Absolute bioavailability and stereoselective pharmacokinetics of doxepin.

1. Commercial doxepin contains geometric isomers in the proportions Z:E = 15:85. Z-doxepin and its metabolite Z-N-desmethyldoxepin are both active antidepressants, whereas the corresponding E-isomers are less active therapeutically. 2. The present pharmacokinetic study was a balanced, randomized, two-treatment, two-period, two-sequence crossover design in which 12 healthy male volunteers were given single doses of commercial doxepin intravenously and orally on two occasions separated by a washout period. 3. A two-compartment model with no lag time and first-order elimination fitted the plasma concentration-time curves after intravenous dosing. Pharmacokinetic parameters estimated from the model were comparable with those estimated by non-compartmental methods. 4. All pharmacokinetic parameters displayed a wide between-subject variability. Both isomers of doxepin showed large volumes of distribution and relatively short half-lives in plasma, suggestive of extensive distribution and/or tissue binding. The mean fraction absorbed after oral administration was 0.29 for each isomer. Renal clearances of each isomer were very low after either oral or intravenous dosing, although all four analytes were quantifiable in the urine for prolonged periods. 5. After oral dosing, plasma concentrations of the doxepin isomers remained roughly in the ratio Z:E = 15:85, whereas those of N-desmethyldoxepin were closer to 1:1 in all but two outliers, who had high levels E-N-desmethyldoxepin.

Effects of food on the pharmacokinetics of methylphenidate.

PURPOSE: To test the hypothesis that the pharmacokinetics of d-methylphenidate (d-MPH) would be altered by food ingested before administration of an immediate release formulation (dl-MPH- IR) but not when food is ingested before a slow release formulation (dl-MPH-SR). METHODS: A randomized, four-phase, open label, crossover design was conducted in 24 healthy men who each received, on separate occasions, dl-MPH-IR and dl-MPH-SR taken after an overnight fast and 15 min after a standardized breakfast (20% protein, 21% fat, 59% carbohydrate). Plasma MPH levels were monitored by a validated, stereoselective. GLC-ECD method. RESULTS: For plasma d-MPH, there were significant differences (ANOVA) between dl-MPH-IR and dl-MPH-SR in tmax, Cmax (peak exposure), and Cmax/AUC (sensitive to rate of absorption). Dl-MPH-SR on average delayed tmax from 2.3 to 3.7 h and lowered Cmax 34%. There was no significant difference between the formulations in AUC (extent of absorption). For dl-MPH-IR, food significantly increased Cmax (23%) and AUC (15%) and for dl-MPH-SR the corresponding increases were Cmax (17%) and AUC (14%). After dl-MPH-IR, food delayed average tmax from 2.0 to 2.5 but had no effect on tmax after dl-MPH-SR. There was no effect of food on Cmax/AUC (rate of absorption). CONCLUSIONS: Food caused a significant increase in extent of absorption but had no effect on rate of absorption of d-MPH after either dl-MPHIR or dl-MPH-SR.

Quinidine inhibits the 7-hydroxylation of chlorpromazine in extensive metabolisers of debrisoquine.

Quindine is a potent inhibitor of CYP2D6 (debrisoquine 4-hydroxylase). Its effect on the disposition of chlorpromazine was investigated in ten healthy volunteers using a randomised crossover design with two phases. A single oral dose of chlorpromazine hydrochloride (100 mg) was given with and without prior administration of quinidine bisulphate (250 mg). Chlorpromazine and seven of its metabolites were quantified in the 0- to 12-h urine while plasma concentrations of chlorpromazine and 7-hydroxychlorpromazine were measured over 48 h. All volunteers were phenotyped as extensive metabolisers with respect to CYP2D6 using the methoxyphenamine/O-desmethyl-methoxyphenamine metabolic ratio. Quinidine significantly decreased the urinary excretion of 7-hydroxylchlorpromazine 2.2-fold. Moreover the urinary excretion of this metabolite correlated inversely (rs = -0.80) with the metabolic ratio. The urinary recoveries of chlorpromazine, chlorpromazine N-oxide, 7-hydroxy-N-desmethylchlorpromazine, N-desmethyl-chlorpromazine sulphoxide and the total of all eight analytes were unaltered by quinidine. However, quinidine administration caused significant increases in the urinary excretions of chlorpromazine sulphoxide, N-desmethylchlorpromazine and N, N-didesmethylchlorpromazine sulphoxide, which indicated that compensatory increase in these metabolic routes of chlorpromazine might have been responsible for the lack of change observed in the urinary recovery of the parent drug. Quinidine administration produced modest decreases (1.2- to 1.3-fold) in the mean peak plasma concentrations and mean areas under the plasma concentration-time curves of 7-hydroxychlorpromazine and increases (1.3- to 1.4-fold) in these parameters for the parent drug chlorpromazine, but none of these changes reached statistical significance. Based on ANOVA the sample sizes required to detect these differences as significant (alpha = 0.5) with a probability of 0.8 were determined to vary between 15 and 42. These data suggest that CYP2D6 is involved in the metabolism of chlorpromazine to 7-hydroxychlorpromazine. However, genetic polymorphism in this metabolic process did not play a dominant role in accounting for the extremely large interindividual variations in plasma concentrations encountered with this drug.

