Effect of SUN 1165, a new potent antiarrhythmic agent, on the kinetics of rate-dependent block of Na channels and ventricular conduction of extrasystoles

Effects of SUN 1165, disopyramide, lorcainide, and mexiletine were studied either on the kinetics of onset of and recovery from rate-dependent depression of maximum rate of rise of phase 0 action potential (Vmax) in isolated guinea pig papillary muscles using standard microelectrode techniques or on intraventricular conduction time of extrasystoles evoked at varied coupling intervals in anesthetized dogs. SUN 1165 and lorcainide produced a slow-developing rate-dependent block of Vmax with the rate constant of 0.12 AP-1 and 0.09 AP-1, respectively. Mexiletine also produced a rate-dependent block of Vmax, but with very rapid onset so as not to be fitted by a single exponential curve. Disopyramide produced an intermediate rate-dependent block of Vmax with the rate constant of 0.46 AP-1. The time constants for recovery from the rate-dependent block for SUN 1165, lorcainide and disopyramide were 27.3-28.2, 23.2, and 17.0 s, respectively, while that for mexiletine was 0.118 s. SUN 1165, lorcainide, and disopyramide slowed ventricular conduction time of extrasystoles at all coupling intervals of 800-250 ms. On the other hand, mexiletine slowed conduction time at short coupling intervals of 500-250 ms. These findings suggest that, like lorcainide, SUN 1165 belongs to class Ic antiarrhythmic agents, and that SUN 1165 and lorcainide as well as disopyramide with slow and intermediate kinetics and mexiletine with fast kinetics may inhibit ventricular extrasystoles conducted at long and short range of coupling intervals, respectively.     

Differing electrophysiological effects of class IA, IB and IC antiarrhythmic drugs on guinea-pig sinoatrial node

Standard microelectrode techniques were used to study the effects of class IA (quinidine, disopyramide, procainamide), IB (lignocaine, mexiletine, tocainide) and IC (flecainide, encainide, lorcainide) antiarrhythmic drugs on action potentials in spontaneously beating sino-atrial node cells from guinea-pigs. The IA drugs all produced significant slowing of spontaneous rate in therapeutic concentrations. The IB agents did so only in concentrations well above therapeutic levels and the IC drugs were of intermediate potency. All nine drugs markedly slowed the repolarization rate and this was the major mechanism of sinus slowing for the IA and IC compounds. The IB drugs shared this effect but prolongation of phase 4 by reduction of the slope of diastolic depolarization was also a prominent feature of their action.     

Assessment of drug effects on spontaneous and induced ventricular arrhythmias in a 24-h canine infarction model

The antiarrhythmic efficacy of encainide, sotalol, flecainide and disopyramide was evaluated in anesthetized dogs subjected to 2-stage total occlusion of the left anterior descending coronary artery. Utilization of this canine model, while anesthetized, permitted the assessment of drug effects not only on uni- and/or multi-focal ectopic ventricular arrhythmias, but also on dysrhythmias associated with aberrant conduction or reentrant excitation pathways. The former was assessed by quantification of ectopic-to-total beat ratios while the later was determined by subjecting the animal to provocative stimuli which produced repetitive ventricular responses. At the cumulative i.v. doses studied, encainide (0.5-4 mg/kg), flecainide (1-8 mg/kg) and disopyramide (0.3-10 mg/kg), but not sotalol (2-8 mg/kg), effectively suppressed ventricular ectopic activity in a dose-related manner. In contrast, sotalol was highly effective in preventing the induction of reentrant ventricular tachyarrhythmias. Disopyramide was only modestly active, while flecainide and encainide had the least favorable profiles of effect in suppressing re-entry arrhythmias in this model. Based on these observations, the anesthetized Harris dog appears to represent a useful two-faceted in vivo model for use in the evaluation of potential antiarrhythmic agents.     

