Hepatocyte spheroids as a viable in vitro model for recapitulation of complex in vivo metabolism pathways of loratadine in humans.

Accurate prediction of in vivo metabolic pathways in humans can be challenging because in vitro liver matrices may fail to produce certain in vivo metabolites.Rat and human spheroids, generated from cryopreserved hepatocytes in media that contained minimal amount of serum, maintained morphology, viability and cytochrome P450 (CYP) activities for at least a week without media exchange.With spheroid cultures, multiple Phase I and Phase II metabolites were observed in rat and human spheroid cultures that were incubated with loratadine (LOR) for multiple days. Consistent with in vivo observations, 3-hydroxydesloratadine, (3-OH-DL), along with its glucuronide, were observed in human spheroids, but not in rat spheroids. Interestingly, the putative intermediate metabolite leading to 3-OH-DL, DL-N-glucuronide, was observed in incubations with both rat and human spheroids. In conclusion, hepatocyte spheroid were capable of recapitulating the inter-species differences in metabolism between human and rat for LOR, therefore, it may represent a viable model for studying complex metabolic pathways.

Effects of CYP inhibitors on precocene I metabolism and toxicity in rat liver slices.

We present a comprehensive in vitro approach to assessing metabolism-mediated hepatotoxicity using male Sprague-Dawley rat liver slices incubated with the well characterized hepatotoxicant, precocene I, and inhibitors of cytochrome P450 (CYP) enzymes. This approach combines liquid chromatography mass spectrometry (LC MS) detection methods with multiple toxicity endpoints to enable identification of critical metabolic pathways for hepatotoxicity. The incubations were performed in the absence and presence of the non-specific CYP inhibitor, 1-aminobenzotriazole (ABT) and isoform-specific inhibitors. The metabolite profile of precocene I in rat liver slices shares some features of the in vivo profile, but also had a major difference in that epoxide dihydrodiol hydrolysis products were not observed to a measurable extent. As examples of our liver slice metabolite identification procedure, a minor glutathione adduct and previously unreported 7-O-desmethyl and glucuronidated metabolites of precocene I are reported. Precocene I induced hepatocellular necrosis in a dose- and time-dependent manner. ABT decreased the toxicity of precocene I, increased exposure to parent compound, and decreased metabolite levels in a dose-dependent manner. Of the isoform-specific CYP inhibitors tested for an effect on the precocene I metabolite profile, only tranylcypromine was noticeably effective, indicating a role of CYPs 2A6, 2C9, 2Cl9, and 2E1. With respect to toxicity, the order of CYP inhibitor effectiveness was ABT>diethyldithiocarbamate∼tranylcypromine>ketoconazole. Furafylline and sulfaphenazole had no effect, while quinidine appeared to augment precocene I toxicity. These results suggest that rat liver slices do not reproduce the reported in vivo biotransformation of precocene I and therefore may not be an appropriate model for precocene I metabolism. However, these results provide an example of how small molecule manipulation of CYP activity in an in vitro model can be used to confirm metabolism-mediated toxicity.

Development and evaluation of a multiple-plate fraction collector for sample processing: application to radioprofiling in drug metabolism studies.

