The fate of 4-cyanoacetanilide in rats and mice; mechanism of formation of a novel electrophilic metabolite

1. The metabolic fate of 4-cyanoacetanilide (CAA), labelled with 14C and 13C in the N-acetyl group, was studied in rats (oral dose, 22.5 mg/kg) and mice (oral dose 21.7 mg/kg). 2. The metabolic profile in the urine of rats was compared with that obtained previously with 4-cyano-N,N-dimethylaniline (CDA) and confirms the intermediacy of CAA in the metabolism of CDA. 3. The precursor of a major metabolite of CDA and CAA (the mercapturic acid N-acetyl-S-[2-keto-2-(4-cyanoanilino)ethyl]cysteine, metabolite C) was identified in the urine of CAA-dosed rats as the O-sulphate conjugate of N-(4-cyanophenyl)glycolamide. 4. Pretreatment of rats with the sulphotransferase inhibitor pentachlorophenol reduced the yield of the mercapturic acid metabolite C, further indicating the intermediacy of a sulphate conjugate. 5. Metabolite C was not formed from CAA by mice; thus, this species difference, also observed with CDA, occurs at the level side-chain (acetyl) hydroxylation as well as at N-acetylation of 4-cyanoaniline as previously proposed. 6. The significance of this pathway as a bioactivation reaction of CDA, CAA and other acetanilides is discussed.     

The fate of 4-cyano-N,N-dimethylaniline in rats; a novel involvement of glutathione in the metabolism of anilines

4-Cyano-N,N-dimethylaniline (CDA), when administered to rats as a single oral dose (18.5 mg/kg), was rapidly absorbed and eliminated as a mixture of metabolites in the urine (86% dose after 24 h). Residues in tissues after 48 h, expressed as microgram equiv. of CDA, were: liver, 0.35; kidney, 0.28; testes, 0.08; fat, 0.06; bone marrow, 0.15 and blood, 0.32. Absorption, metabolism and elimination following four consecutive daily doses of CDA (65 mg/kg) were similar to those at the lower dose. The major metabolite was 2-amino-5-cyanophenyl sulphate with its mono- and di-N-methyl analogues as minor metabolites. 4-Cyanoaniline, its N-acetyl derivative and an unstable derivative were also found as metabolites. Three sulphur-containing metabolites with methylsulphinyl-, methylsulphonyl-, and N-acetylcysteinyl-groups attached to the C2 atom of an N-acetyl group were identified, the latter accounting for 10.3% and 4.1% of the low and high doses, respectively. The sulphur-containing metabolites indicate the involvement of glutathione in metabolism at the N-acetyl group. This implies the generation of an electrophilic intermediate, possibly the sulphate conjugate of an N-glycolylaniline, in the metabolism of CDA.     

The fate of 4-cyano-N,N-dimethylaniline in rats; a novel involvement of glutathione in the metabolism of anilines

1. 4-Cyano-N, N-dimethylaniline (CDA), when administered to rats as a single oral dose (18.5 mg/kg), was rapidly absorbed and eliminated as a mixture of metabolites in the urine (86% dose after 24 h).

2. Residues in tissues after 48 h, expressed as μg equiv. of CDA, were: liver, 0.35; kidney, 0.28; testes, 0-08; fat, 006; bone marrow, 0.15 and blood, 0.32.

3. Absorption, metabolism and elimination following four consecutive daily doses of CDA (65 mg/kg) were similar to those at the lower dose.

4. The major metabolite was 2-amino-5-cyanophenyl sulphate with its mono- and di-N-methyl analogues as minor metabolites. 4-Cyanoaniline, its N-acetyl derivative and an unstable derivative were also found as metabolites.

5. Three sulphur-containing metabolites with methylsulphinyl-, methylsulphonyl-, and N-acetylcysteinyl-groups attached to the C2 atom of an N-acetyl group were identified, the latter accounting for 10.3% and 41% of the low and high doses, respectively.

6. The sulphur-containing metabolites indicate the involvement of glutathione in metabolism at the N-acetyl group. This implies the generation of an electrophilic intermediate, possibly the sulphate conjugate of an N-glycolylaniline, in the metabolism of CDA.     

