Characterization of Divergent Metabolic Pathways in Elucidating an Unexpected, Slow-Forming, and Long Half-Life Major Metabolite of Iclepertin.

PURPOSE: After single oral dosing of the glycine reuptake transporter (GlyT1) inhibitor, iclepertin (BI 425809), a single major circulating metabolite, M530a, was identified. However, upon multiple dosing, a second major metabolite, M232, was observed with exposure levels ~ twofold higher than M530a. Studies were conducted to characterize the metabolic pathways and enzymes responsible for formation of both major human metabolites. METHODS: In vitro studies were conducted with human and recombinant enzyme sources and enzyme-selective inhibitors. The production of iclepertin metabolites was monitored by LC-MS/MS. RESULTS: Iclepertin undergoes rapid oxidation to a putative carbinolamide that spontaneously opens to an aldehyde, M528, which then undergoes reduction by carbonyl reductase to the primary alcohol, M530a. However, the carbinolamide can also undergo a much slower oxidation by CYP3A to form an unstable imide metabolite, M526, that is subsequently hydrolyzed by a plasma amidase to form M232. This difference in rate of metabolism of the carbinolamine explains why high levels of the M232 metabolite were not observed in vitro and in single dose studies in humans, but were observed in longer-term multiple dose studies. CONCLUSIONS: The long half-life iclepertin metabolite M232 is formed from a common carbinolamine intermediate, that is also a precursor of M530a. However, the formation of M232 occurs much more slowly, likely contributing to its extensive exposure in vivo. These results highlight the need to employ adequate clinical study sampling periods and rigorous characterization of unexpected metabolites, especially when such metabolites are categorized as major, thus requiring safety assessment.

The Absolute Bioavailability, Absorption, Distribution, Metabolism, and Excretion of BI 425809 Administered as an Oral Dose or an Oral Dose with an Intravenous Microtracer Dose of [14C]-BI 425809 in Healthy Males.

BACKGROUND AND OBJECTIVES: BI 425809, a novel glycine transporter-1 inhibitor, may ameliorate cognitive deficits in schizophrenia. The objectives of the studies were: to assess absolute bioavailability of oral BI 425809 compared with intravenous (IV) microtracer infusion (study 1), and to determine the mass balance, distribution, metabolism, and excretion of BI 425809 (study 2). METHODS: These were Phase I, open-label, non-randomized, single-period, single-arm studies in healthy males. Study 1 administered a single oral dose of unlabeled BI 425809 25 mg, then an IV microtracer infusion of [14C]-BI 425809 30 µg. In study 2, participants received an oral dose of [14C]-BI 425809 25 mg containing [14C]-labeled (dose: 3.7 megabecquerel (0.41 mSv)) and unlabeled drug. Safety was assessed. RESULTS: In study 1 (n = 6), the absolute bioavailability of a 25 mg tablet of BI 425809 in a fasted state was 71.64%. The geometric mean dose-normalized maximum plasma concentration was approximately 80% lower after oral administration versus IV dose. In study 2 (n = 6), the total recovery of [14C]-BI 425809 was 96.7%, with ~ 48% of [14C]-radioactivity excreted in urine and ~ 48% excreted in feces. Among the labeled drug in urine, ~ 45% of the amount excreted was composed of BI 425809 (17.4%) and two metabolites (BI 758790, 21.0%; BI 761036, 5.9%). In feces, < 1% of BI 425809 was excreted as unchanged drug. In both studies, BI 425809 was generally well tolerated. CONCLUSIONS: After normalization, the absolute bioavailability of tablet-form BI 425809 was 71.64%. The total recovery of [14C]-BI 425809 25 mg was high (96.7%), with low intraindividual variability and similar amounts excreted in urine and feces. CLINICALTRIALS. GOV IDENTIFIERS: NCT03783000 and NCT03654170.

Identification of novel azaindazole CCR1 antagonist clinical candidates.

