Setup of human liver-chips integrating 3D models, microwells and a standardized microfluidic platform as proof-of-concept study to support drug evaluation.

Human 3D liver microtissues/spheroids are powerful in vitro models to study drug-induced liver injury (DILI) but the small number of cells per spheroid limits the models' usefulness to study drug metabolism. In this work, we scale up the number of spheroids on both a plate and a standardized organ-chip platform by factor 100 using a basic method which requires only limited technical expertise. We successfully generated up to 100 spheroids using polymer-coated microwells in a 96-well plate (= liver-plate) or organ-chip (= liver-chip). Liver-chips display a comparable cellular CYP3A4 activity, viability, and biomarker expression as liver spheroids for at least one week, while liver-plate cultures display an overall reduced hepatic functionality. To prove its applicability to drug discovery and development, the liver-chip was used to test selected reference compounds. The test system could discriminate toxicity of the DILI-positive compound tolcapone from its less hepatotoxic structural analogue entacapone, using biochemical and morphological readouts. Following incubation with diclofenac, the liver-chips had an increased metabolite formation compared to standard spheroid cultures. In summary, we generated a human liver-chip model using a standardized organ-chip platform which combines up to 100 spheroids and can be used for the evaluation of both drug safety and metabolism.

Discovery of a Potent, Orally Bioavailable PI4KIIIß Inhibitor (UCB9608) Able To Significantly Prolong Allogeneic Organ Engraftment in Vivo.

The primary target of a novel series of immunosuppressive 7-piperazin-1-ylthiazolo[5,4- d]pyrimidin-5-amines was identified as the lipid kinase, PI4KIIIß. Evaluation of the series highlighted their poor solubility and unwanted off-target activities. A medicinal chemistry strategy was put in place to optimize physicochemical properties within the series, while maintaining potency and improving selectivity over other lipid kinases. Compound 22 was initially identified and profiled in vivo, before further modifications led to the discovery of 44 (UCB9608), a vastly more soluble, selective compound with improved metabolic stability and excellent pharmacokinetic profile. A co-crystal structure of 44 with PI4KIIIß was solved, confirming the binding mode of this class of inhibitor. The much-improved in vivo profile of 44 positions it as an ideal tool compound to further establish the link between PI4KIIIß inhibition and prolonged allogeneic organ engraftment, and suppression of immune responses in vivo.

Comparative analysis of CYP3A heteroactivation by steroid hormones and flavonoids in different in vitro systems and potential in vivo implications.

A systematic analysis of the heteroactivation of CYP3A-mediated carbamazepine 10,11-epoxidation has been investigated in three different in vitro systems, namely recombinant CYP3A4 and CYP3A5, human liver microsomes (HLMs) and cryopreserved human hepatocytes. The effect of 10 endogenous steroids and flavonoids was studied over a range of substrate and effector concentrations. A novel heteroactivation model was used to obtain the parameters EC(200) (concentration of effector required to produce 200% control) and heteroactivation ratio (the ratio of maximum observed reaction velocity to control). The EC(200) values obtained in HLMs and human hepatocytes were corrected for nonspecific binding. Heteroactivation of CYP3A5 has been demonstrated with mean heteroactivation ratios in CYP3A5, HLMs and hepatocytes on average 2-fold greater than in recombinant CYP3A4 for most of the effectors investigated. In recombinant CYP3A4, heteroactivation was greatest at substrate concentrations below K(m). Heteroactivation increased with effector concentration in a nonlinear manner and differed between effectors (mean heteroactivation ratios varied up to 12-fold). A greater extent of heteroactivation was observed in HLMs than in human hepatocytes for steroid effectors, but the opposite was true for flavonoid effectors. The observed heteroactivation of CYP3A in intact cells supports an in vivo relevance. From the in vitro heteroactivation data, a significant increase in clearance in vivo was predicted for substrates with a high dependence on CYP3A4 to the overall elimination, indicating that heteroactivation of CYP3A may be a potential source of interindividual variability.