Metabolism of procainamide in normal and cardiac subjects

Pharmacokinetic determinants for the right dose of antiarrhythmic drugs

INTRODUCTION

Antiarrhythmic drugs (AADs) show a narrow therapeutic range and marked intersubject variability in pharmacokinetics (PK), which may lead to inappropriate dosing and drug toxicity.

AREAS COVERED

The aim of the present review is to describe PK properties of AADs, discussing the main changes in different clinical scenarios, such as the elderly and patients with obese, chronic kidney, liver, and cardiac disease, in order to guide their right prescription in clinical practice.

EXPERT OPINION

There are few data about PK properties of AADs in a special population or challenging clinical setting. The use and dose of AADs is commonly based on physicians' clinical experience observing the clinical effects rather than being personalized on the individual patients PK profiles. More and updated studies are needed to validate a patient centered approach in the pharmacological treatment of arrhythmias based on patients' clinical features, including pharmacogenomics, and AAD pharmacokinetics.

The Clinical Significance of the Pharmacogenetics of Cardiovascular Medications

Inter-individual variability in the response to numerous drugs can be traced to a number of sources. One source of variability in drug response is the variability associated with the metabolic capacity of an individual. The component of metabolic capacity that will be the focus of this article is that determined by heredity. Pharmacogenetics is frequently referred to as the study of the effects of heredity on the disposition and response to medications. This article will review the pharmacokinetic and pharmacodynamic significance of pharmacogenetics as it pertains to a select number of cardiovascular agents. The enzyme systems responsible for drug metabolism discussed in this article will be limited to the P-450IID6 and N-acetylation pathways. Given the extensive use of cardiovascular agents in clinical practice that are affected by this genetic polymorphism, it is important for the practicing pharmacist to be aware of this phenomenon and its implications. Hopefully, the knowledge gained from this article will help practicing pharmacists to appreciate the clinical significance of polymorphic drug metabolism and provide a basis for the application of this knowledge to a variety of practice settings.

Massive doses of procainamide for ventricular tachyarrhythmias due to myocardial infarction

Three patients are described in whom malignant ventricular arrhythmias appeared in connection with a reinfarction some days after hospitalization for an acute myocardial infarction and in whom massive doses of procainamide, up to 7.5 g/day i.v., were necessary to prevent these arrhythmias. The serum concentration of procainamide was 2--4 times higher than the recommended upper level, but no side-effects were observed. With the dose given, one would have expected still higher serum concentrations. Several reasons for this finding are discussed, including the effects of renal function, intestinal leakage, storage of the drug in tissues and hitherto unknown metabolic pathways of procainamide in patients, who are slow acetylators.

Interindividual Variability in 5-Fluorouracil Metabolism and Procainamide N-Acetylation in Human Liver Cytosol

We investigated the enzymatic kinetics and interindividual variability of the metabolism of 5-fluorouracil and procainamide by human liver cytosol and/or microsomes. The Km values for the 5-fluorouracil dihydropyrimidine dehydrogenase (DPD) and procainamide N-acetyltransferase activities in pooled liver cytosol, and procainamide hydrolysis in pooled liver microsomes were 3.9, 1670, and 969 microM, respectively, and the intrinsic clearance (Vmax/Km) values for these reactions were 128, 0.192, and 0.0059 microl/min/mg protein, respectively. The cytosolic activities of 5-fluorouracil metabolism and procainamide N-acetylation ranged from 145 to 790 (469+/-156, mean+/-S.D., n=22) and <1 to 152 (52+/-48, n=12) pmol/min/mg protein, respectively, and the DPD activity of 5-fluorouracil was neither gender-related nor age-dependent. Procainamide N-acetylation activities among 12 human cytosol samples were highly correlated with sulfamethazine N-acetylation activities, suggesting that procainamide N-acetylation is catalyzed by N-acetyltransferase-2. These results suggest that the N-acetylation reaction is more important than the hydrolysis in the metabolic pathway of procainamide, and that there are large interindividual differences in the enzyme activities towards the respective metabolic pathways of 5-fluorouracil and procainamide in human liver.

