Quantitative comparison of cardiac ventricular myocyte electrophysiology and response to drugs in human and nonhuman species.

Explanations for arrhythmia mechanisms at the cellular level are usually based on experiments in nonhuman myocytes. However, subtle electrophysiological differences between species may lead to different rhythmic or arrhythmic cellular behaviors and drug response given the nonlinear and highly interactive cellular system. Using detailed and quantitatively accurate mathematical models for human, dog, and guinea pig ventricular action potentials (APs), we simulated and compared cell electrophysiology mechanisms and response to drugs. Under basal conditions (absence of β-adrenergic stimulation), Na(+)/K(+)-ATPase changes secondary to Na(+) accumulation determined AP rate dependence for human and dog but not for guinea pig where slow delayed rectifier current (I(Ks)) was the major rate-dependent current. AP prolongation with reduction of rapid delayed rectifier current (I(Kr)) and I(Ks) (due to mutations or drugs) showed strong species dependence in simulations, as in experiments. For humans, AP prolongation was 80% following I(Kr) block. It was 30% for dog and 20% for guinea pig. Under basal conditions, I(Ks) block was of no consequence for human and dog, but for guinea pig, AP prolongation after I(Ks) block was severe. However, with β-adrenergic stimulation, I(Ks) played an important role in all species, particularly in AP shortening at fast rate. Quantitative comparison of AP repolarization, rate-dependence mechanisms, and drug response in human, dog, and guinea pig revealed major species differences (e.g., susceptibility to arrhythmogenic early afterdepolarizations). Extrapolation from animal to human electrophysiology and drug response requires great caution.

[1]  P. Kowey,et al.  Electrophysiological Properties of HBI-3000: A New Antiarrhythmic Agent With Multiple-channel Blocking Properties in Human Ventricular Myocytes , 2011, Journal of cardiovascular pharmacology.

[2]  P. Davey,et al.  Prolongation of the QT interval in heart failure occurs at low but not at high heart rates. , 2000, Clinical science.

[3]  Yoram Rudy,et al.  Rate Dependence and Regulation of Action Potential and Calcium Transient in a Canine Cardiac Ventricular Cell Model , 2004, Circulation.

[4]  Donald M Bers,et al.  A mathematical treatment of integrated Ca dynamics within the ventricular myocyte. , 2004, Biophysical journal.

[5]  Antonio Zaza,et al.  Rate dependency of delayed rectifier currents during the guinea‐pig ventricular action potential , 2001, The Journal of physiology.

[6]  David Zeltser,et al.  Drug-induced prolongation of the QT interval. , 2004, The New England journal of medicine.

[7]  D. Feldman,et al.  Mechanisms of Disease: β-adrenergic receptors—alterations in signal transduction and pharmacogenomics in heart failure , 2005, Nature Clinical Practice Cardiovascular Medicine.

[8]  V. Bondarenko,et al.  Transmural heterogeneity of repolarization and Ca2+ handling in a model of mouse ventricular tissue. , 2010, American journal of physiology. Heart and circulatory physiology.

[9]  K.H.W.J. ten Tusscher,et al.  Comments on 'A model for human ventricular tissue' : reply , 2005 .

[10]  Thomas O'Hara,et al.  Arrhythmia formation in subclinical ("silent") long QT syndrome requires multiple insults: quantitative mechanistic study using the KCNQ1 mutation Q357R as example. , 2012, Heart rhythm.

[11]  Yoram Rudy,et al.  Subunit Interaction Determines IKs Participation in Cardiac Repolarization and Repolarization Reserve , 2005, Circulation.

[12]  Yoram Rudy,et al.  Computational biology in the study of cardiac ion channels and cell electrophysiology , 2006, Quarterly Reviews of Biophysics.

[13]  Stanley Nattel,et al.  Molecular basis of species-specific expression of repolarizing K+ currents in the heart. , 2003, American journal of physiology. Heart and circulatory physiology.

[14]  Yoram Rudy,et al.  Properties and ionic mechanisms of action potential adaptation, restitution, and accommodation in canine epicardium. , 2009, American journal of physiology. Heart and circulatory physiology.