Exploring various cyclization strategies, using a submicromolar pyrazole HTS screening hit 6 as a starting point, a novel indazole based CCR1 antagonist core was discovered. This report presents the design and SAR of CCR1 indazole and azaindazole antagonists leading to the identification of three development compounds, including 19e that was advanced to early clinical trials.

Discovery and optimization of pyrazole amides as antagonists of CCR1.

A HTS screen for CCR1 antagonists afforded a novel sub-micromolar hit 5 containing a pyrazole core. In this report the design, optimization, and SAR of novel CCR1 antagonists based on a pyrazole core motif is presented. Optimization led to the advanced candidate compounds (S)-16q and (S)-16r with 250-fold improved CCR1 potency, excellent off-target selectivity and attractive drug-like properties.

Late-stage optimization of a tercyclic class of S1P3-sparing, S1P1 receptor agonists.

Poor solubility and cationic amphiphilic drug-likeness were liabilities identified for a lead series of S1P3-sparing, S1P1 agonists originally developed from a high-throughput screening campaign. This work describes the subsequent optimization of these leads by balancing potency, selectivity, solubility and overall molecular charge. Focused SAR studies revealed favorable structural modifications that, when combined, produced compounds with overall balanced profiles. The low brain exposure observed in rat suggests that these compounds would be best suited for the potential treatment of peripheral autoimmune disorders.

Optimization of drug-like properties of nonsteroidal glucocorticoid mimetics and identification of a clinical candidate.

A series of nonsteroidal "dissociated" glucocorticoid receptor agonists was optimized for drug-like properties such as cytochrome P450 inhibition, metabolic stability, aqueous solubility, and hERG ion channel inhibition. This effort culminated in the identification of the clinical candidate compound ( R )-39.

Identification of highly efficacious glucocorticoid receptor agonists with a potential for reduced clinical bone side effects.

Synthesis and structure-activity relationship (SAR) of a series of nonsteroidal glucocorticoid receptor (GR) agonists are described. These compounds contain "diazaindole" moieties and display different transcriptional regulatory profiles in vitro and are considered "dissociated" between gene transrepression and transactivation. The lead optimization effort described in this article focused in particular on limiting the transactivation of genes which result in bone side effects and these were assessed in vitro in MG-63 osteosarcoma cells, leading to the identification of (R)-18 and (R)-21. These compounds maintained anti-inflammatory activity in vivo in collagen induced arthritis studies in mouse but had reduced effects on bone relevant parameters compared to the widely used synthetic glucocorticoid prednisolone 2 in vivo. To our knowledge, we are the first to report on selective glucocorticoid ligands with reduced bone loss in a preclinical in vivo model.

Discovery and design of benzimidazolone based inhibitors of p38 MAP kinase.

A new class of benzimidazolone p38 MAP kinase inhibitors was discovered through high-throughput screening. X-ray crystallographic data of the lead molecule with p38 were used to design analogues with improved binding affinity and potency in a cell assay of LPS-induced TNFalpha production. Herein, we report the SAR of this new class of p38 inhibitors.

Free-radical-mediated conjugate additions. Enantioselective synthesis of butyrolactone natural products: (-)-enterolactone, (-)-arctigenin, (-)-isoarctigenin, (-)-nephrosteranic acid, and (-)-roccellaric acid.

Lewis acid-mediated conjugate addition of alkyl radicals to a differentially protected fumarate 10 produced the monoalkylated succinates with high chemical efficiency and excellent stereoselectivity. A subsequent alkylation or an aldol reaction furnished the disubstituted succinates with syn configuration. The chiral auxiliary, 4-diphenylmethyl-2-oxazolidinone, controlled the stereoselectivity in both steps. Manipulation of the disubstituted succinates obtained by alkylation furnished the natural products (-)-enterolactone, (-)-arctigenin, and (-)-isoarctigenin. The overall yields for the target natural products were 20-26% over six steps. Selective functionalization of the disubstituted succinates obtained by aldol condensation gave the paraconic acid natural products (-)-nephrosteranic acid (8) and (-)-roccellaric acid (9). The overall yield of the natural products 8 and 9 over four steps was 53% and 42%, respectively.