Therapeutic drug monitoring of antiarrhythmic drugs

Most antiarrhythmic drugs fulfil the formal requirements for rational use of therapeutic drug monitoring, as they show highly variable plasma concentration profiles at a given dose and a direct concentration-effect relationship. Therapeutic ranges for antiarrhythmic drugs are, however, often very poorly defined. Effective drug concentrations are based on small studies or studies not designed to establish a therapeutic range, with varying dosage regimens and unstandardised sampling procedures. There are large numbers of nonresponders and considerable overlap between therapeutic and toxic concentrations. Furthermore, no study has ever shown that therapeutic drug monitoring makes a significant difference in clinical outcome. Therapeutic concentration ranges for antiarrhythmic drugs as they exist today can give an overall impression about the drug concentrations required in the majority of patients. They may also be helpful for dosage adjustment in patients with renal or hepatic failure or in patients with possible toxicological or compliance problems. Their use in optimising individual antiarrhythmic therapy, however, is very limited.

Therapeutic drug monitoring: antiarrhythmic drugs

Antiarrhythmic agents are traditionally classified according to Vaughan Williams into four classes of action. Class I antiarrhythmic agents include most of the drugs traditionally thought of as antiarrhythmics, and have as a common action, blockade of the fast-inward sodium channel on myocardium. These agents have a very significant toxicity, and while they are being used less, therapeutic drug monitoring (TDM) does significantly increase the safety with which they can be administered. Class II agents are antisympathetic drugs, particularly the beta-adrenoceptor blockers. These are generally safe agents which do not normally require TDM. Class III antiarrhythmic agents include sotalol and amiodarone. TDM can be useful in the case of amiodarone to monitor compliance and toxicity but is generally of little value for sotalol. Class IV antiarrhythmic drugs are the calcium channel blockers verapamil and diltiazem. These are normally monitored by haemodynamic effects, rather than using TDM. Other agents which do not fall neatly into the Vaughan Williams classification include digoxin and perhexiline. TDM is very useful for monitoring the administration (and particularly the safety) of both of these agents.

Cardiac anticholinergic effects of procainamide and its N-acetylated metabolite: experimental pharmacological and radioligand binding studies

1. The cardiac anticholinergic effects of procainamide (1 mg kg(-1) min(-1)) and its N-acetylated metabolite (NAPA) at equimolar dose (1.16 mg kg(-1) min(-1)) were studied using in vivo experimental pharmacological and in vitro radioligand binding studies. 2. Procainamide and NAPA progressively reduced vagal stimulation-induced bradycardia in chloralose-anaesthetized dogs. As indicated by the ED50, the vagolytic activity of NAPA is 1.5-2.0 times weaker than that of procainamide. Both drugs increased heart rate, with lowering of mean blood pressure during the second part of procainamide infusion, but not during NAPA infusion. 3. Binding studies on rat heart membranes yielded Ki values that were 1.5 times higher for NAPA than for procainamide. 4. These results show that NAPA exerts a weaker cardiac vagolytic action than procainamide, which is probably linked to a lower ability to bind to cardiac muscarinic receptors.

The effects of programmed ventricular stimulation on plasma procainamide levels: an experimental model

To evaluate the effects of programmed ventricular stimulation on resultant plasma concentrations of intravenously administered procainamide, drug dosing was performed with and without ventricular stimulation on two separate days (48 hours apart) in 12 dogs (13 dosing trials) at > or = 14 days after myocardial infarction (mean: 62 days). During infarct surgery, three bipolar electrodes were plunged into left ventricular epicardium, externalized, and later used for ventricular stimulation. On the first study day, procainamide was dosed to achieve two sequential plateau plasma levels (I and II), with a 20-minute equilibrium period at each plateau before ventricular stimulation. Plasma procainamide concentrations were measured before initiation of ventricular stimulation and at the completion of ventricular stimulation for each sequential plateau level. Stimulation involved delivery of one, two, and three extrastimuli at three paced cycle lengths at three left ventricular sites before procainamide dosing and at each of the two procainamide plateau levels. Three dogs were excluded from analysis due to induction of lethal ventricular arrhythmias. No ventricular arrhythmias were induced in the remaining nine animals. On the second study day, procainamide was dosed identically, but no ventricular stimulation was performed. Intravenous drug administration and collection of plasma concentration samples were performed with +/- 1 minute on both study days. Mean plasma procainamide concentrations at the end of ventricular stimulation at dosage Levels I & II were 10% and 12% greater (P < 0.02 and P < 0.005, respectively) than plasma concentrations measured at comparable times on the study day when no ventricular stimulation was performed.(ABSTRACT TRUNCATED AT 250 WORDS)

