A pharmacodynamic evaluation of hematologic toxicity observed with etoposide phosphate in the treatment of cancer patients.

The pharmacodynamics of etoposide phosphate (Etopophos; Bristol-Myers Squibb Company, Princeton, NJ), a water-soluble prodrug of etoposide, was evaluated in 39 patients with solid tumors after a 30-minute intravenous infusion of escalating doses (equivalent to 50 to 175 mg/m2 of etoposide) on a day 1, 3, and 5 schedule of treatment. Serial blood samples were collected at predose and throughout the 32 hours following day 1 of treatment to determine the area under the plasma concentration-time curve (AUC) of etoposide phosphate and etoposide. Hematology profiles and serum chemistries were determined at predose and twice weekly for approximately 3 weeks after each treatment cycle. Both linear and nonlinear pharmacodynamic models were used to evaluate the relationship between hematologic toxicity and etoposide AUC and patient factors (age, gender, performance status, prior radiation therapy, prior chemotherapy, baseline albumin, bilirubin, alkaline phosphatase, creatinine, leukocyte count, granulocyte count). Etoposide phosphate was converted rapidly to etoposide in vivo. The ratio of the etoposide phosphate AUC to that of etoposide was < or = 1.2% indicating that etoposide was the main species in the systemic circulation. Myelosuppression was the dose-limiting toxicity, and significant decreases in white blood cell and granulocyte counts were noted. Hematologic toxicity was best described by a stepwise linear regression model consisting of etoposide AUC, serum albumin, and bilirubin. In summary, hematologic toxicity produced by the intravenous administration of etoposide phosphate correlates significantly with etoposide AUC and patient factors (baseline serum albumin and bilirubin) in cancer patients.

Effects of gender, age, and race on the pharmacokinetics of etoposide after intravenous administration of etoposide phosphate in cancer patients.

The influence of gender, age, and race on the pharmacokinetics of etoposide and on the extent of conversion of etoposide phosphate (Etopophos; Bristol-Myers Squibb Company, Princeton, NJ) to etoposide are summarized. Included in the integrated statistical analyses were 192 patients from six phase I/II studies (102 men and 90 women, 128 aged < or = 65 years and 64 aged > 65 years; 134 were white, 18 were other races, and race was not recorded for 40). The dose of etoposide phosphate ranged from 25 to 200 mg/m2 of etoposide equivalents and was administered as 5-(bolus) to 210-minute intravenous infusions. Total body clearance of etoposide was comparable between men and women. However, significantly lower steady-state volumes of distribution and shorter half-lives were observed in women relative to men. Patients who were older than 65 years had significantly lower etoposide total body clearance and longer half-lives than younger patients. The gender- and age-related differences observed in the pharmacokinetic parameters of etoposide were significant but generally of a small magnitude (< or = 13%), indicating no need for dose adjustment in these patient populations. There were no significant race-related differences in the pharmacokinetic parameters of etoposide. All patients showed rapid conversion of etoposide phosphate to etoposide. The individual area under the plasma concentration-time curve ratio of etoposide phosphate/etoposide was < or = 0.0324, indicating that etoposide was the major circulating moiety after infusion of etoposide phosphate. Significant gender-, age-, or race-related differences in the area under the plasma concentration-time curve ratios were not observed. An evaluation of the area under the plasma concentration-time curve ratios with respect to infusion time suggested that the conversion of etoposide phosphate to etoposide was independent of infusion time.

Bioequivalence assessment of etoposide phosphate and etoposide using pharmacodynamic and traditional pharmacokinetic parameters.

The bioequivalence of etoposide phosphate, a prodrug of etoposide, to etoposide was assessed in a randomized, crossover study in 29 patients with histologically established solid tumors that had failed conventional treatment. Cohorts of patients received one treatment course each of etoposide and etoposide phosphate which consisted of a 100 mg/m2 per day etoposide equivalent dose infused i.v. over 1 hr on a Day 1 to 5 schedule of treatment. The second course was administered 21 days later or on recovery of blood cell counts. Plasma and urine samples were collected over 24 hr on Day 1 of each course and assayed for etoposide content by a validated HPLC/UV method. Resulting data were subjected to noncompartmental pharmacokinetic analysis. Hematology profiles were obtained by collecting blood samples prior to the first course and twice a week after each course. The pharmacodynamics and pharmacokinetics of etoposide were virtually identical after the two treatments. The point estimates (90% confidence intervals) for nadir WBC, granulocytes, hemoglobin, and platelets expressed as % decrease from the baseline, and for the pharmacokinetic parameters, Cmax, and AUC0 infinity, after intravenous etoposide phosphate relative to etoposide were 100% (96%, 105%), 97% (91%, 103%), 95% (82%, 109%), 95% (84%, 106%), 107% (101%, 113%), and 113% (107%, 119%), respectively. Therefore, etoposide phosphate is bioequivalent to etoposide based on pharmacokinetic and pharmacodynamic assessments.