Microplate scintillation counters are utilized routinely in drug metabolism laboratories for the off-line radioanalysis of fractions collected during HPLC radioprofiling. In this process, the current fraction collection technology is limited by the number of plates that can be used per injection as well as the potential for sample loss due to dripping or spraying as the fraction collector head moves from well to well or between plates. More importantly, sample throughput is limited in the conventional process, since the collection plates must be manually exchanged after each injection. The Collect PAL, an innovative multiple-plate fraction collector, was developed to address these deficiencies and improve overall sample throughput. It employs a zero-loss design and has sub-ambient temperature control. Operation of the system is completely controlled with software and up to 24 (96- or 384-well) fraction collection plates can be loaded in a completely automated run. The system may also be configured for collection into various-sized tubes or vials. At flow rates of 0.5 or 1.0 mL/min and at collection times of 10 or 15s, the system precisely delivered 83-µL fractions (within 4.1% CV) and 250-µL fractions (within 1.4% CV), respectively, of three different mobile phases into 12 mm × 32 mm vials. Similarly, at a flow rate of 1 mL/min and 10s collection times, the system precisely dispensed mobile phase containing a [(14)C]-radiolabeled compound across an entire 96-well plate (% CV was within 5.3%). Triplicate analyses of metabolism test samples containing [(14)C]buspirone and its metabolites, derived from three different matrices (plasma, urine and bile), indicated that the Collect PAL produced radioprofiles that were reproducible and comparable to the current technology; the % CV for 9 selected peaks in the radioprofiles generated with the Collect PAL were within 9.3%. Radioprofiles generated by collecting into 96- and 384-well plates were qualitatively comparable; however, the peak resolution was greater in the profiles that were collected in 384-well plates due to the collection of a larger number of fractions per minute. In conclusion, this new and innovative fraction collector generated radioprofile results that were comparable to current technology and should provide a major improvement in capacity and throughput for radioprofiling studies.

Metabolism and excretion of an oral taxane analog, [14C]3'-tert-butyl-3'-N-tert-butyloxycarbonyl-4-deacetyl-3'-dephenyl-3'-N-debenzoyl-4-O-methoxy-paclitaxel (BMS-275183), in rats and dogs.

3'-tert-Butyl-3'-N-tert-butyloxycarbonyl-4-deacetyl-3'-dephenyl-3'-N-debenzoyl-4-O-methoxy-paclitaxel (BMS-275183) is a taxane analog that has the potential for oral use in the treatment of various types of cancer. In this study, the metabolism and excretion of [(14)C]BMS-275183 were evaluated after a single oral administration of [(14)C]BMS-275183 to rats and dogs (15 and 1 mg/kg, respectively). To aid metabolite identification by mass spectrometry (MS), a stable labeled (phenyl-(13)C(6)) BMS-275183 was included in 1:1 ratio of (13)C(6)/(12)C in the dose administration. Fecal excretion was the major route of elimination for [(14)C]BMS-275183 in both species (85-86 and <9% of the dose in feces and urine, respectively). The highest radioactivity in plasma was observed at 1 h postdose, suggesting rapid absorption of the drug in both species. The total radioactivity in plasma was measurable up to 24 h postdose. Metabolites were identified by liquid chromatography-MS and/or NMR spectroscopy. [(14)C]BMS-275183 was the prominent component in rat and dog plasma and was detected up to 24 h along with various oxidative and hydrolytic metabolites. [(14)C]BMS-275183 was extensively metabolized in both species, forming mainly oxidative metabolites, and unchanged parent drug accounted for <3.5% of the administered dose in urine and feces. The prominent metabolites resulted from oxidation of the tert-butyl groups on the side chain and further oxidation and cyclization of the tert-butylhydroxylated metabolites. A total of 30 oxidative metabolites including M13, a prominent ester cleavage metabolite, were identified in rat and dog samples.

CYP3A4-mediated ester cleavage as the major metabolic pathway of the oral taxane 3'-tert-butyl-3'-N-tert-butyloxycarbonyl-4-deacetyl-3'-dephenyl-3'-N-debenzoyl-4-O-methoxycarbonyl-paclitaxel (BMS-275183).

3'-tert-Butyl-3'-N-tert-butyloxycarbonyl-4-deacetyl-3'-dephenyl-3'-N-debenzoyl-4-O-methoxycarbonyl-paclitaxel (BMS-275183) is an orally available taxane analog that has the potential to be used as an oral agent to treat cancers. The compound is similar to the two clinically intravenously administered taxanes, paclitaxel and docetaxel, in that it contains a baccatin ring linked to a side chain through an ester bond. Unlike the other taxanes, the hydrolysis of this ester bond leads to formation of a free baccatin core (M13) that was the major metabolism pathway in incubations of [(14)C]BMS-275183 in human liver microsomes (HLMs) in the presence of NADPH, but it was not formed in incubations with human liver cytosol or HLM in the absence of NADPH. The other prominent metabolites formed in HLM incubations resulted from oxidation of t-butyl groups on the side chain (M20, M20B, M21, M22, and M23). All these metabolites were formed by cDNA-expressed CYP3A and not by other cytochrome P450 (P450) enzymes tested. Formation of these metabolites was selectively inhibited by ketoconazole and troleandomycin. The formation of M13 followed Michaelis-Menten kinetics with the K(m) values of 1.3 to 2.4 muM in HLM or CYP3A4; the V(max) value for the formation of M13 and M23 in the cDNA-expressed CYP3A4 matched well (within 2-fold difference) with that determined in HLM when expressed in units of per picomole of P450. These results showed that BMS-275183 is metabolized by CYP3A4 to yield baccatin through oxidation of side-chain t-butyl groups. An intramolecular cyclization of a side-chain hydroxylation metabolite is proposed to be responsible for the formation of M13, the side-chain hydrolysis metabolite.

