Application of a Micropatterned Cocultured Hepatocyte System To Predict Preclinical and Human-Specific Drug Metabolism.

Laboratory animal models are the industry standard for preclinical risk assessment of drug candidates. Thus, it is important that these species possess profiles of drug metabolites that are similar to those anticipated in human, since metabolites also could be responsible for biologic activities or unanticipated toxicity. Under most circumstances, preclinical species reflect human in vivo metabolites well; however, there have been several notable exceptions, and understanding and predicting these exceptions with an in vitro system would be very useful.

Bioactivation and toxicity of acetaminophen in a rat hepatocyte micropatterned coculture system.

We have recently shown that primary rat hepatocytes organized in micropatterned cocultures with murine embryonic fibroblasts (HepatoPac™) maintain high levels of liver functions for at least 4 weeks. In this study, rat HepatoPac was assessed for its utility to study chemical bioactivation and associated hepatocellular toxicity. Treatment of HepatoPac cultures with acetaminophen (APAP) over a range of concentrations (0-15 mM) was initiated at 1, 2, 3, or 4 weeks followed by the assessment of morphological and functional endpoints.

Long-term stability of primary rat hepatocytes in micropatterned cocultures.

Primary hepatocytes display functional and structural instability in standard monoculture systems. We have previously developed a model in which primary hepatocytes are organized in domains of empirically optimized dimensions and surrounded by murine embryonic fibroblasts (HepatoPac™). Here, we assess the long-term phenotype of freshly isolated and cryopreserved rat hepatocytes in a 96-well HepatoPac format.

Use of micropatterned cocultures to detect compounds that cause drug-induced liver injury in humans.

Because drug-induced liver injury (DILI) remains a major reason for late-stage drug attrition, predictive assays are needed that can be deployed throughout the drug discovery process. Clinical DILI can be predicted with a sensitivity of ~50% and a false positive (FP) rate of ~5% using 24-h cultures of sandwich-cultured primary human hepatocytes and imaging of four cell injury endpoints (Xu et al., 2008).

Assessment of a micropatterned hepatocyte coculture system to generate major human excretory and circulating drug metabolites.

Metabolism is one of the important determinants of the overall disposition of drugs, and the profile of metabolites can have an impact on efficacy and safety. Predicting which drug metabolites will be quantitatively predominant in humans has become increasingly important in the research and development of new drugs. In this study, a novel micropatterned hepatocyte coculture system was evaluated for its ability to generate human in vivo metabolites.