New antiarrhythmic drugs

While controversy still exists as to the precise indications for the treatment of all forms of ventricular arrhythmia, advances in the number and, more importantly, type of antiarrhythmic drugs can provide the clinician with a rational basis for selecting antiarrhythmic drug therapy. A host of new agents with different pharmacokinetic and electrophysiological actions are now available, and can be compared or contrasted to conventional antiarrhythmic agents such as quinidine, procainamide, disopyramide, lignocaine (lidocaine) and bretylium. This review summarises the electrophysiological, haemodynamic, pharmacokinetic, and efficacy and safety data of mexiletine, tocainide, flecainide, encainide, propafenone, amiodarone, sotalol, pirmenol, cibenzoline (cifenline) and ethmozine (moracizine, moricizine), and aims to provide a basis on which clinicians can compare and contrast these agents and form an algorithm for selection of antiarrhythmic drug therapy in the treatment of patients with ventricular arrhythmias.     

Impact of stereoselectivity on the pharmacokinetics and pharmacodynamics of antiarrhythmic drugs

Many antiarrhythmic drugs introduced into the market during the past three decades have a chiral centre in their structure and are marketed as racemates. Most of these agents, including disopyramide, encainide, flecainide, mexiletine, propafenone and tocainide, belong to class I antiarrhythmics, whereas verapamil is a class IV antiarrhythmic agent. Except for encainide and flecainide, there is substantial stereoselectivity in one or more of the pharmacological actions of chiral antiarrhythmics, with the activity of enantiomers differing by as much as 100-fold or more for some of these drugs. The absorption of chiral antiarrhythmics appears to be nonstereoselective. However, their distribution, metabolism and renal excretion usually favour one enantiomer versus the other. In terms of distribution, plasma protein binding is stereoselective for most of these drugs, resulting in up to two-fold differences between the enantiomers in their unbound fractions in plasma and volume of distribution. For disopyramide, stereoselective plasma protein binding is further complicated by nonlinearity in the binding at therapeutic concentrations. Hepatic metabolism plays a significant role in the elimination of these antiarrhythmics, accounting for >90% of the elimination of mexiletine, propafenone and verapamil. Additionally, in most cases, significant stereoselectivity is observed in different pathways of metabolism of these drugs. For some drugs, such as propafenone and verapamil, the stereoselectivity in metabolism is further complicated by nonlinearity in one or more of the metabolic pathways. Further, the metabolism of a number of chiral antiarrhythmics, such as mexiletine, propafenone, encainide and flecainide, cosegregates with debrisoquine/sparteine hydroxylation phenotype. Therefore, it is not surprising that a wide interindividual variability exists in the metabolism of these drugs. Excretion of the unchanged enantiomers in urine is an important pathway for the elimination of disopyramide, flecainide and tocainide. The renal clearances of both disopyramide and flecainide exceed the filtration rate for these drugs, suggesting the involvement of active tubular secretion. However, the stereoselectivity in the renal clearance of these drugs, if any, is minimal. Similarly, there is no stereoselectivity in the renal clearance of tocainide, a drug that undergoes tubular reabsorption in addition to glomerular filtration. Overall, substantial stereoselectivity has been observed in both the pharmacokinetics and pharmacodynamics of chiral antiarrhythmic agents. Because the effects of these drugs are related to their plasma concentrations, this information is of special clinical relevance.     

Identification of antiarrhythmic drugs and their metabolites in urine

Identification of the antiarrhythmic drugs ajmaline, aprindine, diltiazem, disopyramide, flecainide, gallopamil, lidocaine, lorcainide, mexiletine, phenytoin, prajmaline, propafenone, quinidine, sparteine, tocainide and verapamil and their metabolites in urine is described. After acid hydrolysis of the conjugates, extraction and acetylation, the urine samples were analysed by computerized gas chromatography-mass spectrometry. Using ion chromatography with the selective ions m/z 58, 72, 84, 86, 136, 224, 266, and 426, the possible presence of antiarrhythmic drugs and/or their metabolites was indicated. The identity of positive signals in the reconstructed ion chromatograms was confirmed by a visual or computerized comparison of the stored full mass spectra with the reference spectra. The ion chromatograms, reference mass spectra and gas chromatographic retention indices (OV-101) are documented. The method presented is integrated in a general screening procedure (general unknown analysis) for several groups of drugs.     

