Role of papillary muscle in the generation and maintenance of reentry during ventricular tachycardia and fibrillation in isolated swine right ventricle.

BACKGROUND The role of papillary muscle (PM) in the generation and maintenance of reentry is unclear. METHODS AND RESULTS Computerized mapping (477 bipolar electrodes, 1.6-mm resolution) was performed in fibrillating right ventricles (RVs) of swine in vitro. During ventricular fibrillation (VF), reentrant wave fronts often transiently anchored to the PM. Tissue mass reduction was then performed in 10 RVs until VF converted to ventricular tachycardia (VT). In an additional 6 RVs, procainamide infusion converted VF to VT. Maps showed that 77% (34 of 44) of all VT episodes were associated with a single reentrant wave front anchored to the PM. Purkinje fiber potentials preceded the local myocardial activation, and these potentials were recorded mostly around the PM. When PM was trimmed to the level of endocardium (n = 4), sustained VT was no longer inducible. Transmembrane potential recordings (n = 5) at the PM revealed full action potential during pacing, without evidence of ischemia. Computer simulation studies confirmed the role of PM as a spiral wave anchoring site that stabilized wave conduction. CONCLUSIONS We conclude that PM is important in the generation and maintenance of reentry during VT and VF.

[1]  A. Rosenblueth,et al.  Studies on flutter and fibrillation , 1947 .

[2]  M. Fishbein,et al.  Effects of procainamide on wave-front dynamics during ventricular fibrillation in open-chest dogs. , 1998, Circulation.

[3]  M. Fishbein,et al.  Interaction between strong electrical stimulation and reentrant wavefronts in canine ventricular fibrillation. , 1995, Circulation research.

[4]  J. W. Thomas Numerical Partial Differential Equations: Finite Difference Methods , 1995 .

[5]  J Jalife,et al.  Wave-front curvature as a cause of slow conduction and block in isolated cardiac muscle. , 1994, Circulation research.

[6]  M. Fishbein,et al.  Reentrant wave fronts in Wiggers' stage II ventricular fibrillation. Characteristics and mechanisms of termination and spontaneous regeneration. , 1996, Circulation research.

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

[8]  D. Geselowitz,et al.  The Discontinuous Nature of Propagation in Normal Canine Cardiac Muscle: Evidence for Recurrent Discontinuities of Intracellular Resistance that Affect the Membrane Currents , 1981, Circulation research.

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

[10]  Y. Rudy,et al.  Unidirectional block and reentry of cardiac excitation: a model study. , 1990, Circulation research.

[11]  L. Horowitz,et al.  Torsades de Pointes: Electrophysiologic Studies in Patients Without Transient Pharmacologic or Metabolic Abnormalities , 1981, Circulation.

[12]  G. Moe,et al.  Conduction through a Narrow Isthmus in Isolated Canine Atrial Tissue: A Model of the W‐P‐W Syndrome , 1971, Circulation.

[13]  P. S. Chen,et al.  The relation between atrial fibrillation wavefront characteristics and accessory pathway conduction. , 1995, The Journal of clinical investigation.

[14]  M. Josephson,et al.  Polymorphic ventricular tachycardia induced by programmed stimulation: response to procainamide. , 1993, Journal of the American College of Cardiology.

[15]  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.

[16]  J. W. Thomas Numerical Partial Differential Equations , 1999 .