Discovery and Optimization of Orally Bioavailable Phthalazone and Cinnolone Carboxylic Acid Derivatives as S1P2 Antagonists against Fibrotic Diseases.

Idiopathic pulmonary fibrosis (IPF) is a chronic and progressive lung disease. Current treatments only slow down disease progression, making new therapeutic strategies compelling. Increasing evidence suggests that S1P2 antagonists could be effective agents against fibrotic diseases. Our compound collection was mined for molecules possessing substructure features associated with S1P2 activity. The weakly potent indole hit 6 evolved into a potent phthalazone series, bearing a carboxylic acid, with the aid of a homology model. Suboptimal pharmacokinetics of a benzimidazole subseries were improved by modifications targeting potential interactions with transporters, based on concepts deriving from the extended clearance classification system (ECCS). Scaffold hopping, as a part of a chemical enablement strategy, permitted the rapid exploration of the position adjacent to the carboxylic acid. Compound 38, with good pharmacokinetics and in vitro potency, was efficacious at 10 mg/kg BID in three different in vivo mouse models of fibrotic diseases in a therapeutic setting.

Discovery of the S1P2 Antagonist GLPG2938 (1-[2-Ethoxy-6-(trifluoromethyl)-4-pyridyl]-3-[[5-methyl-6-[1-methyl-3-(trifluoromethyl)pyrazol-4-yl]pyridazin-3-yl]methyl]urea), a Preclinical Candidate for the Treatment of Idiopathic Pulmonary Fibrosis.

Mounting evidence from the literature suggests that blocking S1P2 receptor (S1PR2) signaling could be effective for the treatment of idiopathic pulmonary fibrosis (IPF). However, only a few antagonists have been so far disclosed. A chemical enablement strategy led to the discovery of a pyridine series with good antagonist activity. A pyridazine series with improved lipophilic efficiency and with no CYP inhibition liability was identified by scaffold hopping. Further optimization led to the discovery of 40 (GLPG2938), a compound with exquisite potency on a phenotypic IL8 release assay, good pharmacokinetics, and good activity in a bleomycin-induced model of pulmonary fibrosis.

Targeted delivery via avidin fusion protein: intracellular fate of biotinylated doxorubicin derivative and cellular uptake kinetics and biodistribution of biotinylated liposomes.

In this study, avidin-biotin technology was combined with a multifunctional drug carrier modality i.e. liposomes to achieve an active and versatile targeting approach. The anti-cancer drug doxorubicin (DOX) was modified with direct biotinylation (B-DOX) (Allart et al., 2003), or encapsulated in biotinylated sterically stabilized pH-sensitive liposomes (BL-DOX), and targeted to the lentiviral vector transduced cells expressing an avidin fusion protein on the cell membrane (Lehtolainen et al., 2003; Lesch et al., 2009). The direct biotinylation of doxorubicin improved cell internalization in rat glioma (BT4C) cells expressing avidin fusion protein receptor but cell toxicity was reduced by 78-fold due to impaired nuclear localization. In contrast, liposomal formulations restored the biological activity of the DOX in several cell lines. However, mainly due to uptake via non-specific pathways the active targeting of BL-DOX was negligible in both in vitro and in vivo studies. Active targeting with multifunctional drug carrier systems is challenging and further studies will be needed to optimize the properties of targeted drug carrier and receptor expression systems.

Expediting drug discovery: recent advances in fast medicinal chemistry--optimization of hits and leads.

This article reviews the literature from January 2004 to January 2006 relating to the use of parallel chemistry compound libraries in drug discovery. Examples of libraries that have yielded active compounds across a range of biological targets are presented, together with synthetic details where relevant. The background of the biological target, and any structure-activity relationship that can be discerned from members of a library series, are also commented upon. A brief discussion of new technological developments in library design and synthesis, and likely future directions for parallel chemistry in the context of drug discovery, is also presented.

A stable bis-allyloxycarbonyl biotin aldehyde derivative for biotinylation via reductive alkylation: application to the synthesis of a biotinylated doxorubicin derivative.

A novel, stable, biotin aldehyde derivative is reported in which the biotin moiety is N1,N3-protected by the allyloxycarbonyl group. The derivative is stable to sodium cyanoborohydride mediated reductive alkylation and is cleaved under mild Pd [0] catalysis. This novel biotin aldehyde should have wide application in avidin- and streptavidin-based detection systems and bioassays. The derivative is utilized in the synthesis of a biotinylated doxorubicin analogue that retains topoisomerase activity.