Circulatory and myocardial effects of different sodium antagonistic drugs in comparison to the calcium antagonist verapamil

The hemodynamic effects of intravenous class I and class IV antiarrhythmic drugs were investigated at different doses in comparison. In open-chest rats hemodynamic measurements in the intact circulation and isovolumic registrations 5 min after infusion of flecainide (2, 4, 8 mg/kg), disopyramide (1, 2, 4, 8 mg/kg), quinidine (5 and 10 mg/kg) and verapamil (0.35, 0.7, 1.5 mg/kg) were compared to saline controls. After clinically usual doses all investigated drugs had no effects on stroke volume, cardiac output, dp/dtmax and systemic resistance. The isovolumic pressure generating capacity of the left ventricle was not decreased at these doses. High intravenous doses of the drugs, however, caused a significant depression of myocardial performance (pressure generating capacity). Furthermore, flecainide decreased mean aortic pressure and heart rate, while disopyramide had no significant effect on the peripheral circulation. Blocking of the autonomic system (1 mg/kg propranolol and 0.1 mg/kg atropine) did not change significantly the action of disopyramide. Quinidine lowered heart rate and pressures. Verapamil reduced the heart rate and tended to decrease the mean aortic pressure. Besides the negative inotropic action of high doses the different hemodynamic profiles of class I and class IV antiarrhythmic drugs might be of importance for intravenous application in patients with left ventricular dysfunction.     

Disopyramide. A reappraisal of its pharmacodynamic and pharmacokinetic properties, and therapeutic use in cardiac arrhythmias

Disopyramide is a widely used class IA antiarrhythmic drug with a pharmacological profile of action similar to that of quinidine and procainamide. Over the past 10 years disopyramide has demonstrated its efficacy in ventricular and atrial arrhythmias. In therapeutic trials, usually involving small numbers of patients, the efficacy of disopyramide was comparable with that of mexiletine, perhexiline, tocainide, propafenone or prajmalium. Recent comparisons with quinidine have confirmed the similar efficacy and better tolerability of disopyramide. The suggestion from initial studies that disopyramide may be less effective than amiodarone or flecainide requires further investigation. In addition, studies have failed to demonstrate that the early administration of disopyramide after acute myocardial infarction decreases important arrhythmias or early mortality. Thus, disopyramide is now well established as an effective antiarrhythmic drug in ventricular and supraventricular arrhythmias although its role in therapy relative to that of recently introduced antiarrhythmic agents is not clear.     

Efficacy and plasma concentrations of SC-36602 in canine models of ventricular arrhythmia

The antiarrhythmic effectiveness of a new class I agent, SC-36602, was evaluated in two canine models of ventricular arrhythmia. In a Harris coronary ligation-induced arrhythmia model, SC-36602 significantly reduced ectopic rate at doses of 8 mg/kg i.v. and 15, 20 and 30 mg/kg per os. In a ouabain-induced arrhythmia model, a 9 mg/kg i.v. dose of SC-36602 had a sustained (greater than or equal to 60 min) antiarrhythmic effect. The approximate plasma concentration of SC-36602 necessary for measurable antiarrhythmic activity was estimated to be 2-7 micrograms/ml after either i.v. or oral administration. No adverse cardiovascular or central nervous system effects were observed in conscious or anesthetized dogs in response to SC-36602.     

Frequency-dependent effects of several class I antiarrhythmic drugs on Vmax of action potential upstroke in canine cardiac Purkinje fibers