N(+)-glucuronidation of aliphatic tertiary amines in human: antidepressant versus antipsychotic drugs.

1. Metabolic N(+)-glucuronidation of aliphatic tertiary amine antidepressant or antipsychotic drugs was investigated in man. In each case, urine was collected either from patients and/or from healthy volunteers who were administered the drug orally. 2. Metabolites were separated by hplc and individually collected prior to mass spectrometric analysis in the fast atom bombardment mode. The structure of each metabolite identified as a quaternary ammonium-linked glucuronide metabolite was confirmed by direct comparison of its mass spectrum and chromatographic behaviour with that of an authentic standard synthesized in these laboratories. 3. Of the 10 antipsychotic drugs examined clozapine and loxapine were the only two for which the N(+)-glucuronidation pathway was observed, whereas all four antidepressants gave the respective N(+)-glucuronide metabolite. 4. The N(+)-glucuronide metabolites in 24 h urine samples were quantified by hplc. The mean (n = 3) percentage of the dose excreted as the metabolite was found to be 1.6 and 3.1% in the cases of the antipsychotic agents loxapine and clozapine respectively, whereas for the antidepressants clomipramine, imipramine, trazodone and trimipramine these means varied between 0.1 and 0.8%.

Metabolism of phenothiazine and butyrophenone antipsychotic drugs. A review of some recent research findings and clinical implications.

Whereas some metabolites of antipsychotic drugs are psychoactive and contribute to clinical improvement, recent studies have provided evidence that certain metabolites contribute to side-effects which can be disabling enough to negate clinical improvement as regards the psychosis. The route of administration of the drug can determine the amount of metabolite produced in the body and affect how the patient feels in response to the treatment.

Metabolism of piperidine-type phenothiazine antipsychotic agents. IV. Thioridazine in dog, man and rat.

1. The metabolism of thioridazine was studied in adult male volunteers, female rat and female dog after oral administration of 50 mg, 20 mg/kg and 100 mg over 30 h, respectively. 2. Metabolites in organic extracts of the urine obtained from each species were analysed by plasmaspray h.p.l.c.-mass spectrometry. For phenolic metabolites the crude extracts from each species were derivatized with a silylating reagent (with and without prior enzymic hydrolysis) prior to h.p.l.c.-mass spectrometric analysis. The structures of metabolites, with the exception of phenols, were confirmed by comparison of their chromatographic behaviours and mass spectral data with those of authentic standards. 3. The metabolites identified in the urine of all three species were mesoridazine, sulforidazine, thioridazine ring sulphoxide, mesoridazine ring sulphoxide, sulforidazine ring sulphoxide, the lactam of mesoridazine ring sulphoxide and unconjugated phenolic derivatives of mesoridazine and sulforidazine. Other compounds observed were: unchanged thioridazine (dog, rat), sulforidazine N-oxide (man), N-desmethylthioridazine ring sulphoxide (dog, rat), N-desmethylmesoridazine ring sulphoxide (dog, rat), the lactam of sulforidazine ring sulphoxide (rat, man), phenolic derivative of thioridazine in unconjugated form (rat), and conjugated form (man), and conjugated phenolic derivative of mesoridazine (man). 4. Thioridazine and six of its metabolites present in the urine of man, rat and dog were quantified by a h.p.l.c.-UV procedure. The mean total urinary excretion (+/- SD) of the measured analytes in man, rat and dog were determined to be 4.3 +/- 2.9, 4.8 +/- 1.7 and 12.1 +/- 5.4% of the dose, respectively. The mean excretion of the lactam of mesoridazine ring sulphoxide was greater in man (1.2 +/- 1.0%) and rat (0.2 +/- 0.2%) than dog (< 0.02%). Moreover, the mean excretion of the lactam of sulforidazine ring sulphoxide was quantifiable in both man (0.5 +/- 0.4%) and rat (0.2 +/- 0.2%). 5. Interspecies comparison of the lactam metabolites indicated that both qualitatively and quantitatively, man more closely resembled rat than dog. Similar observations were previously reported for mesoridazine and sulforidazine, therefore rat may be a more suitable animal than dog to undertake further study of the importance of C-oxidation of the piperidine ring of this class of drug.

