Pharmacokinetic evaluation of a sustained-release compounded procainamide preparation after 24-h (acute) administration in normal dogs.

INTRODUCTION: The objective of the present study was to evaluate the pharmacokinetics of a compounded sustained-release procainamide formulation in normal dogs. ANIMALS: Six healthy, purpose-bred mixed-breed dogs participated in the study. METHODS: In phase I, two dogs were administered oral procainamide (30 mg/kg), and plasma was obtained to determine plasma concentration ranges and duration. In phase II, six dogs were administered procainamide (30 mg/kg by mouth every 12 hours) to determine the pharmacokinetics of sustained-release procainamide. Serum procainamide concentration was determined using an immunochemistry assay. RESULTS: No adverse clinical effects were noted in any of the dogs studied. The average maximum serum concentration, average serum concentration, and average minimum serum concentration were 10.17, 7.13, and 3.07 µg/mL, respectively. The average time over a 12-h period during which procainamide concentration exceeded 12 µg/mL was 2.35 h, was between 4 and 12 µg/mL was 7.19 h, and was less than 4 µg/mL was 2.46 h. The average times at maximum concentration and minimum concentration were 18.67 and 12.25 h, respectively. CONCLUSIONS: Administration of sustained-release procainamide twice daily achieved targeted plasma concentrations in most dogs. Evaluation of serum trough concentrations should be considered owing to interanimal variability to confirm that serum concentrations are within the reported therapeutic range for an individual patient.

Variability of bioavailability and intestinal absorption characteristics of bisoprolol.

We previously reported that renal function is partly responsible for the interindividual variability of the pharmacokinetics of bisoprolol. The aim of the present study was to examine the variability of bioavailability (F) of bisoprolol in routinely treated Japanese patients and intestinal absorption characteristics of the drug. We first analyzed the plasma concentration data of bisoprolol in 52 Japanese patients using a nonlinear mixed effects model. We also investigated the cellular uptake of bisoprolol using human intestinal epithelial LS180 cells. The oral clearance (CL/F) of bisoprolol in Japanese patients was positively correlated with the apparent volume of distribution (V/F), implying variable F. The uptake of bisoprolol in LS180 cells was temperature-dependent and saturable, and was significantly decreased in the presence of quinidine and diphenhydramine. In addition, the cellular uptake of bisoprolol dissolved in an acidic buffer was markedly less than that dissolved in a neutral buffer. These findings suggest that the rate/extent of the intestinal absorption of bisoprolol is another cause of the interindividual variability of the pharmacokinetics, and that the uptake of bisoprolol in intestinal epithelial cells is highly pH-dependent and also variable.

Membrane transport mechanisms of quinidine and procainamide in renal LLC-PK1 and intestinal LS180 cells.

The aim of the present study was to compare the membrane transport mechanisms of procainamide with those of quinidine using renal epithelial LLC-PK(1) and intestinal epithelial LS180 cells. In LLC-PK(1) cells, the transcellular transport of 10 microM quinidine in the basolateral-to-apical direction was similar to that in the opposite direction, and 1 mM tetraethylammonium (TEA) did not affect the transcellular transport of the drug. On the other hand, the transcellular transport of 10 microM TEA and procainamide in LLC-PK(1) cells was directional from the basolateral side to the apical side. In addition, this directional transcellular transport of procainamide was diminished in the presence of 1 mM TEA. In LS180 cells, the temperature-dependent cellular uptake of 100 microM quinidine and procainamide was markedly increased by alkalization of the apical medium, and was inhibited significantly by 1 mM several hydrophobic cationic drugs, but not by TEA. The rank order of the inhibitory effects of hydrophobic cationic drugs on the uptake of procainamide in LS180 cells was imipramine>quinidine>diphenhydramine asymptotically equal topyrilamine>procainamide, which was consistent with that on the uptake of quinidine. These findings suggested that procainamide (but not quinidine) was transported by cation transport systems in renal epithelial cells, but that both procainamide and quinidine were taken up by another cation transport system in intestinal epithelial cells.

Intense pseudotransport of a cationic drug mediated by vacuolar ATPase: procainamide-induced autophagic cell vacuolization.