Vmax of the action potential upstroke in canine cardiac Purkinje fibers was studied in the presence of seven class I antiarrhythmic drugs--lidocaine (4 micrograms/ml), mexiletine (4 micrograms/ml), propranolol (0.9 micrograms/ml), procainamide (30 micrograms/ml), quinidine (5 micrograms/ml), flecainide (4 micrograms/ml), and disopyramide (3.1 micrograms/ml)--at constant cycle lengths (CCL) and after abrupt changes in cycle length (ACCL). The time constant of Vmax recovery after ACCL at a basic cycle length of 500 ms was 0.09 +/- 0.01 s for lidocaine, 0.18 +/- 0.03 s for mexiletine, 1.35 +/- 0.20 s for propranolol, 4.4 +/- 0.8 s for procainamide, 8.3 +/- 1.2 s for quinidine, 11.0 +/- 0.9 s for flecainide, and 37.9 +/- 9.4 s for disopyramide. These values were similar to those reported by others in guinea pig papillary muscle, and, with the exception of flecainide, conformed to the scheme proposed by Courtney (J Mol Cell Cardiol 1980; 12:1273-86) based on the molecular weight and lipid solubility hypothesis. Each drug altered the Vmax differently at CCL from after ACCL at the same diastolic intervals. The magnitude of these differences and the range of diastolic intervals at which they were present varied among different drugs. These observations explain differences in the drug effects on the Vmax of the regularly and prematurely occurring depolarizations. In the presence of lidocaine and mexiletine, the recovery kinetics of Vmax were not altered by CCL within the 300-1,500-ms range, and the magnitude of Vmax depression was not influenced by action potential duration within the 200-270-ms range.     

Clinical implications of variable antiarrhythmic drug metabolism.

Due to their narrow therapeutic indices, antiarrhythmic drugs have a great potential for adverse outcome. This is amplified by extreme inter-individual variability in their disposition and their pharmacological actions. Genetically determined inter-individual differences in metabolism account for a great deal of this variability. However, because of active metabolites, chirally-specific actions and chirally-specific metabolism, it is not possible to generalize about the outcome of phenotypic differences in the metabolism of a given drug. Careful study of these factors can enable physicians to understand the spectrum of potential responses to a drug. Newly developed molecular biology techniques now make it possible to determine the genotype for the CYP2D6 gene that controls metabolism of many antiarrhythmic drugs. This information, combined with a full understanding of the drugs' clinical pharmacology now makes it possible to predict the clinical outcome for drugs such as encainide, flecainide, mexiletine, propafenone and combinations of these drugs with quinidine.     

Human organic cation transporter 3 mediates the transport of antiarrhythmic drugs

Antiarrhythmic drugs have been considered to be transported by the organic cation transport system. The purpose of this study was to elucidate the molecular mechanism underlying the transport of antiarrhythmic drugs using cells from the second segment of the proximal tubule (S2) cells of mice expressing human-organic cation transporter 3 (S2 human-OCT3). The antiarrhythmic drugs tested were cibenzoline, disopyramide, lidocaine, mexiletine, phenytoin, pilsicanide, procainamide and quinidine. Human-OCT3 mediated a time- and dose-dependent uptake of quinidine and lidocaine, with Km values of 216 and 139 microM, respectively. Human-OCT3 also mediated the uptake of disopyramide and procainamide but not that of phenytoin. All antiarrhythmic drugs tested inhibited histamine uptake mediated by human-OCT3 in a dose-dependent manner. The IC50 values of antiarrhythmic drugs for human-OCT3 ranged between 0.75 and 656 microM. Kinetic analysis revealed that disopyramide, lidocaine, procainamide and quinidine inhibited histamine uptake mediated by human-OCT3 in a competitive manner. In conclusion, these results suggest that human-OCT3 mediates the transport of antiarrhythmic drugs, which may be the mechanism underlying the distribution and the elimination of these drugs.     

Onset and recovery kinetics of V̇max reduction by class I antiarrhythmic agents: Relation to frequency dependence

The onset and recovery kinetics of rate-dependent n?max reduction in guinea pig papillary muscles were measured for a new class I antiarrhythmic agent, bidisomide (SC-40230), and compared to standard agents lidocaine, flecainide, and disopyramide. Frequency-independent reduction of n?max was found to be associated with long recovery time rather than onset kinetics or other factors, such as molecular weight. Bidisomide and flecainide had the slowest onset rates (τ=4 and 6 sec at 3.3 Hz, respectively) while lidocaine and disopyramide had much faster onset rates (τ=0.2 and 0.5 sec at 3.3 Hz, respectively). Recovery time constants were obtained by using the first n?max value following a variable recovery time period after a stimulus train used to produce drug blockade. Flecainide and lidocaine had recovery time constants on the order of seconds (19 and 1 sec, respectively). Disopyramide, unlike previously reported, and bidisomide had very slow recovery time constants, on the order of minutes (2.4 and 8.8 min, respectively). The onset of n?max reduction caused by bidisomide was most similar to flecainide, but the recovery time was most similar to disopyramide. The n?max reduction caused by bidisomide and disopyramide was frequency-independent (between 1 and 3.3 Hz), while that caused by flecainide and lidocaine was frequency-dependent. Both bidisomide and disopyramide are frequency-independent, which may be due to their long time constants for recovery from block.     

