Evaluation of an open-loop, computer-based infusion system designed to achieve a series of constant, targeted plasma procainamide concentrations in patients undergoing electrophysiologic testing.

STUDY OBJECTIVE: To evaluate the performance of a computer-based procainamide infusion system in patients undergoing electrophysiologic testing. DESIGN: Prospective case series. SETTING: Electrophysiology laboratory in a university hospital. PATIENTS: Thirty-four patients with inducible sustained ventricular tachycardia. INTERVENTIONS: Intravenous infusion of procainamide to achieve and maintain targeted plasma concentrations. MEASUREMENTS AND MAIN RESULTS: System performance was assessed by comparing targeted and observed plasma concentrations. The population median absolute performance error (size of typical miss) was 12.6% (95% CI 11.2-14.1%). The population median performance error (system bias) was not significantly different from zero. A small but statistically significant improvement in performance over time was observed (population absolute performance error divergence -0.125%/min). Population wobble (overall system stability) was 7.6% (95% CI 6.8-8.3%). Population-based estimates of central compartment volume and volume of distribution at steady state were significantly higher and lower, respectively, than estimates used by the infusion system. CONCLUSION: The computer-based infusion system is capable of achieving and maintaining a series of targeted procainamide concentrations in patients undergoing electrophysiologic testing.

Electrophysiologic interactions of procainamide and N-acetylprocainamide in isolated canine cardiac Purkinje fibers.

The study objective was to characterize the electrophysiologic interactions of procainamide (PA) and its metabolite, N-acetylprocainamide (NAPA), in canine Purkinje fibers. Cell (N = 43) action potentials were measured in Tyrode's solution (K+ = 4.0 mM, 36 degrees C) at a basic cycle length of 1,000 ms using standard microelectrode techniques. Six PA concentrations (0.020-0.32 mM) and six NAPA concentrations (0.010-0.24 mM) were studied alone and in combination. PA caused concentration-dependent decreases in Vmax and APD50 but did not alter APD90, ERP, or RMP. NAPA caused a small but not significant concentration-dependent decrease in Vmax, no change in RMP, and significant concentration-dependent increases in APD50, APD90, and ERP. Low NAPA concentrations increased, intermediate concentrations did not affect, and high NAPA concentrations again increased PA's effect on Vmax. PA-NAPA combinations resulted in concentration-dependent changes in APD50 that were intermediate between the effects of PA or NAPA alone. PA did not significantly alter NAPA's effects on APD90 at NAPA concentrations less than or equal to 0.040 mM, while it antagonized NAPA's effect at higher concentrations. The effects of PA-NAPA combinations on ERP were generally similar to their effects on APD90. The electrophysiologic effects of PA-NAPA combinations in normal canine Purkinje fibers are complex functions of the relative and absolute concentrations of the two compounds.

Evaluation of very rapid emit Qst methods for measuring serum procainamide and N-acetylprocainamide concentrations.

This study assessed the Emit Qst procainamide (PA) and N-acetylprocainamide (NAPA) assays. Accuracy and intraday precision were evaluated by repeatedly measuring PA and NAPA concentrations in spiked serum samples using Qst and high-performance liquid chromatography methods. Interday precision was evaluated by measuring concentrations in spiked samples over 4 weeks. Correlation between methods was assessed in patient samples, and proportional, constant, and random errors were estimated. Intraday coefficients of variation (CVs) were below 6.4% for PA and NAPA for both methods; interday CVs were below 7.8%. The proportional, constant, and random errors of the PA Qst assay in patient samples were 5.7%, -0.224 mg/L, and +/- 0.574 mg/L, respectively. The same errors in the NAPA Qst assay were 17.2%, 0.229 mg/L, and +/- 1.79 mg/L, respectively. The Qst assays are rapid, accurate, and precise methods for routine clinical measurement of PA and NAPA, although the proportional error in the NAPA assay should be recognized.

Acecainide pharmacokinetics in normal subjects of known acetylator phenotype.

The purpose of this study was to determine the pharmacokinetics of acecainide (formerly N-acetylprocainamide) in six normal subjects of known acetylator phenotype. Three subjects were fast acetylators and three slow acetylators by sulfapyridine phenotyping criteria. Each subject received a 20-min, 3 mg kg-1 intravenous acecainide infusion. Concentrations of acecainide, procainamide, and their deethylated metabolites were measured in serum and urine samples using HPLC. Acecainide renal clearance, nonrenal clearance, steady-state volume of distribution, and other pharmacokinetic parameters were estimated using standard approaches. Acecainide renal clearance and steady-state volume of distribution were (mean +/- SD) 13.6 +/- 1.581 h-1 and 135 +/- 20.31, respectively, and were not significantly different in fast and slow acetylators. Acecainide nonrenal clearance in the six subjects was 3.0 +/- 1.01 h-1; however, nonrenal clearance in slow acetylators was 1.8 times that in fast acetylators (3.9 vs 2.21 h-1, p = 0.012) with clear separation of the subjects into two groups when the data were grouped by acetylator phenotype. The nonrenal clearance of acecainide was inversely correlated with percentage sulfapyridine acetylation. Computer simulations were conducted to explore possible explanations for the observed difference in nonrenal clearance.

