Biotransformation of tirilazad in human: 1. Cytochrome P450 3A-mediated hydroxylation of tirilazad mesylate in human liver microsomes.

Tirilazad mesylate (Freedox), a potent inhibitor of membrane lipid peroxidation in vitro, is under clinical development for the treatment of subarachnoid hemorrhage. In humans, tirilazad is cleared almost exclusively via hepatic elimination. Characterization of three major microsomal metabolites of tirilazad by mass spectrometry indicated that hydroxylation had occurred in the pyrrolidine ring(s) and at the 6 beta-position of the steroid domain. A role for CYP3A4 in the formation of the three major metabolites (tirilazad hydroxylase activity) was established in human liver microsomal preparations: 1) Tirilazad hydroxylation was potently inhibited by troleandomycin and ketoconazole, specific inhibitors of CYP3A4. 2) The rates of tirilazad hydroxylation within a population of 14 human livers displayed a 9-fold interindividual variation and a significant correlation (r2 = .95) between tirilazad hydroxylation and testosterone 6 beta-hydroxylation. 3) Kinetic analysis of tirilazad hydroxylase activity in three human livers resulted in an apparent Km of 2.12, 1.68 and 1.66 microM, and Vmax = 0.85, 0.44 and 3.45 (nmol/mg protein/min) for HL14, HL17 and HL21, respectively. In addition, an apparent Km of 2.07 microM was established for tirilazad hydroxylation in a cDNA-expressed CYP3A4 microsomal system. Collectively, these data indicate that the metabolic clearance of tirilazad in humans is catalyzed primarily by CYP3A4 and provide an insight into factors (i.e., age, sex, drug-drug interactions) that modulate the metabolic clearance of tirilazad in vivo.

Quantitative analysis quantitation of 2-n-nonyl-1,3-dioxolane by stable-isotope dilution gas chromatography-mass spectrometry.

We report here a quantitative methodology developed for determination of SEPA (2-n-nonyl-1,3-dioxolane) in human serum. The method employed solid-phase extraction of SEPA and internal standard, [13C2]SEPA, from serum followed by gas chromatography-mass spectrometry analysis using EI monitoring m/z 73 and 75. We have investigated the utility of stable isotope dilution gas chromatography-mass spectrometry (GC-MS) for the determination of SEPA concentrations in serum using chemical ionization (positive ion, CI) or electron ionization (EI). The comparison of the specificity and sensitivity between EI and CI indicated that monitoring the m/z 73 ion in EI was superior to monitoring either MH+ or m/z 73 using CI. The method was simple, sensitive and accurate, demonstrating a lower limit of quantitation (LLOQ) of 0.25 ng/ml and intra- and inter-assay accuracy and precision of < or = 7.5%.

Preparation and characterization of the deepoxy trichothecenes: deepoxy HT-2, deepoxy T-2 triol, deepoxy T-2 tetraol, deepoxy 15-monoacetoxyscirpenol, and deepoxy scirpentriol.

The production of deepoxy metabolites of the trichothecene mycotoxins T-2 toxin and diacetoxyscirpenol, including deepoxy HT-2 (DE HT-2), deepoxy T-2 triol, deepoxy T-2 tetraol, deepoxy 15-monoacetoxyscirpenol, and deepoxy scirpentriol is described. The metabolites were prepared by in vitro fermentation with bovine rumen microorganisms under anaerobic conditions and purified by normal and reverse-phase high-pressure liquid chromatography. Capillary gas chromatographic retention times and mass spectra of the derivatized metabolites were obtained. The deepoxy metabolites were significantly less toxic to brine shrimp than were the corresponding epoxy analogs. Polyclonal and monoclonal T-2 antibodies were examined for cross-reactivity to several T-2 metabolites. Both HT-2 and DE HT-2 cross-reacted with mouse immunoglobulin monoclonal antibody 15H6 to a greater extent than did T-2 toxin. Rabbit polyclonal T-2 antibodies displayed greater specificity to T-2 toxin compared with the monoclonal antibody, with relative cross-reactivities of only 17.4, 14.6, and 9.2% for HT-2, DE HT-2, and deepoxy T-2 triol, respectively. Cross-reactivity of both antibodies was weak for T-2 triol, T-2 tetraol, 3'OH T-2, and 3'OH HT-2.

