Suppression of alternans and conduction blocks despite steep APD restitution: electrotonic, memory, and conduction velocity restitution effects.

We examine the utility of the action potential (AP) duration (APD) restitution curve slope in predicting the onset of electrical alternans when electrotonic and memory effects are considered. We develop and use two ionic cell models without memory that have the same restitution curve with slope >1 but different AP shapes and, therefore, different electrotonic effects. We also study a third cell model that incorporates short-term memory of previous cycle lengths, so that it has a family of S1-S2 restitution curves as well as a dynamic restitution curve with slope >1. Our results indicate that both electrotonic and memory effects can suppress alternans, even when the APD restitution curve is steep. In the absence of memory, electrotonic currents related to the shape of the AP, as well as conduction velocity restitution, can affect how alternans develops in tissue and, in some cases, can prevent its induction entirely, even when isolated cells exhibit alternans. When short-term memory is included, alternans may not occur in isolated cells, despite a steep APD restitution curve, and may or may not occur in tissue, depending on conduction velocity restitution. We show for the first time that electrotonic and memory effects can prevent conduction blocks and stabilize reentrant waves in two and three dimensions. Thus we find that the slope of the APD restitution curve alone does not always well predict the onset of alternans and that incorporating electrotonic and memory effects may provide a more useful alternans criterion.

[1]  L. Hondeghem,et al.  Phase 2 prolongation, in the absence of instability and triangulation, antagonizes class III proarrhythmia. , 2001, Cardiovascular research.

[2]  H. E. Hering,et al.  Experimentelle Studien an Säugethieren über das Elektrokardiogramm , 1909, Archiv für die gesamte Physiologie des Menschen und der Tiere.

[3]  James P. Keener,et al.  Stability conditions for the traveling pulse: Modifying the restitution hypothesis. , 2002, Chaos.

[4]  I R Efimov,et al.  Evidence of Three‐Dimensional Scroll Waves with Ribbon‐Shaped Filament as a Mechanism of Ventricular Tachycardia in the Isolated Rabbit Heart , 1999, Journal of cardiovascular electrophysiology.

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

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

[7]  R. Gilmour,et al.  Memory models for the electrical properties of local cardiac systems. , 1997, Journal of theoretical biology.

[8]  L. Gettes,et al.  Influence of rate-dependent cellular uncoupling on conduction change during simulated ischemia in guinea pig papillary muscles: effect of verapamil. , 1989, Circulation research.

[9]  Eberhard Bodenschatz,et al.  Period-doubling instability and memory in cardiac tissue. , 2002, Physical review letters.

[10]  R. Gilmour A novel approach to identifying antiarrhythmic drug targets. , 2003, Drug discovery today.

[11]  Marc Courtemanche,et al.  Complex spiral wave dynamics in a spatially distributed ionic model of cardiac electrical activity. , 1996, Chaos.

[12]  M R Boyett,et al.  Human ventricular action potential duration during short and long cycles. Rapid modulation by ischemia. , 1996, Circulation.

[13]  Harold M. Hastings,et al.  Memory in an Excitable Medium: A Mechanism for Spiral Wave Breakup in the Low-Excitability Limit , 1999 .

[14]  N. B. Strydom,et al.  The influence of boot weight on the energy expenditure of men walking on a treadmill and climbing steps , 2004, Internationale Zeitschrift für angewandte Physiologie einschließlich Arbeitsphysiologie.

[15]  R. Ideker,et al.  Steepness of the Restitution Curve: A Slippery Slope? , 2002, Journal of cardiovascular electrophysiology.

[16]  Daniel J Gauthier,et al.  Condition for alternans and stability of the 1:1 response pattern in a "memory" model of paced cardiac dynamics. , 2003, Physical review. E, Statistical, nonlinear, and soft matter physics.

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

[18]  Alvin Shrier,et al.  Spiral wave generation in heterogeneous excitable media. , 2002, Physical review letters.

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

[20]  R. Gilmour,et al.  Dynamic restitution of action potential duration during electrical alternans and ventricular fibrillation. , 1998, The American journal of physiology.

[21]  J Jalife,et al.  Supernormal excitability as a mechanism of chaotic dynamics of activation in cardiac Purkinje fibers. , 1990, Circulation research.

[22]  R. Gilmour,et al.  Conduction block in one-dimensional heart fibers. , 2002, Physical review letters.

[23]  M. Franz,et al.  Cycle length dependence of human action potential duration in vivo. Effects of single extrastimuli, sudden sustained rate acceleration and deceleration, and different steady-state frequencies. , 1988, The Journal of clinical investigation.

[24]  Aoxiang Xu,et al.  Alternans and higher-order rhythms in an ionic model of a sheet of ischemic ventricular muscle. , 2000, Chaos.

[25]  R. Gilmour,et al.  Electrical restitution and spatiotemporal organization during ventricular fibrillation. , 1999, Circulation research.