Pharmacokinetics of chlorpromazine and key metabolites.

A study was carried out in 11 healthy young men to investigate the pharmacokinetics of chlorpromazine (CPZ) after a bolus intravenous (i.v.) dose (10 mg) and three single oral doses (25, 50 and 100 mg), with a washout period of two weeks between doses. Plasma levels of CPZ, CPZ N-oxide (CPZNO), CPZ sulfoxide (CPZSO) and both free and conjugated 7-hydroxy-CPZ (7-HOCPZ) were measured by extraction radioimmunoassays. CPZ exhibited multicompartmental pharmacokinetics in most subjects. There was wide between-subject variability in half life (11.05 h), volume of distribution (1215 l), volume of distribution at steady state (642 l) and mean residence time (8.88 h), whereas systemic clearance was somewhat less variable (76.6 l.h-1). All metabolites were present in measurable concentrations in the plasma of 9 of 11 subjects after i.v. CPZ, whereas free 7-HOCPZ was not detected in the other 2 individuals. With the exception of CPZNO, the biological half lives of the primary metabolites were longer than the half life of CPZ. After oral administration, the percentage of CPZ reaching the systemic circulation intact (F%) was very low (4-38%) and dose dependent. Moreover, both within-subject and between-subject variances were very high. The maximum plasma concentration (Cmax) and area under the plasma concentration versus time curve extrapolated to infinite time (AUC) showed evidence of nonlinearity, whereas half life did not appear to be dose dependent. These data suggest that the high degree of variability in the pharmacokinetics of CPZ is a result of extensive first pass metabolism rather than variation in half life.(ABSTRACT TRUNCATED AT 250 WORDS)

The metabolism of piperidine-type phenothiazine antipsychotic agents. II. Sulforidazine in dog and human.

1. The metabolism of sulforidazine was studied in female dogs and adult male humans after oral administration of 37.5 mg and 25.0 mg, respectively. 2. Metabolites in organic extracts of dog urine were separated by h.p.l.c. and individually collected prior to mass spectrometric analysis, while organic extracts of human urine were directly subjected to plasmaspray h.p.l.c.-mass spectrometric determination. In the case of phenolic metabolites, the urinary extracts from both species were derivatized with a silylating reagent (with or without prior enzymic hydrolysis) and subsequently analysed by h.p.l.c.-mass spectrometry. The structures of metabolites with the exception of phenols were confirmed by comparison of their mass spectra and chromatographic behaviours with those of authentic standards. 3. The compounds identified in urine of both species were sulforidazine, two diastereomers of sulforidazine ring sulphoxide, the lactam of sulforidazine ring sulphoxide and a phenolic derivative of sulforidazine, whereas sulforidazine N-oxide and the lactam of sulforidazine were identified only in human urine. Moreover the phenolic metabolite was present in human urine in both unconjugated and conjugated forms, whereas dog urine had only the conjugated form. 4. Sulforidazine and some of its major metabolites were quantified by an h.p.l.c. method. The mean urinary excretions (0-48 h) of sulforidazine were similar in human (n = 3) and dog (n = 3) (5.9 +/- 0.7% and 7.2 +/- 1.9%), as were the excretions of sulforidazine ring sulphoxide (13.2 +/- 4.6% and 13.3 +/- 4.4%), while the lactam of sulforidazine ring sulphoxide was a major metabolite only in human (7.5 +/- 2.8% and < 0.1%). The lactam of sulforidazine was a minor metabolite in human. 5. The metabolites observed in human urine were similar to those previously reported in rat, except that sulforidazine N-oxide was found only in human, whereas the two diastereomers of N-desmethylsulforidazine ring sulphoxide were observed only in rat. These data suggest that rat may be a more suitable animal than dog for further study of the metabolism of the piperidine ring of sulforidazine.