The fate of 4-cyanoacetanilide in rats and mice; mechanism of formation of a novel electrophilic metabolite

1. The metabolic fate of 4-cyanoacetanilide (CAA), labelled with ¹⁴C and ¹³C in the N-acetyl group, was studied in rats (oral dose, 22.5 mg/kg) and mice (oral dose 21.7 mg/kg).

2. The metabolic profile in the urine of rats was compared with that obtained previously with 4-cyano-N,N-dimethylaniline (CDA) and confirms the intermediacy of CAA in the metabolism of CDA.

3. The precursor of a major metabolite of CDA and CAA (the mercapturic acid N-acetyl-S-[2-keto-2-(4-cyanoanilino)ethyl]cysteine, metabolite C) was identified in the urine of CAA-dosed rats as the O-sulphate conjugate of N-(4-cyanophenyl)glycolamide.

4. Pretreatment of rats with the sulphotransferase inhibitor pentachlorophenol reduced the yield of the mercapturic acid metabolite C, further indicating the intermediacy of a sulphate conjugate.

5. Metabolite C was not formed from CAA by mice; thus, this species difference, also observed with CDA, occurs at the level side-chain (acetyl) hydroxylation as well as at N-acetylation of 4-cyanoaniline as previously proposed.

6. The significance of this pathway as a bioactivation reaction of CDA, CAA and other acetanilides is discussed.     

Metabolites of [(14)C]-5-(2-ethyl-2H-tetrazol-5-yl)-1-methyl-1,2,3, 6-tetrahydropyridine in mice, rats, dogs, and humans.

The M1 muscarine agonist, 5-(2-ethyl-2H-tetrazol-5-yl)-1-methyl-1,2, 3,6-tetrahydropyridine (Lu 25-109), is extensively metabolized in mice, rats, dogs, and humans. The metabolite profile after an oral dose of [(14)C]Lu 25-109 was determined in plasma and in urine. Lu 25-109 was metabolized by N-demethylation (Lu 25-077), N-oxidation (Lu 32-181), and N-deethylation (Lu 31-126). In addition, combined N-demethylation and N-deethylation (Lu 31-190), and formation of a pyridine derivative took place (Lu 31-102). Lu 25-109 was also oxidized to pyridinium (Lu 29-297), 3-hydroxy-pyridinium (Lu 35-080), N-deethyl-2-pyridone (Lu 35-026), and a glucuronide of a 4, 6-dihydroxy-pyridinium ("m/z 398") compounds. A glucuronide of a dihydroxylated dihydro-pyridine compound ("m/z 400") was isolated from human urine, but not fully identified. In vitro studies were undertaken to elucidate the order of formation of the metabolites. In human plasma, the concentrations of Lu 25-109 and the pharmacologically active N-demethyl metabolite (Lu 25-077) were small compared with the N-oxide (Lu 32-181) and the N-deethyl-2-pyridone (Lu 35-026) at the first sample time (0.75 h). The N-deethyl metabolite (Lu 31-126) was the major component in human plasma between 3 and 10 h postdose. The major human metabolites in urine (Lu 32-181, Lu 35-026, and Lu 31-126) and the minor metabolites (Lu 25-077, Lu 35-080, Lu 31-190, and Lu 29-297) were all present in urine from rats, dogs, and mice, whereas m/z 398 was present in only mice and humans, and Lu 31-102 in only rats. The minor human metabolite m/z 400 was not detected in mice, rats, or dogs.     

Dehalogenation and N-dealkylation of chlorpromazine as revealed by plasma concentrations of metabolites in a population of chronically medicated schizophrenics.