Cationic drugs frequently exhibit large apparent volumes of distribution, consistent with various forms of cellular sequestration. The contributions of organelles and metabolic processes that may mimic drug transport were defined in human vascular smooth muscle cells. We hypothesized that procainamide-induced vacuolar cytopathology is driven by intense pseudotransport mediated by the vacuolar (V)-ATPase and pursued the characterization of vesicular trafficking alterations in this model. Large amounts of procainamide were taken up by intact cells (maximal in 2 h, reversible upon washout, apparent KM 4.69 mM; fluorometric determination of cell-associated drug). Procainamide uptake was extensively prevented or reversed by pharmacological inhibition of the V-ATPase with bafilomycin A1 or FR 167356, decreased at low extracellular pH and preceded vacuolar cell morphology. However, the uptake of procainamide was unaffected by mitochondrial poisons that reduced the uptake of rhodamine 6G. Large vacuoles induced by millimolar procainamide were labeled with the late endosome/lysosome markers Rab7 and CD63 and the autophagy effector LC3; their osmotic formation (but not procainamide uptake) was reduced by extracellular mannitol and parallel to LC3 II formation. Procainamide-induced vacuolization is associated with defective endocytosis of fluorophore-labeled bovine serum albumin, but not with induction of the unfolded protein response. The contents of a vacuole subset slowly (> or =24 h) become positive for Nile red staining (phospholipidosis-like response). V-ATPase-driven ion trapping is a form of intense cation pseudotransport that concerns the uncharged form of the drugs, and is associated with a vacuolar, autophagic and evolutive cytopathology and profound effects on vesicular trafficking.

Drug-herb interaction: effect of St John's wort on bioavailability and metabolism of procainamide in mice.

CONTEXT: St John's wort induces the activity of the cytochrome P450 enzyme system causing treatment failure because of increased metabolism of many drugs. Procainamide is metabolized by a different pathway to N-acetyl procainamide. OBJECTIVE: To study St John's wort-procainamide interaction using a mouse (Swiss Webster) model. DESIGN: One group of mice (group A, 4 mice in each group) was fed St John's wort each day for 2 weeks (last dose 1 day before administration of procainamide); another group (group B) received the same dose of St John's wort for 1 week. The third group (group C) received only a single dose 1 hour before administration of procainamide, and the control group (group D) received no St John's wort. All groups later received a single oral dose of procainamide. Blood was drawn 1, 4, and 24 hours after administration of procainamide and concentrations in serum of procainamide as well as N-acetyl procainamide were measured using immunoassays. RESULTS: The procainamide concentrations 1 hour after administration was highest in group C (mean, 11.59 microg/mL) followed by group A (9.92 microg/mL), whereas group B (7.44 microg/mL) and control group D (7.36 microg/mL) showed comparable values. The concentration in group C was significantly greater than the control group D (P = .03, 2-tailed independent t test). N-Acetyl procainamide concentrations and estimated half-life of procainamide among groups were comparable. In a separate experiment when mice were fed purified hypericin, the active component of St John's wort, a significant increase in bioavailability (53%) of procainamide was observed compared with the control group. CONCLUSIONS: St John's wort has an acute effect to increase bioavailability of procainamide but has no effect on its metabolism.

Therapeutic levels of intravenous procainamide in neonates: a retrospective assessment.