Biotransformation of lifibrol (U-83860) to mixed glyceride metabolites by rat and human hepatocytes in primary culture.

Lifibrol (U-83860), K12.148) is a lipid-lowering drug that has the potential to accumulate in the liver and induce hepatic peroxisome proliferation. To investigate the identity and potential human relevance of persistent lifibrol-related residues in rat liver, rat and human hepatocyte primary cultures were treated with 30 microM of [14C]lifibrol. After a steady uptake for 24 hr, cellular levels of radioactivity became stable for the next 24-48 hr. A nonradioactive lifibrol chase caused an efflux of intracellular radioactivity. Cellular autoradiography revealed the association of radioactivity with small lipid drops at 6 hr exposure and with large lipid drops at 24 hr exposure. HPLC analysis of media revealed that lifibrol acyl glucuronide and a t-butylcarboxylic acid metabolite (U-94613) were the major metabolites of rat and human hepatocytes, respectively. Using an HPLC method suitable for nonpolar metabolites, the analysis of rat and human cell extracts revealed a broad band of multiple, radioactive peaks that had a similar retention and UV spectrum to a synthetic standard of lifibrol cholesterol ester. Folch extracts of liver from rats treated with [14C]lifibrol or unlabeled lifibrol and [14C]acetate had a unique radioactive TLC band that had similar HPLC retention to hepatocyte residues. The group of nonpolar peaks from the hepatocytes was purified by HPLC. Conversion of the lifibrol sec-hydroxy group to a nicotinate ester afforded particle beam-electron impact mass spectra of the cholesterol ester standard and hepatocyte residues. The derivatized rat hepatocyte residue did not contain detectable lifibrol cholesterol ester (M+.816), but did contain molecular ion clusters corresponding to a mixed triglyceride of lifibrol and two fatty acids. Lifibrol-specific product ions of molecular ion clusters centered at M+.1021, 1047, and 1073 were observed at m/z 448, 430, and 310. The major lifibrol-containing triglycerides had a fatty acid composition of C16-C20 with 0-6 unsaturations.

Interaction of delavirdine with human liver microsomal cytochrome P450: inhibition of CYP2C9, CYP2C19, and CYP2D6.

Delavirdine, a non-nucleoside inhibitor of HIV-1 reverse transcriptase, is metabolized primarily through desalkylation catalyzed by CYP3A4 and CYP2D6 and by pyridine hydroxylation catalyzed by CYP3A4. It is also an irreversible inhibitor of CYP3A4. The interaction of delavirdine with CYP2C9 was examined with pooled human liver microsomes using diclofenac 4'-hydroxylation as a reporter of CYP2C9 catalytic activity. As delavirdine concentration was increased from 0 to 100 microM, the K(M) for diclofenac metabolism rose from 4.5+/-0.5 to 21+/-6 microM, and V(max) declined from 4.2+/-0.1 to 0.54+/-0.08 nmol/min/mg of protein, characteristic of mixed-type inhibition. Nonlinear regression analysis revealed an apparent K(i) of 2.6+/-0.4 microM. There was no evidence for bioactivation as prerequisite to inhibition of CYP2C9. Desalkyl delavirdine, the major circulating metabolite of delavirdine, had no apparent effect on microsomal CYP2C9 activity at concentrations up to 20 microM. Several analogs of delavirdine showed similar inhibition of CYP2C9. Delavirdine significantly inhibited cDNA-expressed CYP2C19-catalyzed (S)-mephenytoin 4'-hydroxylation in a noncompetitive manner, with an apparent K(i) of 24+/-3 microM. Delavirdine at concentrations up to 100 microM did not inhibit the activity of CYP1A2 or -2E1. Delavirdine competitively inhibited recombinant CYP2D6 activity with a K(i) of 12.8+/-1.8 microM, similar to the observed K(M) for delavirdine desalkylation. These results, along with previously reported experiments, indicate that delavirdine can partially inhibit CYP2C9, -2C19, -2D6, and -3A4, although the degree of inhibition in vivo would be subject to a variety of additional factors.

Metabolism of delavirdine, a human immunodeficiency virus type-1 reverse transcriptase inhibitor, by microsomal cytochrome P450 in humans, rats, and other species: probable involvement of CYP2D6 and CYP3A.

