.

[25]  D. T. Kaplan,et al.  Repolarization Inhomogeneities in Ventricular Myocardium Change Dynamically With Abrupt Cycle Length Shortening , 1991, Circulation.

[26]  A. Tonkin,et al.  Passive ventricular constraint amends the course of heart failure: a study in an ovine model of dilated cardiomyopathy. , 1999, Cardiovascular research.

[27]  Daniel J Gauthier,et al.  Experimental control of cardiac muscle alternans. , 2002, Physical review letters.

[28]  L. Glass,et al.  DYNAMIC CONTROL OF CARDIAC ALTERNANS , 1997 .

[29]  P M Rautaharju,et al.  Ventricular action potentials, ventricular extracellular potentials, and the ECG of guinea pig. , 1985, Circulation research.

[30]  Shahriar Iravanian,et al.  Optical mapping system with real-time control capability. , 2007, American journal of physiology. Heart and circulatory physiology.

[31]  N. Smedira,et al.  Global surgical experience with the Acorn cardiac support device. , 2003, The Journal of thoracic and cardiovascular surgery.

[32]  A. Garfinkel,et al.  Dynamic origin of spatially discordant alternans in cardiac tissue. , 2006, Biophysical journal.

[33]  A. M. Scher,et al.  Influence of Cardiac Fiber Orientation on Wavefront Voltage, Conduction Velocity, and Tissue Resistivity in the Dog , 1979, Circulation research.

[34]  Raymond E Ideker,et al.  Do clinically relevant transthoracic defibrillation energies cause myocardial damage and dysfunction? , 2003, Resuscitation.

[35]  S. Hohnloser,et al.  Predictive value of T-wave alternans for arrhythmic events in patients with congestive heart failure , 2000, The Lancet.

[36]  D. Rosenbaum,et al.  Mechanism linking T-wave alternans to the genesis of cardiac fibrillation. , 1999, Circulation.

[37]  Blas Echebarria,et al.  Spatiotemporal control of cardiac alternans. , 2002, Chaos.

[38]  S. Dunbar Psychosocial issues of patients with implantable cardioverter defibrillators. , 2005, American journal of critical care : an official publication, American Association of Critical-Care Nurses.

[39]  R. Goldberg,et al.  Psychiatric morbidity following implantation of the automatic implantable cardioverter defibrillator. , 1991, Psychosomatics.

[40]  A. Garfinkel,et al.  Mechanisms of Discordant Alternans and Induction of Reentry in Simulated Cardiac Tissue , 2000, Circulation.

[41]  R. Milne,et al.  Implantable cardioverter-defibrillators in arrhythmias: a rapid and systematic review of effectiveness , 2002, Heart.

[42]  K Hall,et al.  Restricted feedback control of one-dimensional maps. , 2001, Physical review. E, Statistical, nonlinear, and soft matter physics.

[43]  B. Hoffman,et al.  Effect of heart rate on cardiac membrane potentials and the unipolar electrogram. , 1954, The American journal of physiology.

[44]  L. J. Leon,et al.  Spatiotemporal evolution of ventricular fibrillation , 1998, Nature.

[45]  M. Glikson,et al.  The implantable cardioverter defibrillator , 2001, The Lancet.

[46]  R J Cohen,et al.  Electrical alternans and cardiac electrical instability. , 1988, Circulation.

[47]  Steven H. Strogatz,et al.  Nonlinear Dynamics and Chaos , 2024 .