STUDY OBJECTIVES: To evaluate dosing and pharmacokinetic parameters of intravenous continuous-infusion procainamide in neonates, and to identify dosage regimens and factors leading to therapeutic procainamide levels and minimal adverse events. DESIGN: Retrospective, observational study. SETTING: Pediatric hospital. PATIENTS: . Twenty-one patients (seven preterm, 14 full term) younger than 30 days who received continuous-infusion procainamide therapy for more than 15 hours or had two consecutive therapeutic procainamide levels obtained while receiving therapy between June 1, 2002, and December 31, 2005. MEASUREMENTS AND MAIN RESULTS: Data on demographics, dosing, drug levels, and adverse effects were collected. Doses that achieved therapeutic levels were documented, and procainamide clearance was calculated and evaluated with regard to renal function and gestational age in patients who were at steady state. Mean clearance and mean N-acetylprocainamide (NAPA):procainamide ratios were compared between preterm and term neonates. No patients experienced hemodynamic instability or other adverse effects due to procainamide. Procainamide was given as a mean +/- SD 9.6 +/- 1.5-mg/kg bolus in 20 of 21 patients before continuous infusion. The mean +/- SD dose at which two therapeutic levels were achieved was 37.56 +/- 13.52 microg/kg/minute. Procainamide clearance was 6.36 +/- 8.85 ml/kg/minute and correlated with creatinine clearance (r=0.78, p<0.00001) and age at day of sampling (r=0.49, p<0.00001). The NAPA:procainamide ratio at steady state was 0.84 +/- 0.53; two patients were determined to be fast acetylators (ratio > 1). Preterm infants had lower mean clearance rates (p<0.001) but higher NAPA:procainamide ratios (p<0.01) than those of term infants. Five patients experienced seven supratherapeutic levels while receiving therapy; four of these patients were preterm, and all had creatinine clearances less than 30 ml/minute/1.73 m(2). Three patients had four pairs of levels obtained after discontinuation of procainamide, and elimination rate constant and half-life were calculated. CONCLUSION: Procainamide can be safely used in neonates, with no short-term adverse effects. The dosage regimen for intravenous procainamide required to achieve therapeutic levels in neonates is similar to that of older infants and children. Doses may need to be reduced in premature infants and in those with renal dysfunction.

Levofloxacin and ciprofloxacin decrease procainamide and N-acetylprocainamide renal clearances.

Ten healthy adults participated in a randomized, crossover drug interaction study testing procainamide only, procainamide plus levofloxacin, and procainamide plus ciprofloxacin. During levofloxacin therapy, most procainamide and N-acetylprocainamide (NAPA) pharmacokinetic parameters, including decreased renal clearances and renal clearance/creatinine clearance ratios, changed (P < 0.05). During ciprofloxacin treatment, only procainamide and NAPA renal clearances decreased significantly.

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.

Intrapericardial therapeutics: a pharmacodynamic and pharmacokinetic comparison between pericardial and intravenous procainamide delivery.

INTRODUCTION: Procainamide delivery into the pericardial space may produce a greater and more prolonged electrophysiologic effect, particularly in thin superficial atrial tissue, compared with intravenous delivery. METHODS AND RESULTS: Swine were randomized to sequential procainamide doses delivered intravenously (n = 6) or into the pericardial space (n = 7). The cumulative pericardial doses were 0.5, 1.5, and 3.5 mg/kg, and the intravenous doses were 2, 10, and 26 mg/kg. Pericardial procainamide prolonged right atrial effective refractory period from baseline by 22% (P < 0.01) but only at the 3.5 mg/kg cumulative dose. This dose slowed interatrial conduction time by 14% (P < 0.05) and raised atrial fibrillation threshold by 70 mA (P < 0.05). Pericardial procainamide had minimal effect on ventricular electrophysiology. Similar results occurred with a single 2 mg/kg pericardial dose in a closed chest model. Intravenous 10 and 26 mg/kg cumulative doses prolonged atrial effective refractory period from baseline by 24% and 18% (P < 0.01), respectively. The 26 mg/kg cumulative intravenous dose slowed interatrial and atrial-ventricular conduction times by 27% and 17%, respectively (P < 0.05), raised atrial fibrillation threshold, and slowed ventricular conduction time by 29% (P < 0.05). Pericardial procainamide produced pericardial fluid concentrations ranging from 250 to 1,500 microg/mL, but plasma concentrations were <1 microg/mL. Intravenous procainamide doses produced pericardial fluid concentrations similar to plasma trough concentrations 0 to 12 microg/mL. CONCLUSION: The single 2 mg/kg and 3.5 mg/kg cumulative pericardial procainamide doses prolonged atrial refractoriness and raised atrial fibrillation threshold similar to the 26 mg/kg cumulative intravenous dose, but the duration of effect was similar between delivery methods. Pericardial procainamide did not affect global or endocardial ventricular electrophysiology nor was it associated with ventricular proarrhythmia.