The metabolism of piperidine-type phenothiazine antipsychotic agents. III. Mesoridazine in dog, human and rat.

1. The metabolism of mesoridazine was studied in female rats (20 mg/kg, oral), female dogs (50 mg over 30 h, oral) and adult male volunteers (25 mg, oral). 2. Solvent extracts of urines from each species were directly analysed by h.p.l.c.-mass spectrometry with a plasmaspray interface. In the case of phenolic metabolites the urinary extracts were derivatized with a silylating reagent (with and without prior enzymic hydrolysis) prior to analysis. The structures of metabolites, with the exceptions of mesoridazine N-oxide and phenols, were confirmed by comparison of their chromatographic behaviours and mass spectra with those of authentic standards. 3. Compounds identified in the urine of all three species were mesoridazine, sulforidazine, mesoridazine ring sulphoxide, sulforidazine ring sulphoxide, N-desmethylmesoridazine ring sulphoxide, the lactam of sulforidazine ring sulphoxide and phenolic derivatives of mesoridazine and sulforidazine. Whereas the unconjugated phenolic metabolite of sulforidazine was present in urine of all three species, the conjugated form was identified only in dog and rat urines. Also, the unconjugated phenolic metabolite of mesoridazine was identified only in the urine of dog and human, but rat urine contained only the conjugated form. 4. Other metabolites found were: the lactam of mesoridazine (rat), the lactam of mesoridazine ring sulphoxide (rat and human), mesoridazine N-oxide (human) and sulforidazine N-oxide (dog and human). 5. Mesoridazine and six of its metabolites present in urines of human, rat and dog were quantified by a h.p.l.c.-u.v. method. The mean total excretion of measured analytes in human, rat and dog were 6.3, 2.6 and 29.1%, respectively. The excretion of the lactam of sulforidazine ring sulphoxide was greater in human (0.4%) and rat (0.2%) than dog (0.02%). Moreover, the urinary excretion of the lactam of mesoridazine ring sulphoxide in human and rat constituted 0.4% and 0.2%, respectively. Of the three lactams found in rat the lactam of mesoridazine was present in the least amount (0.05%). 6. Interspecies comparison of the lactam metabolites indicated that both qualitatively and quantitatively human more closely resembled rat than dog. On the other hand, N-oxide metabolites were detected in human and dog but not in rat.

Effect of quinidine on the interconversion kinetics between haloperidol and reduced haloperidol in humans: implications for the involvement of cytochrome P450IID6.

Haloperidol (HAL) is a potent butyrophenone antipsychotic agent which is reversibly metabolized to reduced haloperidol (RHAL). In order to determine if this reversible metabolic pathway is linked to the debrisoquine 4-hydroxylase isozyme of cytochrome P-450 (P450IID6). HAL (5 mg) or RHAL (5 mg) was orally administered to healthy male volunteers in a randomized crossover design both with and without a prior (1 h) oral dose of quinidine (250 mg bisulfate), a potent inhibitor of this isozyme. Thirteen volunteers, 11 extensive metabolizers, 2 poor metabolizers, completed all four phases of the study. Plasma samples harvested over seven days were analysed for HAL and RHAL. An expression for the apparent fractional availability of metabolite from the parent compound given (Fapppm) was derived and was used to determine whether HAL or RHAL is the preferred metabolite, and whether quinidine co-administration alters Fapp for either compound. The AUC (0-t) for both HAL and RHAL were significantly greater following the administration of either compound with quinidine compared with AUC (0-t) values obtained in the absence of quinidine. The maximum plasma concentration (Cmax) of the administered compound was also greater following the administration of quinidine. Quinidine had no effect on the half-lives of the administered compounds. The Fapp for HAL and RHAL were not significantly affected by the administration of quinidine, indicating that the interconversion of HAL and RHAl is not linked to P450IID6. The Fapp of RHAL after administration of HAL was significantly greater than the Fapp of HAL after RHAL administration, indicating that RHAL is the preferred metabolic form. This difference was not affected by quinidine.(ABSTRACT TRUNCATED AT 250 WORDS)

Enantioselective pharmacokinetics of dl-threo-methylphenidate in humans.

