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

Species difference in stereoselective involvement of CYP3A in the mono-N-dealkylation of disopyramide

1. To determine which CYP isoenzyme is involved in the N-dealkylation of disopyramide (DP) metabolism in human and dog, and to determine the stereoselectivity of DP metabolism with human CYP and dog CYP isoenzymes, the following in vitro metabolism studies of DP were conducted: correlation between human CYP isoenzyme activities and DP metabolism with human liver microsomes; inhibition of DP metabolism in human and dog liver microsomes with chemical inhibitors of CYP isoenzymes; inhibition of DP metabolism in human microsomes with human CYP antibodies; inhibition of DP metabolism in dog liver microsomes with human and dog CYP antibodies; metabolism of DP with human (CYP3A4) and dog (CYP3A12) cDNA-expressed isoenzymes; determination of Km and Vmax of DP enantiomers by using cDNA-expressed CYP3A4 and CYP3A12. 2. In human liver microsomes, the formation of the mono-N-dealkylated disopyramide (MNDP) metabolite was best correlated with CYP3A4 activities. DP metabolism was substantially inhibited by ketoconazole, troleandomycin (TA) and human CYP3A4 antibody. DP was metabolized by cDNA-expressed CYP3A isoenzymes. In dog liver microsomes, DP metabolism was inhibited by ketoconazole, TA and dog anti-CYP3A12. DP was also metabolized by cDNA-expressed CYP3A12. 3. CYP3A4 and CYP3A12 are the principal isoenzymes involved in DP metabolism in human and dog respectively. There was no stereoselectivity in N-dealkylation of DP by human CYP3A4. However, there was notable stereoselectivity in the N-dealkylation by dog CYP3A12.

Vasoconstrictor and vasodilator effects of disopyramide on isolated rat vascular smooth muscle

We investigated the effects of disopyramide on the isometric contractions and intracellular Ca2+ concentrations ([Ca2+]i) measured by Fura-2 fluorescence in isolated rat aorta and portal veins. Disopyramide at concentrations > or = 10(-5) M increased the duration and complexity of the spontaneous contractions in rat portal veins. At > 10(-6) M, it induced a concentration-dependent contraction in the rat aorta. This effect was endothelium independent, associated with an increase in [Ca2+]i and abolished in aortic rings incubated in Ca2+-free solution or pretreated with 10(-7) M nifedipine, suggesting that disopyramide increased [Ca2+]i through the activation of L-type Ca2+ channels. In aortic rings precontracted by KCl (30 and 80 mM), 80 mM KCl in a low-concentration (26.2 mM) Na+ solution or 10(-5) M noradrenaline, disopyramide induced a concentration-dependent relaxation. The relaxant response in 80 mM KCl-precontracted arteries was associated with a parallel reduction in [Ca2+]i, an effect attributable to its Ca2+ channel blocking properties. In contrast, disopyramide had no effect on the concentration-response curves to noradrenaline in the presence of nifedipine. Disopyramide also inhibited in a concentration-dependent manner the relaxation induced by levcromakalim in aortic rings precontracted by 30 mM KCl because of its inhibitory action on K(ATP) channels, whereas it had no effect on the relaxant response to sodium nitroprusside. These effects, together with the negative inotropic effects of the drug, may account for the increase in mean arterial pressure observed in disopyramide-treated patients and the profound hypotension observed after overdosages of disopyramide.

Stereoselective biliary elimination of disopyramide and mono-N-desisopropyldisopyramide in humans

The results of a previous pharmacokinetic study of disopyramide (DP) enantiomers in humans suggested that DP and/or mono-N-desisopropyldisopyramide (MND) may show stereoselective extrarenal elimination. Thus, the present study investigates the biliary elimination of DP and MND enantiomers in three patients who had undergone cholecystectomy for cholelithiasis. DP and MND enantiomers displayed biliary elimination. In both subjects, this elimination pathway showed the same characteristics: (1) biliary elimination of DP and MND was stereoselective, (2) the stereoselectivity was opposite to that observed for the metabolic and renal elimination pathways, i.e., the elimination of the (-)-(R)-enantiomer was higher than that of the (+)-(S)-enantiomer, and (3) biliary elimination of MND was higher than that of DP, for both enantiomers. Estimates of the relative contribution of the biliary clearance in the total clearance of DP and MND indicated that this elimination pathway was secondary, especially for DP. The biliary clearance (expressed as % of total clearance) was 1.9 to 4.0% for (-)-(R)-DP, 1.2 to 1.7% for (+)-(S)-DP, 7.8 to 22.9% for (-)-(R)-MND, and 5.2 to 10.5% for (+)-(S)-MND.