Etoposide bioavailability after oral administration of the prodrug etoposide phosphate in cancer patients during a phase I study.

PURPOSE: The purpose of this study was to determine the bioavailability (F) of etoposide (E;VP-16) after oral administration of the water-soluble prodrug etoposide phosphate (EP;BMY-40481) during a phase I trial in cancer patients. PATIENTS AND METHODS: Twenty-nine patients received oral EP (capsules, 50 to 150 mg/m2/d of E equivalent) for 5 days in week 1 (course 1), followed every 3 weeks thereafter by a daily intravenous (i.v.) infusion for 5 days of E (80 mg/m2, 1-hour i.v. infusion; course 2); in three patients, the i.v. E course was given before oral EP. Plasma and urine E pharmacokinetics (high-performance liquid chromatography [HPLC]) were performed on the first day of oral EP administration and on the first day of i.v. E. RESULTS: Twenty-six of 29 patients completed two courses or more, whereas three patients received only one course due to toxicity. Myelosuppression was dose-dependent and dose-limiting, with grade 4 leukoneutropenia in four of 15 patients at 125 mg/m2 and in five of seven patients at 150 mg/m2. One patient died of meningeal hemorrhage related to grade 4 thrombocytopenia. Other toxicities were infrequent and/or manageable. No objective response was observed. The maximum-tolerated dose (MTD) is therefore 150 mg/m2, and the recommended oral dose of EP for phase II trials in this poor-risk patient population is 125 mg/m2. Twenty-six patients had pharmacokinetic data for both oral EP and i.v. E, whereas three had pharmacokinetic data on the i.v. E course only. After oral administration of EP, the pharmacokinetics of E were as follows: mean absorption rate constant (Ka), 1.7 +/- 1.7 h-1 (mean +/- SD); lag time, 0.3 +/- 0.2 hours; time of maximum concentration (t(max)), 1.6 +/- 0.8 hours; and mean half-lives (t1/2), 1.6 +/- 0.2 (first) and 10.3 +/- 5.8 hours (terminal); the increase in the area under the plasma concentration-versus-time curve (AUC) of E was proportional to the EP dose. After the 1-hour i.v. infusion of E, maximum concentration (C(max)) was 15 +/- 3 micrograms/mL; mean AUC, 88.0 +/- 22.0 micrograms.h/mL; mean total-body clearance (CL), 0.97 +/- 0.24 L/h/m2 (16.2 mL/min/m2); and mean t1/2, 0.9 +/- 0.6 (first) and 8.1 +/- 4.1 hours (terminal). The 24-hour urinary excretion of E after i.v. E was significantly higher (33%) compared with that of oral EP (17%) (P < .001). Significant correlation was observed between the neutropenia at nadir and the AUC of E after oral EP administration (r = .58, P < .01, sigmoid maximum effect [E(max)] model). The mean F of E after oral administration of EP in 26 patients was 68.0 +/- 17.9% (coefficient of variation [CV], 26.3%; F range, 35.5% to 111.8%). In this study, tumor type, as well as EP dose, did not significantly influence the F in E. There was no difference in F of E, whether oral EP was administered before or after i.v. E. Compared with literature data on oral E, the percent F in E after oral prodrug EP administration was 19% higher at either low ( < or = 100 mg/m2) or high ( > 100 mg/m2) doses. CONCLUSION: Similarly to E, the main toxicity of the prodrug EP is dose-dependent leukoneutropenia, which is dose-limiting at the oral MTD of 150 mg/m2/d for 5 days. The recommended oral dose of EP is 125 mg/m2/d for 5 days every 3 weeks in poor-risk patients. Compared with literature data, oral EP has a 19% higher F value compared with oral E either at low or high doses. This higher F in E from oral prodrug EP appears to be a pharmacologic advantage that could be of potential pharmacodynamic importance for this drug.

