Acute electrophysiological effects of intravenous milnacipran, a new antidepressant agent.

Milnacipran is a new antidepressant agent selected from a series of cycloproprane derivatives. The aim of this study was to investigate the acute electrophysiological effects and the tolerance of intravenous administration of this drug in 10 patients without any abnormality as shown in an electrophysiological study done for various complaints. Milnacipran was given over a 30-min period at doses of 0.2 mg/kg (2 patients), 0.4 mg/kg (2 patients) and 0.8 mg/kg (6 patients). The most significant alterations observed in this study were increases in heart rate (average of maximal increase: +19.5% at 50 min, P = 0.06) and systolic blood pressure (average of maximal increase: +21.5% at 10 min, P < 0.005), and decreases in the functional refractory period of the atrium (-3%, P < 0.05), the atrioventricular node (-9%, P < 0.005) and the effective refractory period of the right ventricle (-10.8%, P < 0.05) at 50 min. The sinus node function was improved in nine patients but depressed in one patient with previous slight baseline sinus node alterations. Milnacipran being devoid of both anticholinergic and monoamine oxidase inhibition activities, these alterations could be related to inhibition of noradrenaline uptake leading to an increase of adrenergic activities. No other ECG or electrophysiological parameters were significantly altered. Five of the 10 patients reported transient nausea, four of them for the highest dosage (0.8 mg/kg) and at the moment of peak of milnacipran plasma level. In conclusion, electrophysiological effects of intravenous milnacipran are negligible. These findings differ from those, well described in the literature, for imipramine-like antidepressant agents.(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of acute and chronic administration of acebutolol on the right ventricular effective refractory period in conscious dogs.

beta-Adrenergic blocking drugs are effective in reducing sudden cardiac death after acute myocardial infarction but the precise mechanism of this effect is unclear. We investigated the acute and chronic effects of acebutolol, a beta-adrenergic blocker, on electrocardiographic parameters, diastolic excitability threshold (DET), and right ventricular effective refractory period (RVERP) in chronically instrumented conscious dogs. These parameters were determined during spontaneous sinus rhythm and at a fixed pacing rate (200 beats/min). Acebutolol (0.5, 1, and 5 mg/kg i.v.) decreased the heart rate (HR) (by 23, 26, and 24%, respectively) without effects on any electrocardiographic parameters or on the DET. The maximal increases in ERP were 4.7, 7, and 7.8%, respectively, during pacing and 8.5, 13.3, and 10.3%, respectively, during sinus rhythm. Acebutolol, 10 mg/kg/day P.O. for 6 weeks, reduced the HR from the third day onward without altering the PR, QRS, QT, or QTc intervals or the DET. The increase in ERP was significant from the third day (14%) during pacing and from the seventh day (15.5%) during sinus rhythm. The degree of prolongation of the ERP subsequently remained stable during the 6 weeks of treatment. The ERP returned to the baseline value 7 days after acebutolol withdrawal. This increase in ERP, which was more marked during chronic oral treatment, could contribute to the documented protective effect of the beta-blocking drugs against sudden cardiac death after myocardial infarction.

Comparative electrophysiologic effects of metabolites of quinidine and hydroquinidine.

To evaluate whether the hydroxylated metabolites of quinidine (Q) and hydroquinidine (HQ): hydroxy-3S-quinidine (OH-Q) and hydroxy-3S-hydroquinidine (OH-HQ), exert electrophysiologic effects and participate in the therapeutic action of the parent drugs, we examined and compared the effects of the metabolites and the parent drugs on the electrical activity of guinea pig ventricular cells recorded by standard microelectrode technique. In addition, we investigated the potential arrhythmogenic properties of these compounds in rabbit Purkinje fibers in low K+ (2.7 mM) Tyrode's solution. The concentration [C]-, frequency-, and voltage-dependent effects of the drugs were investigated. Maximum upstroke velocity of phase 0 (Vmax) was [C]-dependently depressed by both OH-Q and OH-HQ but at a lesser degree than with Q and HQ, respectively: at the [C] of 50 microM, Vmax depression attained 26.7 +/- 2.6% with OH-Q versus 45.9 +/- 1.6% with Q and 32.3 +/- 1.9% with OH-HQ versus 54.6 +/- 1.4% with HQ. This effect was frequency and voltage dependent without significant differences between the four compounds. In the presence of equipotent [C], recovery kinetics of Vmax was significantly slower with metabolites than with respective parent drugs. In contrast, the effects of metabolites on action potential duration at 90% of repolarization (APD90) and effective refractory period (ERP) differed from those observed with parent drugs. With metabolites, APD90 and ERP were increased in a [C]-dependent manner, whereas the Q- and HQ-induced lengthening in APD90 and ERP was observed only at low concentration and low frequency. In addition, the OH-Q- and OH-HQ-induced APD90 lengthening was not altered by increasing pacing rate. In rabbit Purkinje fibers, increase in cycle length and prolonged exposure to either metabolites or parent drug caused early afterdepolarizations (EADs) and triggered activity. With all drugs tested, EADs arose more frequently at the plateau level than at the final repolarization of AP, but the incidence of EADs appeared to be much lower with metabolites than with parent drugs. The present results demonstrate that OH-Q and OH-HQ exert qualitatively similar but quantitatively less potent depressant effects on Vmax than Q and HQ, respectively, but differ in the lengthening effect on APD. We suggest that metabolites may participate in class I antiarrhythmic action of their respective parent drug and contribute to their arrhythmogenicity.

[Unwanted cardiovascular effects of anti-arrhythmia agents]. / Effets indésirables cardiovasculaires des antiarythmiques.

Antiarrhythmic drugs can cause many undesirable side effects affecting a number of organs and functions. Of those which affect the cardiovascular system, the proarrhythmic and negative inotropic effects are the most serious. Proarrhythmic effects, suggested by an aggravation of an arrhythmia or the induction of a previously undocumented arrhythmia, may be favorised by the presence of an arrhythmogenic substrate (unidirectional lock, delayed conduction, dual conduction pathways, low thresholds of depolarisation or fibrillation, presence of zones of hyperautomaticity...), "triggering" mechanisms (extrasystoles, variations of heart rate, after-depolarisation) and by changes in the cardiac environment (variations of autonomic nervous tone and hormonal changes, electrolytic or metabolic disorders...). An antiarrhythmic may have a beneficial action on one of these factors (for example, suppression of extrasystoles) but an aggravating effect on others (for example, an increase in the heart rate, creation of zones of reentry). This probably explains the fact that, for the moment, only molecules which have multifactorial modes of action have been shown to be beneficial in arrhythmias after myocardial infarction. Negative inotropic effects may be directly responsible for a deterioration in the hemodynamic status of patients on antiarrhythmics and indirectly responsible for aggravating arrhythmia by altering the anatomical substrate, so favorising proarrhythmic effects. The negative inotropic action may be related to ionic mechanisms (lowering intracellular calcium concentration due to blockade of the sodium channel by Class I antiarrhythmics) or to indirect mechanisms (reduced sympathetic tone, non-specific beta inhibition, calcium channel blockade, decreased left ventricular compliance, vasoconstrictor effects...).(ABSTRACT TRUNCATED AT 250 WORDS)