In vitro assessment of stereoselective hepatic metabolism of disopyramide in humans: comparison with in vivo data

Metabolism of disopyramide (DP) enantiomers has been investigated in primary cultures of adult human hepatocytes. Results were compared with in vivo data obtained from a previous pharmacokinetic study (Le Corre et al. Drug Metab. Dispos. 16:858-864 1988). Metabolism of DP enantiomers as a function of incubation time showed constant velocity over time. The intracellular/extracellular distribution of both DP and mono-N-desisopropyldisopyramide did not appear to be stereoselective. Metabolism of DP enantiomers as a function of substrate concentration followed a first order kinetics. The average fractions of (-)-(R)-DP and (+)-(S)-DP metabolized in vitro (4.7 +/- 2.7 and 7.1 +/- 4.2%, respectively, n = 4) were about 5-fold lower than the fractions metabolized in vivo (26.0 +/- 6.0 and 40.2 +/- 8.8%, respectively, n = 6). The stereoselective index [(+)-(S)/(-)-(R)] of the N-dealkylation pathway obtained in vitro (1.51 +/- 0.11, n = 4) was very close to the one obtained in vivo (1.55 +/- 0.10, n = 6). These results highlight the interest of hepatocyte cultures in the evaluation of drug metabolism and especially in the assessment of stereoselectivity.

Poisoning due to class IA antiarrhythmic drugs. Quinidine, procainamide and disopyramide

Quinidine, procainamide and disopyramide are antiarrhythmic drugs in the class 1A category. These drugs have a low toxic to therapeutic ratio, and their use is associated with a number of serious adverse effects during long term therapy and life-threatening sequelae following acute overdose. Class 1A agents inhibit the fast inward sodium current and decrease the maximum rate of rise and amplitude of the cardiac action potential. Prolonged Q-T interval and, to a lesser extent, QRS duration may be observed at therapeutic concentrations of quinidine. With increasing plasma concentrations, progressive depression of automaticity and conduction velocity occur. 'Quinidine syncope' (a transient loss of consciousness due to paroxysmal ventricular tachycardia, frequently of the torsade de pointes type) occurs with therapeutic dosing, often in the first few days of therapy. Extracardiac adverse effects of quinidine include potentially intolerable gastrointestinal effects and hypersensitivity reactions such as fever, rash, blood dyscrasias and hepatitis. Procainamide produces electrophysiological changes that are similar to those of quinidine, although Q-T interval prolongation with the former is less pronounced at therapeutic concentrations. Hypersensitivity reactions including fever, rash and (more seriously) agranulocytosis are associated with procainamide, and a frequent adverse effect requiring cessation of therapy is the development of systemic lupus erythematosus. Of the 3 drugs, disopyramide has the most pronounced negative inotropic effects, which are especially significant in patients with pre-existing left ventricular dysfunction. As with quinidine, unexpected 'disopyramide syncope' at therapeutic concentrations has been described. Anticholinergic side effects are common with this drug and may require cessation of therapy. Disopyramide therapy may unpredictably induce severe hypoglycaemia. Severe intoxication with the class 1A agents may result from acute accidental or intentional overdose, or from accumulation of the drugs during long term therapy. Acute overdose can result in severe disturbances of cardiac conduction and hypotension, frequently accompanied by central nervous system toxicity. Decreased renal function can cause significant accumulation of procainamide and its active metabolite acecainide (N-acetyl-procainamide), resulting in severe intoxication. Mild to moderate renal dysfunction is less likely to lead to quinidine or disopyramide intoxication, unless renal failure is severe or concurrent hepatic dysfunction is present. Management of acute intoxication with class 1A drugs includes gut decontamination with provision of respiratory support and treatment of seizures as needed. Hypertonic sodium bicarbonate, by antagonising the inhibitory effect of quinidine on sodium conductance, may reverse many or all manifestations of cardiovascular toxicity.(ABSTRACT TRUNCATED AT 400 WORDS)

