Supression of ventricular extrasystoles by perhexiline

Electrophysiological and ECG Effects of Perhexiline, a Mixed Cardiac Ion Channel Inhibitor, Evaluated in Nonclinical Assays and in Healthy Subjects

Perhexiline has been used to treat hypertrophic cardiomyopathy. In addition to its effect on carnitine-palmitoyltransferase-1, it has mixed ion channel effects through inhibition of several cardiac ion currents. Effects on cardiac ion channels expressed in mammalian cells were assayed using a manual patch-clamp technique, action potential duration (APD) was measured in ventricular trabeculae of human donor hearts, and electrocardiogram effects were evaluated in healthy subjects in a thorough QT (TQT) study. Perhexiline blocked several cardiac ion currents at concentrations within the therapeutic range (150-600 ng/mL) with IC₅₀ for hCav1.2 ∼ hERG < late hNav1.5. A significant APD shortening was observed in perhexiline-treated cardiomyocytes. The TQT study was conducted with a pilot part in 9 subjects to evaluate a dosing schedule that would achieve therapeutic and supratherapeutic perhexiline plasma concentrations on days 4 and 6, respectively. Guided by the results from the pilot, 104 subjects were enrolled in a parallel-designed part with a nested crossover comparison for the positive control. Perhexiline caused QTc prolongation, with the largest effect on ΔΔQTcF, 14.7 milliseconds at therapeutic concentrations and 25.6 milliseconds at supratherapeutic concentrations and a positive and statistically significant slope of the concentration-ΔΔQTcF relationship (0.018 milliseconds per ng/mL; 90%CI, 0.0119-0.0237 milliseconds per ng/mL). In contrast, the JTpeak interval was shortened with a negative concentration-JTpeak relationship, a pattern consistent with multichannel block. Further studies are needed to evaluate whether this results in a low proarrhythmic risk.

Inhibition of HERG channels stably expressed in a mammalian cell line by the antianginal agent perhexiline maleate

Perhexiline has been used as an anti-anginal agent for over 25 years, and is known to cause QT prolongation and torsades de pointes. We hypothesized that the cellular basis for these effects was blockade of I(Kr). A stable transfection of HERG into a CHO-K1 cell line produced a delayed rectifier, potassium channel with similar properties to those reported for transient expression in Xenopus oocytes. Perhexiline caused voltage- and frequency-dependent block of HERG (IC50 7.8 microM). The rate of inactivation was increased and there was a 10 mV hyperpolarizing shift in the voltage-dependence of steady-state inactivation, suggestive of binding to the inactivated state. In conclusion, perhexiline potently inhibits transfected HERG channels and this is the probable mechanism for QT prolongation and torsades de pointes. Channel blockade shows greatest affinity for the inactivated state.

Slow inward current and cardiac arrhythmias

The slow inward current contributes to the normal electrical and contractile activity of several cardiac and vascular tissues and also may mediate the electrical abnormalities responsible for certain cardiac arrhythmias. The slow inward current differs from the fast inward sodium current in that it is carried primarily by calcium rather than sodium, requires a more positive level of membrane potential to be activated, has slower activation and inactivation kinetics, is responsible for normal depolarization in sinus and atrioventricular (AV) nodal cells and is blocked by a rather specific group of agents that includes verapamil, diltiazem and nifedipine. Recent data suggest that slow-channel openings occur in bursts, separated by silent periods, and that less negative membrane potentials and beta-adrenergic stimulation increase the probability that the channels will open. Inactivation of the channels is associated with a lower probability of channel opening. Slow-channel blocking agents such as verapamil, diltiazem and nifedipine appear to bind to activated, rather than rested, slow channels. Therefore, their effects are more prominent at faster pacing rates and at less negative membrane potentials. Clinically occurring cardiac arrhythmias dependent on the slow inward current include primarily sinus and AV nodal reentry and reciprocating tachycardia in the Wolff-Parkinson-White syndrome when one of the pathways incorporates the AV node. Damaged atrial, ventricular and specialized tissue also can generate slow response-mediated reentry or forms of automaticity that may be clinically important under certain circumstances.

Suppression of ventricular ectopic depolarizations by flecainide acetate, a new antiarrhythmic agent

Flecainide acetate, a new antiarrhythmic agent, was given orally to 11 hospitalized patients with chronic high-frequency ventricular ectopic depolarizations. Drug effectiveness was evaluated with a dose-ranging single-blind protocol, which included placebo control and washout periods. Twice-daily dosing (average daily dose 436 mg) completely suppressed all ventricular ectopic activity in five of 11 patients; average suppression in the 11 patients was 96.3%. Complex ventricular arrhythmias, which were present in all 11 patients during the placebo control period, were completely suppressed in eight patients and markedly suppressed in the other three patients during flecainide therapy. Ejection fraction and velocity of circumferential fiber shortening measured by M-mode echocardiography did not change significantly during flecainide dosing. Ventricular arrhythmias returned in all patients during the placebo washout period. During subsequent outpatient therapy with flecainide, significant suppression was present after 1 and 2 weeks of treatment (94.4% and 93.3%, respectively). Drug elimination was slow (average plasma half-life 20 hours). Ninety-five percent suppression of ventricular ectopic depolarization during dosing and 5% reappearance of arrhythmias during washout occurred with flecainide concentrations of 200-800 ng/ml. Side effects occurred in five of 11 patients, but did not require discontinuation of the drug. These results indicate that flecainide is a very effective antiarrhythmic agent that merits further clinical investigation.

High-performance liquid chromatographic assay of perhexiline maleate in plasma

A sensitive assay is described for the calcium antagonist perhexiline maleate. Alkalinized plasma was extracted with nb-hexane, the organic phase was evaporated, and the residue was dansylated prior to analysis by reversed-phase high-performance liquid chromatography using a fluorescence detector. Perhexiline was resolved from its mono- and dihydroxylated metabolites, and the limit of sensitivity was 5 ng of perhexiline/ml. This limit represents approximately 100 times the sensitivity of the previously described GLC assay. Single-dose pharmacokinetic studies were performed with 150- and 300-mg oral doses of perhexiline maleate in five patients with severe angina pectoris and impaired left ventricular function. Peak plasma perhexiline levels occurred 3-6 hr after drug ingestion in four patients and after 12-18 hr in the fifth patient. The mean elimination half-life, measured 24 hr after drug ingestion, varied with plasma perhexiline concentration. It was 11.2 +/- 2.1 hr after the 150-mg dose and 19.1 +/- 2.8 hr after the 300-mg dose. The mean ratio of areas under the concentration-time curve for the 300-versus 150-mg doses ws 5.3:1, suggesting that hepatic metabolism of perhexiline may be saturable and that the bioavailability of perhexiline is dose dependent.