A definitive enantioselective pharmacokinetic evaluation of dl-threo-methylphenidate (MPH) was carried out in 11 healthy volunteers, all of whom received, in a randomized crossover design, three oral administrations of MPH: immediate release (IR), slow release (SR), and SR chewed before swallowing (CH). In addition, all subjects received MPH intravenously (IV) on a separate occasion. Both plasma and urine samples were collected for up to 16 hr after each drug administration. Significant enantioselective differences were found in pharmacokinetic parameters such as CL, MRT, Vdss, AUC infinity 0, and t1/2. A profound distortion of the enantiomeric ratio for MPH (d >> 1) was evident in all plasma samples harvested after oral administration. After IV MPH, however, there was no significant distortion in the plasma d/l ratio until 1.5 hr after dosing, whereafter there was a divergence of the plasma levels of the enantiomers. After oral administration of dl-MPH, the absolute bioavailability (F) of d-MPH was 0.23 and that of l-MPH was 0.05. There were no significant differences in renal clearance for d- or l-MPH after oral or IV administration, although the fraction of the dose excreted unchanged in the urine was significantly greater after IV MPH. These data suggest that enantioselective differences in the pharmacokinetics of oral MPH are the result of enantioselectivity in presystemic metabolism rather than in renal excretion, such that l-MPH is preferentially converted into l-ritalinic acid. Finally, it was found that chewing the slow release formulation led to a pharmacokinetic profile very similar to that of MPH-IR, suggesting that MPH-SR should not be prescribed for children who chew tablets.

Stereoselective urinary pharmacokinetics of dl-threo-methylphenidate and its major metabolite in humans.

Stereoselective urinary pharmacokinetics of dl-threo-methylphenidate (MPH) and its major metabolite, dl-ritalinic acid (RA), were examined in a cohort of healthy subjects. On two occasions, separated by one week, each subject received MPH.HCl either intravenously (10 mg) or orally (40 mg). Urine was collected in six time segments, up to 16 h after each dosing. In the first 2 h after oral administration of MPH, d-MPH found in the urine was 10-fold greater than the l-antipode, whereas there was no significant difference between the amounts of MPH enantiomers excreted after the intravenous dose. Examination of RA content in the 0-2-h urine samples after oral administration of MPH indicated the presence of higher levels of l-RA (d-RA:l-RA, 0.37), whereas after intravenous MPH, there was no significant difference between the amounts of RA enantiomers. Moreover, after oral administration of MPH, the ratio of d-MPH to l-MPH was approximately 10 in urine samples from each of the time segments. By contrast, after intravenous administration of MPH, the d:l ratio changed progressively from 1.16 in the 0-2-h urine sample to 9.06 in the 12-16-h sample. These observations suggest that, after oral administration of dl-MPH, the distortion in the ratio of MPH or RA enantiomers in urine samples was attributable to enantioselective presystemic conversion of MPH to RA rather than to enantioselective excretion.

Stereoselective pharmacokinetics of doxepin isomers.

Commercial preparations of the tricyclic anti-depressant doxepin contain 15% of the more active cis-doxepin and 85% of the trans-isomer. The single dose pharmacokinetics of doxepin and its major metabolite N-desmethyldoxepin were examined in 30 healthy young men. Results for total doxepin showed wide intersubject variation in all pharmacokinetic parameters except tmax and Cmax. Plasma levels of cis-doxepin were extremely low and it was only possible to estimate the stereoselective pharmacokinetics of the parent drug in 3 subjects. The data from those particular subjects resulted in an average ratio of cis- to trans-doxepin isomers in plasma of 15:85. In contrast, the mean plasma levels of cis-N-desmethyldoxepin in 28 subjects exceeded those of the trans-isomer at every time point after 10 h, such that the areas under the plasma concentration versus time curves (AUC) of cis-N-desmethyldoxepin were significantly higher than those of the corresponding trans-isomer. This phenomenon may play an important role in the therapeutic action of doxepin since it has been suggested that cis-N-desmethyldoxepin is pharmacologically active. In 2 subjects, however, the AUC0-inf of trans-N-desmethyldoxepin were respectively 4 and 8 fold higher than those of the cis-isomer.

N(+)-glucuronidation of aliphatic tertiary amines, a general phenomenon in the metabolism of H1-antihistamines in humans.