Issues in the use of generic antiarrhythmic drugs.

Formulation substitution using generic preparations for innovator products is becoming increasingly prevalent in the name of cost containment. So long as generic substitutes are truly clinically equivalent to the innovator compounds, patient harm should not ensue. However, for drugs with a narrow therapeutic index, serious concerns about generic equivalence are beginning to arise, particularly with neurologic, immunosuppressive, anticoagulant, and antiarrhythmic drugs. This article reviews the guidelines used to approve a generic compound and their limitations and provides case-based information as to the adverse clinical consequences-arrhythmia recurrence, proarrhythmia, and death-that have now been reported in association with generic substitution of antiarrhythmic compounds. Additionally, guidelines for allowance or avoidance of antiarrhythmic drug formulation substitution are suggested.

Transport of procainamide via H(+)/tertiary amine antiport system in rabbit intestinal brush-border membrane.

Transport characteristics of procainamide in the brush-border membrane isolated from rabbit small intestine were studied by a rapid-filtration technique. Procainamide uptake by brush-border membrane vesicles was stimulated by an outward H(+) gradient (pH(in) = 6.0, pH(out) = 7.5) against a concentration gradient (overshoot phenomenon), and this stimulation was reduced when the H(+) gradient was subjected to rapid dissipation by the presence of a protonophore, FCCP. An outward H(+) gradient-dependent procainamide uptake was not caused by H(+) diffusion potential. The initial uptake of procainamide was inhibited by other tertiary amines with N-dimethyl or N-diethyl moieties in their structures, such as triethylamine, dimethylaminoethyl chloride, and diphenhydramine, but not by tetraethylammonium and thiamine. Furthermore, procainamide uptake was stimulated by preloading the vesicles with these tertiary amines (trans-stimulation effect), indicating the existence of a specific transport system for tertiary amines. These findings indicate that procainamide transport in the intestinal brush-border membrane is mediated by the H(+)/tertiary amine antiport system that recognizes N-dimethyl or N-diethyl moieties in the structures of tertiary amines.

Pharmacokinetic variability and therapeutic drug monitoring actions at steady state.

PURPOSE: To develop a mathematical model for therapeutic drug monitoring and to assess the kinetic relationships between the intensity of corrective action and the approach of drug concentrations to target values. METHODS: A mathematical model that succinctly accounts for the corrective actions and the variability inherent in the pharmacokinetics was used. RESULTS: The validity of the variability term was tested using experimental data for steady state concentrations of the drug procainamide. The approach of the monitored process to the target value followed exponential kinetics and an analytical expression for dependence the variance with time and various dosing parameters was derived. The variance of the drug concentration depends critically on a single non-dimensional parameter containing the rate constant for the therapeutic corrective actions and a coefficient describing the variance rate. When the rate constant for the therapeutic corrective actions was less than this critical value, the variance increased indefinitely. CONCLUSIONS: From a dosing standpoint, large variances in drug concentrations are undesirable because some patients will be overdosed or underdosed. Since deterministic models cannot provide analytical solutions for the moments of drug concentration distribution functions, stochastic models can be used to provide useful insights into the design of therapeutic regimens.

Comparison of antitumor activity of declopramide (3-chloroprocainamide) and N-acetyl-declopramide.

Previous studies have suggested that some of the antitumor activity of declopramide (3-chloroprocainamide) could be due to its metabolites. One metabolite has been identified as N-acetyl-declopramide (N-acetyl-3-chloroprocainamide). The aim of this study is to investigate the bioactivity of N-acetyl-declopramide and to compare it with its parent compound. The data have shown that N-acetyl-declopramide inhibited tumor cell growth in vitro in HL60 and K562 cells, and in vivo in scid mice xenografted with a human brain astrocytoma (T24), which was evaluated after oral doses of 20 and 40 mg/kg given at 0, 24 and 48 hr +/- a single im dose of cisplatin (7.5 mg/kg). The action was presumably by inducing DNA strand breaks and apoptosis. No acute toxic symptoms and no body weight loss were observed. N-acetyl-declopramide given orally or im gave a similar drug level in mouse serum 30 minutes after administration (p > 0.05). It had a greater antitumor activity in vitro in HL60 or K562 cells and a similar efficacy of inhibiting tumor growth in vivo, when compared with declopramide. These data provided an explanation for the primary result obtained in this study, i.e. declopramide administered orally at 40 mg/kg gave the same efficacy of inhibiting tumor growth as im injection although oral administration had a lower bioavailability due to the formulation of N-acetyl-declopramide. Based on these data, it was concluded that the antitumor properties of declopramide administered orally were not compromised by metabolism to N-acetyl-declopramide because the latter also has strong antitumor properties.

