Pharmacokinetics of the Multi-kinase Inhibitor Pexidartinib: Mass Balance and Dose Proportionality.

Pexidartinib is an oral small-molecule tyrosine kinase inhibitor that selectively targets colony-stimulating factor 1 receptor. Two phase 1 single-center trials were conducted in healthy subjects to determine the absorption, distribution, metabolism, and excretion of pexidartinib using radiolabeled drug and to assess the dose proportionality of pexidartinib following single oral doses. In the mass balance study, eight male subjects received a single oral dose of [ C]-pexidartinib 400 mg with radioactivity assessed in plasma, urine, and feces samples taken at various timepoints postdose.

Species differences between rats and primates (humans and monkeys) in complex cleavage pathways of DS-8500a characterized by C-ADME studies in humans and monkeys after administration of two radiolabeled compounds and in vitro studies.

Our previous study in rats demonstrated that the metabolic pathways of DS-8500a, a novel GPR119 agonist, include cleavage pathways: reductive cleavage of the oxadiazole ring in the liver and hydrolysis of the amide side chain. In the present study, in vivo metabolic profiling in humans and monkeys after the oral administration of two C-labeled compounds was performed to investigate species differences of the cleavage pathways. In monkeys, the oxadiazole ring-cleaved metabolites were mainly detected in feces, but not observed in bile, unlike in rats, suggesting that the reductive ring-opening metabolism occurs in the gastrointestinal tract.

In vivo multiple metabolic pathways for a novel G protein-coupled receptor 119 agonist DS-8500a in rats: involvement of the 1,2,4-oxadiazole ring-opening reductive reaction in livers under anaerobic conditions.

A 1,2,4-oxadiazole ring-containing compound DS-8500a was developed as a novel G protein-coupled receptor 119 agonist. In vivo metabolic fates of [C]DS-8500a differently radiolabeled in the benzene ring or benzamide side carbon in rats were investigated. Differences in mass balances were observed, primarily because after the oxadiazole ring-opening and subsequent ring-cleavage small-molecule metabolites containing the benzene side were excreted in the urine, while those containing the benzamide side were excreted in the bile.

In vitro evaluation of the potential for drug-induced toxicity based on (35)S-labeled glutathione adduct formation and daily dose.

Background: Drug-induced toxicity such as idiosyncratic drug toxicity is believed to be reduced when either reactive metabolite formation or exposure to a drug is minimized. The objective of the present study was therefore to clarify the relationship between the daily doses, the formation rates of reactive metabolite adduct with (35)S-glutathione (RM-GS) and the safety profiles of compounds.

Results: The RM-GS formation rates for 113 test compounds were determined by incubation with human liver microsomes, and the test compounds were classified into three categories of safe, warning and withdrawn/black box warning.

Quantitative assessment of reactive metabolite formation using 35S-labeled glutathione.

The metabolic bioactivation of a drug to a reactive metabolite (RM) and its covalent binding to cellular macromolecules is believed to be involved in clinical adverse events, including idiosyncratic drug toxicities. Therefore, it is important to assess the potential of drug candidates to generate RMs and form drug-protein covalent adducts during lead optimization processes. In this study, the RM formation of some marketed drugs were quantitatively assessed by means of a sensitive and robust detection method that we have established using (35)S-glutathione ((35)S-GSH) as a trapping agent.

Covalent binding and tissue distribution/retention assessment of drugs associated with idiosyncratic drug toxicity.

Bioactivation of a drug to a reactive metabolite and its covalent binding to cellular macromolecules is believed to be involved in clinical adverse events, including idiosyncratic drug toxicities (IDTs). For the interpretation of the covalent binding data in terms of risk assessment, the in vitro and in vivo covalent binding data of a variety of drugs associated with IDTs or not were determined. Most of the "problematic" drugs, including "withdrawn" and "warning" drugs, exhibit higher human liver microsome (HLM) in vitro covalent binding yields than the "safe" drugs.

Prediction of in vivo potential for metabolic activation of drugs into chemically reactive intermediate: correlation of in vitro and in vivo generation of reactive intermediates and in vitro glutathione conjugate formation in rats and humans.

The covalent binding of reactive intermediates to macromolecules might have potential involvement in severe adverse drug reactions. Thus, quantification of reactive metabolites is necessary during the early stage of drug discovery to avoid serious toxicity. In this study, the relationship between covalent binding and glutathione (GSH) conjugate formation in rat and human liver microsomes were investigated using 10 representative radioactive compounds that have been reported as hepatotoxic or having other toxicity derived from their reactive intermediates: acetaminophen, amodiaquine, carbamazepine, clozapine, diclofenac, furosemide, imipramine, indomethacin, isoniazid, and tienilic acid, all at a concentration of 10 microM.