Biotransformation profiling of [(14)C]ixabepilone in human plasma, urine and feces samples using accelerator mass spectrometry (AMS).

Ixabepilone (BMS-247550, Ixempra is a semi-synthetic analog of the natural product epothilone B and marketed for its use in the treatment of cancer. A conventional human ADME study using decay counting methods for (14)C detection could not be conducted due to the radiolytic instability of [(14)C]ixabepilone at a typical specific activity (generally 1-10 microCi/mg). However, [(14)C]ixabepilone was sufficiently stable at low specific activity (1-2 nCi/mg). These low levels required the use of accelerator mass spectrometry (AMS) for radioactivity detection. The metabolic fate of this compound was investigated in eight patients following single intravenous doses of [(14)C]ixabepilone (70 mg, 80 nCi; specific activity: 1.14 nCi/mg). Metabolite profiles in pooled urine, feces and plasma samples were determined by HPLC-AMS analysis. The major radioactive component in urine and plasma was [(14)C]ixabepilone. Feces had a small amount of ixabepilone. There were numerous other drug-related components in both urine and fecal extracts (each <6% of the administered dose). LC/MS analysis of plasma, urine and feces samples showed the presence of three degradants of ixabepilone and several oxidative metabolites (M+16, M+14 and M-2 metabolites). This study demonstrates the utility of AMS in investigating the metabolite and excretion profiles of [(14)C]ixabepilone following administration to humans.

The effect of ketoconazole on the pharmacokinetics and pharmacodynamics of ixabepilone: a first in class epothilone B analogue in late-phase clinical development.

PURPOSE: To determine if ixabepilone is a substrate for cytochrome P450 3A4 (CYP3A4) and if its metabolism by this cytochrome is clinically important, we did a clinical drug interaction study in humans using ketoconazole as an inhibitor of CYP3A4. EXPERIMENTAL DESIGN: Human microsomes were used to determine the cytochrome P450 enzyme(s) involved in the metabolism of ixabepilone. Computational docking (CYP3A4) studies were done for epothilone B and ixabepilone. A follow-up clinical study was done in patients with cancer to determine if 400 mg/d ketoconazole (inhibitor of CYP3A4) altered the pharmacokinetics, drug-target interactions, and pharmacodynamics of ixabepilone. RESULTS: Molecular modeling and human microsomal studies predicted ixabepilone to be a good substrate for CYP3A4. In patients, ketoconazole coadministration resulted in a maximum ixabepilone dose administration to 25 mg/m(2) when compared with single-agent therapy of 40 mg/m(2). Coadministration of ketoconazole with ixabepilone resulted in a 79% increase in AUC(0-infinity). The relationship of microtubule bundle formation in peripheral blood mononuclear cells to plasma ixabepilone concentration was well described by the Hill equation. Microtubule bundle formation in peripheral blood mononuclear cells correlated with neutropenia. CONCLUSIONS: Ixabepilone is a good CYP3A4 substrate in vitro; however, in humans, it is likely to be cleared by multiple mechanisms. Furthermore, our results provide evidence that there is a direct relationship between ixabepilone pharmacokinetics, neutrophil counts, and microtubule bundle formation in PBMCs. Strong inhibitors of CYP3A4 should be used cautiously in the context of ixabepilone dosing.