Substrate size as a determinant of fibrillatory activity maintenance in a mathematical model of canine atrium.

Tissue size has been considered an important determinant of atrial fibrillation (AF), but recent work has questioned the critical size hypothesis. Here, we use a previously developed mathematical model of the two-dimensional canine atrium with realistic action potential, ionic, and conduction properties to address substrate size effects on the maintenance of fibrillatory activity. Cholinergic AF was simulated at different acetylcholine (ACh) concentrations ([ACh]) and distributions, with substrate area varied 11.1-fold. Automated phase singularity detection was used to facilitate the analysis of arrhythmic activity. The duration of activity induced by a single extrastimulus increased with increasing substrate dimensions. Two general mechanisms underlying activity were observed and were differentially affected by substrate size. For large mean [ACh], single primary rotors anchored in low-[ACh] zones maintained activity and substrate dimensions were not critical. At lower mean [ACh], extensive spiral wave meander prevented the emergence of single stable rotors. Prolonged activity was favored when substrate size permitted a sufficiently large number of simultaneous longer-lasting rotors that extinction of all was unlikely. Thus either single dominant rotor or multiple reentrant spiral generator mechanisms could maintain fibrillatory activity in this model and were differentially dependent on substrate size. These results speak to recent debates about the role in AF of single driver rotors versus multiple reentrant circuit mechanisms by suggesting that either may maintain fibrillatory atrial activity depending on atrial size and electrophysiological properties.

[1]  Alan Garfinkel,et al.  Electrical refractory period restitution and spiral wave reentry in simulated cardiac tissue. , 2002, American journal of physiology. Heart and circulatory physiology.

[2]  J Jalife,et al.  Dynamics of wavelets and their role in atrial fibrillation in the isolated sheep heart. , 2000, Cardiovascular research.

[3]  B. Victorri,et al.  Numerical integration in the reconstruction of cardiac action potentials using Hodgkin-Huxley-type models. , 1985, Computers and biomedical research, an international journal.

[4]  J L Cox,et al.  Cholinergically mediated tachyarrhythmias induced by a single extrastimulus in the isolated canine right atrium. , 1992, Circulation research.

[5]  W. Henry,et al.  Relation between Echocardiographically Determined Left Atrial Size and Atrial Fibrillation , 1976, Circulation.

[6]  M. Allessie,et al.  Length of Excitation Wave and Susceptibility to Reentrant Atrial Arrhythmias in Normal Conscious Dogs , 1988, Circulation research.

[7]  Wayne R. Giles,et al.  Simulations of the human atrial action potential , 2001, Philosophical Transactions of the Royal Society of London. Series A: Mathematical, Physical and Engineering Sciences.

[8]  J Jalife,et al.  Reentry and fibrillation in the mouse heart. A challenge to the critical mass hypothesis. , 1999, Circulation research.

[9]  S Nattel,et al.  Basic mechanisms of atrial fibrillation--very new insights into very old ideas. , 2000, Annual review of physiology.

[10]  Walter E. Garrey THE NATURE OF FIBRILLARY CONTRACTION OF THE HEART.—ITS RELATION TO TISSUE MASS AND FORM , 1914 .

[11]  M. Fishbein,et al.  Attachment of meandering reentrant wave fronts to anatomic obstacles in the atrium. Role of the obstacle size. , 1997, Circulation research.

[12]  S Nattel,et al.  Mechanism of flecainide's antiarrhythmic action in experimental atrial fibrillation. , 1992, Circulation research.

[13]  J Jalife,et al.  Mechanisms of atrial fibrillation: mother rotors or multiple daughter wavelets, or both? , 1998, Journal of cardiovascular electrophysiology.

[14]  Progressive action potential duration shortening and the conversion from atrial flutter to atrial fibrillation in the isolated canine right atrium. , 2001, Journal of the American College of Cardiology.

[15]  S Nattel,et al.  Differing sympathetic and vagal effects on atrial fibrillation in dogs: role of refractoriness heterogeneity. , 1997, The American journal of physiology.

[16]  T. Johns,et al.  Ibutilide: Efficacy and safety in atrial fibrillation and atrial flutter in a general cardiology practice , 2001, Clinical cardiology.

[17]  S Nattel,et al.  Promotion of atrial fibrillation by heart failure in dogs: atrial remodeling of a different sort. , 1999, Circulation.

[18]  Edward G Lakatta,et al.  &bgr;-Adrenergic Stimulation Modulates Ryanodine Receptor Ca2+ Release During Diastolic Depolarization to Accelerate Pacemaker Activity in Rabbit Sinoatrial Nodal Cells , 2002, Circulation research.

[19]  Stanley Nattel,et al.  New approaches to atrial fibrillation management: a critical review of a rapidly evolving field. , 2002, Drugs.

[20]  J Jalife,et al.  Stable microreentrant sources as a mechanism of atrial fibrillation in the isolated sheep heart. , 2000, Circulation.

