Short-term administration of ethanol does not affect functional recovery from myocardial stunning in awake dogs

Role of acetaminophen in acute myocardial infarction

Acetaminophen, the active ingredient in Tylenol, is a widely used drug that is well known for its analgesic and antipyretic properties. Acetaminophen is a commonly used alternative to nonsteroidal anti-inflammatory drugs, which have recently been demonstrated to increase mortality after acute myocardial infarction (AMI). The safety and potential cardioprotective properties of acetaminophen in the setting of AMI have recently been investigated; however, the results from these studies have been inconclusive. Using both large (ovine) and small (rabbit) collateral-deficient animal models, we studied the effects of acetaminophen in the setting of reperfused AMI. In both species we studied the effects of acetaminophen on myocardial salvage and ventricular function. Additionally, we studied the effects of acetaminophen on myocardial perfusion in sheep and on myocyte apoptosis in rabbits. Sixteen sheep and twenty-two rabbits were divided into two groups and administered acetaminophen or a vehicle before undergoing ischemia and reperfusion. The ischemic period was 60 min in sheep and 30 min in rabbits. All animals were reperfused for 3 h. There were no significant differences observed in myocardial perfusion, myocyte apoptosis, or infarct size in acetaminophen-treated animals. Acetaminophen increased cardiac output and mean arterial pressure before ischemia in sheep but had no effect on any other hemodynamic parameter. In rabbits, no effect on cardiac output or blood pressure was detected. These results support the role of acetaminophen as a safe drug in the postmyocardial infarction setting; however, no significant cardioprotective effect of the drug could be demonstrated.

Effects of alcohol on intracellular pH regulators and electromechanical parameters in human myocardium

BACKGROUND

Disturbances in intracellular pH (pHi) of the heart can trigger major changes in the strength and rhythm of the heartbeat. It is well known that two extruders, Na+/H+ exchange (NHE) and Na+/HCO3- symporter (NHS), and a monocarboxylic acid transporter (MCT) are involved in acid-equivalent extruding in the human heart. Drinking alcohol has been proven to affect blood pressure and heart contractility and, sometimes, causes cardiac arrhythmia. To assess the effects of alcohol on pHi regulators and electromechanical parameters, various concentrations of alcohol were superfused into human myocardium in the present study.

METHODS

Human atrial myocardium was obtained from hearts of patients undergoing corrective cardiac surgery. Institutional rules for the protection of human subjects were observed. In the whole study, pHi was measured by an epifluorescent, ratiometric microspectrofluorimetry technique with the dye BCECF, while electrophysiological experiments were performed by traditional micropipette. NHE and NHS activities were measured after pHi recovery from intracellular acidosis induced by NH4Cl prepulse, while MCT activity was measured by a lactate adding/removing technique.

RESULTS

In pHi experiments, we demonstrated that alcohol could induce a biphasic, concentration-dependent (30-1000 mM) pHi change (i.e., alkalosis after acidosis) in human atrium in HEPES-buffered Tyrode solution. To a smaller extent, similar results were found when the superfusate was replaced by HCO3- -buffered Tyrode solution. NHE activity was increased by a moderate concentration of alcohol (30 mM), while it was inhibited in a concentration-dependent manner by higher concentrations of alcohol (>100 mM). On the contrary, 30-1000 mM alcohol increased the activity of NHS in a concentration-dependent manner. Surprisingly, MCT activity was not affected by alcohol. In electromechanical experiments, we found that alcohol (30-1000 mM) had a notable concentration-dependent inhibitory effect on the contractile force, while higher concentrations of alcohol (>100 mM) decreased the action potential amplitude, upstroke velocity, duration of repolarization, and force of contractions in a concentration-dependent way. All these alcohol-induced pHi changes and electromechanical inhibitions were reversible.

CONCLUSIONS

To our knowledge, this study provides the first evidence that alcohol can affect pHi in human myocardial tissue by changing the activity of acid extruders (i.e., NHE and NHS).

Protective and anti-protective effects of acute ethanol exposure in myocardial ischemia/reperfusion

Epidemiological data suggest that a cardioprotective effect of acute alcohol exposure exists in humans. Recent studies in animal models indicate that transient alcohol exposure can indeed reduce myocardial infarct size and exert a preconditioning-like protective effect akin to ischemic preconditioning (IPC). Moreover, the mechanism of alcohol-induced cardioprotection in part resembles the signaling cascade triggered by ischemic preconditioning, with adenosine receptors, PKC, protein tyrosine kinases, and mitochondrial K(ATP) channels all being implicated as key components. However, it was also seen, at least in the rabbit, that if alcohol were present during the ischemic insult, it could block its own protection. The primary protective effect of alcohol use is probably in the chronic setting where alcohol exposure causes a second window type of protection that persists for many days thereafter. Regular moderate drinking should keep the heart in a second window state indefinitely.