Dehalogenaton and N-demethylation of chlorpromazine (CPZ) were studied in twelve psychotic inpatients orally treated for four weeks with a daily CPZ dose of 6.4 +/- 1.1 (S.E.) mg/kg body weight (1.5-14.1, range). Weekly drug and metabolite plasma concentrations were measured by a gas liquid chromatography-nitrogen/phosphorus detector method (GLC/NPD). Plasma concentrations of the parent compound CPZ, of the dehalogenated metabolite promazine (PZ) and of the N-dealkylated metabolites N-monodemethylated chlorpromazine (CPZ-nor1) and N-didemethylated chlorpromazine (CPZ-nor2) had already reached a steady state by the end of the first week of treatment. During the entire treatment period the major plasma component was found to be PZ. Patients (N = 6) on a low dose regimen (3.7 +/- 0.2 mg/kg body weight) showed significantly lower mean plasma concentrations of CPZ and nor metabolites than patients (N = 6) on a higher dose regimen (8.6 +/- 0.7 mg/kg body weight). PZ mean plasma concentrations, however, were not significantly different in the two groups of patients, indicating that the yield of the CPZ dechlorination pathway, as opposed to that of the N-demethylation pathway, was already maximal at the CPZ concentrations attained under the low dose regimen. Male patients (N = 5) exhibited significantly higher mean PZ plasma concentrations over the 4 week period of the study than female patients (N = 7).     

Decreased pulmonary drug metabolism in mice treated with the PCB metabolite 4-methylsulphonyl-2,2',5,5'-tetrachlorobiphenyl

4-Methylsulphonyl-2,2',5,5'-tetrachlorobiphenyl (4-MeSO2-TCB) is a major polychlorinated biphenyl (PCB) metabolite present in lung tissue of PCB-exposed human subjects. After treatment of mice with 4-MeSO2-TCB (100 mg/kg), the pulmonary N-demethylation of aminopyrine in vitro was significantly decreased, while hepatic N-demethylation was concomitantly increased, as compared to tissue from control mice. Treatment of mice with 4-MeSO2-TCB also decreased the in vivo pulmonary covalent binding of o,p'-DDD, while the in vivo hepatic covalent binding was increased. The results indicate that 4-MeSO2-TCB inhibits or represses a cytochrome P-450-dependent enzyme activity in the mouse lung, while in contrast this activity is induced in the mouse liver.     

Pharmacokinetics of gemcitabine in non-small-cell lung cancer patients: impact of the 79A>C cytidine deaminase polymorphism

Objective

To study the impact of the 79A>C polymorphism in the cytidine deaminase (CDA) gene on the pharmacokinetics of gemcitabine and its metabolite 2′,2′-difluorodeoxyuridine (dFdU) in non-small-cell lung cancer (NSCLC) patients.

Patients and methods

Patients (n?=?20) received gemcitabine 1,125 mg/m² as a 30 min i.v. infusion as part of treatment for NSCLC. Plasma samples were collected during 0–6 h after gemcitabine administration. Gemcitabine and dFdU were quantified by high performance liquid chromatography with ultraviolet detection. The CDA 79A>C genotype was determined with PCR and DNA sequencing.

Results

Gemcitabine was rapidly cleared from plasma and undetectable after 3 h. The allele frequency of the 79A>C polymorphism was 0.40. Diplotypes were distributed as A/A n?=?8, A/C n?=?8 ,and C/C n?=?4. No significant differences were found between the different CDA genotypes and gemcitabine or dFdU AUC, clearance, or half-life.

Conclusion

The 79A>C polymorphism in the CDA gene does not have a major consistent and signficant impact on gemcitabine pharmacokinetics.     

The metabolism of 1-phenyl-2-(N-methyl-N-furfurylamino)propane (furfenorex) in the rat in vivo and in vitro

The metabolism of 1-phenyl-2-(N-methyl-N-furfurylamino)propane (furfenorex) was studied in the rat in vivo and in vitro. Nine metabolites with only traces of the unchanged drug were obtained from urine after oral administration of furfenorex to rats. The major metabolite was an acidic compound, isolated and identified as 1-phenyl-2-(N-methyl-N-gamma-valerolactonylamino)propane. Amphetamine, methamphetamine and their hydroxylated metabolites were excreted as minor metabolites. Metabolites excreted in two days after administration of the drug amounted to about 20% of dose. The acidic metabolite, a major metabolite in vivo, was not detected after incubation of furfenorex with rat-liver microsomes. The major metabolic routes of furfenorex in vitro were N-demethylation and N-defurfurylation which produced 1-phenyl-2-(N-furfurylamino)propane (furfurylamphetamine) and methamphetamine, respectively. The formation of furfurylamphetamine and methamphetamine were catalysed by rat-liver microsomes supplemented with NADPH and O2, and were inhibited by either SKF 525-A or CO. The formation of both metabolites were inhibited by 2-methyl-1,2-bis-(3-pyridyl)-1-propanone (metyrapone), but not by 7,8-benzoflavone. They were enhanced by pretreatment of rats with phenobarbitone, but not with 3-methylcholanthrene. These data suggested that N-demethylation and N-defurfurylation of furfenorex were mainly mediated by cytochrome P-450 but not cytochrome P-448.     

