phosphocreatine and Alkalosis--Respiratory

During acute respiratory alkalosis, myocardial contractility initially increases but then declines toward control levels. To elucidate the mechanism of this response, two parallel strategies were adopted: isovolumic left ventricular developed pressure (DP) and intracellular pH (pHi) were measured in isolated ferret hearts using 31P-nuclear magnetic resonance spectroscopy, and isometric developed tension (DT) and intracellular Ca2+ concentration ([Ca2+]i) were measured in ferret papillary muscles using microinjected fura 2 salt. When hypocapnia was induced by sudden introduction of perfusate equilibrated with 2% CO2 (from 5% CO2 in control), DP increased to a maximum of 120 +/- 3% (SE; n = 7) of control within 40 s. Afterward, DP decreased toward control levels, reaching a new steady state in 2-3 min. In contrast, pHi increased from control (7.11 +/- 0.01) only after 30 s of hypocapnia and reached a peak of 7.25 +/- 0.02 between 80 and 100 s. Thus pHi lagged behind contractility. In contrast to pHi, [Ca2+]i changed in parallel with DT: when DT reached a maximum (251 +/- 63% of control; n = 5) during hypocapnia, the amplitude of [Ca2+]i transients also peaked (190 +/- 22% of control; n = 5). A simulation of contractile force based on our measurements of pHi and [Ca2+]i, along with published Ca(2+)-tension relations, described adequately the changes in developed force during hypocapnia. These results indicate that the biphasic changes in [Ca2+]i, coupled with an out-of-phase change in pHi, underlie the biphasic response of myocardial contractility to hypocapnia.

Topics: Adenosine Triphosphate; Alkalosis, Respiratory; Animals; Atenolol; Calcium; Carbon Dioxide; Energy Metabolism; Ferrets; Heart; Hydrogen-Ion Concentration; In Vitro Techniques; Magnetic Resonance Spectroscopy; Male; Myocardial Contraction; Myocardium; Phosphates; Phosphocreatine; Phosphorus; Ventricular Function, Left

The effect of pH of the reperfusion buffer on postischemic changes in tissue Ca and Na was examined in isolated Langendorff-perfused Sprague-Dawley rat hearts. Reperfusion began after 15-, 25-, or 60-min ischemia at 37 degrees C. After 60-min ischemia, reperfusion at pH 6.4 or 6.6 attenuated the reperfusion-induced Ca gain so long as the acidotic conditions were maintained (3.08 +/- 0.22, 1.37 +/- 0.41, and 16.96 +/- 1.18 mumol Ca gain/g dry wt for pH 6.4, 6.6, and 7.4, respectively after 15-min reperfusion). Conversely, reperfusion under alkalotic conditions (pH 7.9) after 60-min ischemia exacerbated the gain (27.45 +/- 4.75 and 8.92 +/- 1.53 mumol Ca gain/g dry wt during 5-min reperfusion at pH 7.9 and 7.4, respectively). Similar, but less pronounced Ca gains occurred during reperfusion after 15- or 25-min ischemia. Sodium content during reperfusion, but not during aerobic perfusion, was also found to be pH sensitive with acidosis causing a reduction and alkalosis an increase. These results could not be explained in terms of an effect of pH on recovery of high-energy phosphates, percentage "reflow" during reperfusion, or reperfusion-induced increases in tissue water or resting tension. The results are in agreement with the hypothesis that the "inhibitory" effect of acidosis on postischemic Ca overload could involve an effect of pH on the Na(+)-H+ exchanger and intracellular Ca storage.

Topics: Acidosis; Acidosis, Respiratory; Adenosine Triphosphate; Alkalosis; Alkalosis, Respiratory; Animals; Biomechanical Phenomena; Buffers; Coronary Disease; Female; Hydrogen-Ion Concentration; In Vitro Techniques; Mitochondria, Heart; Myocardial Reperfusion; Perfusion; Phosphocreatine; Rats; Rats, Inbred Strains; Time Factors

Topics: Acid-Base Equilibrium; Alkalosis, Respiratory; Ammonia; Animals; Bicarbonates; Blood; Brain; Carbon Dioxide; Energy Metabolism; Glucose; Hydrogen-Ion Concentration; Hyperventilation; Ketoglutaric Acids; Lactates; Malates; Partial Pressure; Phosphocreatine; Pyruvates; Rats; Ribonucleotides