Phase I and pharmacokinetic study of a water-soluble etoposide prodrug, etoposide phosphate (BMY-40481).

Etoposide phosphate is a water-soluble prodrug of etoposide. A phase I and pharmacokinetic study has been performed over the dose range 25-110 mg/m2/day for 5 days (etoposide equivalent doses). The maximum tolerated dose (MTD) was 110 mg/m2/day for 5 days every 3 weeks and the dose-limiting toxicity was neutropenia. Other toxicities were mild, with the exception of 2 patients who displayed significant hypersensitivity reactions. The etoposide phosphate:etoposide area under the plasma concentration versus time curve (AUC) ratio was < 1% and the pharmacokinetic parameters for etoposide were within previously reported ranges. Pharmacodynamic analyses demonstrated that etoposide AUC and baseline white blood cell count were significant determinants of leucopenia (model r2 = 0.51).

Pharmacokinetics and bioequivalence of etoposide following intravenous administration of etoposide phosphate and etoposide in patients with solid tumors.

PURPOSE: To assess the pharmacokinetics and bioequivalence of etoposide following intravenous (i.v.) administration of etoposide phosphate (Etopophos; Bristol-Myers Squibb, Princeton, NJ), a prodrug of etoposide, and VePesid (Bristol-Myers Squibb). PATIENTS AND METHODS: Forty-nine solid tumor patients were randomized to receive Etopophos or VePesid on day 1 of a day-1,3,5 schedule of treatment. The alternate drug was given on day 3 and repeated on day 5. The dose, 150 mg/m2 of etoposide equivalent, was administered by constant rate infusion over 3.5 hours. The plasma concentrations of etoposide phosphate and etoposide were determined using validated high-performance liquid chromatography (HPLC) assays. Pharmacokinetic parameters were calculated by a noncompartmental method. Etopophos was considered to be bioequivalent to VePesid if the 90% confidence limits for the differences in mean maximum concentration (Cmax) and AUCinf of etoposide were contained within 80% to 125% for the long-transformed data. RESULTS: Forty-one patients were assessable for pharmacokinetics and bioequivalence assessment. Following i.v. administration, etoposide phosphate was rapidly and extensively converted to etoposide in systemic circulation, resulting in insufficient data to estimate its pharmacokinetics. The mean bioavailability of etoposide from Etopophos, relative to VePesid, was 103% (90% confidence interval, 99% to 106%) based on Cmax, and 107% (90 confidence interval, 105% to 110%) based on area under the concentration versus time curve from zero to infinity (AUCinf) values. Mean terminal elimination half-life (t1/2), steady-state volume of distribution (Vss), and total systemic clearance (CL) values of etoposide were approximately 7 hours, 7 L/m2, and 17 mL/min/m2 after Etopophos and VePesid treatments, respectively. The main toxicity observed was myelosuppression, characterized by leukopenia and neutropenia. CONCLUSION: With respect to plasma levels of etoposide, i.v. Etopophos is bioequivalent to i.v. VePesid.

Assessment of toxicokinetics and toxicodynamics following intravenous administration of etoposide phosphate in beagle dogs.

The toxicokinetics and toxicodynamics of etoposide phosphate (BMY-40481), a water soluble phosphate ester derivative of etoposide, were investigated in beagle dogs (N = 4) following 5 min i.v. infusion doses equivalent to 57, 114 and 461 mg/m2 of etoposide. The doses were administered in sequence starting with the low dose. There was a 28 day wash-out period between the doses. Serial blood samples were collected over 32 hr and the levels of intact BMY-40481 and etoposide in plasma were measured using validated HPLC assays. Hematology profiles were obtained at pre-dose, and twice a week post-dose for 28 days to correlate systemic exposure to etoposide and hematologic toxicity. Following i.v. administration, plasma concentrations of BMY-40481 declined rapidly. For the 3 doses, mean t 1/2 of BMY-40481 ranged from 0.11-0.17 hr (6.6-11 min). The mean Cmax and AUC values of BMY-40481 ranged from 1.72-40.5 micrograms/ml and 0.16-4.14 hr.micrograms/ml, respectively. Both systemic clearance and steady state volume of distribution of BMY-40481 decreased significantly at the high dose. In contrast, the mean Cmax and AUC values of etoposide ranged from 5.46-39.4 micrograms/ml and 2.28-22.6 hr.micrograms/ml, respectively. Cmax occurred at the end of infusion (5 min) at all dose levels, indicating that etoposide was rapidly formed from BMY-40481. The apparent systemic clearance (range: 342-435 ml/min/m2) and apparent steady state volume of distribution (range: 21.5-26.6 l/m2) of etoposide were dose-independent. The AUC of etoposide was significantly correlated with hematologic toxicity, i.e., percent decreases in white blood count (WBC), absolute neutrophil count (ANC) and platelets.(ABSTRACT TRUNCATED AT 250 WORDS)