[26]  Guy Salama,et al.  Simultaneous maps of optical action potentials and calcium transients in guinea‐pig hearts: mechanisms underlying concordant alternans , 2000, The Journal of physiology.

[27]  A. McCulloch,et al.  Three-dimensional analysis of regional cardiac function: a model of rabbit ventricular anatomy. , 1998, Progress in biophysics and molecular biology.

[28]  J Jalife,et al.  Spiral waves in two-dimensional models of ventricular muscle: formation of a stationary core. , 1998, Biophysical journal.

[29]  Blas Echebarria,et al.  Instability and spatiotemporal dynamics of alternans in paced cardiac tissue. , 2001, Physical review letters.

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

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

[32]  M. Lab,et al.  Electrical alternans and the onset of rate-induced pulsus alternans during acute regional ischaemia in the anaesthetised pig heart. , 1996, Cardiovascular research.

[33]  H. E. Hering,et al.  Experimentalle studien an säugethieren über das elektrocardiogramm , 1909 .

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

[35]  A Garfinkel,et al.  Intracellular Ca(2+) dynamics and the stability of ventricular tachycardia. , 1999, Biophysical journal.

[36]  A. Karma,et al.  New paradigm for drug therapies of cardiac fibrillation. , 2000, Proceedings of the National Academy of Sciences of the United States of America.

[37]  Arun V. Holden,et al.  Tension of organizing filaments of scroll waves , 1994, Philosophical Transactions of the Royal Society of London. Series A: Physical and Engineering Sciences.

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

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

[40]  A. Garfinkel,et al.  Preventing ventricular fibrillation by flattening cardiac restitution. , 2000, Proceedings of the National Academy of Sciences of the United States of America.

[41]  Wouter-Jan Rappel,et al.  Filament instability and rotational tissue anisotropy: A numerical study using detailed cardiac models. , 2001, Chaos.

[42]  José Jalife,et al.  Blockade of the Inward Rectifying Potassium Current Terminates Ventricular Fibrillation in the Guinea Pig Heart , 2003, Journal of cardiovascular electrophysiology.

[43]  A. Garfinkel,et al.  Effects of amiodarone on wave front dynamics during ventricular fibrillation in isolated swine right ventricle. , 2002, American journal of physiology. Heart and circulatory physiology.

[44]  A Garfinkel,et al.  Spatiotemporal complexity of ventricular fibrillation revealed by tissue mass reduction in isolated swine right ventricle. Further evidence for the quasiperiodic route to chaos hypothesis. , 1997, The Journal of clinical investigation.

[45]  T J Lewis,et al.  Chaotic dynamics in an ionic model of the propagated cardiac action potential. , 1990, Journal of theoretical biology.

[46]  Richard A Gray,et al.  Effect of Action Potential Duration and Conduction Velocity Restitution and Their Spatial Dispersion on Alternans and the Stability of Arrhythmias , 2002, Journal of cardiovascular electrophysiology.

[47]  Daniel J. Gauthier,et al.  Prevalence of Rate-Dependent Behaviors in Cardiac Muscle , 1999 .

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

[49]  Thomas Lewis,et al.  NOTES UPON ALTERNATION OF THE HEART , 1911 .

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

[51]  Robert F Gilmour,et al.  Ionic mechanism of electrical alternans. , 2002, American journal of physiology. Heart and circulatory physiology.

[52]  M. Rosen What is Cardiac Memory? , 2000, Journal of cardiovascular electrophysiology.

[53]  J. Keener,et al.  The effects of discrete gap junction coupling on propagation in myocardium. , 1991, Journal of theoretical biology.

[54]  R. Gilmour Electrical Restitution and Ventricular Fibrillation: Negotiating a Slippery Slope , 2002, Journal of cardiovascular electrophysiology.

[55]  B. Surawicz,et al.  Cycle length effect on restitution of action potential duration in dog cardiac fibers. , 1983, The American journal of physiology.

[56]  M. Eiswirth,et al.  Turbulence due to spiral breakup in a continuous excitable medium. , 1993, Physical review. E, Statistical physics, plasmas, fluids, and related interdisciplinary topics.

[57]  J Jalife,et al.  Rectification of the Background Potassium Current: A Determinant of Rotor Dynamics in Ventricular Fibrillation , 2001, Circulation research.

[58]  R. Gilmour,et al.  Memory and complex dynamics in cardiac Purkinje fibers. , 1997, The American journal of physiology.

[59]  M. Courtemanche,et al.  Ionic mechanisms underlying human atrial action potential properties: insights from a mathematical model. , 1998, The American journal of physiology.

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

[61]  R Plonsey,et al.  Significance of inwardly directed transmembrane current in determination of local myocardial electrical activation during ventricular fibrillation. , 1994, Circulation research.

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