The metabolism of delavirdine was examined using liver microsomes from several species with the aim of comparing metabolite formation among species and characterizing the enzymes responsible for delavirdine metabolism. Incubation of 10 microM [14C]delavirdine with either an S9 fraction from human jejunum or liver microsomes from rat, human, dog, or monkey followed by high pressure liquid chromatography analysis showed qualitatively similar metabolite profiles among species with the formation of three significant metabolites. The major metabolite was desalkyl delavirdine; however, the identity of MET-7 and MET-7a (defined by high pressure liquid chromatography elution) could not be unambiguously established, but they seem to be related pyridine hydroxy metabolites, most likely derived from 6'-hydroxylation of the pyridine ring. The apparent KM for delavirdine desalkylation activity ranged from 4.4 to 12.6 microM for human, rat, monkey, and dog microsomes, whereas Vmax ranged from 0.07 to 0.60 nmol/min/mg protein, resulting in a wide range of intrinsic clearance (6-135 microL/min/mg protein). Delavirdine desalkylation by microsomes pooled from several human livers was characterized by a KM of 6.8 +/- 0.8 microM and Vmax of 0. 44 +/- 0.01 nmol/min/mg. Delavirdine desalkylation among 23 human liver microsomal samples showed a meaningful correlation (r = 0.96) only with testosterone 6beta-hydroxylation, an indicator of CYP3A activity. Among ten human microsomal samples selected for uniform distribution of CYP3A activity, formation of MET-7 was strongly correlated with CYP3A activity (r = 0.95) and with delavirdine desalkylation (r = 0.98). Delavirdine desalkylation was catalyzed by cDNA-expressed CYP2D6 (KM 10.9 +/- 0.8 microM) and CYP3A4 (KM 5.4 +/- 1.4 microM); however, only CYP3A4 catalyzed formation of MET-7 and MET-7a. Quinidine inhibited human liver microsomal delavirdine desalkylation by about 20%, indicating a minor role of CYP2D6. These findings suggest the potential for clinical interaction with coadministered drugs that are metabolized by or influence the activity of CYP3A or CYP2D6.

Metabolism of the HIV-1 reverse transcriptase inhibitor delavirdine in mice.

Delavirdine mesylate (U-90152T) is a highly specific nonnucleoside HIV-1 reverse transcriptase inhibitor currently under development for the treatment of AIDS. The excretion, disposition, brain penetration, and metabolism of delavirdine were investigated in CD-1 mice after oral administration of [14C]delavirdine mesylate at single doses of 10 and/or 250 mg/kg and multiple doses of 200 mg/kg/day. Studies were conducted with 14C-carboxamide and 2-14C-pyridine labels, as well as 13C3-labeled drug to facilitate metabolite identification. Excretion was dose dependent with 57-70% of the radioactivity eliminated in feces and 25-36% in urine. Pharmacokinetic analyses of delavirdine and its N-desisopropyl metabolite (desalkyl delavirdine) in plasma showed that delavirdine was absorbed and metabolized rapidly, that it constituted a minor component in circulation, that its pharmacokinetics were nonlinear, and that its metabolism to desalkyl delavirdine was capacity limited or inhibitable. Delavirdine did not significantly cross the blood-brain barrier; however, its N-isopropylpyridinepiperazine metabolite arising from amide bond cleavage-was present in brain at levels 2- to 3-fold higher than in plasma. The metabolism of delavirdine in the mouse was extensive and involved amide bond cleavage, N-desalkylation, hydroxylation at the C-6' position of the pyridine ring, and pyridine ring-cleavage as determined by MS and/or 1H and 13C NMR spectroscopies. N-desalkylation and amide bond cleavage were the primary metabolic pathways at low drug doses and, as the biotransformation of delavirdine to desalkyl delavirdine reached saturation or inhibition, amide bond cleavage became the predominant pathway at higher doses and after multiple doses.

Identification of the metabolites of the HIV-1 reverse transcriptase inhibitor delavirdine in monkeys.