Moricizine: a new class I antiarrhythmic

The chemistry, pharmacology, pharmacokinetics, clinical efficacy, adverse effects, and dosage of the Class I antiarrhythmic agent moricizine hydrochloride are reviewed. Moricizine is chemically similar to the phenothiazines but does not appear to block dopaminergic receptors. Its major electrophysiologic actions are a concentration-dependent decrease in maximum rate of phase 0 depolarization; increased rates of phase 2 and 3 repolarization, decreased action potential duration, and decreased effective refractory period. Moricizine causes a dose-related prolongation of the PR interval and of AV nodal, infranodal, and intraventricular conduction times but has little effect on ventricular repolarization. The antiarrhythmic and electrophysiologic effects are not correlated with plasma concentrations of the drug or its metabolites. Moricizine reduces the occurrence of ventricular premature contractions (VPCs), couplets, and nonsustained ventricular tachycardia. It appears to suppress symptomatic nonsustained ventricular tachycardia, sustained ventricular tachycardia, and ventricular fibrillation or flutter. Moricizine appears to be as effective as quinidine and more effective than disopyramide, propranolol, and imipramine but less effective than flecainide and encainide at reducing VPCs. Moricizine continues to be evaluated in the Cardiac Arrhythmia Suppression Trial, which was designed to assess the long-term benefit of arrhythmia suppression in patients with left ventricular dysfunction after myocardial infarction. Moricizine seems to be better tolerated than quinidine, disopyramide, and imipramine and to have less proarrhythmic potential than flecainide or encainide. Noncardiac adverse effects include dizziness, nausea, and headache. Cimetidine appears to decrease moricizine clearance, and decreased theophylline clearance has been reported in subjects given moricizine. The usual adult dosage of moricizine hydrochloride is 600-900 mg/day given in three divided doses; an every-12-hour regimen may be used in some patients. Because of the risk of proarrhythmic effects, indications are limited to treatment of documented life-threatening arrhythmias. Moricizine will compete with other agents as first-line therapy for life-threatening arrhythmias.     

Inhibitory effects of antiarrhythmic drugs on phenacetin O-deethylation catalysed by human CYP1A2

Aims The aim of the study was to clarify whether the pharmacokinetic interaction between theophylline and mexiletine is mediated by inhibition of CYP1A2 and to assess the possible interaction potential of other antiarrhythmic drugs with drugs metabolized by CYP1A2.
Methods The inhibitory effects of mexiletine and 10 antiarrhythmic drugs on phenacetin O -deethylation, a marker reaction of CYP1A2, were studied using human liver microsomes and cDNA-expressed CYP1A2.
Results Propafenone and mexiletine inhibited phenacetin O -deethylation with I C ₅₀ values of 29 and 37  μm, respectively. Disopyramide, procainamide and pilsicainide produced negligible inhibition of phenacetin O -deethylation (I C ₅₀>1  mm ). Amiodarone, bepridil, aprindine, lignocaine, flecainide and quinidine inhibited phenacetin O -deethylation in a concentration-dependent manner, although the inhibitory effects were relatively weak with I C ₅₀ values ranging from 86 to 704  μm. Propafenone and mexiletine selectively abolished the high-affinity component of phenacetin O -deethylation in human liver microsomes. In addition, propafenone and mexiletine inhibited phenacetin O -deethylation catalysed by cDNA-expressed CYP1A2.
Conclusions These data suggest that, among the antiarrhythmic drugs studied, propafenone and mexiletine are relatively potent inhibitors of CYP1A2, which may cause a drug-drug interaction with drugs metabolized by CYP1A2.     