A comparison of the anticholinergic effects of two formulations of disopyramide in healthy volunteers

Eight healthy male volunteers took a single oral dose of one of the following: Rythmodan (conventionally formulated disopyramide) 150 mg; Rythmodan 250 mg; Rythmodan Retard (controlled-release disopyramide) 250 mg; placebo. The subjects were allocated double-blind to sessions and treatments according to a Latin square design. In each session pupil diameter, heart rate, salivation, and QT interval were measured immediately before and at 1, 2, 3, 4, 6, 8, and 24 h after the drug. QT interval was corrected for heart rate (QT60). Plasma concentrations of total and unbound disopyramide were also determined at each time point. Both formulations of disopyramide reduced salivary output and increased QT60 interval, but there was not significant difference between the effects of the three active treatments. Neither formulation had any effect on pupil diameter or heart rate. The peak plasma concentration of unbound disopyramide was reached 2 h after Rythmodan and 4 h after Rythmodan Retard. The peak plasma concentration of disopyramide was significantly lower after Rythmodan Retard 250 mg than after Rythmodan 250 mg. The plasma concentration of unbound disopyramide was positively correlated with the reduction in salivation and prolongation of the QT60 interval. The reduction in salivation is likely to reflect blockade of muscarinic receptors by disopyramide, whereas the increase in QT60 interval is likely to be related to a direct effect of the drug on the heart. The results of this single-dose study do not indicate that disopyramide in the controlled-release formulation would be better tolerated by patients than conventionally formulated disopyramide.

Simultaneous determination of disopyramide and its mono-N-dealkylated metabolite enantiomers in human plasma and urine by enantioselective high-performance liquid chromatography

Enantiomers of disopyramide (DP) and its mono-N-dealkylated metabolite (MND) were determined in human plasma and urine by enantioselective high-performance liquid chromatography using a chiral stationary-phase column. This method was precise and sensitive: the mean recoveries from plasma at a concentration of 0.5 microgram/ml were 101.1% for (+)-DP, 98.0% for (-)-DP, 94.4% for (+)-MND and 82.9% for (-)-MND; the within- and between-day coefficients of variation at the same concentration were 4.4 and 3.3% for (+)-DP, 4.7 and 4.1% for (-)-DP, 6.5 and 4.1% for (+)-MND and 7.8 and 2.4% for (-)-MND for plasma; the lower detection limits were 40 ng/ml for (+)-DP, 80 ng/ml for (-)-DP, 100 ng/ml for (-)-MND and 200 ng/ml for (+)-MND, for 0.5 ml of plasma and 0.2 ml of urine. The ultrafiltration technique was used for determination of the unbound concentration of DP enantiomers in plasma. A preliminary study of the determination of DP and MND enantiomers in plasma and urine samples from a healthy subject given racemic DP demonstrated the clinical applicability of the present method for therapeutic monitoring and pharmacokinetic studies.

Cardiovascular effects of acute normovolemic hemodilution in rats with disopyramide-induced myocardial depression

The effect of myocardial depression on the circulatory response to acute normovolemic hemodilution (hematocrit 23%) with hetastarch was evaluated in 28 anesthetized Sprague-Dawley rats. Cardiac output was recorded using an electromagnetic flow probe. Mild, moderate, and severe myocardial depression were achieved by infusing disopyramide 50, 75, and 85 mg/kg. This resulted in a dose-dependent decrease in cardiac output (r = -0.73, p less than 0.05) and mean arterial pressure (r = -0.65, p less than 0.05), and an increase in left ventricular end-diastolic pressure (r = 0.77, p less than 0.05) and total peripheral resistance (r = 0.46, p less than 0.05). Following hemodilution, cardiac output and mean arterial pressure were significantly lower and total peripheral resistance significantly higher in animals with myocardial depression compared with saline anemic controls. These differences were dose-dependent for cardiac output (r = -0.83, p less than 0.05), mean arterial pressure (r = -0.68, p less than 0.05), and total peripheral resistance (r = 0.51, p less than 0.05). Although control animals were able to significantly increase their cardiac output and stroke volume after hemodilution compared with baseline, animals with severe myocardial depression were unable to do so. This resulted in marked hypotension after hemodilution in controls compared with severely depressed animals. The results suggest a diminished ability of the pharmacologically depressed heart to tolerate acute normovolemic hemodilution.