The metabolism of fenclofenac in the horse

14C-Fenclofenac (2-(2'-4'-dichlorophenoxy)-phenylacetic acid) was administered orally to horses, and urinary metabolites investigated by chromatography. Fenclofenac was rapidly absorbed and eliminated, with a plasma half-life (t1/2) of 2.3 h, with 83.2 and 85.8% of the dose being recovered in the urine in 0-24 h. The major urinary metabolite was the ester glucuronide (58.8, 70.0% dose), and evidence is presented that this metabolite undergoes a structural rearrangement to give beta-glucuronidase-resistant isomers. The other 14C-labelled components in horse urine were unchanged fenclofenac (13.1, 11.5% dose), and two minor metabolites, one of which was identified as a monohydroxy fenclofenac. This study is the first to show an ester glucuronide to be the major metabolite of a non-steroidal anti-inflammatory drug in the horse.     

Disposition of bemitradine, a renal vasodilator and diuretic, in man

1. 14C-Bemitradine (50 mg) was rapidly and efficiently absorbed (approximately 89%) in man following a single oral dose, as a solution in gelatine capsules. Peak 14C levels of 895 +/- 154 ng equiv./ml (mean +/- S.E.M.) were reached within 2 h, and declined with half-lives of 1.07 +/- 0.25 and 13.0 +/- 5.6h. 2. No bemitradine was detected in plasma, but peak concn. (124 +/- 29 ng/ml) of its desethyl metabolite were reached at 1.05 +/- 0.28 h, and declined with a half-life of 1.32 +/- 0.08 h. 3. Desethylbemitradine was rapidly metabolized to its ether glucuronide, a phenol and a dihydrodiol which were also present as glucuronide conjugates. The glucuronides were the major compounds in plasma from 2 h after drug administration. 4. Excretion in 5 days amounted to 88.8 +/- 2.3% and 10.4 +/- 2.1% dose in urine and faeces respectively. No bemitradine or desethylbemitradine were excreted unchanged. 8-(2-Hydroxyethyl)-7-(3,4- dihydroxycyclohexa-1,5-dienyl)-1,2,4-triazolo-1,5c-pyrimidin e-5-amine (E; 17% dose); 8-(2-hydroxyethyl)-7-(4-hydroxyphenyl)-1,2,4-triazolo-1,5c- pyrimidine-5-amine (F; 4% dose), their glucuronides (A, 19% dose and B, 6% dose respectively), desethylbemitradine glucuronide (D, 25% dose) and an unidentified metabolite (C, 12% dose) were excreted in urine. Compound F was the major faecal metabolite.     

Identification of urinary metabolites of 8-methyl-8-azabicyclo- 3,2,1] octan-3-yl 3,5-dichlorobenzoate (MDL 72,222) in the dog and monkey.

The metabolism of 8-methyl-8-azabicyclo- 3,2,1]octan-3-yl 3,5-dichlorobenzoate (MDL 72,222) was studied in the dog and monkey. Four urinary metabolites were detected by HPLC, HPLC/MS, and GC/MS, and were identified by comparison to authentic standards. The major metabolite in the dog, approximately 41% of the administered dose excreted between 0 and 120 hr, was the MDL 72,222-N-oxide. On the other hand, the major metabolite in the monkey was the glycine conjugate of 3,5-dichlorobenzoic acid (greater than 56% of the dose). Seven percent of the dose in the monkey urine was free 3,5-dichlorobenzoic acid. N-Desmethyl MDL 72,222 was present at 2.5 and 1% in the dog and monkey, respectively. Very little (less than 1%) of the parent compound was found in urine. The major pathways of metabolism of MDL 72,222 are N-oxidation, N-demethylation, ester hydrolysis, and amino acid conjugation.     