Modified polypeptides containing gamma-benzyl glutamic acid as drug delivery platforms.

We previously reported the development of diffusion-controlled biodegradable polypeptides for drug delivery purposes. In this paper, we describe the synthesis of three modified polypeptides that contain gamma-benzyl glutamic acid as the common structural backbone. The properties of these polymers were characterized with regard to their potential application as drug delivery platforms. Procainamide hydrochloride, a hydrophilic drug, and protamine sulfate, a low molecular weight protein, were used as model drugs for examining release rate profiles from these polymers. The homopolymer of poly(gamma-benzyl-L-glutamic acid), PBLG, showed a highly helical configuration and a moderate release rate of procainamide. Modification of structural attributes by random copolymerization of the D- and L- isomers of gamma-benzyl glutamic acid produced poly(gamma-benzyl-D,L-glutamic acid), PBDLG, which displayed a significantly slower release of procainamide when compared to PBLG. The modification of polymer bulk hydrophobicity by copolymerization of PBLG (A) with poly(ethylene glycol) (B) yielded an ABA triblock copolymer exhibiting much faster release rates for both procainamide and protamine than those demonstrated by the other two polymers. Using this triblock copolymer, protamine release rates ranging from 2 weeks to approximately 2 months were obtained by simply varying the polymer processing conditions and protein particle size. A nearly complete release of protein was obtained from the triblock copolymer blends and this occurred without reliance upon degradation of the polymer backbone. Fickian diffusion-controlled release mechanisms were implied for release of procainamide and protamine from these polypeptide formulations based on the linear relationship displayed between cumulative drug release and the square root of time.

Pharmacokinetics and central nervous system toxicity of declopramide (3-chloroprocainamide) in rats and mice.

Declopramide (3-chloroprocainamide) has been identified in previous studies as a representative of a new class of chemosensitizers. In this study, the toxicity and pharmacokinetics of declopramide have been investigated and compared with a structural analog, metoclopramide (MCA). Declopramide has not induced central nervous system (CNS)-related side effects in rats at doses up to 200 mg/kg, whereas MCA does at 12.5 mg/kg. In addition, declopramide did not bind to dopamine D2 receptors in subcellular preparations at doses up to 100 microM, whereas MCA showed affinity at 1 microM. Declopramide bound with affinity to 5-hydroxytryptamine3 receptors which are important in controlling vomiting. In contrast to MCA, declopramide has a rapid clearance from serum, a lower tissue concentration (about 15-fold lower than MCA) and a lower oral bioavailability (about 6-fold lower than MCA). However, declopramide was shown in vitro to possess a higher tumor cell absorption rate. One of the main metabolites of declopramide was identified as N-acetyl declopramide. Taken together, these data suggest that the clinical development of declopramide as a sensitizer of radio- and chemotherapies is an improvement over MCA, because it can be administered in a high dose and is devoid of CNS side effects.

Involvement of CYP2D6 activity in the N-oxidation of procainamide in man.