Phase I study of etoposide phosphate (etopophos) as a 30-minute infusion on days 1, 3, and 5.

Etoposide phophate is a phosphate ester prodrug of etoposide designed to improve the pharmaceutical characteristics of the parent compound. A Phase I dose-escalating study of etoposide phosphate was conducted concurrently at two institutions to determine its toxicity, pharmacokinetics, and maximum tolerated dose. Etoposide phosphate was administered i.v. for 30 min on days 1, 3, and 5 every 21 days or on recovery from toxicity. Cohorts of at least three patients received etoposide phosphate at dose levels from 50 mg/m2 to 150 mg/m2 expressed as molar equivalents of etoposide. Blood and urine samples were obtained from all patients during the first cycle of treatment and the concentrations of etoposide phosphate and etoposide were measured. Thirty-nine patients with documented cancers received a total of 75 cycles of etoposide phosphate. The dose-limiting toxicity was myelosuppression which occurred at the 150-mg/m2 etoposide equivalent dose. Etoposide phosphate was rapidly and extensively converted to etoposide. No measurable etoposide phosphate was detectable in the plasma by 15-60 min after the end of the infusion. The mean half-life of etoposide at the different dose levels ranged from 5.5 to 9.3 h. The pharmacokinetics of etoposide, generated from etoposide phosphate, was linear over the dose range studied and was comparable to results reported in the literature for i.v. etoposide. In summary, i.v. etoposide phosphate is rapidly and extensively converted to etoposide. The maximum tolerated dose of etoposide phosphate when given on days 1, 3, and 5 is 150 mg/m2/day. The dose-limiting toxicity is myelosuppression. The maximum tolerated dose and adverse event profile are consistent with those of etoposide.

High-performance liquid chromatographic analysis using a highly sensitive fluorogenic reagent, 2-anthroyl chloride, and stereoselective determination of the enantiomers of mexiletine in human serum.

A stereoselective and highly sensitive HPLC assay was developed for mexiletine enantiomers using a new fluorogenic derivatization reagent, 2-anthroyl chloride. The reagent was synthesized and utilized for the fluorescent detection (excitation at 270 nm, emission at 400 nm) of mexiletine enantiomers as their N-anthroyl derivatives on a Pirkle phenylglycine ionic HPLC column. The assay had a lower limit of quantitation at 2.5 ng/ml with a limit of detection measured at 0.5 ng/ml for each enantiomer in serum with a signal-to-noise ratio of 5:1. In a preliminary pharmacokinetic study, 200 mg of racemic mexiletine hydrochloride were administered orally to two healthy volunteers. Serum samples were collected at timed intervals over 48 h. The terminal elimination half-lives determined for total R(-)- and S(+)-mexiletine were 10.9 and 11.5 h, respectively. The serum free fractions for R(-)- and S(+)-mexiletine were found to be 0.56 and 0.53, respectively.

Phase I evaluation of a water-soluble etoposide prodrug, etoposide phosphate, given as a 5-minute infusion on days 1, 3, and 5 in patients with solid tumors.

