We propose to investigate the mechanisms and dynamics of wave propagation in two-dimensional cardiac tissue in general, and of vortex-like (spiral wave) reentrant activity in particular. It is well known that factors such as excitability, tissue geometry and intercellular coupling are essential in these processes. We postulate that, in addition to these factors, the curvature of the wavefront and the frequency dependence of action potential duration and wavelength are necessary for a full description of propagation in two-dimensional muscle. In fact, our preliminary results demonstrate the existence of frequency adaptation phenomena in experimental preparations, and suggest that the curvature of the wavefront may play an important role in determining the characteristics of propagation during spiral wave activity. We will seek to test the validity of our conjectures by using a combination of high resolution optical mapping, conventional electrophysiologic recordings and computer simulations of propagation in - 2-dimensional cardiac muscle. For this purpose, we will develop and use a new ionic model on the ba sis of patch clamp experiments and the Luo & Rudy model. Although presently available ionic models are appropriate to study many of the features associated with wavefront dynamics in two-dimensional cell matrices, they do not account for many of the behaviors that have been demonstrated for experimental preparations of thinned cardiac muscle, including self-sustaining spiral wave activity. Thus, we will carry out patch clamp experiments in single cells and seek to derive the parameters needed to accurately reproduce essential ionic mechanisms of dynamic control of the action potential duration and excitability, which determine the ability of the cardiac cell to adapt to exceedingly high frequencies. This model will be used to make quantitative and testable predictions about wave propagation and reentrant excitation. In addition, we will use an improved video imaging system (time resolution = 4 msec) and our well- established epicardial ventricular muscle preparation, as well as an ionic model, to measure the critical curvature for propagation and its dependence on excitability and stimulation frequency. Those measurements will be used in our quantitative studies of the characteristics of the functional core, the excitable gap and the curvature of the wavefront during spiral wave activity, as well as to make predictions about other potentially important phenomena related to lateral instabilities of wavefront propagation in two-dimensional myocardium. Achieving our goals should lead to a better understanding of the dynamics of wave propagation in two dimensional cardiac muscle, and provide definite answers to important questions related to the mechanisms underlying vortex-like reentrant activity.

Agency
National Institute of Health (NIH)
Institute
National Heart, Lung, and Blood Institute (NHLBI)
Type
Research Program Projects (P01)
Project #
5P01HL039707-07
Application #
5213685
Study Section
Project Start
Project End
Budget Start
Budget End
Support Year
7
Fiscal Year
1996
Total Cost
Indirect Cost
Ponce-Balbuena, Daniela; Guerrero-Serna, Guadalupe; Valdivia, Carmen R et al. (2018) Cardiac Kir2.1 and NaV1.5 Channels Traffic Together to the Sarcolemma to Control Excitability. Circ Res 122:1501-1516
Rodrigo, M; Climent, A M; Liberos, A et al. (2017) Minimal configuration of body surface potential mapping for discrimination of left versus right dominant frequencies during atrial fibrillation. Pacing Clin Electrophysiol 40:940-946
Rodrigo, Miguel; Climent, Andreu M; Liberos, Alejandro et al. (2017) Highest dominant frequency and rotor positions are robust markers of driver location during noninvasive mapping of atrial fibrillation: A computational study. Heart Rhythm 14:1224-1233
Quintanilla, Jorge G; Pérez-Villacastín, Julián; Pérez-Castellano, Nicasio et al. (2016) Mechanistic Approaches to Detect, Target, and Ablate the Drivers of Atrial Fibrillation. Circ Arrhythm Electrophysiol 9:e002481
Takemoto, Yoshio; Ramirez, Rafael J; Yokokawa, Miki et al. (2016) Galectin-3 Regulates Atrial Fibrillation Remodeling and Predicts Catheter Ablation Outcomes. JACC Basic Transl Sci 1:143-154
Filgueiras-Rama, David; Jalife, José (2016) STRUCTURAL AND FUNCTIONAL BASES OF CARDIAC FIBRILLATION. DIFFERENCES AND SIMILARITIES BETWEEN ATRIA AND VENTRICLES. JACC Clin Electrophysiol 2:1-3
Pedrón-Torrecilla, Jorge; Rodrigo, Miguel; Climent, Andreu M et al. (2016) Noninvasive Estimation of Epicardial Dominant High-Frequency Regions During Atrial Fibrillation. J Cardiovasc Electrophysiol 27:435-42
Herron, Todd J; Rocha, Andre Monteiro Da; Campbell, Katherine F et al. (2016) Extracellular Matrix-Mediated Maturation of Human Pluripotent Stem Cell-Derived Cardiac Monolayer Structure and Electrophysiological Function. Circ Arrhythm Electrophysiol 9:e003638
Guillem, María S; Climent, Andreu M; Rodrigo, Miguel et al. (2016) Presence and stability of rotors in atrial fibrillation: evidence and therapeutic implications. Cardiovasc Res 109:480-92
Willis, B Cicero; Pandit, Sandeep V; Ponce-Balbuena, Daniela et al. (2016) Constitutive Intracellular Na+ Excess in Purkinje Cells Promotes Arrhythmogenesis at Lower Levels of Stress Than Ventricular Myocytes From Mice With Catecholaminergic Polymorphic Ventricular Tachycardia. Circulation 133:2348-59

Showing the most recent 10 out of 257 publications