Temperature-dependent inotropic effects of lignocaine and ethanol on rat heart papillary muscles.

1. The main objective of the present study was to investigate the temperature dependence of the cardiac inotropic effects of lignocaine and ethanol (EtOH). 2. We studied the in vitro inotropic actions and interactions of EtOH (2.4 g/L) and lignocaine (25 mg/L) on rat papillary muscles superfused with Tyrode's solution and stimulated at 1 Hz at either 37 or 30 degrees C. Peak tension developed (PTD), maximum velocity of development of tension (VmaxT) and time to peak tension (TPT) were measured. 3. At 37 degrees C, EtOH depressed PTD, while VmaxT and TPT remained unchanged. At 37 degrees C, lignocaine alone or in combination with EtOH depressed all three parameters. 4. At 30 degrees C, EtOH did not modify PTD or VmaxT, whereas TPT decreased. At 30 degrees C, lignocaine decreased TPT, but VmaxT did not change and the effect of lignocaine on PTD was smaller at 30 degrees C than at 37 degrees C. Ethanol and lignocaine in combination decreased all three parameters at 30 degrees C. However, the depression of VmaxT by the combination of lignocaine and EtOH was less at 30 degrees C than at 37 degrees C. 5. Hypothermia (30 degrees C) protected the myocardium against the depressant actions of EtOH and lignocaine, alone or in combination. With EtOH alone, the protection resulted in no change in PTD. When lignocaine was involved, the protection resulted in a weaker action on PTD and VmaxT. The temperature dependence of the action of lignocaine may explain, at least in part, the development of ventricular failure in cardiac surgical patients exposed to lignocaine during hypothermia and rewarming.

Actions and interactions of ethanol and imipramine on the rat sinus node.

We studied the actions and interactions of ethanol and imipramine on the sinus node. Strips of the right rat atrium including the sinus node were superfused with Tyrode's solution at 37 degrees C while beating spontaneously. The preparations were exposed to imipramine or ethanol alone as well as to the two drugs in combination while recording membrane potentials with standard intracellular microelectrodes. The results obtained show that ethanol 0.8 and 2.4 g/l exerted a positive chronotropic action. On the other hand, imipramine 0.25 mg/l did not modify the sinus node rate. However, it reduced significantly the positive chronotropic action of ethanol. The sinus node rate decreased under the action of a higher concentration of imipramine (1 mg/l). When ethanol was tested in combination with this concentration of imipramine, the effect of the latter prevailed. In conclusion, a concentration of imipramine that did not affect the sinus node rate antagonized the positive chronotropic action of ethanol. In addition, the negative chronotropic action of a higher concentration of imipramine prevailed over the positive action of ethanol. The results obtained provide additional support to the notion that the use of ethanol and cardioactive drugs in combination may result in significant changes in the actions of either of the two, or both. This is of clinical relevance, since at least some of the individuals under treatment with cardioactive drugs will be alcoholics and/or social drinkers.

Cardiac beta-adrenergic mediated chrono- and inotropic effects of imipramine in vitro.

Clinical and experimental studies show that tricyclic antidepressants in "therapeutic plasma concentrations" can increase heart rate, myocardial contractility and blood pressure. Our study was undertaken to analyze the role of beta-adrenergic stimulation in the chronotropic and inotropic effects of imipramine. Strips of rat right atrium including the sinus node, which were beating spontaneously, were used to study chronotropism. Strips of the left atrium, electrically stimulated to beat at 1 Hz, were used to study inotropism. The preparations were superfused in vitro with Tyrode's solution at 37 degrees C and exposed to imipramine while recording membrane potentials or force of contraction. Imipramine exerted dose-dependent biphasic actions. Imipramine 0.8 microM produced positive chronotropic and inotropic actions which were blocked by propranolol. Imipramine 1.6 microM depressed the sinus node automaticity, but it did not modify the force of contraction. Imipramine 3.2 microM depressed both the sinus node automaticity and the myocardial contractility. In conclusion, imipramine in "therapeutic plasma concentrations" produces beta-adrenergic mediated cardiac positive chronotropic and inotropic actions. The possible mechanisms of the depressant effects of imipramine itself on automaticity and contractility are still not clear. The results presented can explain stimulatory and depressant cardiac effects of therapeutic doses and overdoses of tricyclic antidepressants.

Characterization of angiotensin pressor responses in the turtle Pseudemys scripta.

Studies were conducted in turtles (Pseudemys scripta) to characterize vascular responses to administration of exogenous angiotensin [Asp1-Ile5]angiotensin II (AII). Marked pressor responses were present following AII administration (2 microgram/kg iv). The pressor response was completely blocked by concomitant administration of an analogue of AII, [Sar1-Ile8]AII. Both alpha-receptor blockade with phenoxybenzamine or catecholamine depletion by reserpine administration reduced the pressor response approximately 50%. Further treatment with [Sar1-Ile8]AII completely blocked the AII pressor response. We conclude that the pressor response to AII in this species that represents an ancient group of reptiles includes a catecholamine-dependent component and direct vascular receptors, both of which are sensitive to AII.