Delavirdine mesylate (U-90152T) is a highly specific nonnucleoside HIV-1 reverse transcriptase inhibitor currently under development for the treatment of AIDS. The metabolism of delavirdine was investigated in male and female cynomolgus monkeys after oral administration of [14C-carboxamide]delavirdine mesylate at single doses of 80 mg/kg and multiple doses of 160 to 300 mg/kg/day. Desalkyl delavirdine was the major metabolite in circulation. In urine, desalkyl delavirdine accounted for nearly half of the radioactivity, with despyridinyl delavirdine and conjugates of desalkyl delavirdine accounting for most of the remaining radioactivity. Bile was mostly composed of desalkyl delavirdine and 6'-O-glucuronide delavirdine, with parent drug, 4-O-glucuronide delavirdine, and conjugates of desalkyl delavirdine as significant components. In addition, several minor metabolites were observed in urine and bile of delavirdine treated monkeys. The metabolism of delavirdine in the monkey was extensive and involved N-desalkylation, hydroxylation at the C-4' and C-6' positions of the pyridine ring, hydroxylation at the C-4 position of the indole ring, pyridine ring-cleavage, N-glucuronidation of the indole ring, and amide bond cleavage as determined by MS and/or one-dimensional and two-dimensional NMR spectroscopies. Phase II biotransformations included glucuronidation, sulfation, and beta-N-acetylglucosaminidation. The identification of the N-linked beta-N-acetylglucosamine and 4-O-glucuronide metabolites of delavirdine represents novel biotransformation pathways.

Metabolism of the bisphosphonate ester U-91502 in rats.

The major metabolites of the bisphosphonate ester U-91502 were isolated from the bile and urine of male Sprague-Dawley rats and identified by NMR and MS. Bile duct-exteriorized and taurocholate-supplemented rats received single oral doses of 10-140 mg/kg of labeled U-91502. Analysis of radioactivity in bile, urine, and feces showed that U-91502-related radioactivity was rapidly excreted, predominantly in bile, achieving peak concentrations in bile of 1250 +/- 622 micrograms-eq/g during first 3 hr after a 10 mg/kg dose. The three major drug-related materials in bile and urine were separated by HPLC and designated in order of reversed-phase elution as metabolites A, B, and C. The least polar metabolite (C) was shown by HPLC/particle beam/MS and HPLC/electrospray/MS to be the triester, U-94532. Metabolite C cochromatographed with a synthesized standard of U-94532A. Metabolite B was the glucuronide conjugate of the 5-hydroxy pyrimidinone, U-97294. Metabolite A was a product of glutathione addition to a putative pyrimidinone 4,5-epoxide. Mechanisms for the formation of metabolites A, B, and C based on metabolite structure and stability were proposed.

In vitro and in vivo biotransformation of 6,7-dimethyl-2,4-di-1-pyrrolidinyl-7H-pyrrolo[2,3-D]pyrimidine (U-89843) in the rat.

The biotransformation of 6,7-dimethyl-2,4-di-1-pyrrolidinyl-7H-pyrrolo[2,3-d]pyrimidine (U-89843) has been studied in rat both in vitro and in vivo. Major metabolites observed by HPLC analysis of rat plasma, liver cytosol, and microsomal incubations were characterized by UV, LC/MS, and comparison with synthetic standards. The structures of the metabolites were shown to be the C-6 hydroxymethyl (U-97924), C-6 formyl (U-97865), and C-6 carboxyl analogs of U-89843. In the male rat, formation of U-97924 is mediated by cytochrome P4502C11. Kinetic analysis of U-97924 formation indicated that it was a high-affinity/high-capacity process (KM = 4.2 +/- 0.5 microM; Vmax = 21.2 +/- 0.8 nmol/mg/min). Formation of U-97865 via enzymatic oxidation from the primary metabolite U-97924 was catalyzed by both the microsomal subcellular fraction in a NADPH-dependent process (presumably via cytochrome P450) and in cytosol by NAD(+)-dependent alcohol dehydrogenase. Upon incubation with cytosolic fractions, U-97865 was found to undergo NAD(+)-dependent oxidation, mediated by aldehyde dehydrogenase, to the corresponding carboxylic acid. Although significant levels of U-89843, U-97924, and U-97865 were observed in vivo in rat plasma, only a minor amount of the carboxylic acid together with larger amounts of unidentified polar metabolites were excreted in urine and feces.