Metabolism of 14C-estazolam in dogs and humans

14C-Estazolam (2 mg) administered orally to dogs and human subjects was rapidly and completely absorbed with peak plasma levels occurring within one hour. In humans, plasma levels peaked at 103 +/- 18 ng/ml and declined monoexponentially with a half-life of 14 h. The mean concn. of estazolam in dog plasma at 0.5 h was 186 ng/ml. Six metabolites were found in dog plasma at 0.5 and 8 h, whereas only two metabolites were detected in human plasma up to 18 h. Metabolites common to both species were 1-oxo-estazolam (I) and 4-hydroxy-estazolam (IV). Major metabolites in dog and human plasma were free and conjugated 4-hydroxy-estazolam; the concn. were higher in dogs. After five days, 79% and 87% of the administered radioactivity was excreted in dog and human urine, respectively. Faecal excretion accounted for 19% of the dose in dog and 4% in man. Eleven metabolites were found in the 0-72 h urine of dogs and humans; less than 4% dose was excreted unchanged. Four metabolites were identified as: 1-oxo-estazolam (I), 4'-hydroxy-estazolam (II), 4-hydroxy-estazolam (IV) and the benzophenone (VII), as free metabolites and glucuronides. The major metabolite in dog urine was 4-hydroxy-estazolam (20% of the dose), while the predominant metabolite in human urine (17%) has not been identified, but is likely to be a metabolite of 4-hydroxy-estazolam. The metabolism of estazolam is similar in dog and man.     

Pharmacokinetics and metabolism of endothelin receptor antagonist: Contribution of kidneys in the overall<Emphasis Type="Italic">in vivo N</Emphasis>-demethylation

In vivo clearance of BMS-182874 was primarily due to metabolism via stepwise N-demethylation. Despite in vivo clearance approached ca 50% of the total liver plasma flow, BMS-182874 was completely bioavailable after oral administration in rats. Saturable first-pass metabolism and the role of extrahepatic tissue were evaluated as possible reasons for complete oral bioavailability despite extensive metabolic clearance. Pharmacokinetic parameters were obtained after an intravenous and a range of oral doses of BMS-182874 in rats. Bile and urine were collected from bile-duct cannulated (BDC) rats and the in vivo metabolic pathways of BMS-182874 were evaluated. Pharmacokinetics of BMS-182874 were also compared in nephrectomized (renally impaired) vs. sham-operated control rats. Oral bioavailability of BMS-182874 averaged 100%, indicating that BMS-182874 was completely absorbed and the first-pass metabolism (liver or intestine) was negligible. The AUC and Cmax values increased dose-proportionally, indicating kinetics were linear within the oral dose range of 13 to 290 mmole/kg. After intravenous administration of BMS-182874 to BDC rats, about 2% of intact BMS-182874 was recovered in excreta, indicating that BMS-182874 was cleared primarily via metabolism in vivo. The major metabolite circulating in plasma was the mono-N-desmethyl metabolite and the major metabolite recovered in excreta was the di-N-desmethyl metabolite. In vivo clearance of BMS-182874 was significantly reduced in nephrectomized rats. These observations suggest saturable first-pass metabolism is unlikely to be a mechanism for complete oral bioavailability of BMS-182874. Reduced clearance observed in the nephrectomized rats suggests that extrahepatic tissues (e.g., kidneys) may play an important role in the in vivo clearance of xenobiotics that are metabolized via N-demethylation.     

Pharmacokinetics of cimetidine and its sulphoxide metabolite during haemodialysis