PURPOSE: To determine the toxicities, maximum-tolerated dose (MTD), and pharmacology of etoposide phosphate, a water-soluble etoposide derivative, administered as a 5-minute intravenous infusion on a schedule of days 1, 3, and 5 repeated every 21 days. PATIENTS AND METHODS: Thirty-six solid tumor patients with a mean age of 63 years, performance status of 0 to 1, WBC count > or = 4,000/microL, and platelet count > or = 100,000/microL, with normal hepatic and renal function were studied. Doses evaluated in etoposide equivalents were 50, 75, 100, 125, 150, 175, and 200 mg/m2/d. Etoposide in plasma and urine and etoposide phosphate in plasma were measured by high-performance liquid chromatography (HPLC). Eleven of 36 patients were treated with concentrated etoposide phosphate at 150 mg/m2/d. RESULTS: Grade I/II nausea, vomiting, alopecia, and fatigue were common. Leukopenia (mainly neutropenia) occurred at doses greater than 75 mg/m2, with the nadir occurring between days 15 and 19 posttreatment. All effects were reversible. Hypotension, bronchospasm, and allergic reactions were not observed in the first 25 patients. The MTD due to leukopenia was determined to be between 175 and 200 mg/m2/d. In 11 patients treated with concentrated etoposide phosphate, no local phlebitis was noted, but two patients did develop allergic phenomena. The conversion of etoposide phosphate to etoposide was not saturated in the dosages studied. Etoposide phosphate had peak plasma concentrations at 5 minutes, with a terminal half-life (t1/2) of 7 minutes. Etoposide reached peak concentrations at 7 to 8 minutes, with a t1/2 of 6 to 9 hours. Both etoposide phosphate and etoposide demonstrated dose-related linear increases in maximum plasma concentration (Cmax) and area under the curve (AUC). CONCLUSION: Etoposide phosphate displays excellent patient tolerance in conventional dosages when administered as a 5-minute intravenous bolus. The suggested phase II dose is 150 mg/m2 on days 1, 3, and 5. The ability to administer etoposide phosphate as a concentrated, rapid infusion may prove of value both in the outpatient clinic and in high-dose regimens.

Clinical and pharmacokinetic overview of parenteral etoposide phosphate.

Etoposide phosphate (Etopophos, BMY-40481) is a water-soluble derivative of the widely used podophyllotoxin etoposide (VP-16). The phosphate ester renders the compound water-soluble, eliminating the need for formulation in polysorbate (Tween) 80, ethanol, and polyethylene glycol. As a result the compound can be given at high concentrations and as a bolus. In animals and in vitro, etoposide phosphate (EP) is rapidly and completely converted to VP-16. Clinical development of the i.v. formulation has focused on the identification of the maximum tolerated dose (MTD) and pharmacokinetic characteristics of the drug using a 5 daily dose schedule and a days 1, 3, and 5 schedule, with the drug being given over 30 or 5 (bolus) min. Myelosuppression was dose-limiting. Data from these trials show the rapid and complete conversion of EP to VP-16, a pharmacokinetic/pharmacodynamic relationship for myelosuppression and exposure to VP-16, and an MTD of 100 and 150 mg/m2 (molar equivalent to VP-16) when EP is given daily for 5 days and on days 1, 3, and 5, respectively. A formal randomized trial has been conducted to show the pharmacokinetic comparability of EP and VP-16. In this trial, exposure to VP-16 was the same after the parenteral administration of equimolar doses of EP or VP-16. The feasibility of bolus dosing and treatment at high concentrations has been demonstrated, with no effects on the cardiovascular system being noted. Parenteral EP is pharmacokinetically and biologically equivalent to VP-16 and has the advantages of the elimination of potentially toxic excipients; more convenient administration; and ability to be given as a bolus, at high concentrations, and as a continuous infusion.

Chiral separation by high performance liquid chromatography. I. Review on indirect separation of enantiomers as diastereomeric derivatives using ultraviolet, fluorescence and electrochemical detection.

The increased attention on the therapeutic implications of stereoisomerism has provided an impetus for the development of analytical methods for enantiomeric separation. The indirect method of separation of enantiomers as diastereomers using high performance liquid chromatography (HPLC) has emerged as an efficient and versatile approach. This is due mainly to the availability of numerous chiral derivatization reagents (CDRs). This article reviews CDRs useful for the development of an indirect HPLC method using ultraviolet, fluorescence and electrochemical detection. In addition, factors crucial for the development of the indirect method are discussed.

Mexiletine's antifibrillatory actions are limited by the occurrence of convulsions in conscious animals.