In vitro metabolic transformations of 2,4-dipyrrolidinylpyrimidine: a chemical probe for P450-mediated oxidation of tirilazad mesylate.

1. We have determined that 2,4-dipyrrolidinylpyrimidine (2,4-DPP), used as a model for studies of the metabolism of therapeutic agents containing this moiety, undergoes three characteristic hydroxylations when incubated with male rat liver microsomes. Analysis of microsomal incubates of stable isotope labelled analogues of 2,4-DPP by particle beam-liquid chromatography-mass spectrometry (LC-PB-MS) has shown that the three metabolites are 4-(3-hydroxypyrrolidinyl)-2-(pyrrolidinyl)-pyrimidine (M1), 4-(2-hydroxypyrrolidinyl)-2-(pyrrolidinyl)-pyrimidine (M2) and 2-(2-hydroxypyrrolidinyl)-4-(pyrrolidinyl)-pyrimidine (M3). 2. We determined that enzymes of the cytochrome P450 family are responsible for the in vitro hydroxylations of 2,4-DPP. 3. We observed that in microsomal incubations carried out in the presence of cyanide, a single cyanide adduct is formed implicating an iminium ion intermediate in the oxidation of the 2-pyrrolidine ring. 4. We also determined the intermolecular deuterium isotope effects for the formation of each of the three products. For M1, kH/kD = 14.55 +/- 0.54; for M2, kH/kD = 6.01 +/- 0.65; and for M3, kH/kD = 5.35 +/- 1.18. 5. We interpret these data as suggesting that M2 and M3 are formed by the same mechanism, probably including the formation of an iminium ion, and that M1 is formed by direct hydrogen abstraction.

Metabolism of the human immunodeficiency virus type 1 reverse transcriptase inhibitor delavirdine in rats.

Delavirdine mesylate (U-90152T) is a highly specific nonnucleoside reverse transcriptase inhibitor currently under development for the treatment of AIDS. The excretion, disposition, and metabolism of delavirdine were investigated in Sprague-Dawley rats after oral administration of [14C]delavirdine mesylate at single doses ranging from 10 to 250 mg/kg and multiple doses ranging from 20 to 250 mg/kg/day. Excretion studies showed that feces was the major route of elimination, delavirdine was well absorbed (>80%) after a 10 mg/kg single dose, and excretion was dose-dependent. The metabolism of delavirdine in the rat was extensive. The following metabolites were identified (% of dose in rats given 10 and 100 mg/kg, respectively): 6'-hydroxy delavirdine (7.1% and 15.6%) and its glucuronide (12.2% and 6.2%) and sulfate (5.5% and 3.2%) conjugates, despyridinyl delavirdine (12.1% and 11.7%) and its conjugate (13.0% and 11.7%), desalkyl delavirdine (16.5% and 13.4%), and its N-sulfamate, 6'- and 4'-sulfate conjugates (2.9% and 3.9%). Cleavage of the amide bond in delavirdine to give N-isopropylpyridinepiperazine and indole carboxylic acid constituted a minor pathway. Degradation of 6'-hydroxy delavirdine generated despyridinyl delavirdine and the pyridine-ring opened MET-14. The metabolic pathway of delavirdine involved N-desalkylation, pyridine ring hydroxylation, pyridine ring cleavage, and amide bond cleavage.

Metabolism of a bisphosphonate ester (PNU-91638) in rat.

1. Metabolites of the cyclic bisphosphonate ester, 4-[2,2'-bis-(5,5- dimethyl-1,3,2-dioxaphosphorinan-2-yl)] butanoyl-3-fluoro-benzene (PNU-91638) in bile or urine of the male Sprague-Dawley rat were characterized by mass spectrometry. The chronically bile duct/duodenal-cannulated male rats received a single oral dose of 100 mg/kg [13C] [14C]PNU-91638. Bile and urine samples were analysed for radioactivity and profiled by hplc with radiometric and UV detection. 2. The 0-28-h bile and urine accounted for 46.0 and 19.7% of dose respectively. The structures of radioactive peaks were investigated by ionspray and liquid secondary ion mass spectrometry (LSIMS) and LSIMS/MS analysis. 3. Major metabolites in urine included two regioisomeric phenol glucuronides, a gem methyl hydroxylated metabolite of the bisphosphonate heterocycle, a phenol metabolite, parent drug and a benzylic alcohol metabolite. Additional metabolites in bile included an unstable phenol/glutathione adduct (from a putative epoxide intermediate) with several minor isobaric regioisomers, and a carboxylic acid derived from the gem methyl hydroxylated bisphosphonate ring. 4. The structures proposed have not been confirmed by nmr due to discontinuation of the development of PNU-91638.