1. Representative drugs of the various structural classes of H1 antihistamines were chosen for study. The drugs chosen (class name in parentheses) were chlorpheniramine maleate and pheniramine maleate (alkylamines), diphenhydramine hydrochloride and doxylamine succinate (ethanolamines), pyrilamine maleate and tripelennamine hydrochloride (ethylenediamines), promethazine hydrochloride (phenothiazine), cyclizine lactate (piperazine) and terfenadine (miscellaneous). In each case oral dose(s) were administered over no more than 6 h to two healthy volunteers and the total urine collected for 36 h. 2. Metabolites from urine were separated by h.p.l.c. and individually collected prior to mass spectrometric analysis in the fast atom bombardment mode. The structure of each metabolite identified as a quaternary ammonium-linked glucuronide metabolite was confirmed by direct comparison of its mass spectrum and chromatographic behaviour with that of a synthetic authentic compound. 3. For eight of the nine drugs studied, metabolism by the N(+)-glucuronidation pathway was observed in each of the volunteers. Terfenadine was the exception. 4. The amount of each N(+)-glucuronide in the urine was estimated by h.p.l.c. analysis. The mean proportion of dose excreted as the metabolite was 14.3%, 6.5% and 4.0% for cyclizine, tripelennamine and diphenhydramine, respectively. Promethazine was the only case where the N(+)-glucuronide accounted for less than 1.0% of the administered dose in both volunteers examined.

Extensive and enantioselective presystemic metabolism of dl-threo-methylphenidate in humans.

1. Two pilot studies were carried out to investigate the enantioselective pharmacokinetics of methylphenidate (MPH) in children with attention deficit-hyperactivity disorder (ADHD). A more definitive study, which included administration of an intravenous dose, was carried out in healthy young men. 2. Serial plasma samples were harvested from predose to 8 hours in the first pilot study, predose to 12 hours in the second pilot study and predose to 16 hours in the definitive study. Plasma levels of the separate isomers d-MPH and 1-MPH were determined by an enantioselective gas chromatographic method. 3. In the first pilot study, 6 boys with ADHD each received his regular dose of MPH (10mg n = 5, 5mg n = 1), which contained equal proportions of d-MPH and 1-MPH in an immediate release formulation (MPH-IR). No MPH was detectable in the predose plasma. Thereafter, plasma levels of the more active d-MPH were 4 to 10 fold higher than those of 1-MPH. Plasma levels of 1-MPH were so low that it was not possible to monitor them beyond 4 hours in some children. 4. In the second pilot study, 5 boys and 1 girl with ADHD each received their regular dose (20mg) of a slow release formulation (MPH-SR). No MPH was detectable in the predose plasma. Thereafter, plasma levels of the more active d-MPH were 5 to 10 fold higher than those of 1-MPH. It was possible to monitor plasma levels of 1-MPH over the full 12 hour period of study in 5 of the 6 children.(ABSTRACT TRUNCATED AT 250 WORDS)

Quinidine but not quinine inhibits in man the oxidative metabolic routes of methoxyphenamine which involve debrisoquine 4-hydroxylase.

Healthy male volunteers (n = 13) took a single oral dose of 60.3 mg of methoxyphenamine HCl with and without prior administration of either quinidine (250 mg as bisulphate salt) or its diastereomer quinine (300 mg as sulphate salt). Methoxyphenamine and its N-desmethyl, O-desmethyl and aromatic 5-hydroxy metabolites were quantified in the 0-32 h urine. The oxidative routes of methoxyphenamine metabolisms which had been previously shown to involve debrisoquine 4-hydroxylase, namely O-demethylation and 5-hydroxylation were both significantly inhibited by quinidine in the 12 extensive metabolizers. The inhibition was selective in that N-demethylation which does not involve this isozyme was not affected by quinidine. In all but one of these volunteers the methoxyphenamine/O-desmethylmethoxyphenamine ratio changed such that extensive metabolizers could be classified as poor metabolizers due to quinidine pretreatment. No marked change occurred in the renal excretion of methoxyphenamine and its three metabolites either in the extensive metabolizers because of quinine pretreatment or in the poor metabolizer because of treatment with either quinidine or quinine. Thus in the extensive metabolizer phenotype it was demonstrated in one study that enzyme inhibition of quinidine was selective in terms of the metabolic pathways inhibited as well as stereoselective with respect to the inhibitor.

The identification of urinary metabolites of doxepin in patients.