Rapid infusions of bidisomide or disopyramide in conscious dogs: effect of myocardial infarction on acute tolerability.

The acute tolerability of rapid infusions of bidisomide or disopyramide was evaluated in normal conscious dogs and in conscious dogs 48 h after the creation of myocardial infarctions (MIs). Both drugs were given in total doses of 15 mg/kg (1.5 x the canine antiarrhythmic dose for each drug). Bidisomide was well tolerated at infusion rates of 3, 5, 11, and 15 mg/kg/min by normal dogs. Disopyramide was well tolerated, except for anticholinergic effects, by normal dogs given infusions at rates of 1.5 and 3 mg/kg/min. Disopyramide caused a ventricular arrhythmia at 4.5 mg/kg/min in one dog, however. Bidisomide (15 mg/kg/min) was well tolerated and antiarrhythmic in dogs with infarctions. Disopyramide (3 and 4.5 mg/kg/min) was lethal in dogs that had myocardial infarctions. A 1 mg/kg/min infusion rate of disopyramide was antiarrhythmic and well tolerated, except for anticholinergic effects, in the post-MI dogs. Both drugs prolonged the ECG lead II P duration, PR interval (bidisomide more so than disopyramide), and QRS duration. Both bidisomide and disopyramide shifted the mean electrical axis of the QRS complex from a right axis deviation to the normal range in dogs with infarctions. The data indicated that the desired cardiac electropharmacologic effects of bidisomide can be achieved in a 1 min infusion. Normal dogs, and especially dogs with infarctions, revealed the potential hazards of rapidly infusing disopyramide.     

High-performance liquid chromatographic determination of 12 antiarrhythmic drugs in plasma using solid-phase column extraction

Monitoring of plasma concentrations of antiarrhythmic drugs may assist in individualizing dosage regimens and in assessing patient compliance. A rapid high-performance liquid chromatographic assay using solid-phase column extraction was developed for the following antiarrhythmic drugs: amiodarone, aprindine, disopyramide, flecainide, lidocaine, lorcainide, mexiletine, procainamide, propafenone, sotalol, tocainide, and verapamil. As most of the antiarrhythmic drugs are basic compounds, good adsorption on the extraction columns was obtained by alkalinization; aprindine, however, was applied at neutral pH and amiodarone at pH 3.5. After washing with water, the compounds were eluted with methanol, but amiodarone was eluted with a mixture of acetonitrile and acetate buffer at pH 5 (8/2, vol/vol). Most of the eluates were evaporated to dryness and reconstituted in the mobile phase; for amiodarone, disopyramide, and tocainide, direct injection onto the column was performed. Separation was done on a Spherisorb hexyl 5 mu column (150 x 4.6 mm I.D.) and the mobile phases consisted of mixtures of acetonitrile or methanol with phosphate or acetate buffers at different pH values. Detection was performed by UV or fluorescence detector. Coefficients of variation were lower than 10% with good recovery and linearity in the expected therapeutic ranges.     

Electrocardiographic interactions between pinacidil,a potassium channel opener and class I antiarrhythmic agents in guinea-pig isolated perfused heart.

1. Drugs that shorten action potential duration could decrease the Na-channel blocking effect of class I antiarrhythmic agents by reducing the availability of Na channel in the inactivated state. 2. This hypothesis was tested in guinea-pig perfused heart, measuring the surface ECG effects of three class I drugs endowed with different binding kinetics (15 microM mexiletine, 10 microM quinidine and 3 microM flecainide) in the presence of increasing concentrations of pinacidil (10 microM, 30 microM, 50 microM), a potassium channel opener that shortens action potential duration. 3. The ECG parameters measured were: the QRS interval, i.e. the intraventricular conduction time; the JT interval, which reflects the duration of ventricular repolarization; the ratio between JT peak (the time from the end of QRS and the peak of T wave) and JT interval, which quantifies changes in the morphology of the T wave. 4. At the concentrations tested all the antiarrhythmic drugs widened the QRS complex by 55-60%. Flecainide did not significantly change JT interval, but quinidine prolonged and mexiletine shortened it. Mexiletine also decreased the JTpeak/JT ratio. Pinacidil by itself decreased the JT interval and the JT peak/JT ratio in a dose-dependent way, but did not affect QRS duration. 5. In the presence of fixed antiarrhythmic drug concentrations, however, pinacidil decreased the QRS prolongation induced by mexiletine (-17%) and quinidine (-8%), but not that induced by flecainide: this effect was already maximal at the lower concentration tested (10 microM) and there was no relationship between pinacidil-induced JT shortening and QRS changes.(ABSTRACT TRUNCATED AT 250 WORDS)     