Moricizine: a novel antiarrhythmic agent.

Moricizine is a phenothiazine derivative with Vaughan Williams class 1 antiarrhythmic properties. It undergoes extensive first-pass metabolism, has a bioavailability of 34-38 percent, and is 95 percent bound to plasma proteins. Moricizine is extensively metabolized and may have pharmacologically active metabolites. A recent clinical study has shown that moricizine is slightly less effective than encainide or flecainide in suppressing ventricular premature depolarizations. Compared with disopyramide and quinidine, moricizine was equally or more effective in suppressing ventricular premature depolarizations, couplets, and nonsustained ventricular tachycardia. Further studies are needed comparing moricizine with other class 1 agents in the treatment of life-threatening arrhythmias; available data suggest that moricizine is comparable with these agents in the treatment of ventricular tachycardias and fibrillation. Moricizine appears to have a low incidence of serious adverse effects compared with other antiarrhythmics. This combination of apparently similar efficacy with a decreased incidence of adverse effects makes moricizine a worthwhile addition to currently available antiarrhythmic agents.

Reversed-phase liquid chromatography method for measurement of procainamide and three metabolites in serum and urine: percent of dose excreted as deethyl metabolites.

We report a reversed-phase high-performance liquid chromatography method for the determination of procainamide (PA) and three of its metabolites, n-acetylprocainamide (NAPA), deethylprocainamide (DEPA), and deethyl-n-acetylprocainamide (DENAPA), in serum and urine. (p-Amino)-n-(2-dipropylaminoethyl)-benzamide was the internal standard. A phenyl column (1.0-mL/min flow rate) and a mobile phase consisting of 0.075 M acetate buffer (pH 4.3):acetonitrile (20:3) resulted in a total chromatography time of 21.6 min. The optimum detector wavelength was 270 nm. Maximum linear concentrations were 37.8, 34.2, 20.0, and 16.3 mg/L for DEPA, DENAPA, PA, and NAPA, respectively. Minimum detectable concentrations were 0.05 mg/L or less for all four compounds. One-tenth milliliter of sample was extracted into methylene chloride:2-propyl alcohol (9:1). Extraction efficiencies were independent of concentration or biological fluid for each compound. Standard curves were linear and best-fit by dividing the curve into two portions and/or using weighted linear regression. Within-day and day-to-day precison were excellent. No interfering substances were observed in the serum or urine of normal subjects with the exception of caffeine, which was resolved by alteration of the mobile phase. Advantages of this method include a small sample volume, low minimum detectable concentrations, and an order of elution which enhances the detectability of the deethyl metabolites. Urinary excretion of DEPA and DENAPA accounted for an average of only 0.58 and 0.53%, respectively, of PA doses administered intravenously to six normal volunteers.

Concentration-dependent clearance of procainamide in normal subjects.

Four normal volunteers each received two intravenous doses of PA. The mean low dose was 3.30 mg kg-1 (infused over 20 minutes) while the mean high dose was 12.5 mg kg-1 (infused over 60 minutes). Blood samples were collected for 12 hours and urine was collected for 48 hours after each dose. PA concentrations were determined by both HPLC and fluorescent immunoassay methods. The reported concentrations and pharmacokinetic parameters are from the HPLC data unless otherwise indicated. The mean peak serum PA concentrations resulting from the low and high doses were 3.18 and 9.07 micrograms ml-1, respectively. Total PA clearance averaged 763 ml min-1 and 577 ml min-1 while renal clearance averaged 360 ml min-1 and 318 ml min-1 after the low and high doses, respectively. Concentration-dependent decreases in nonrenal PA clearance ranged from 31 to 43 percent (p less than 0.05) in the four subjects. Total clearance decreases ranged from 4.7 to 36 per cent (p less than 0.05). Differences between doses in renal clearance, elimination rate constant, and volume of distribution were not statistically significant. This study demonstrates that the nonrenal and total clearances of PA are concentration-dependent in normal subjects at therapeutic plasma PA concentrations and suggests that the total clearance changes are of sufficient magnitude to be clinically important.

Fluoroimmunoassays for procainamide and N-acetylprocainamide compared with a liquid-chromatographic method.

We measured procainamide and its active metabolite, N-acetylprocainamide (NAPA), in 80 sera from 37 patients by a new fluorimmunoassay procedure and an established "high-performance" liquid-chromatographic method. Additive and proportional differences between the methods were 0.07 mg/L and 9%, respectively, for procainamide and 0.62 mg/L and 16% for NAPA. Between-day CVs by the chromatographic and immunoassay methods, respectively, were 3.9% and 2.2% for procainamide at a concentration of 6 mg/L, and 5.1% and 1.2% for NAPA (14 mg/L). We applied a modification of the fluoroimmunoassay for determination of procainamide concentrations, using sera obtained during a pharmacokinetic study, and demonstrated excellent agreement with the chromatographic method.