Practical optimisation of antiarrhythmic drug therapy using pharmacokinetic principles

The optimisation of antiarrhythmic drug therapy is dependent on the definitions and methods of short term efficacy testing and the characteristics of those drugs used for rhythm disturbances. The choice of an initial antiarrhythmic drug dosage is highly empirical, and will remain so until the measurement of free concentrations, enantiomeric fractions and genetic phenotyping becomes routine. However, the clinician can devise an efficient initial dosage for efficacy testing procedures based on pharmacokinetic principles and disposition variables in the literature. In this regard, a nomogram for commonly used agents and dosages was constructed and is offered as a guide to accomplish this goal. Verification of the accuracy and usefulness of this nomogram in a prospective manner in patients with symptomatic tachyarrhythmias is still required. On a long term basis, dosage regimens can be modified by the use of pharmacokinetic principles and patient-specific target concentrations, in accordance with the methods used to monitor arrhythmia recurrence and drug-related side effects.

Effects of cardiovascular disease on pharmacokinetics

The pathophysiologic changes occurring in cardiovascular disease can affect the kinetics of drugs in several different ways. The present review examines these modifications and the underlying mechanisms. The kinetics of specific agents, such as antiarrhythmic, antihypertensive, cardiotonic, and other drugs are considered, and the clinical implications are outlined. The clinician should be aware of these modifications, because they require an adjustment of the dosage regimen. A rational basis for a correct therapeutic choice can be provided by adequate knowledge of these modifications.

Effect of amiodarone on the disposition of procainamide in the rat

We examined the effect of amiodarone on the disposition of procainamide in the rat to determine the mechanism of a reported interaction between amiodarone and procainamide and to determine the effect of amiodarone on drug acetylation. Animals received a 5-d pretreatment with amiodarone hydrochloride (100 mg/kg) or diluent prior to the intravenous administration of 50 mg/kg of procainamide hydrochloride. The plasma clearance, volume of distribution, and half-life of procainamide did not significantly differ between the two groups. The urinary recovery of N-acetylprocainamide was increased by 31% (p less than 0.01) in amiodarone pretreated animals. However, there was no change in the partial clearance of procainamide to N-acetylprocainamide. Neither the renal clearance of procainamide nor N-acetylprocainamide was altered by amiodarone pretreatment. These data suggest that amiodarone interacts with procainamide by reduction of an alternate pathway of elimination, possibly oxidative metabolism.

Procainamide in the dog: antiarrhythmic plasma concentrations after intravenous administration

Procainamide hydrochloride was administered to ouabain-intoxicated dogs to determine an antiarrhythmic plasma concentration of procainamide. Ventricular arrhythmias were produced in dogs following intravenous injections of ouabain. After a sustained ventricular tachycardia was achieved, procainamide was administered and plasma samples collected for assay. Plasma procainamide was assayed by fluorescence polarization immunoassay. Procainamide was administered at increasingly higher constant rate infusions in order to achieve intermittent, steady-state plasma concentrations. Infusion rates were calculated on the basis of previous pharmacokinetic information. All six dogs that received procainamide converted to a normal sinus cardiac rhythm after attaining a mean plasma concentration of 33.8 micrograms/ml with a range of 48.5 micrograms/ml-25.0 micrograms/ml. It was observed that the computer-generated prediction of plasma concentrations based upon previous pharmacokinetic data produced an underestimate of the actual plasma concentrations. These data may suggest that plasma concentrations of procainamide for controlling some cardiac arrhythmias in dogs may be higher than plasma concentrations cited for human patients.