Absorption, distribution, metabolism, and excretion of atevirdine in the rat.

Atevirdine mesylate (U-87201E) is a highly specific nonnucleoside inhibitor of human immunodeficiency virus type 1 reverse transcriptase. The absorption, metabolism, and excretion of atevirdine were investigated in male and female Sprague-Dawley rats after oral administration of nonradiolabeled atevirdine mesylate at doses of 20 mg/kg/day or 200 mg/kg/day for 8 days, with [14C]atevirdine mesylate single doses of 10 mg/kg or 100 mg/kg on study days 1 and 10. The distribution of [14C]atevirdine mesylate was also evaluated by whole-body autoradiography in male and female Sprague-Dawley, pregnant Sprague-Dawley, and male Long-Evans rats after a single 10 mg/kg oral dose. Plasma levels of atevirdine and its N-desethyl and O-desmethyl metabolites were determined by high-performance liquid chromatography (HPLC) with ultraviolet detection, urine and feces were profiled for atevirdine and metabolites by HPLC with radiochemical detection, major metabolites in urine were isolated and identified by nuclear magnetic resonance and mass spectrometry, and minor urinary metabolites were identified by liquid chromatography/mass spectrometry. Atevirdine was rapidly absorbed. The pharmacokinetics of atevirdine were nonlinear. Gender differences in the pharmacokinetics and metabolism of atevirdine were observed, consistent with the involvement of cytochrome P450 3A. Atevirdine effectively crossed the blood-brain barrier and had a high rate of maternal-fetal transfer. At the low doses, <2% of the dose was excreted as unchanged parent drug, while atevirdine constituted 9%-25% of the dose at the high doses. The metabolism of atevirdine was extensive in the rat and involved N-deethylation, O-demethylation, hydroxylation at the C-6 position of the indole ring, and hydroxylation of the pyridine ring.

Pharmacokinetics, metabolism, and excretion of linezolid following an oral dose of [(14)C]linezolid to healthy human subjects.

Linezolid (Zyvox), the first of a new class of antibiotics, the oxazolidinones, is approved for treatment of Gram-positive bacterial infections, including resistant strains. The disposition of linezolid in human volunteers was determined, after a 500-mg (100-microCi) oral dose of [(14)C]linezolid. Radioactive linezolid was administered as a single dose, or at steady-state on day 4 of a 10-day, 500-mg b.i.d. regimen of unlabeled linezolid (n = 4/sex/regimen). Mean recovery of radioactivity in excreta was 93.8 +/- 1.1% (range 91.2-95.2%, n = 15), of which 83.9 +/- 3.3% (range 76.7-88.4%) was in urine and 9.9 +/- 3.4% (range 5.3-16.9%) was in feces. There was no major difference in rate or route of excretion of radioactivity by dose regimen. Linezolid was excreted primarily intact, and as two inactive, morpholine ring-oxidized metabolites, PNU-142586 and PNU-142300. Other minor metabolites were characterized by high-performance liquid chromatography-atmospheric pressure chemical ionization-mass spectrometry and (19)F NMR spectroscopy. After the single radioactive dose, linezolid was the major circulating drug-related material accounting for about 78% (male) and 93% (female) of the radioactivity area under the curve (AUC). PNU-142586 (T(max) of 3-5 h) accounted for about 26% (male) and 9% (female) of the radioactivity AUC. PNU-142300 (T(max) of 2-3 h) accounted for about 7% (male) and 4% (female) of the radioactivity AUC. Overall, mean linezolid and PNU-142586 exposures at steady-state were similar across sex. In conclusion, linezolid circulates in plasma mainly as parent drug. Linezolid and two major, inactive metabolites account for the major portion of linezolid disposition, with urinary excretion representing the major elimination route. Formation of PNU-142586 was the rate-limiting step in the clearance of linezolid.