Simple in vitro method to characterize antiarrhythmic agents

A simple, nonmicroelectrode method was developed for the in vitro identification and characterization of potential antiarrhythmic agents. To evaluate the method, standard antiarrhythmic agents from three different classifications (I, III, IV) were tested in isolated right ventricular guinea pig papillary muscles for their effect on developed tension (DT), excitability (EX), and effective refractory period (ERP). ERP was measured with the use of paired field stimuli. Depression or reversal of the force frequency relationship was an index of an agent's effect on DT. A shift in the stimulus strength-duration relationship was an index of an agent's effect on EX. A computer program was developed for data handling and analysis. Disopyramide phosphate (D, 3.0 x 10(-5) M), sotalol (S, 3.0 x 10(-5) M), clofilium phosphate (C, 1.0 x 10(-5) M), and N-acetyl procainamide hydrochloride (N, 3.0 x 10(-5) M) significantly prolonged ERP (+20, +35, +24, +16 ms, respectively), while verapamil (V, 3.0 x 10(-7) M) and the distilled water vehicle (W) did not. D and V significantly decreased DT (-78% and -57% at 1 Hz, respectively) while W, S, C, and N did not. Only D decreased EX. These data correspond well with findings in other models reported in the literature, supporting the use of this simple in vitro method for identification and characterization of potential antiarrhythmic agents.

Clinical pharmacokinetics of levorotatory and racemic disopyramide, at steady state, following oral administration in patients with ventricular arrhythmias

Electrophysiological effects, antiarrhythmic activity and kinetics of levorotatory disopyramide (R(-) DP) and racemic disopyramide (equimolar mixture of R(-) DP and S(+) DP) were compared in patients with ventricular arrhythmias. This double blind cross-over randomized trial was achieved, at steady-state, following oral administration of 200 mg three times a day. In comparison with baseline values, electrophysiological data indicated that R(-) DP and racemic DP prolonged, significantly and similarly, PR interval (+11.7% and +10%, respectively, P less than .01), and QTc interval (+9.2% and +7%, respectively, P less than .001), while QRS interval was not significantly affected. The antiarrhythmic activity, assessed by percent reduction in ventricular extrasystoles frequency, showed a similar efficiency of levorotatory and racemic DP: 80% and 74%, respectively (P = .24). Ventricular tachycardias disappeared with both treatments in the three patients concerned. During the racemic period, the mean total plasma clearance, expressed as CL/F, of S(+) DP (114.6 ml/min), was significantly lower than that of R(-) DP (157 ml/min), (P less than .001). The mean total plasma clearance of R(-) DP, during the levorotatory period (163 ml/min), did not differ from the respective value determined during the racemic period (P = .32). During the racemic period, the stereoselective difference in total plasma clearances, which is not observed when DP enantiomers are administered separately, may result from an increase in unbound fraction of R(-) DP, due to the presence of S(+) DP, which is known to be a potent displacer of R(-) DP.

Mechanisms of termination of reentrant atrial arrhythmias by class I and class III antiarrhythmic agents

