, 2007,

Lecluyse et al., 2012 and Mingoia et al., 2007). However, these modifications, while increasing CYP activities and prolonging the functional lifespan of primary hepatocytes to a certain extent, do not recapitulate all the important functions of the liver, mainly because of the lack of hepatic non-parenchymal cells (NPC; Hasmall et al., 2001 and Roberts et al., 2007). Substantial improvements in hepatocyte in vitro models were achieved by the development of more complex human liver systems created by co-culturing of parenchymal ITF2357 cost cells (PC) with NPC or other cell types. For example, human hepatocytes in a 2D micro-patterned co-culture with mouse 3 T3-J2 fibroblasts ( Khetani and Bhatia, 2008) maintained hepatocellular function for several weeks. Yet, the model may not be physiologically relevant for detection of species-specific Natural Product Library drug toxicity due to the lack of other liver NPC and the fact that a mouse embryonic fibroblast cell line is used for stabilization of human hepatocyte function ( Hasmall et al., 2001 and Roberts et al., 2007). In this regard, hepatic stellate cells (HSC) and Kupffer cells play a key role in modulating

DILI, including idiosyncratic toxicity and hepatocarcinogenesis, probably due to the release of inflammatory mediators, growth factors and reactive oxygen species after their activation by drugs ( Hasmall et al., 2001, Lecluyse et al., 2012 and Roberts et al., 2007). More sophisticated models containing hepatocytes and NPC are the 3D liver co-culture bioreactors Dimethyl sulfoxide ( Dash et al., 2009, Gerlach et al., 2003, Sivaraman et al., 2005 and Zeilinger et al., 2011). These models can be kept in culture for several weeks but due to their complexity may not be suited for drug testing in pharmaceutical industry. At present only few human co-culture models are

available which can be used for drug-safety assessment (Dash et al., 2009, Khetani and Bhatia, 2008 and Naughton et al., 1994). There is an urgent need to establish and validate human in vitro liver models able to produce clinically-relevant data. We therefore characterized a 3D liver culture model using both human and rat primary cells and evaluated its suitability to assess DILI potential in vitro. The model originally described by Naughton and co-workers is based on an industry-standard multiwell format and is therefore amenable to higher-throughput testing ( Naughton et al., 1994 and Naughton et al., 1995). We show that hepatocytes inoculated into a pre-established NPC culture grown on 3D nylon scaffolds can be kept in culture for up to 3 months while maintaining some important hepatic functions and metabolic CYP activities. This allows exposure to compounds over longer time and allows repeated drug-treatments which are not possible using short-term 2D hepatocyte cultures or other currently available 3D models.