Summary A single intravenous dose of cimetidine 200mg was administered to 6 patients with severe chronic renal failure one hour prior to haemodialysis. The plasma concentrations of cimetidine and its sulphoxide metabolite at the start of haemodialysis were 2.74±0.12 and 0.76±0.08 µg/ml, and after dialysis for 4h 1.08±0.10 and 0.51±0.08 µg/ml, respectively (mean ± SE). The average haemodialysis clearance (Cl_HDa) of cimetidine during dialysis was 46–92ml/min at a dialysate flow rate of 320ml/min and blood flow rates in the 6 patients between 160–240ml/min. The mean Cl_HDa of the sulphoxide metabolite was 44% higher than that of cimetidine, and ranged between 49–148ml/min. During haemodialysis the mean plasma elimination half-life (t_1/2) of cimetidine was 3.24h (range 2.08–5.08) and of the sulphoxide metabolite 9.49h (range 4.70–14.39). There was a significant relationship between the elimination rate constant () and Cl_HDa of the sulphoxide metabolite (p<0.01), but no such relationship was found between and Cl_HDa of cimetidine. However, there was a tendency to a relationship between of cimetidine and the capacity to metabolise the drug, expressed as the ratio between the plasma concentrations of the sulphoxide metabolite and cimetidine after dialysis for 4h. These ratios ranged between 0.23–0.76, and the lowest ratio was seen in the patient with the lowest value of cimetidine. Thus, the large variations in the plained by differences in their capacity to metabolise the drug. The mean total amount of cimetidine eliminated during dialysis was 27.3mg (range 17.9–31.8), which was 9.0–15.9% of the given dose. Between 12.2–21.2mg (mean 15.3) of the sulphoxide metabolite was eliminated in the dialysate. Major adjustment of the dose of cimetidine on days of dialysis is not necessary.     

Metabolism of 14C-labeled doxylamine succinate (Bendectin) in the rhesus monkey (Macaca mulatta)

The time-course of the metabolic fate of [14C]doxylamine was determined after the p.o. administration of 13 mg/kg doxylamine succinate as Bendectin plus [14C]doxylamine succinate to the rhesus monkey. Urine and plasma samples were analyzed by reversed-phase high performance liquid chromatography (HPLC), chemical derivatization, and mass spectrometry. The cumulative 48-hr urinary metabolic profile contained 81% of the administered radiolabeled dose and consisted of at least six radiolabeled peaks. They were peak 1: unknown polar metabolites (8% of dose); peak 2: 2-[1-phenyl-1-(2-pyridinyl)ethoxy] acetic acid, 1-[1-phenyl-1(2-pyridinyl)ethoxy] methanol, and another minor metabolite(s) (31%); peak 3: doxylamine-N-oxide (1%); peak 4a: N,N-didesmethyldoxylamine (17%); peak 4b: doxylamine (4%); and peak 5: N-desmethyldoxylamine (20%). The plasma metabolic profile was the same as the urinary profile except for the absence of doxylamine-N-oxide. The maximum plasma concentrations and elapsed time to attain these concentrations were as follows. Peak 1: 540 ng/mL, 4 hr; peak 2: 1700 ng/mL, 1 hr; peak 4a: 430 ng/mL, 4 hr; peak 4b: 930 ng/mL, 2 hr; and peak 5: 790 ng/mL, 2 hr. These data suggest that in the monkey, doxylamine metabolism follows at least four pathways: a minor pathway to the N-oxide; a minor pathway to unknown polar metabolites; a major pathway to mono- and didesmethyldoxylamine via successive N-demethylation; and a major pathway to side-chain cleavage products (peak 2) via direct side-chain oxidation and/or deamination.     

NMR study of whole rat bile: the biliary excretion of 4-cyano-N,N-dimethyl aniline by an isolated perfused rat liver and a liver in situ

The structure of two biliary metabolites of 4-cyano-N,N,-dimethyl aniline (CDA) contained in whole rat bile have been studied in detail by NMR at 400 MHz. A 4-cyano-N-methyl glutathione-N-aniline conjugate was identified as a biliary metabolite of CDA using relatively simple ¹H NMR techniques. Isotopically ¹³C labelled CDA was used to generate ¹³C labelled xenobiotic conjugates. Our use of ¹H/¹³C heteronuclear NMR techniques, in particular a ¹³C-selective HMQC-TOCSY experiment, allowed a N-β-glucuronide conjugate, a previously unknown biliary metabolite of CDA, to be identified. Bile samples obtained from both the isolated perfused rat liver and the rat liver in situ were analysed.     

Hepatic metabolism of MK-0457, a potent aurora kinase inhibitor: interspecies comparison and role of human cytochrome P450 and flavin-containing monooxygenase.

