James Mitroka

Comparative Metabolism of 14C-Labeled Apixaban in Mice, Rats, Rabbits, Dogs, and Humans

The metabolism and disposition of [14C]apixaban, a potent, reversible, and direct inhibitor of coagulation factor Xa, were investigated in mice, rats, rabbits, dogs, and humans after a single oral administration and in incubations with hepatocytes. In plasma, the parent compound was the major circulating component in mice, rats, dogs, and humans. O-Demethyl apixaban sulfate (M1) represented approximately 25% of the parent area under the time curve in human plasma. This sulfate metabolite was present, but in lower amounts relative to the parent, in plasma from mice, rats, and dogs. Rabbits showed a plasma metabolite profile distinct from that of other species with apixaban as a minor component and M2 (O-demethyl apixaban) and M14 (O-demethyl apixaban glucuronide) as prominent components. The fecal route was a major elimination pathway, accounting for >54% of the dose in animals and >46% in humans. The urinary route accounted for <15% of the dose in animals and 25 to 28% in humans. Apixaban was the major component in feces of every species and in urine of all species except rabbit. M1 and M2 were common prominent metabolites in urine and feces of all species as well as in bile of rats and humans. In vivo metabolite profiles showed quantitative differences between species and from in vitro metabolite profiles, but all human metabolites were found in animal species. After intravenous administration of [14C]apixaban to bile duct-cannulated rats, the significant portion (approximately 22%) of the dose was recovered as parent drug in the feces, suggesting direct excretion of the drug from gastrointestinal tracts of rats. Overall, apixaban was effectively eliminated via multiple elimination pathways in animals and humans, including oxidative metabolism, and direct renal and intestinal excretion.

Comparative Metabolism of Radiolabeled Muraglitazar in Animals and Humans by Quantitative and Qualitative Metabolite Profiling

Muraglitazar (Pargluva), a dual α/γ peroxisome proliferator-activated receptor (PPAR) activator, has both glucose- and lipid-lowering effects in animal models and in patients with diabetes. This study describes the in vivo and in vitro comparative metabolism of [14C]muraglitazar in rats, dogs, monkeys, and humans by quantitative and qualitative metabolite profiling. Metabolite identification and quantification methods used in these studies included liquid chromatography/mass spectrometry (LC/MS), LC/tandem MS, LC/radiodetection, LC/UV, and a newly described mass defect filtering technique in conjunction with high resolution MS. After oral administration of [14C]muraglitazar, absorption was rapid in all species, reaching a concentration peak for parent and total radioactivity in plasma within 1 h. The most abundant component in plasma at all times in all species was the parent drug, and no metabolite was present in greater than 2.5% of the muraglitazar concentrations at 1 h postdose in rats, dogs, and humans. All metabolites observed in human plasma were also present in rats, dogs, or monkeys. Urinary excretion of radioactivity was low (<5% of the dose) in all intact species, and the primary route of elimination was via biliary excretion in rats, monkeys, and humans. Based on recovered doses in urine and bile, muraglitazar showed a very good absorption in rats, monkeys, and humans. The major drug-related components in bile of rats, monkeys, and humans were glucuronides of muraglitazar and its oxidative metabolites. The parent compound was a minor component in bile, suggesting extensive metabolism of the drug. In contrast, the parent drug and oxidative metabolites were the major components in feces, and no glucuronide conjugates were found, suggesting that glucuronide metabolites were excreted in bile and hydrolyzed in the gastrointestinal tract. The metabolites of muraglitazar resulted from both glucuronidation and oxidation. The metabolites in general had greatly reduced activity as PPARα/γ activators relative to muraglitazar. In conclusion, muraglitazar was rapidly absorbed, extensively metabolized through glucuronidation and oxidation, and mainly eliminated in the feces via biliary excretion of glucuronide metabolites in all species studied. Disposition and metabolic pathways were qualitatively similar in rats, dogs, monkeys, and humans.

Oral Bioavailability and Disposition of [14C]Omapatrilat in Healthy Subjects

The objective of this study was to determine the absolute oral bioavailability and disposition of omapatrilat. This singledose, randomized, crossover study of 20 mg intravenous and 50 mg oral [14C]omapatrilat was conducted in 12 healthy male subjects to determine the disposition and oral bioavailability of omapatrilat, an orally active vasopeptidase inhibitor. Blood samples were collected up to 120 hours, and the excreta were collected over 168 hours postdose. Plasma concentrations of omapatrilat were determined by a validated LC/MS/MS procedure. Radioactivity in blood, plasma, urine, and feces was determined by liquid scintillation counting. Urinary excretion of radioactivity averaged 80% and 64% of intravenous and oral doses, respectively; < 1% of oral dose was excreted unchanged in urine. The absolute oral bioavailability of omapatrilat averaged 31%. Total body clearance of omapatrilat (80 L/h) exceeded liver plasma flow. Apparent steady‐state volume of distribution of omapatrilat (21 L/kg) was extremely high compared with total body water. Omapatrilat undergoes substantial presystemic first‐pass metabolism after oral administration. Omapatrilat is eliminated primarily by metabolism, and its metabolites are eliminated primarily in urine. Extrahepatic organs may be involved in the elimination of omapatrilat. Plasma concentrations of omapatrilat exhibit a prolonged terminal elimination phase, which represents elimination from a deep compartment.