Procainamide pharmacokinetics in patients with acute myocardial infarction or congestive heart failure

Abnormal procainamide pharmacokinetics (prolonged half-life and decreased volume of distribution) and pharmacodynamics (decreased threshold for the suppression of premature ventricular complexes) have been suggested in patients with acute myocardial infarction or congestive heart failure, or both. To better define procainamide kinetics, 37 patients in the acute care setting received intravenous procainamide (25 mg/min, median dose 750 mg) with peak and hourly blood samples taken over 6 hours. Compared with the 10 control patients, the 12 patients with acute myocardial infarction and the 15 patients with congestive heart failure had normal procainamide pharmacokinetics with respect to half-life (2.3 +/- 1.0, 2.5 +/- 0.9 and 2.6 +/- 0.8 hours, respectively), volume of distribution (1.9 +/- 0.7, 1.8 +/- 0.4 and 1.8 +/- 0.5 liters/kg, respectively), clearance (11.3 +/- 7.5, 9.3 +/- 3.6 and 9.1 +/- 3.5 ml/min per kg, respectively) and unbound drug fraction (66 +/- 9, 66 +/- 9 and 69 +/- 4%, respectively). Low thresholds for greater than 85% premature ventricular complex suppression were confirmed in these patients (median 4.7 micrograms/ml in patients with acute myocardial infarction and 3.3 micrograms/ml in patients with congestive heart failure). Thus, differences in the response of premature ventricular complexes to procainamide reflect electropharmacologic differences dependent on clinical setting rather than pharmacokinetic abnormalities. Furthermore, the reduction of procainamide dosing in patients with acute myocardial infarction or congestive heart failure, based solely on prior kinetic data, may result in inappropriate antiarrhythmic therapy.

Pharmacokinetics of cibenzoline in patients with renal impairment

Pharmacokinetic values of cibenzoline, a new, investigational, antiarrhythmic drug, were determined in 13 patients with varying degree of renal impairment, creatinine clearance range between 5 and 53 mL/min. Cibenzoline plasma levels were measured after direct intravenous injection of one single 1 mg/kg dose. The apparent volume of distribution of the drug (276 1) was similar to that reported in healthy subjects. Total body clearance decreased with creatinine clearance, and there was a close correlation between cibenzoline renal clearance and creatinine clearance (r = 0.956; P less than 0.001). Plasma elimination half-life was prolonged, with values ranging from 7:4 to 23.6 hours. This study showed that cibenzoline total body clearance correlated with the degree of renal impairment, and it is suggested that in patients with chronic renal failure dosage should be adjusted according to creatinine clearance values.

Procainamide: clinical pharmacology and efficacy against ventricular arrhythmias

Procainamide (PA) has been a mainstay of treatment against acute and chronic supraventricular and ventricular arrhythmias for more than 30 years. PA's clinical pharmacology has been studied extensively and its bioavailability (75-95%); volume of distribution (1.5-2.5 liters per kg), plasma protein-binding (15-25%), half-time for elimination (3-7 hours), and metabolism are known. PA's efficacy against acute ventricular arrhythmias and chronic stable VPDs is associated with plasma drug concentrations of 4 to 10 micrograms per ml; but much higher plasma concentrations may be required against sustained ventricular arrhythmias. From 30 to 60% of a PA dose is excreted as the metabolite, N-acetylprocainamide (NAPA), and PA's metabolism is determined genetically (fast or slow acetylation phenotype). Studies in patients with VPDs indicate that NAPA is also antiarrhythmic, although the contribution of NAPA to the antiarrhythmic effect after PA is not known. Studies in patients with the systemic lupus-like syndrome from PA show that NAPA is not associated with this. Investigations comparing efficacy and adverse effects of PA with those of new antiarrhythmic agents available for clinical trials are indicated in the future.

Population pharmacokinetics of procainamide from routine clinical data

Routine clinical pharmacokinetic data collected from patients receiving procainamide were analysed to estimate population pharmacokinetic parameters. 116 plasma concentration determinations for procainamide and 14 timed urine collections for the drug and its major metabolite N-acetylprocainamide (NAPA) were obtained from 39 patients, mostly males. The data were analysed using NONMEM, a computer program designed for population pharmacokinetic analysis that allows pooling of data from many individuals. Estimates of the influence of weight, height, renal function, and the presence of congestive heart failure (CHF) on the renal clearance (CLR), acetylation clearance (CLA), miscellaneous metabolic clearance (CLO), and volume of distribution (Vd) of procainamide were obtained. The mean (SE) CLR, CLA, CLO and Vd for procainamide in a 70kg patient with normal renal function were estimated to be 14.4 (2.3) L/h, 10.1 (1.7) L/h, 1.2 (1.3) L/h, and 136.0 (20.0) L, respectively. These pharmacokinetic parameters vary linearly with bodyweight; height adds no information if weight is known. The presence of CHF has no significant effect on either CLO or Vd, but reduces CLA and CLR by 11% (p less than 0.01). Even after adjustments for CHF, renal function and weight, the total clearance and Vd of procainamide vary unpredictably among individuals, with a coefficient of variation between 30 and 40%, and less than 50%, respectively.

