Passive electrical properties, mechanical activity, and extracellular potassium in arterially perfused and ischemic rabbit ventricular muscle. Effects of calcium entry blockade or hypocalcemia.

The relation among passive electrical resistive properties, longitudinal conduction velocity, extracellular potassium concentration, [K+]o, and mechanical activity was investigated in the isolated rabbit papillary muscle during normal arterial perfusion and no-flow ischemia in the presence and absence of verapamil, or a reduced extracellular Ca2+ concentration [Ca2+]o. During normal arterial perfusion, verapamil (0.5 microM, free [Ca2+]o = 1.0 mM) and hypocalcemic blood perfusate (free [Ca2+]o = 0.4 mM) reduced the maximal isometric twitch tension by 48% and 78%, depolarized the resting membrane by +3 and +7 mV, decreased the extracellular longitudinal resistance (ro) by 15% and 26%, and increased conduction velocity by 4% and 6%, respectively. The changes in conduction velocity during these interventions were consistent with those predicted by linear cable theory (+3% and +9%) for the observed changes in ro. In contrast, verapamil shortened whereas a reduced [Ca2+]o lengthened action potential duration. Comparison of simultaneously measured longitudinal whole tissue resistance (rt), intracellular longitudinal resistance (ri), [K+]o, and resting tension during ischemia showed a close association between abrupt cell-to-cell electrical uncoupling, development of ischemic contracture, and the secondary rise of [K+]o, which all started to develop after approximately 15 minutes of ischemia. Electrical cell-to-cell uncoupling was completed within 15 minutes. In the presence of verapamil, the relation among the onset of electrical cell-to-cell uncoupling, secondary rise of [K+]o, and onset of ischemic contracture in ischemia was qualitatively the same as in its absence; however, these events were postponed by approximately 10 minutes, and the rates of contracture development and uncoupling were diminished. Conduction velocity decreased after 12 minutes of ischemia from 54 to 36 cm/sec in the absence of and from 61 to 46 cm/sec in the presence of verapamil. This slowing effect on impulse conduction could not be attributed to changes of electrical cell-to-cell coupling because at this time an increase in ri had not yet taken place. In the presence of a reduced [Ca2+]o, the resting tension and ri increased almost immediately after the onset of ischemia. Although the resting tension rose progressively throughout the course of ischemia, the ri showed a biphasic increase characterized by an early transient increase that reached a peak at 8 minutes (+87%) and a second, irreversible increase beginning at approximately 12 minutes. This final onset of electrical cell-to-cell uncoupling and the secondary rise of [K+]o were not different from the findings with a normal [Ca2+]o.(ABSTRACT TRUNCATED AT 400 WORDS)

[1]  R. Bates,et al.  Ionic hydration and single ion activities in unassociated chlorides at high ionic strengths , 1970 .

[2]  R. Kernoff,et al.  Reduction of Ischemic Depolarization by the Calcium Channel Blocker Diltiazem: Correlation with Improvement of Ventricular Conduction and Early Arrhythmias in the Dog , 1984, Circulation research.

[3]  A. Kleber,et al.  Electrical uncoupling and increase of extracellular resistance after induction of ischemia in isolated, arterially perfused rabbit papillary muscle. , 1987, Circulation research.

[4]  W. Moore,et al.  The role of protons in nerve conduction , 1973 .

[5]  J. L. Hill,et al.  Flexible valinomycin electrodes for on-line determination of intravascular and myocardial K+. , 1978, The American journal of physiology.

[6]  D. Wilkie,et al.  Mechanical relaxation rate and metabolism studied in fatiguing muscle by phosphorus nuclear magnetic resonance. , 1980, The Journal of physiology.

[7]  A. Wilde,et al.  The Combined Effects of Hypoxia, High K+, and Acidosis on the Intracellular Sodium Activity and Resting Potential in Guinea Pig Papillary Muscle , 1986, Circulation research.

[8]  A. Coray,et al.  Sodium/calcium exchange in mammalian ventricular muscle: a study with sodium‐sensitive micro‐electrodes. , 1983, The Journal of physiology.

[9]  J. Burt,et al.  Block of intercellular communication: interaction of intracellular H+ and Ca2+. , 1987, The American journal of physiology.

[10]  P. Garlick,et al.  Ischemic contracture of the myocardium: mechanisms and prevention. , 1977, The American journal of cardiology.

[11]  A. Kleber,et al.  Effect of Oxygen Withdrawal on Active and Passive Electrical Properties of Arterially: Perfused Rabbit Ventricular Muscle , 1989, Circulation research.

[12]  S. Wissner The effect of excess lactate upon the excitability of the sheep Purkinje fiber. , 1974, Journal of electrocardiology.

[13]  D. Allen,et al.  A nuclear magnetic resonance study of metabolism in the ferret heart during hypoxia and inhibition of glycolysis. , 1985, The Journal of physiology.

[14]  A. Noma,et al.  Dependence of junctional conductance on proton, calcium and magnesium ions in cardiac paired cells of guinea‐pig. , 1987, The Journal of physiology.

[15]  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.

[16]  D. Bers,et al.  Rat vs. rabbit ventricle: Ca flux and intracellular Na assessed by ion-selective microelectrodes. , 1989, The American journal of physiology.

[17]  H. Fozzard,et al.  Influence of Extracellular K+ Concentration on Cable Properties and Excitability of Sheep Cardiac Purkinje Fibers , 1970, Circulation research.

[18]  M J Janse,et al.  Electrophysiological changes and ventricular arrhythmias in the early phase of regional myocardial ischemia. , 1981, Circulation research.