The metabolism of doxepin was investigated in three patients who provided cumulative urine samples on each of 3 successive days. These samples were examined by means of stereoselective HPLC or HPLC combined with mass spectrometry through a plasmaspray interface (LCMS). In addition, sufficient quantities of the major metabolites were isolated from the urine by column chromatography. The isolated metabolites were examined by HPLC, proton nuclear magnetic resonance spectroscopy (1H-NMR), and chemical ionization and/or electron impact mass spectrometry (EIMS). The resultant spectra and chromatographic properties were compared with authentic reference standards. The metabolites were identified as (E)-2-hydroxydoxepin, (E)-2-hydroxy-N-desmethyldoxepin, (Z)- and (E)-N-desmethyldoxepin, and (Z)- and (E)-doxepin N-oxide. There was no evidence of hydroxylation at the oxymethylene bridge. A further metabolite previously unreported was tentatively identified by LCMS and EIMS as an aromatic hydroxy-N-desmethyldoxepin hydrated at the exocyclic double bond. This metabolite was present in very low amounts, precluding its analysis by 1H-NMR. Moreover, this type of compound dehydrated readily in vitro, and numerous attempts to synthesize reference materials were unsuccessful. The tentative identification of this hydrated metabolite lends significant support to a possible mechanism responsible for the enrichment of cis-N-desmethyldoxepin over time in plasma.

Bioequivalence of two thorazine tablet formulations using radioimmunoassay and gas chromatographic-mass spectrometric methods.

Two analytical methods for the analysis of chlorpromazine (CPZ), a radioimmunoassay (RIA) and a GLC-MS method, were compared in a bioequivalence study of two CPZ tablet formulations (Thorazine: film coated and sugar coated). Thirty-six nonsmoking, healthy, male volunteers completed the study. Each subject ingested single doses (2 x 25 mg) of the test (T) and the reference (R) formulations in a two-way crossover design with a two-week drug-free interval between doses. Following each administration, plasma concentrations of CPZ were monitored over a period of 24 h by both RIA and GLC-MS methods. Plasma concentrations and pharmacokinetic parameters determined by either analytical method showed wide intersubject variation, with the GLC-MS data showing relatively higher magnitude of intersubject variation than the RIA data. In general, plasma concentrations measured by RIA were significantly different from those measured by GLC-MS (paired t tests: p less than 0.0001). As indicated by the regression analysis, concentrations determined by RIA were 1.3-1.4 times higher than those determined by GLC-MS. There were strong and significant correlations between the two methods for both T and R (r greater than 0.75: p less than 0.0001). Similar statistical relationships were found between the plasma concentrations of CPZ determined by the two methods at each sampling time and the bioequivalence parameters area under the plasma level versus time curves up to the last measurable concentration (AUCt0) and the maximum plasma concentration (Cmax).(ABSTRACT TRUNCATED AT 250 WORDS)

Single dose kinetics of thioridazine and its two psychoactive metabolites in healthy humans: a dose proportionality study.

Dose proportionality in some pharmacokinetic parameters for thioridazine and its two active metabolites (mesoridazine and sulforidazine) was investigated in 11 healthy human subjects following oral administration of three single doses (25, 50, and 100 mg) of thioridazine hydrochloride separated in each case by an interval of two weeks. Also, after a further two weeks, another 100-mg dose of thioridazine (divided as 5 mg every 0.5 h) was administered to all the volunteers to investigate the effect of a slow rate of dosage input on the pharmacokinetic parameters of this drug. An HPLC method was used to measure concentrations of thioridazine, mesoridazine, and sulforidazine in plasma samples collected up to 72 h following each dose. Dose proportionality for the three single doses of thioridazine was observed for all three analytes in the area under the plasma concentration versus time curves (AUC infinity 0 or AUCt0) and the maximum plasma concentration (Cmax) in that the relationships between the dose and these parameters were each describable by an equation for a straight line (r2 greater than or equal to 0.8). However, the mean apparent distribution and elimination rate constants for thioridazine and mesoridazine and the mean apparent oral clearance for thioridazine decreased significantly with increasing dose. This suggests nonlinear trends in the elimination kinetics at high doses of thioridazine. When a 100-mg divided oral dose of thioridazine was administered, no statistically significant differences between single and divided doses were observed in the mean AUC infinity 0 or AUCt0 for thioridazine or sulforidazine. A significant decrease in the mean AUC infinity 0 or AUCt0 was observed for mesoridazine after the administration of the divided dose.(ABSTRACT TRUNCATED AT 250 WORDS)