Pharmacokinetics in man of a new antiarrhythmic drug, cibenzoline

The kinetics of cibenzoline (UP 339.01), a new antiarrhythmic drug, was studied after i.v. and oral administration to 5 healthy subjects. Cibenzoline levels in plasma and urine cibenzoline were measured by a GLC method. After i.v. administration, the total clearance was 826 ml . min-1. The fraction of cibenzoline excreted unchanged in the urine was 0.602 and it was correlated with the creatinine clearance. After i.v. and oral administration, the renal clearances were 499 ml . min-1 and 439 ml . min-1, and the half-lives were 4 h 01 min and 3 h 24 min, respectively. The differences were not significant. Availability by the oral route was 0.92, the maximum plasma concentration being observed at 1 h 36 min. The results were compared with those for other antiarrhythmic drugs.

The electropharmacology of acute drug testing using pacemakers

Acute drug testing in patients is useful to select prophylactic treatment for life-threatening or intractable tachycardias. This is generally done by induction of tachycardias with pacing. Acute studies that depend on temporary insertion of pacing electrodes do not determine efficacy in the same sense as longer term clinical drug trials because of the biased population referred for testing with pacemakers. However, the pharmacologic activity of compounds can be tested in terms of electrical functions such as conductivity and refractoriness not merely of the heart in general, but also of the arrhythmogenic focus. Such data can be directly applied to patients with similar arrhythmias, obviating the confusion often caused by interspecies and disease differences.

Ethanol-induced increase in procainamide acetylation in man

1 The effect of ethanol on procainamide pharmacokinetics was studied in humans by two different experimental designs. In one, ethanol was given 1.5 h after taking the drug followed by hourly drinks, while in the other ethanol was given 2 h before and subsequently after taking the drug. 2 In both studies, ethanol caused a significant reduction of T1/2 and a significant increase in total clearance of procainamide, while the apparent volume of distribution of procainamide, as well as the renal clearance of both procainamide and N-acetylprocainamide were unaffected by ethanol treatment. 3 Ethanol treatment increased the percentage of N-acetylprocainamide measured in blood and urine and the ratio of AUCNAPA/AUCPA significantly. 4 The T1/2 and total clearance of procainamide was significantly different in slow and rapid acetylators.

The implications of procainamide metabolism to its induction of lupus

The principal metabolic pathway of procainamide leads to formation of the less toxic N-acetyl-procainamide and the rapid acetylator phenotype is associated with a lower incidence of procainamide-induced lupus. Another metabolic pathway forms a reactive metabolite which causes revertants in the Ames test and covalently binds to microsomal protein. A study of the metabolism of procainamide revealed three metabolites that have not been previously described. A comparison of the metabolites of N-acetylprocainamide with those of procainamide suggests possibilities for the identity of the reactive metabolite. The hypotheses to be discussed explore the relationships between the formation of a reactive metabolite and the induction of lupus.

Electrophysiologic effects of N-acetylprocainamide in human beings

The electrophysiologic properties of N-acetylprocainamide (NAPA) were studied in 10 patients undergoing cardiac catheterization. Each patient received two successive intravenous infusions: one loading infusion over 15 minutes and one maintenance infusion at a slower rate for 30 minutes. Eight patients received 10.5 mg/kg body weight and two received larger doses (16 and 21 mg/kg, respectively). NAPA plasma concentration was measured at 5 minute intervals from 0 to 25 minutes, and then at 15 and 30 minutes of the second infusion. Mean blood pressure and electrophysiologic data obtained by programmed stimulation were recorded before drug administration and at 15 and 30 minutes of the infusion when the concentration of NAPA was nearly constant in each patient (range 12 to 35 microgram/ml). NAPA decreased blood pressure (p less than 0.005), increased corrected Q-T interval (p less than 0.01) and increased the atrial and ventricular effective refractory periods from 267 +/- 40 to 307 +/- 41 ms (p less than 0.01) and from 278 +/- 37 to 301 +/- 32.8 ms (p less than 0.05), respectively. NAPA did not significantly change sinus cycle length or sinus nodal recovery time, conduction intervals (A-H, H-V, P-R, QRS), atrioventricular nodal functional refractory period or nodal Wenckebach cycle length. The patient receiving the largest dose experienced mild nausea when the plasma concentration was above 35 microgram/ml. These data show that the electrophysiology of NAPA in human beings is different from that reported for procainamide. At the plasma concentrations studied NAPA increases atrial and ventricular refractory periods without increasing cardiac conduction times

