Lack of pharmacokinetic interaction between nifedipine, sparteine and phenytoin in man.

Nifedipine, sparteine and phenytoin were administered orally to eight healthy subjects separately and as a 'cocktail' on four different occasions to investigate any kinetic interactions. All subjects were extensive metabolizers of sparteine. After drug intake plasma and urine samples were collected up to 32 h and the concentrations of parent drugs and main metabolites were measured. Clearances and formation clearances were not significantly different after single substrate and 'cocktail' administration. Low or non significant correlation coefficients were found between the oxidation of the individual substrates or formation of their metabolites. With this strategy of simultaneous administration of substrates ('cocktail') it appears possible to characterize (and correlate) activities of different cytochrome P-450 isoenzymes, without the disturbing influence of intraindividual variation of drug oxidation with time.

Relationship between mephenytoin oxidation polymorphism and phenytoin, methylphenytoin and phenobarbitone hydroxylation assessed in a phenotyped panel of healthy subjects.

1. In a phenotyped panel of healthy subjects correlations were studied between the oxidation of mephenytoin, phenytoin, methylphenytoin and phenobarbitone, with respect to the formation of their 4-hydroxy metabolites (OH-). 2. On different occasions phenotyped extensive metabolizers (EM; n = 16) and poor metabolizers (PM; n = 4) of mephenytoin received phenytoin (100 mg), methylphenytoin (100 mg) and phenobarbitone (50 mg) and urine was collected up to 24 h. The excreted 4-hydroxy metabolites of all compounds were measured by h.p.l.c. 3. Urinary recovery of OH-phenytoin was 31.0 +/- 11.7%, of OH-methylphenytoin 3.4 +/- 2.7% and of OH-phenobarbitone 1.4 +/- 1.2%. No correlation was found between the recovery of OH-mephenytoin and OH-phenytoin. A subject who produced virtually no OH-phenytoin was an EM of mephenytoin, confirming a dissociation of mephenytoin polymorphism and phenytoin hydroxylation. 4. The correlation coefficient for OH-mephenytoin and OH-methylphenytoin recovery was 0.71 (Spearman rank, P = 0.002). The PMs of mephenytoin excreted the least amount of OH-methylphenytoin, suggesting a cosegregation of the 4-hydroxylation pathways. No correlation was found between the urinary recovery of OH-phenobarbitone and that of the other 4-hydroxy metabolites.

Relationship between the metabolism of antipyrine, hexobarbital and theophylline in patients with liver disease as assessed by a 'cocktail' approach.

Antipyrine (AP), hexobarbital (HB) and theophylline (TH) were administered simultaneously ('cocktail' design) to 24 patients with various types of liver disease. Clearance (Cl) of AP, HB and TH and formation clearance of the AP-metabolites 3-hydroxymethylantipyrine (HMA), norantipyrine (NORA) and 4-hydroxyantipyrine (OHA) were determined and correlation coefficients and orthogonal least-squares regression lines calculated between the clearance and formation clearance parameters. The results were compared with those obtained in a study in which the same 'cocktail' was administered to 26 healthy control subjects. In the patients ClAP, ClHB and ClTH were 23.0 +/- 14.3 ml min-1, 206 +/- 128 ml min-1 and 39.9 +/- 26.1 ml min-1 respectively. All values were considerably lower than those found in the control subjects. With regard to AP metabolism preferential impairment of NORA formation was observed. Relatively high correlation coefficients were found between ClAP, ClHB and ClTH, which suggests, like the results of orthogonal regression analysis, a strong correlation between total metabolism of these probe drugs. Therefore it is likely that impairment in oxidation in patients with liver disease not only leads to reduction in clearance but also to reduced substrate selectivity of cytochrome P-450 isozymes.

Influence of enzyme induction and inhibition on the oxidation of nifedipine, sparteine, mephenytoin and antipyrine in humans as assessed by a "cocktail" study design.