The antiarrhythmic actions of the racemate and enantiomers of mexiletine were studied in conscious and anaesthetised rats. Racemate or enantiomers, at 20 mg/kg i.v., had little effect on ischaemia-induced ventricular fibrillation in conscious or anaesthetised rats. In conscious rats 20 mg/kg caused convulsions in 78-89% of rats when the plasma concentration of racemate was 20 +/- 2 microM. In anaesthetized animals a higher dose (40 mg/kg) of racemate could be given; this completely prevented ischaemia-induced fibrillation when the plasma concentration was 26 +/- 2 microM. Racemate and enantiomers accumulated in the heart and brain of conscious animals to give tissue: plasma ratios of 7.5 and 23, respectively. With electrical stimulation, both racemate and enantiomers dose dependently (4-32 mg/kg) increased threshold currents for induction of ventricular fibrillation, increased refractory period and minimally changed the ECG; findings expected with a Class Ib antiarrhythmic. The above studies failed to show major differences between racemate or enantiomers except for consistently lower (20-30%) plasma concentrations of R(-) at all dose levels. In conclusion, mexiletine prevented ischaemia-induced ventricular fibrillation in anaesthetised animals but only when given at doses producing convulsions in conscious animals.

In vitro assessment of vancomycin HCl compatibility after coinfusion with a specialized amino acid formulation.

Vancomycin usage at British Columbia's Children's Hospital has increased substantially in the Special Care Nursery as a consequence of a study demonstrating a reduced morbidity and mortality in neonates with necrotizing enterocolitis when treated with vancomycin and cefotaxime. The inability to place more than one peripheral intravenous access necessitates interruption of parenteral nutrition to infuse vancomycin, resulting in a reduction of the planned daily intake of these neonates. This is clinically significant with the administration of vancomycin because of the long administration period required for this drug (60 minutes). This study was designed to assess the physical and chemical stability of vancomycin with a standard neonatal parenteral nutrition solution, Vamin A, when coadministered through the same intravenous line. To simulate the actual clinical setting, the dose of vancomycin and the infusion rate of Vamin A were chosen to represent those commonly used in a 1-kg neonate. Physical compatibility was assessed using effluent obtained after coinfusion of vancomycin with parenteral nutrition solution. Duplicate samples were visually checked for color changes and precipitate. High-pressure liquid chromatography (HPLC) and pH testing were used to assess chemical compatibility of vancomycin. The results of physical compatibility revealed no color change or precipitate. No changes in pH were observed. HPLC determination confirmed that there were no significant time-dependent changes in vancomycin stability. The samples were studied over 24 hours to determine the rate of degradation of vancomycin, if any, under various temperature conditions. The concentrations were not significantly different from each other at the different temperatures studied. Thus, there was no apparent change in the concentration of vancomycin in the presence of Vamin A.(ABSTRACT TRUNCATED AT 250 WORDS)

Tissue distribution of mexiletine enantiomers in rats.

1. The kinetics of distribution of the enantiomers of mexiletine were studied in various tissue (heart, brain, lungs, liver, kidneys and fat) in male Sprague-Dawley rats after administration of a single i.v. dose (10 mg/kg) of racemic mexiletine. 2. The pharmacokinetic parameters calculated from the serum data showed a 32% greater systemic clearance (162 ml/min per kg vs 123 ml/min per kg) and a 22% greater steady-state volume of distribution (9.0 l/kg vs 7.4 l/kg) for R(-)-mexiletine relative to the S(+)-enantiomer. However, the terminal elimination half-lives of the enantiomers (1.4 and 1.3 h for R(-)- and S(+)-mexiletine, respectively) did not exhibit stereoselectivity. 3. Maximum tissue concentrations of the enantiomers were observed at 5 min after dosage in all tissues studied. Stereoselective uptake was evident only in the liver tissue and was 2.4-fold greater for S(+)-mexiletine. High tissue/serum ratios (greater than 20 for both enantiomers) were observed in lungs, brain and kidneys. The cardiac concentrations of R(-)- and S(+)-mexiletine were 8- and 7-fold those of serum, respectively. 4. The results demonstrate that the uptake of mexiletine enantiomers into the target tissue (heart) is not stereoselective. However, the relatively high brain accumulation of the enantiomers may be related to the CNS side-effects commonly associated with mexiletine therapy.

Stereoselective pharmacokinetics of tocainide in human uraemic patients and in healthy subjects.