MK-0457 (N-[4([4-(4-methylpiperazin-1-yl)-6-[(3-methyl-1H-pyrazol-5 -yl)amino]pyrimidin-2-yl]thio)phenyl]cyclopropanecarboxamide), an Aurora kinase inhibitor in development for the treatment of cancer, was evaluated for its in vitro metabolism in different species. This compound primarily underwent N-oxidation and N-demethylation in human, monkey, dog, and rat liver preparations. However, N-demethylation was less significant in dogs. The formation of minor metabolites varied with species, but all metabolites generated in human hepatocytes were observed in animals. Results of immunoinhibition, selective chemical inhibition, thermal inactivation, and metabolism by recombinant cytochromes P450 and flavin-containing monoogygenases (FMOs) strongly suggest that CYP3A4 and FMO3 comparably contributed to MK-0457 N-oxidation in human liver microsomes, where the reaction conformed to Michaelis-Menten kinetics. These studies indicate a major role of CYP2C8 in the N-demethylation reaction, whereas CYP3A4 only made a minor contribution. However, significant substrate inhibition was observed with MK-0457 N-demethylation at high substrate concentrations (>10 microM) in human liver microsomes relative to the anticipated therapeutic exposure. A multienzyme metabolic pathway such as this may mitigate the potential of drug interactions in clinical treatment with MK-0457.     

Antipyrine metabolite kinetics in rats: studies on dose and time dependence

Antipyrine metabolite kinetics have been investigated in the rat with respect to dose and time dependence. The metabolic pathways, 4-hydroxylation, benzylic oxidation, and N-demethylation, are of equal quantitative importance (approximately 20 per cent of dose) and show no dose dependence over the range 25-500 mg kg-1. By using [N-methyl-14C]-antipyrine, the single carbon fragment lost by N-demethylation may be monitored as 14CO2. Serial sampling of 14CO2 exhalation rate provides a half-life estimate which, according to theoretical principles, reflects the antipyrine plasma half-life. When both half-lives were measured in the same animals a statistically significant correlation was evident. At doses of 250 mg kg-1 and 500 mg kg-1 there is an increase in CER half-life (218 and 303 min respectively) when compared to a dose below 100 mg kg-1 (152 min). The metabolite formation rate constants are decreased accordingly at the high doses but are invariant over the dose range 25-100 mg kg-1. Although inter-rat variation in antipyrine metabolite kinetics was substantial, intra-rat variability was small. The noninvasive nature of determining antipyrine metabolite kinetics via breath and urine analysis provides a potentially useful animal model system to investigate the factors influencing hepatic mixed function oxidase activity in vivo.     

Plasma pharmacokinetics and metabolism of the histone deacetylase inhibitor trichostatin a after intraperitoneal administration to mice.

Trichostatin A is a potent and specific histone deacetylase inhibitor with promising antitumor activity in preclinical models. Plasma pharmacokinetics of trichostatin A were studied following single-dose intraperitoneal administration of 80 mg/kg (high dose) or 0.5 mg/kg (low dose) to female BALB/c mice. Plasma trichostatin A concentrations were quantified by high performance liquid chromatography (HPLC)-UV assay (high dose) or by HPLC-multiple reaction monitoring assay (low dose). Trichostatin A was rapidly absorbed from the peritoneum and detectable in plasma within 2 min. Cmax of 40 microg/ml and 8 ng/ml occurred within 5 min, followed by rapid exponential decay in plasma trichostatin A concentration with t1/2 of 6.3 min and 9.6 min (high and low doses, respectively). Phase I metabolites at the high dose were identified by simultaneous UV and positive ion electrospray mass spectrometry. Trichostatin A underwent extensive metabolism: primary metabolic pathways were N-demethylation, reduction of the hydroxamic acid to the corresponding trichostatin A amide, and oxidative deamination to trichostatic acid. N-Monomethyl trichostatin A amide was the major plasma metabolite. No didemethylated compounds were identified. Trichostatic acid underwent further biotransformation: reduction and beta-oxidation of the carboxylic acid, with or without N-demethylation, resulted in formation of dihydro trichostatic acid and dinor dihydro trichostatic acids. HPLC fractions corresponding to trichostatin A and N-demethylated trichostatin A exhibited histone deacetylase-inhibitory activity; no other fractions were biologically active. We conclude that trichostatin A is rapidly and extensively metabolized in vivo following intraperitoneal administration to mice, and N-demethylation does not compromise histone deacetylase-inhibitory activity.