Effects of acid-base changes on excitation--contraction coupling in guinea-pig and rabbit cardiac ventricular muscle.

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Effects of acid-base changes on excitation--contraction coupling in guinea-pig and rabbit cardiac ventricular muscle.

C H Fry and P A Poole-Wilson

1. Respiratory and metabolic acid-base changes caused similarsteady-state changes in the contractility of cardiac ventricularmuscle, but the rate of response was more rapid with the formerintervention. 2. Variations in extracellular pCO2 and [HCO3-]at constant pH caused only a transient change in contractility.3. An intracellular pH change can describe the above events.4. The changes in contractility caused by extracellular acid-basechanges could be explained by competition between Ca2+ and H+ions for a single process. 5. Assuming an electroneutral schemewhereby one extracellular Ca2+ ion or two intracellular H+ ionscompete for a binding site, the interior of ventricular cellsmust be better buffered than the extracellular fluid. 6. H+ions evoked a release of Ca2+ ions from a mitochondrial suspensionwith a time course similar to the partial recovery of tensionobserved during a respiratory acidosis. 7. Respiratory and metabolicacidosis depressed the action potential plateau and prolongedrepolarization. 8. The resting potential and the maximum rateof depolarization were unaffected by the above acid-base changes.9. An acidosis depressed Ca2+ influx through the slow inwardchannel by an amount sufficient to account for the observedcontractility changes. 10. It is concluded that between pH 7.6and 6.6 the major physiological effect of an acidosis is todepress the slow inward current as a result of an intracellularpH change.

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