We studied atrial flutter due to circus movement in chronically instrumented conscious dogs to identify the mechanism by which class I and class III antiarrhythmic drugs terminate reentrant excitation. We used a crossover experimental design administering five class I agents and one class III agent, by intravenous bolus followed by intravenous infusion. The class I agents other than lidocaine were almost uniformly effective in terminating the arrhythmia (disopyramide in six of seven dogs, propafenone in six of six, flecainide in seven of seven, and SC-40230 in seven of seven). Termination was preceded by a marked increase in cycle length (ranging from +78% with propafenone to +55% with disopyramide), but with the exception of disopyramide, class I agents did not significantly shorten the excitable gap. With disopyramide the gap decreased from 49 +/- 3% to 28 +/- 3% of the cycle length. With no class I agent did the wavelength of effective refractoriness increase to approach the cycle length of the arrhythmia. Lidocaine, used as a negative control, terminated the reentry in one dog with modest prolongation of the cycle length. Terminations with class I agents correlated with depression of conduction rather than prolongation of refractoriness. In contrast with class I agents, D-sotalol prolonged the cycle length minimally (+10%) and terminated the arrhythmia in six of seven dogs. It decreased the excitable gap from 42 +/- 4% to 26 +/- 6% of the cycle, but it still did not cause the wavelength of effective refractoriness to equal the cycle length. Terminations by D-sotalol seemed to result from either failure of the lateral boundaries of the circus path or reflection within the path.

The influence of acidosis on the myocardial uptake and electrocardiographic effects of disopyramide

The time course for the ECG effects and myocardial uptake of disopyramide was studied in isolated perfused guinea pig hearts under different pH conditions. At pH 7.46 the drug depressed the overall AV conduction time (PR) by 16.64%, the His-ventriculum conduction time (HV interval) by 30.46% and delayed the ventricular repolarization (QT interval) by 8.08%, on average. The maximum intraventricular pressure (Pmax) was also depressed by 35.6%. The maximum effect on the QT interval (constant rate: 0.609 min-1) was reached faster than the maximum effect on the PR and HV intervals (constant rates: 0.399 and 0.400 min-1, respectively), while the myocardium uptake process was complete before any ECG parameter reached a steady state (uptake constant: 1.58 min-1). Under conditions of extracellular acidosis (pH 6.92), the disopyramide disposition parameters (uptake rate constant and myocardial concentration) were not modified. However, the drug exerted significantly smaller effects on the HV and QT intervals and on myocardial contractility. These results are in contrast with those obtained previously with lidocaine and quinidine, and indicate that the influence of acidosis on class 1 antiarrhythmic agents may also depend on the characteristics of the individual drug.

Clinical pharmacokinetics in heart failure. An updated review

Pharmacokinetics is the study of the effect that the body has on drug absorption, distribution, metabolism and excretion. The pharmacokinetics of a specific drug are assessed by the volume of distribution, bioavailability, clearance and elimination half-life. Elimination half-life is directly related to the volume of distribution and inversely related to clearance. Any 1 or more of these parameters may be altered by physiological changes such as ageing, or disease states such as congestive heart failure. Congestive heart failure is associated with hypoperfusion to various organs including the sites of drug clearance, i.e. the liver and kidneys. It also leads to organ congestion as seen in the liver and gut. The main changes in drug pharmacokinetics seen in congestive heart failure are a reduction in the volume of distribution and impairment of clearance. The change in elimination half-life consequently depends on whether both clearance and the apparent volume of distribution change, and the extent of that change. Pharmacokinetic changes are not always predictable in congestive heart failure, but it seems that the net effect of reduction in the volume of distribution and impairment of clearance is that plasma concentrations of drugs are usually higher in patients with congestive heart failure than in healthy subjects. The changes in pharmacokinetics assume importance only in the case of drugs with a narrow therapeutic ratio (e.g. digoxin) and some of the antiarrhythmics such as lignocaine (lidocaine), procainamide and disopyramide. This necessitates reduction in both the loading and maintenance doses. Prolongation of the elimination half-life leads to delay in reaching steady-state, and therefore dose increments must be made more gradually. Plasma concentration measurements of the drugs concerned are a good guide to therapy and help to avoid toxicity. Pharmacokinetic changes are of less importance in the case of drugs with immediate clinical response, e.g. diuretics and intravenous vasodilators such as nitrates and phosphodiesterase inhibitors. The dose in the latter group can be titrated to the desired effect. Not all adverse reactions to drugs that may occur in heart failure are the result of alterations in pharmacokinetics; rather, some may be due to important drug interactions. An interaction may occur directly e.g. reduction of renal clearance of digoxin by captopril and quinidine; or indirectly, e.g. through diuretic-induced hypokalaemia, which exacerbate arrhythmias associated with digoxin and antiarrhythmics such as quinidine and procainamide.