[15]  Yoram Rudy,et al.  Kinetic properties of the cardiac L-type Ca2+ channel and its role in myocyte electrophysiology: a theoretical investigation. , 2007, Biophysical journal.

[16]  Andrew C. Zygmunt,et al.  Electrophysiological Effects of Ranolazine, a Novel Antianginal Agent With Antiarrhythmic Properties , 2004, Circulation.

[17]  Yoram Rudy,et al.  Simulation of the Undiseased Human Cardiac Ventricular Action Potential: Model Formulation and Experimental Validation , 2011, PLoS Comput. Biol..

[18]  R. Winslow,et al.  A computational model of the human left-ventricular epicardial myocyte. , 2004, Biophysical journal.

[19]  K. T. ten Tusscher,et al.  Alternans and spiral breakup in a human ventricular tissue model. , 2006, American journal of physiology. Heart and circulatory physiology.

[20]  Marc A. Vos,et al.  Probing the Contribution of IKs to Canine Ventricular Repolarization: Key Role for &bgr;-Adrenergic Receptor Stimulation , 2003, Circulation.

[21]  Y. Rudy,et al.  Calsequestrin mutation and catecholaminergic polymorphic ventricular tachycardia: a simulation study of cellular mechanism. , 2007, Cardiovascular research.

[22]  Klaus Benndorf,et al.  Voltage-gated Na+ channel transcript patterns in the mammalian heart are species-dependent. , 2008, Progress in biophysics and molecular biology.

[23]  Antonis A Armoundas,et al.  Phenotypic differences in transient outward K+ current of human and canine ventricular myocytes: insights into molecular composition of ventricular Ito. , 2004, American journal of physiology. Heart and circulatory physiology.

[24]  K. Sipido,et al.  Accumulation of slowly activating delayed rectifier potassium current (IKs) in canine ventricular myocytes , 2003, The Journal of physiology.

[25]  Balázs Horváth,et al.  Contribution of IKr and IK1 to ventricular repolarization in canine and human myocytes: is there any influence of action potential duration? , 2008, Basic Research in Cardiology.

[26]  A. Brown,et al.  Drugs, hERG and sudden death. , 2004, Cell calcium.

[27]  W. Giles,et al.  A mathematical model of action potential heterogeneity in adult rat left ventricular myocytes. , 2001, Biophysical journal.

[28]  P. C. Viswanathan,et al.  Effects of IKr and IKs heterogeneity on action potential duration and its rate dependence: a simulation study. , 1999, Circulation.

[29]  Y Rudy,et al.  Action potential and contractility changes in [Na(+)](i) overloaded cardiac myocytes: a simulation study. , 2000, Biophysical journal.

[30]  Nathan A. Baker,et al.  A multiscale model linking ion-channel molecular dynamics and electrostatics to the cardiac action potential , 2009, Proceedings of the National Academy of Sciences.

[31]  Fabio Mosca,et al.  Prevalence of the Congenital Long-QT Syndrome , 2009, Circulation.

[32]  T. Bíró,et al.  Asymmetrical distribution of ion channels in canine and human left-ventricular wall: epicardium versus midmyocardium , 2005, Pflügers Archiv.

[33]  Yoram Rudy,et al.  Local control of β-adrenergic stimulation: Effects on ventricular myocyte electrophysiology and Ca(2+)-transient. , 2011, Journal of molecular and cellular cardiology.

[34]  D. Bers,et al.  A novel computational model of the human ventricular action potential and Ca transient. , 2010, Journal of Molecular and Cellular Cardiology.

[35]  Lars S. Maier,et al.  Rate Dependence of [Na+]i and Contractility in Nonfailing and Failing Human Myocardium , 2002, Circulation.

[36]  C Antzelevitch,et al.  Ionic bases for electrophysiological distinctions among epicardial, midmyocardial, and endocardial myocytes from the free wall of the canine left ventricle. , 1993, Circulation research.

[37]  S Nattel,et al.  Effects of flecainide and quinidine on human atrial action potentials. Role of rate-dependence and comparison with guinea pig, rabbit, and dog tissues. , 1990, Circulation.