[21]  N Trayanova,et al.  Reentry in a Morphologically Realistic Atrial Model , 2001, Journal of cardiovascular electrophysiology.

[22]  B. Roth,et al.  Experimental and Theoretical Analysis of Phase Singularity Dynamics in Cardiac Tissue , 2001, Journal of cardiovascular electrophysiology.

[23]  José Jalife,et al.  Ionic determinants of functional reentry in a 2-D model of human atrial cells during simulated chronic atrial fibrillation. , 2005, Biophysical journal.

[24]  F A Roberge,et al.  Reconstruction of Propagated Electrical Activity with a Two‐Dimensional Model of Anisotropic Heart Muscle , 1986, Circulation research.

[25]  S Nattel,et al.  Mathematical analysis of canine atrial action potentials: rate, regional factors, and electrical remodeling. , 2000, American journal of physiology. Heart and circulatory physiology.

[26]  B. Avitall,et al.  Time Course of Left Atrial Mechanical Recovery After Linear Lesions: , 2000, Journal of cardiovascular electrophysiology.

[27]  L. Joshua Leon,et al.  Development of a computer algorithm for the detection of phase singularities and initial application to analyze simulations of atrial fibrillation. , 2002, Chaos.

[28]  W. Rheinboldt,et al.  A COMPUTER MODEL OF ATRIAL FIBRILLATION. , 1964, American heart journal.

[29]  R. W. Joyner,et al.  Effects of the Discrete Pattern of Electrical Coupling on Propagation through an Electrical Syncytium , 1982, Circulation research.

[30]  José Jalife,et al.  Mechanisms of Atrial Fibrillation Termination by Pure Sodium Channel Blockade in an Ionically-Realistic Mathematical Model , 2005, Circulation research.

[31]  L. J. Leon,et al.  Cholinergic Atrial Fibrillation in a Computer Model of a Two-Dimensional Sheet of Canine Atrial Cells With Realistic Ionic Properties , 2002, Circulation research.

[32]  M. Allessie,et al.  Experimental evaluation of Moe's multiple wavelet hypothesis of atrial fibrillation , 1985 .

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

[34]  Pierre L. Page,et al.  Method for Simultaneous Epicardial and Endocardial Mapping of In Vivo Canine Heart: Application to Atrial Conduction Properties and Arrhythmia Mechanisms , 2001, Journal of cardiovascular electrophysiology.

[35]  S Nattel,et al.  Functional mechanisms underlying tachycardia-induced sustained atrial fibrillation in a chronic dog model. , 1997, Circulation.

[36]  T. Aybek,et al.  Impact of left atrial size reduction on chronic atrial fibrillation in mitral valve surgery. , 2003, The Journal of heart valve disease.

[37]  T Ikeda,et al.  Meandering and unstable reentrant wave fronts induced by acetylcholine in isolated canine right atrium. , 1997, The American journal of physiology.

[38]  A Garfinkel,et al.  Role of pectinate muscle bundles in the generation and maintenance of intra-atrial reentry: potential implications for the mechanism of conversion between atrial fibrillation and atrial flutter. , 1998, Circulation research.

[39]  S Nattel,et al.  Regional and functional factors determining induction and maintenance of atrial fibrillation in dogs. , 1996, The American journal of physiology.

[40]  O. Garcia-Villarreal,et al.  Left atrial reduction and mitral valve surgery: the "functional-anatomic unit" concept. , 2001, The Annals of thoracic surgery.

[41]  L. J. Leon,et al.  Simulation of two-dimensional anisotropic cardiac reentry: Effects of the wavelength on the reentry characteristics , 1994, Annals of Biomedical Engineering.

[42]  Stanley Nattel,et al.  Time-dependent transients in an ionically based mathematical model of the canine atrial action potential. , 2002, American journal of physiology. Heart and circulatory physiology.

[43]  A. Waldo Mechanisms of atrial flutter and atrial fibrillation: distinct entities or two sides of a coin? , 2002, Cardiovascular research.

[44]  S. Nattel New ideas about atrial fibrillation 50 years on , 2002, Nature.

[45]  Stanley Nattel,et al.  The effect of vagally induced dispersion of action potential duration on atrial arrhythmogenesis. , 2004, Heart rhythm.

[46]  M. Fishbein,et al.  Mechanism of spontaneous termination of functional reentry in isolated canine right atrium. Evidence for the presence of an excitable but nonexcited core. , 1996, Circulation.

[47]  J A ABILDSKOV,et al.  Atrial fibrillation as a self-sustaining arrhythmia independent of focal discharge. , 1959, American heart journal.

[48]  J. McWilliam Fibrillar Contraction of the Heart , 1887, The Journal of physiology.

[49]  A. Skanes,et al.  Spatiotemporal periodicity during atrial fibrillation in the isolated sheep heart. , 1998, Circulation.