beta-endorphin and Acidosis

Elevated blood levels of beta-endorphin have been associated with high-intensity exertion, but the stimulus for beta-endorphin release is unknown. Some studies of exercise have associated beta-endorphin release with increased exertion levels, but other evidence suggests that acidosis may stimulate the release of beta-endorphin. This study examines acidosis as a possible stimulus for beta-endorphin release by examining the effects of arterial blood gases, whole blood lactate, and respiratory changes on beta-endorphin levels and by examining the effects of buffering during exercise on these levels. Initially, seven healthy adult males were evaluated during incremental exercise. During incremental exertion, indicators of acidosis correlated with endorphin levels: pH (r = -0.94), PCO2 (r = -0.85), HCO3- (r = -0.88), base excess (r = -0.94), and lactate (r = 0.89). A multivariate model showed that beta-endorphin levels were predicted best by the change in base excess. A time course analysis showed that beta-endorphin responses peaked postexercise and paralleled blood acid levels. Subsequently, subjects were compared after alkali loading and placebo during constant-intensity exercise at 85% of maximal exertion to determine whether acidosis is necessary for endorphin release. Treatment with a buffer, which effectively maintained pH above 7.40, significantly suppressed endorphin release (F = 3.07; P < 0.0001). The results of this study indicate that acidosis rather than any other physiological change associated with high-intensity exertion is the primary stimulus for beta-endorphin release.

Topics: Acidosis; Adult; beta-Endorphin; Blood Gas Analysis; Buffers; Humans; Hydrogen-Ion Concentration; Lactates; Lactic Acid; Male; Middle Aged; Physical Exertion; Respiratory Function Tests; Sodium Bicarbonate

Using the opiate receptor antagonist naloxone, we tested the hypothesis that endorphins act on opiate receptors to cause cardiovascular depression in primate shock. Mean arterial pressure (MAP), cardiac output, and left ventricular contractility (LV dP/dtmax) were measured in 34 anesthetized cynomolgus monkeys. Hemorrhagic shock was induced by bleeding into a heparinized reservoir to achieve (t = 0) and maintain MAP at 45 mm Hg. At t = 60 min, the reservoir was clamped and the animals were treated with 2 mg/kg plus 2 mg/kg.h naloxone (n = 5) or 0.9% NaCl as a control (n = 5). There were no significant differences in the cardiovascular responses to naloxone and saline when acid-base balance and core body temperature were not controlled. Pressor responses to naloxone, however, were present in proportion to arterial pH and body temperature. When these factors were controlled, naloxone (n = 6) significantly increased MAP and LV dP/dtmax by 48% and 83%, respectively, whereas saline (n = 6) had no significant effect. Blood was reinfused at t = 120 min, and survival rate at 72 h was significantly (p = .01) higher with naloxone (3/6) than saline controls (0/6). In the endotoxic shock model, cynomolgus monkeys were treated with 2 mg/kg plus 2 mg/kg.h naloxone (n = 6) or 0.9% NaCl (n = 6) when MAP reached 75 mm Hg or its nadir 60 to 90 min after Escherichia coli endotoxin, 5 mg/kg iv. Naloxone significantly increased MAP and LV dP/dtmax by 24% and 22%, respectively, whereas saline had no effect. Survival rate at 48 h was significantly (p = .01) higher with naloxone (6/6) than saline (1/6). Plasma beta-endorphin and beta-lipotropin concentrations rose three to five-fold in both shock models and were not affected by treatment. We conclude that endorphins are activated in primate shock and act on opiate receptors to contribute to the cardiovascular depression found with hemorrhage and endotoxemia.

Topics: Acidosis; Animals; beta-Endorphin; beta-Lipotropin; Cold Temperature; Female; Hemodynamics; Macaca fascicularis; Male; Naloxone; Shock, Hemorrhagic