Clinical pharmacology and antiarrhythmic efficacy of N-acetylprocainamide

Eleven patients with chronic ventricular arrhythmias took part in a study of N-acetylprocainamide (NAPA), the major metabolite of procainamide, in order to characterize further NAPA's clinical pharmacology and antiarrhythmic action. The frequency of ventricular arrhythmia on 24 hour ambulatory electrocardiographic recordings was comparable on recordings obtained in a prestudy screening, during treatment with placebo before administration of NAPA and after treatment with NAPA. The initial dosage of NAPA was 500 mg every 8 hours, which was increased by 500 mg increments every few days until 90 percent suppression of arrhythmia or intolerable adverse effects occurred. Only two patients achieved 90 percent suppression of ventricular ectopic complexes. The mean plasma concentration associated with 90 percent suppression of arrhythmia in these two patients ws 12.6 and 32.3 mg/ml, respectively. One of these two patients was unable to continue long-term therapy with NAPA because of a rash. Other adverse effects included gastrointestinal symptoms in seven patients with visual symptoms in four patients at plasma concentratons as low as 6.9 mg/ml. NAPA obeyed linear pharmacokinetics over the range of dosages studied (500 to 2,500 mg every 8 hours) and had a half-life of 10.7 +/- 1.98 hours (mean +/- standard deviation). There was no change in the P-R or QRS intervals and there was a dose-dependent prolongation of the Q-Tc interval. It is concluded that in this patient group, NAPA suppressed chronic ventricular ectopic complexes without adverse effects in only a minority of patients.

Factors influencing procainamide total body clearance in the immediate postmyocardial infarction period

Fifteen acute myocardial infarction patients (only one of whom had evidence of significant renal dysfunction) received a constant-rate intravenous infusion of procainamide at one rate for a least 24 hours. Steady-state plasma levels achieved during these infusions were used to calculate total body clearance (C/B). Linear regression analysis of C/B versus a variety of clinical and laboratory patient characteristics yielded only body weight (or parameters derived from it) as a significant covariant (r = 0.713, P less than or equal to 0.005). Interestingly, the data from these 15 patients suggest that the presence of a significant degree of heart failure at the start of therapy did not result in a significant decrease in C/B (C/B = 5.9 ml/min/kg when class 0-I failure was present at the start of therapy and C/B = 5.5 ml/min/kg when class III-IV failure was present). If the data from five other patients who were studied previously are added to the group reported here, the conclusions reached would be the same. These data suggest that in patients with good renal and hepatic function, initial procainamide infusion rate could be selected on the basis of body weight and need not consider the initial presence of moderate heart failure. However, intense clinical monitoring for signs of impeding serious toxicity is strongly recommended since the observed regression line did not predict total body clearance accurately in 10-15 per cent of the patients studied.

The clinical pharmacology and antiarrhythmic efficacy of acetylprocainamide in patients with arrhythmias

The actions of acetylprocainamide, the major metabolite of procainamide in man, were studied in a placebo-controlled oral-dose-ranging trial in 16 persons with arrhythmias. The occurrences of arrhythmias decreased in 15 patients receiving acetylprocainamide and increased subsequently in 10 of 13 patients given placebo. The frequency of arrhythmias was reduced by more than 75 percent in nine patients. Antiarrhythmic effects were dependent on dose and serum drug concentrations, with levels of 10 to 24 microgram/ml observed in patients with a reduction of more than 70 percent in premature ventricular complexes. The ratio of preejection period to left ventricular ejection time decreased during therapy. Side effects of light-headedness, insomnia, nausea and diarrhea occurred in six patients at serum levels ranging from 11 to 22 microgram/ml. The serum half-life of acetylprocainamide lengthened from 7 to 21 hours as the creatinine clearance decreased from 105 to 35 ml/min. Acetylprocainamide has antiarrhythmic efficacy, but causes side effects in human beings. This compound appears to contribute to the effects of procainamide therapy and may be useful as an antiarrhythmic drug.