[19]  H. Hirche,et al.  Myocardial extracellular K+ and H+ increase and noradrenaline release as possible cause of early arrhythmias following acute coronary artery occlusion in pigs. , 1980, Journal of molecular and cellular cardiology.

[20]  R. Tsien,et al.  Control of action potential duration by calcium ions in cardiac Purkinje fibers , 1976, The Journal of general physiology.

[21]  R. Haworth,et al.  Inhibition of calcium influx in isolated adult rat heart cells by ATP depletion. , 1987, Circulation research.

[22]  A. Kleber Extracellular potassium accumulation in acute myocardial ischemia. , 1984, Journal of molecular and cellular cardiology.

[23]  D. Durrer,et al.  The Effect of Acute Coronary Artery Occlusion on Subepicardial Transmembrane Potentials in the Intact Porcine Heart , 1977, Circulation.

[24]  R. Myerburg,et al.  Regional effects of verapamil on recovery of excitability and conduction time in experimental ischemia. , 1987, Circulation.

[25]  D M Bers,et al.  SR Ca loading in cardiac muscle preparations based on rapid-cooling contractures. , 1989, The American journal of physiology.

[26]  H Kusuoka,et al.  Intracellular free calcium concentration measured with 19F NMR spectroscopy in intact ferret hearts. , 1987, Proceedings of the National Academy of Sciences of the United States of America.

[27]  M. Marcus,et al.  Microvascular distribution of coronary vascular resistance in beating left ventricle. , 1986, The American journal of physiology.

[28]  J. Burt Electrical and contractile consequences of Na+ or Ca2+ gradient reduction in cultured heart cells. , 1982, Journal of molecular and cellular cardiology.

[29]  A. Kléber,et al.  Electrical constants of arterially perfused rabbit papillary muscle. , 1987, The Journal of physiology.

[30]  R. Coronel,et al.  The change of the free energy of ATP hydrolysis during global ischemia and anoxia in the rat heart. Its possible role in the regulation of transsarcolemmal sodium and potassium gradients. , 1984, Journal of molecular and cellular cardiology.

[31]  C W Balke,et al.  Two Periods of Early Ventricular Arrhythmia in the Canine Acute Myocardial Infarction Model , 1979, Circulation.

[32]  P. Poole‐Wilson,et al.  Hypoxia and calcium. , 1979, Journal of molecular and cellular cardiology.

[33]  K I Shine,et al.  Effects of heart rate on extracellular [K+] accumulation during myocardial ischemia. , 1986, The American journal of physiology.

[34]  G. Kabell Modulation of conduction slowing in ischemic rabbit myocardium by calcium-channel activation and blockade. , 1988, Circulation.

[35]  R. London,et al.  Elevation in Cytosolic Free Calcium Concentration Early in Myocardial Ischemia in Perfused Rat Heart , 1987, Circulation research.

[36]  T Powell,et al.  Sodium‐calcium exchange during the action potential in guinea‐pig ventricular cells. , 1989, The Journal of physiology.

[37]  A. L. Wit,et al.  Effect of Verapamil on the Normal Action Potential and on a Calcium Dependent Slow Response of Canine Cardiac Purkinje Fibers , 1974 .

[38]  D. Zipes,et al.  Effect of drugs on conduction delay and incidence of ventricular arrhythmias induced by acute coronary occlusion in dogs. , 1977, The American journal of cardiology.

[39]  J. L. Hill,et al.  Effect of Acute Coronary Artery Occlusion on Local Myocardial Extracellular K+ Activity in Swine , 1980, Circulation.

[40]  J. C. Bailey,et al.  Effects of Extracellular Calcium Ions, Verapamil, and Lanthanum on Active and Passive Properties of Canine Cardiac Purkinje Fibers , 1982, Circulation research.

[41]  C. C. Hale,et al.  The stoichiometry of the cardiac sodium-calcium exchange system. , 1984, The Journal of biological chemistry.

[42]  M. Schnall,et al.  Intracellular sodium flux and high-energy phosphorus metabolites in ischemic skeletal muscle. , 1988, The American journal of physiology.

[43]  E. Braunwald,et al.  Preservation of high-energy phosphates by verapamil in reperfused myocardium. , 1984, Circulation.

[44]  W. D. De Mello Cell-to-cell communication in heart and other tissues. , 1982, Progress in biophysics and molecular biology.

[45]  E Jüngling,et al.  Free energy change of ATP-hydrolysis: a causal factor of early hypoxic failure of the myocardium? , 1982, Journal of molecular and cellular cardiology.

[46]  L. Gettes,et al.  Effects of verapamil on ischemia-induced changes in extracellular K+, pH, and local activation in the pig. , 1986, Circulation.

[47]  K I Shine,et al.  Extracellular K+ accumulation during myocardial ischemia in isolated rabbit heart. , 1982, The American journal of physiology.

[48]  L. D. Davis,et al.  Effect of Calcium Concentration on the Transmembrane Potentials of Purkinje Fibers , 1967, Circulation research.

[49]  H. Oetliker,et al.  Energetics and electrogenicity of the sarcoplasmic reticulum calcium pump. , 1983, Annual review of physiology.

[50]  M. Rovetto,et al.  Mechanisms of Glycolytic Inhibition in Ischemic Rat Hearts , 1975, Circulation research.

[51]  K. Philipson,et al.  Sodium-calcium exchange and sarcolemmal enzymes in ischemic rabbit hearts. , 1982, The American journal of physiology.

[52]  W. Wier,et al.  Sodium‐calcium exchange in guinea‐pig cardiac cells: exchange current and changes in intracellular Ca2+. , 1989, The Journal of physiology.