Cellular electrophysiological properties of a new aminosteroid antiarrhythmic agent, SC-35135

SC-35135 is a structurally unique class I antiarrhythmic agent previously shown to suppress arrhythmias produced by a two-stage coronary artery ligation or by administration of ouabain, but to be arrhythmogenic at high doses. SC-35135 was evaluated in guinea pig papillary muscle using standard microelectrode techniques to record transmembrane action potentials. SC-35135 markedly blocked Vmax (maximum rate of membrane depolarization) as a function of pacing frequency in the concentration range of 3 x 10(-6) to 3 x 10(-5) M, and was without effect on action potential duration. The effective refractory period was significantly shortened only at the highest concentration tested (3 x 10(-5) M). Rate constants for the onset of Vmax block determined at two stimulation rates, 60 and 200 pulses/min, were 0.17 +/- 0.052 and 0.06 +/- 0.005 (action potentials)-1, respectively, in the presence of 10(-5) M SC-35135. The recovery from Vmax depression following a train of stimuli was very slow in the presence of SC-35135. The average time constant for the recovery from block of Vmax after addition of 10(-5) M SC-35135 was 10.2 +/- 0.94 s. SC-35135 caused both a concentration- and stimulation frequency-dependent hyperpolarizing shift in the half point of the relationship between Vmax and resting membrane potential. Slow response (Ca current-dependent) action potentials were not changed by SC-35135 at concentrations less than or equal to 3 x 10(-5) M, indicating a lack of class IV antiarrhythmic activity. The results of these experiments indicate that SC-35135 has electrophysiological properties similar to other previously studied aminosteroid antiarrhythmics such as amafolone and CCI 22277. Its onset and recovery kinetics also resemble the well known class IC antiarrhythmics flecainide, lorcainide, and encainide. The arrhythmogenic activity of SC-35135 has prevented further development of this compound.     

Canine plasma concentration-cardiovascular effect relationships for bidisomide,a new antiarrhythmic drug,and disopyramide,cibenzoline, and propafenone

Bidisomide (SC-40230) is a unique new antiarrhythmic agent. In this study the canine intravenous (i.v.) antiarrhythmic doses of bidisomide (9 ± 1 mg/kg), disopyramide (8 ± 1 mg/kg), cibenzoline (8 ± 2 mg/kg), and propafenone (6 ± 0.5 mg/kg) were established in a 24 h coronary ligation ventricular arrhythmia model. Based on the canine therapeutic doses of the four agents, three cumulative i.v. doses (load/maintenance infusions) of each of these drugs and placebo were then studied in normal anesthetized dogs to evaluate their general cardiovascular effects. Propafenone (0.7–3.0 μg/ml plasma concentration) caused potent reductions in cardiac output and increases in QRS duration relative to the other agents. Cibenzoline (0.9–7.0 μg/ml) and disopyramide (1.4–12.9 μg/ml), at matched plasma concentrations, caused very similar cardiac output reductions, but cibenzoline caused nearly double the QRS increase. Bidisomide (1.9–16.1 μg/ml) had the least potent effects on cardiac output and QRS duration. All four drugs increased PR and QT in addition to QRS, but only disopyramide and propafenone increased JT (QT-QRS). These experiments suggest that the antiarrhythmic plasma concentrations of bidisomide, in contrast to those of selected reference agents, do not cause prominent ventricular conduction slowing or prolongation of ventricular repolarization, and in addition, cause only modest hemodynamic effects in normal dogs. © 1995 Wiley-Liss, Inc.