Metabolism of clebopride in vitro. Mass spectrometry and identification of products of amide hydrolysis and N-debenzylation

1. Electron impact and field desorption mass spectrometry is described and discussed for clebopride, a newly developed benzamide with anti-emetic and anti-dopaminergic properties, and for some related compounds. 2. When clebopride was incubated with liver homogenates of rabbits, 4-amino-5-chloro-2-methoxybenzoic acid and N-(4'-piperidyl)-4-amino-5-chloro-2-methoxybenzamide were identified as metabolites.

Clinical pharmacokinetics of procainamide infusions in relation to acetylator phenotype

The pharmacokinetics of procainamide was determined in 21 lidocaine-resistant patients who received the drug according to a pharmacokinetically designed double-infusion technique. Thirteen patients were phenotyped as slow acetylators, seven as fast, and one as intermediate. The total body clearances (ClT) of PA in slow and fast acetylators were 22.6 and 34.8 liters/hr, respectively. The fraction of PA cleared by the formation of NAPA in the corresponding acetylator group was 0.2 and 0.4. Renal impairment affected the pharmacokinetics of PA more profoundly as the ClT's of PA in patients with and without renal impairment were 17.9 and 31.2 liters/hr, respectively. None of the calculated volumes of distribution was affected by acetylator phenotype or renal impairment. These data identify the contribution of at least two of the major factors accounting for variability in PA disposition in patients undergoing therapy.

The pharmacokinetics of slow-release procainamide

Procainamide was given to 20 patients with normal renal function as an i.v. bolus of 500 mg followed by 1.0 or 1.5 g eight-hourly by mouth in the form of a slow release preparation (Durules). 97.6 +/- 27.1 (SD)% of the oral procainamide was absorbed, the absorption half life being 1.54 h. The elimination half life following the oral formulation was 6.0 +/- 0.8 h, compared to a mean of 3.4 +/- 0.4 h following i.v. administration. Elimination half life following i.v. administration was slightly related to acetylator status, being 2.75 +/- 0.9 h in fast acetylators, and 4.4 +/- 2.4 h in slow acetylators. This dependence on acetylator status was not seen in half life following oral administration. Total body clearance, steady state plasma procainamide and N-acetylprocainamide were not significantly dependent on acetylator status, although a few patients who are slow acetylators had unexpectedly low clearance and high steady state procainamide concentrations when given the higher dose.

Metabolism of procainamide in patients with chronic heart failure, chronic respiratory failure and chronic renal failure

Fractional hydrolysis and acetylation of procainamide, acetylation of procainamide-derived p-aminobenzoic acid and plasma hydrolysis of procaine were studied in 20 patients with chronic heart failure (CHF), 20 patients with chronic respiratory insufficiency (CRI) and 20 patients with chronic renal failure (RF). The results were compared with those obtained in a group of 20 normal volunteers. Hydrolysis of procainamide and procaine were reduced in patients with CHF and CRI, but not in patients with RF. Moreover, more marked decreases in procainamide and procaine hydrolysis were seen in subgroups with secondary hepatic dysfunction. The diminution of hydrolysis of procainamide was not paralleled by changes in acetylation of procainamide or p-aminobenzoic acid. It is concluded that in patients with hepatic involvement secondary to advanced CHF or CRI, hepatic and plasmatic hydrolysis activity is decreased to a degree equivalent to primary liver failure.

Procainamide accumulation kinetics in the immediate postmyocardial infarction period

The rate of change of plasma procainamide concentration during 36 hours of constant-rate intravenous infusion was examined in five acute myocardial infarction patients. It was observed that a steady-state plasma concentration was established in about 16 hours, which is consistent with simulations of plasma concentrations based on pharmacokinetic constants obtained from studies in young healthy volunteers. However, the steady-state level that was attained in these patients was markedly higher than that which the simulations predicted. Thus, on the average, acute myocardial infarction patients have lower total body clearances of procainamide than normal volunteers.