Nifedipine (NF), sparteine (SP), mephenytoin (MP) and antipyrine (AP) were administered simultaneously ("cocktail" design) to 15 healthy subjects, including 4 poor metabolizers (PM) of SP and 4 PMs of MP, on three different occasions: without pretreatment, after pentobarbital (PB) pretreatment and together with cimetidine (cim). Concentrations of AP, NF, its pyridine metabolite 2,6-dimethyl-4-(2-nitrophenyl)-pyridine-3,5-dicarboxylate-methylester (M-O), SP, dehydrosparteine (DHS) were determined in plasma; 2,6-dimethyl-4-(2-nitrophenyl)-pyridine-3,5-dicarboxylate-monomethyle ster (which is ester hydrolyzed M-O), SP, DHS, 4-hydroxymephenytoin, AP and metabolites 3-hydroxymethylantipyrine, norantipyrine and 4-hydroxyantipyrine were measured in urine. Clearance of NF had increased 270% after PB and decreased 32% with cim. Area under the plasma-concentration time curve of M-O and urinary excretion of 2,6-dimethyl-4-(2-nitrophenyl)-pyridine-3,5-dicarboxylate-monoethyles ter had also decreased after PB. Neither extensive metabolizers nor PMs of SP and MP were sensitive to PB treatment, but sparteine clearance was reduced 55% by cim in extensive metabolizers and 59% in PMs. Ratio SP/DHS in urine was hardly influenced by cim. AP oxidation was significantly induced and inhibited by PB and cim, respectively. The cocktail study design seems to be suitable to assess induction and inhibition of the metabolism of the applied model substrates, which are metabolized by at least partly independent isozymes of the cytochrome P-450 system, simultaneously.

Relationship between the metabolism of antipyrine, hexobarbitone and theophylline in man as assessed by a 'cocktail' approach.

1. Three model substrates for the characterization of drug oxidation activity, antipyrine (AP), hexobarbitone (HB) and theophylline (TH), were administered to 26 healthy volunteers on two different occasions: in the first experiment a combination of AP (250 mg) and HB (250 mg) was given and in the second experiment TH (150 mg) was added to the former combination. 2. Plasma concentrations of AP, HB and TH and urinary excretion of TH and the three main metabolites of AP (3-hydroxymethylantipyrine: HMA, norantipyrine: NORA and 4-hydroxyantipyrine: OHA) were determined and the intrinsic clearance (CLint) of the three substrates and the clearance to the formation of AP metabolites were calculated. 3. The correlation coefficients between CLHB and CL-greater than metabolites of AP were highest for CL-greater than HMA and CL-greater than NORA (greater than 0.80) and lowest for CL-greater than OHA (0.63). High correlation coefficients also were found between CLTH and CL-greater than OHA (0.89) and CL-greater than HMA (0.80). 4. Ideal relationships, defined by a slope of the orthogonal regression line equal to unity, did exist between CLHB and CL-greater than HMA as well as CL-greater than NORA and between CLTH and CLAP as well as CL-greater than OHA. 5. Based on the results of correlation and regression analysis it can be concluded that isozymes of the cytochrome P-450 system responsible for the oxidation of HB and formation of HMA and NORA are very closely related and also that isozymes responsible for the oxidation of TH and formation of OHA show a very close relation. 6. With this strategy of simultaneous administration of substrates ('cocktail' approach) it seems possible to characterize and correlate activities of different P-450 isozymes and to investigate their in vivo substrate selectivity without the disturbing influence of intra-individual variation in drug oxidation.

Identification and quantitative determination of four different mercapturic acids formed from 1,3-dibromopropane and its 1,1,3,3-tetradeutero analogue by the rat.

1,3-Dibromopropane (1,3-DBP) was administered i.p. in doses ranging from 5.6 to 54 mg to male Wistar rats. Four different mercapturic acids, viz. N-acetyl-S-3-bromopropyl-(MA I), N-acetyl-S-3-chloropropyl-(MA II), N-acetyl-S-2-carboxyethyl-(MA III) and N-acetyl-S-3-hydroxypropyl(-1-)cysteine (MA IV) were synthesized and identified as metabolites in urine by g.l.c.-mass spectrometry. 1,1,3,3-Tetradeutero-1,3-dibromopropane was used to study the mechanism of formation of the mercapturic acids in more detail. It was found that in the formation of MA IV a reactive episulphonium ion could be involved. Gas chromatographic quantification of the mercapturic acids (mercapturic acid assay) was correlated with a spectrophotometric thioether determination of the metabolites (thioether test). At doses up to 30 mg of 1,3-DBP, excretion of mercapturic acids was virtually complete in 24 h urine and amounted to about 19% of the dose (11.3% MA I, 4.9% MA II, 2.6% MA III and 0.2% MA IV). From excretion rate curves a half-time t1/2 was calculated as being about 4.5 h. A plateau in the dose-excretion curve was observed at 1,3-DBP doses higher than 40 mg, probably caused by glutathione depletion.