The disposition of tocainide enantiomers were examined in healthy human subjects and uraemic patients following a single i.v. dose (200 mg) of racemic tocainide hydrochloride. In the healthy subjects, the total body clearance of R(-)-tocainide was significantly greater than that of S(+)-tocainide (2.62 vs 1.70 ml.min-1.kg-1). Renal clearance also favoured R(-)-tocainide and appeared to contribute significantly to the stereoselective total body clearance. The volume of distribution of the enantiomers did not differ significantly. Uraemia produced a marked decrease in the total body clearance with no apparent effect on the volume of distribution of both enantiomers. The S/R ratio for total body clearance decreased significantly from 0.66 in healthy subjects to 0.54 in the uraemics, while the ratio for terminal elimination half-life significantly increased from 1.43 to 1.59. These results indicate that uraemia alters the degree of stereoselectivity in the pharmacokinetic parameters of tocainide enantiomers.

The pharmacokinetics of the enantiomers of mexiletine in humans.

1. This study examined the pharmacokinetics of the enantiomers of mexiletine in five healthy subjects who were each given a single, 300 mg, oral dose of racemic mexiletine hydrochloride. 2. The time course of the concentration ratio between the R(-) and the S(+) enantiomers (R/S) in plasma showed a progressive decrease, with a mean +/- S.D. ratio of 1.37 +/- 0.11 at 1 h and 0.64 +/- 0.11 at 48 h. Similarly, the R/S ratios in urine were 1.38 +/- 0.42 and 0.55 +/- 0.12 at 1 h and 72 h, respectively. 3. The terminal elimination half-life of S(+)mexiletine was 11.0 +/- 3.80 h, which was significantly greater (P less than 0.05) than that of the R(-) enantiomer, 9.10 +/- 2.90 h. S(+)Mexiletine also showed a significantly greater apparent volume of distribution (P less than 0.01) and renal clearance (P less than 0.05) than R(-)mexiletine. There was no significant difference in the apparent oral total drug clearance of the enantiomers. 4. The disposition of mexiletine enantiomers in man was stereoselective, and the differences observed between the enantiomers may be due largely to differences in their serum protein binding.

Stereoselective analysis of the enantiomers of mexiletine by high-performance liquid chromatography using fluorescence detection and study of their stereoselective disposition in man.

A sensitive, stereoselective high-performance liquid chromatographic assay was developed for the resolution of the enantiomers of mexiletine as their 2-naphthoyl derivatives on a Pirkle type 1A chiral phase column. Detection of the derivatives was accomplished with a fluorescent detector. Maximum recovery of the enantiomers from plasma was 83% and was observed when plasma proteins were precipitated with a mixture of barium hydroxide-zinc sulphate. The calibration curve in plasma was linear over the concentration range 5-750 ng/ml for each enantiomer (r2 = 0.999) and in urine the linear range was 0.25-7.5 micrograms/ml (r2 = 0.999) for each enantiomer. The minimum detectable quantity of each enantiomer in plasma was 5 ng/ml at a signal-to-noise ratio of 5:1, representing 100 pg injected. A preliminary pharmacokinetic study was undertaken in one healthy male volunteer following an oral dose of 300 mg of racemic mexiletine hydrochloride. The apparent elimination half-lives determined from the plasma data were 12.1 and 14.1 h for the R(-) and S(+) enantiomers, respectively. The cumulative urinary excretion amounts of R(-)- and S(+)-mexiletine were found to be 8.01 and 10.46 mg, respectively. The plasma data indicated that a cross-over of the enantiomer ratios occurred at approximately 8 h. The urinary excretion of the enantiomers was consistent with the pattern found in plasma.

Stereoselective serum protein binding of mexiletine enantiomers in man.

The binding of mexiletine enantiomers to human serum proteins was studied in vitro using serum samples collected from five healthy male subjects. Racemic mexiletine was added to an aliquot of each subject's serum to cover the concentration range 0.2 to 2.0 micrograms/mL. Following ultrafiltration of the serum samples containing racemic mexiletine, the individual enantiomers were determined using a stereoselective high-performance liquid chromatographic method developed in our laboratory. The assay data thus obtained for the free levels of the enantiomers showed that the free fraction of S(+) mexiletine was 28.32 +/- 1.45% and that of the R(-) enantiomer was 19.80 +/- 1.49%. The binding was shown to be significantly greater (p less than 0.001) for R(-) mexiletine than its antipode. There was no evidence of concentration dependence in binding over the concentration range studied, which covered the normal therapeutic range. However, significant inter-individual variability in the free fractions was observed. The total binding of the enantiomers was 76%.