METABOLISM OF [14C]GEMOPATRILAT AFTER ORAL ADMINISTRATION TO RATS, DOGS, AND HUMANS

This study describes the pharmacokinetic parameters of gemopatrilat, a potent vasopeptidase inhibitor, in humans and the comparative biotransformation of the compound in rats, dogs, and humans after administration of a single oral dose of [14C]gemopatrilat. Gemopatrilat was rapidly absorbed in humans with an oral bioavailability of 49%. Within 5 h after dose, the mean concentrations of gemopatrilat were less than 1% of the mean Cmax values. The total area under the first-moment time curve extrapolated to infinity [AUC(INF)] value for gemopatrilat was only 2% of the AUC(INF) of radioactivity in plasma. Gemopatrilat showed a large apparent steady-state volume of distribution (2500 liters) and a prolonged terminal-phase decline in plasma concentration. These results are consistent with the idea that the free sulfhydryl group of gemopatrilat forms reversible disulfide linkages with plasma and tissue proteins and is thus eliminated from the body at a very slow rate. Approximately half of the drug-related radioactivity in 1-h plasma samples from rat, dog, and human was reduced chemically with dithiothreitol to gemopatrilat, suggesting that disulfide linkage occurred in all species. In addition, metabolites formed through S-methylation and amide hydrolysis were also detected in rat, dog, and human plasma. No gemopatrilat was detected in urine and fecal samples from all three species, indicating that the compound is extensively metabolized in vivo. The major metabolites identified in human urine and feces were also present in rat and dog. These data suggest that the metabolism of gemopatrilat in all three species were qualitatively very similar.

In Vitro and In Vivo Metabolism of a Gamma-Secretase Inhibitor BMS-299897 and Generation of Active Metabolites in Milligram Quantities with a Microbial Bioreactor

BMS-299897 is a gamma-secretase inhibitor that has the potential for treatment of Alzheimers disease. The metabolism of [(14)C]BMS-299897 was investigated in human liver microsomes, in rat, dog, monkey and human hepatocytes and in bile duct cannulated rats. Seven metabolites (M1-M7) were identified from in vitro and in vivo studies. LC-MS/MS analysis showed that M1 and M2 were regioisomeric acylglucuronide conjugates of BMS-299897. Metabolites M3, M4 and M6 were identified as monohydroxylated metabolites of BMS-299897 and M5 was identified as the dehydrogenated product of monooxygenated BMS-299897. In vivo, 52% of the radioactive dose was excreted in bile within 0-6 h from bile duct cannulated rats following a single oral dose of 15 mg/kg of [(14)C]BMS-299897. Glucuronide conjugates, M1 and M2 accounted for 80% of the total radioactivity in rat bile. In addition to M1 and M2, M7 was observed in rat bile which was identified as a glucuronide conjugate of an oxidative metabolite M5. For structure elucidation and pharmacological activity testing of the metabolites, ten microbial cultures were screened for their ability to metabolize BMS-299897 to form these metabolites. Among them, the fungus Cunninghamella elegans produced two major oxidative metabolites M3 and M4 that had the same HPLC retention time and mass spectral properties as those found in in vitro incubations. NMR analysis indicated that M3 and M4 were stereoisomers, with the hydroxyl group on the benzylic position. However, M3 and M4 were unstable and converted to their corresponding lactones readily. Based on x-ray analysis of the synthetically prepared lactone of M3, the stereochemistry of benzylic hydroxyl group was assigned as the R configuration. Both the hydroxy metabolites (M3 and M4) and the lactone of M3 showed gamma-secretase inhibition with IC(50) values similar to that of the parent compound. This study demonstrates the usefulness of microbial systems as bioreactors to generate metabolites of BMS-299897 in large quantities for structure elucidation and activity testing. This study also demonstrates the biotransformation profile of BMS-299897 is qualitatively similar across the species including rat, dog, monkey and human which provides a basis to support rat, dog and monkey as preclinical models for toxicological testing.

Cerebrospinal Fluid Retrieval in the Conscious Dog: A Methods Development Study

A chronic cerebrospinal fluid access system is described for use in the conscious sling-restrained dog. In a pilot study of ten dogs, a fenestrated barium-impregnated silastic catheter was surgically implanted in the subarachnoid space of the second cervical vertebra through a dorsal laminectomy. This fenestrated catheter was coupled to a subcutaneous access port. Following surgery, cerebrospinal fluid was sampled weekly and evaluated for protein content and cytology. The cerebrospinal fluid albumin to serum albumin ratio was calculated for each sample to evaluate blood-brain barrier integrity. The instrumentation was successfully implanted in five of the first eight dogs using a midbody dorsal laminectomy. Cerebrospinal fluid access was maintained in these dogs for 21 +/- 10 days. Using a slight modification of the original technique, the final two dogs were instrumented through a caudodorsal laminectomy of the second cervical vertebra. The cerebrospinal fluid access system remains patent after 444 days of study in these two dogs. Necropsy evaluation suggested that catheter failure in the immediate postoperative period was due to gross malposition of the catheter. Chronic catheter failure occurred secondary to obstruction by local fibrous tissue reaction. Using this instrumentation, a pharmacokinetic evaluation of the plasma and cerebrospinal fluid deposition of an intravenous bolus of acyclovir was successfully performed twice in a single dog without complications. This instrumentation could provide chronic cerebrospinal fluid access for multiple pharmacokinetic studies in the conscious dog.