Effect of acetylator phenotype on the rate at which procainamide induces antinuclear antibodies and the lupus syndrome

To investigate the relation between acetvlator phenotype and the development of procainamide-induced lupus, we determined the rate of development of antinuclear antibodies in 20 patients of known acetylator phenotype receiving chronic procainamide therapy. The duration of therapy required to induce antibodies in 50 per cent of slow (11) and rapid (nine) acetylators was 2.9 and 7.3 months respectively. The median total dose that produced ant;bodies was 1.5 g per kilogram and 6.1 g per kilogram respectively. After one year antibodies had developed in 18 patients. Retrospective studies of patients in whom procainamide lupus had developed revealed that the duration of therapy required for induction in 14 slow and seven rapid acetylators was 12 +/- 5 and 48 +/- 22 months respectively (P less than 0.002). We conclude that acetylator phenotype influences the rate at which procainamide induces antinuclear antibodies and probably the lupus syndrome. Antibody production is probably related to the parent compound or a non-acetylated metabolite.

Kinetics of procainamide and N-acetylprocainamide in renal failure

Four normal subjects and four functionally anephric patients were given 6.5 mg/kg of body wt of procainamide hydrochloride i.v., and plasma concentrations of procainamide (PA) and its major active metabolite N-acetylprocainamide (NAPA) were measured. Two individuals in each group were fast isonicotinic acid hydrazide (INH) and PA acetylators. The pharmacokinetics of PA and NAPA were analyzed with a computer program (SAAM 23). Volume of distribution (Vdss) and renal clearance of PA were similar in normal subjects regardless of acetylator phenotype. Nonrenal clearance was faster (383 vs. 244 ml/min), and PA elimination half-life (t 1/2) was shorter (2.6 vs. 3.5 hr) in fast acetylators. In the functionally anephric patients, Vdss was similar to that of normal subjects. Nonrenal clearence was faster (117.5 vs. 93.5 ml/min) and PA t 1/2 shorter (10.8 vs. 17.0 hr) in fast than in slow acetylators. In these patients, acetylation accounted for 56% of PA elimination, and NAPA concentrations reached 0.8 microgram/ml or more. The t 1/2 of NAPA in renal failure was 41.5 hr, in accord with predictions from studies in normal subjects, assuming no impairment in nonrenal NAPA elimination. PA metabolism, however, is severely impaired by renal failure, so PA t 1/2 was prolonged to an unpredictably greater extent than would be expected from studies in normal subjects.

The relationship between the metabolism of procainamide and sulfamethazine

The metabolism of sulfamethazine (SMZ), which is acetylated by a binodally distributed enzyme, and procainamide (PA) was compared in 21 normal volunteers, each given a single oral dosted metabolites, N-acetyl-procainamide (NAPA) and Ac-SMZ, were measured. Subjects with less than 64% Ac-SMZ in the 0-8 hour collection were termed "slow" and those with more than 64% were termed "fast" SMZ acetylators. Slow SMZ acetylators had 9.8 to 43.8% (24.1 +/- 10.13) NAPA recovered, and fast SMZ acetylators, 22.0 to 42.6% (33.7 +/- 7.29) NAPA, P less than 0.01. In addition, the calculated half-life of PA metabolism for slow SMZ acetylators was 9.0 to 33.8 hours (18.4 +/- 8.82) and for fast SMZ acetylators was 8.1 to 14.4 hours (10.9 +/- 2.19), P less than 0.01. For four subjects, SMZ acetylation phenotype did not correlate with the half-life of SMZ or PA metabolism; and in two, SMZ acetylation phenotype and half-life of metabolism did not correlate with the same PA indices. Even though slow SMZ acetylators have less NAPA recovered than fast SMZ acetylators, it is not yet clear that procainamide is metabolized by a bimodally distributed enzyme as is sulfamethazine.

Simultaneous quantification of procainamide and N-acetylprocainamide with high-performance liquid chromatography

A rapid, precise and specific method for the simultaneous determination of procainamide and N-acetylprocainamide (NAPA) in plasma using high-performance liquid chromatography is described. N-Formylprocainamide was utilized as internal standard. The coefficients of variation of the method for both procainamide and NAPA were 3.6% in the range of plasma levels to be expected clinically. The method is especially useful for rapid determination of acetylator phenotype in patients requiring procainamide for control of arrhythmias.