Occurrence of a lupus-like syndrome in a significant number of patients treated with procainamide has limited the clinical use of this antiarrhythmic drug. In-vitro studies conducted in our laboratory have demonstrated that CYP2D6 is the major cytochrome P450 isozyme involved in the formation of N-hydroxyprocainamide, a metabolite potentially involved in the drug-induced lupus erythematosus syndrome observed with procainamide. In the current study, we evaluated the role of CYP2D6 activity in the in-vivo oxidation of procainamide in man. Nineteen healthy individuals, 13 with high (extensive metabolizers) and six with low (poor metabolizers) CYP2D6 activity, received a single 500 mg oral dose of procainamide hydrochloride on two occasions, once alone (period 1) and once during the concomitant administration of the selective inhibitor quinidine (50 mg four times daily; period 2). Blood and urine samples were collected over 36 h after drug administration of procainamide and analysed for procainamide and its major metabolites (N-acetylprocainamide, desethylprocainamide, N-acetyl-desethylprocainamide, p-aminobenzoic acid and its N-acetylated derivative, and nitroprocainamide). No differences were observed in the oral and renal clearances of procainamide between extensive metabolizers and poor metabolizers during either study period. However, partial metabolic clearance of procainamide to desethylprocainamide was significantly greater in extensive metabolizers than in poor metabolizers during both periods. Most importantly, the urinary excretion of nitroprocainamide during period 1 was measurable in 7/13 extensive metabolizers but in none of the poor metabolizers. During the concomitant administration of quinidine, nitroprocainamide could not be detected in the urine of any individuals tested. Therefore, our results suggest that CYP2D6 is involved in the in-vivo aliphatic amine deethylation and N-oxidation of procainamide at its arylamine function in man. Further studies are needed to demonstrate whether a low CYP2D6 activity, either genetically determined or pharmacologically modulated, could prevent drug-induced lupus erythematosus syndrome observed during chronic therapy with procainamide.

The influence of moderate and chronic exercise training on the pharmacokinetics of procainamide and N-acetylprocainamide.

The effect of moderate and prolonged exercise on the disposition and metabolism of drugs has not been extensively examined. The present study examined the effect of exercise training on the pharmacokinetics of procainamide and its active metabolite, N-acetylprocainamide. Male Sprague Dawley rats were randomly assigned to three testing groups: (1) sedentary, (2) 4 weeks of exercise training and (3) 8 weeks of exercise training. Treadmill speed and exercise duration were gradually increased, reaching a final rate of 24 m min-1 for an hour by the end of the 4-week or 8-week period. Sedentary and exercise trained rats received a single i.p. dose of procainamide (100 mg kg-1). Serial blood samples were collected over a 10 h period and plasma samples were analysed by an UV-HPLC method. Noncompartmental analysis was performed to estimate the pharmacokinetic parameters. The t1/2 of procainamide was significantly (p < 0.05) higher in the 8 week exercise group (331 min) as compared to the sedentary group (77 min). In addition, there was a significant reduction in the amount of N-acetylprocainamide formed after 8 weeks of exercise (AUCNAPA = 739 ng mL-1 min-1). Results of this study suggest that prolonged exercise (8 weeks of training) alters the pharmacokinetics of procainamide by modifying the amount of active metabolite formed.

Effect of age, gender, and race on steady state procainamide pharmacokinetics after administration of procanbid sustained-release tablets.

Procainamide hydrochloride is a Class 1A antiarrhythmic agent administered intravenously or orally for treatment of symptomatic ventricular premature depolarizations (VPD), nonsustained ventricular tachycardia, and life-threatening ventricular arrhythmias. A new sustained-release formulation, Procanbid, which allows for twice-daily dosing was recently approved for marketing in the United States. This paper describes the population pharmacokinetics of procainamide and N-acetylprocainamide (NAPA), the major metabolite, in healthy volunteers and patients with VPD by combining Cmax, tmax, Cmin, and AUC(0-12) values at steady state from six multiple-dose studies in which one 1000-mg or two 500-mg Procanbid tablets were administered. Means of parameters by race and gender were inspected for trends likely to be of clinical relevance. Procainamide and NAPA pharmacokinetic parameters observed after administration of Procanbid tablets were similar in blacks and whites, and in men and women. However, differences in body size should be considered when determining the Procanbid dose for women. Participant age had significant impact on NAPA pharmacokinetics in this study population and should be considered in dose selection. Age effects on procainamide were not detected in the study population, which was heavily weighted toward younger subjects, but are anticipated in the older population of patients for which procainamide is indicated. Procanbid formulation performance was not altered by patient demographics.