Enhancing the drug metabolism activities of C3A--a human hepatocyte cell line--by tissue engineering within alginate scaffolds.

In this study, we investigated the applicability of C3A--a human hepatocyte cell line--as a predicting tool for drug metabolism by applying tissue-engineering methods. Cultivation of C3A cells within alginate scaffolds induced the formation of spheroids with enhanced drug metabolism activities compared to that of two-dimensional (2-D) monolayer cultures. The spheroid formation process was demonstrated via histology, immunohistochemistry, and transmission electron microscope (TEM) analyses. The C3A spheroids displayed multilayer cell morphology, characterized by a large number of tight junctions, polar cells, and bile canaliculi, similar to spheroids of primary hepatocytes. Spheroid formation was accompanied by a reduction in P-glycoprotein (Pgp) gene expression and C3A cell proliferation was limited mainly to cells on the spheroid outskirt. The 3-D constructs maintained a nearly constant cell number according to MTT assay. Drug metabolism by the two most important cytochrome p-450 (CYP) enzymes in human liver, CYP1A2 and CYP3A4, was tested using preferred drugs. With CYP1A2, 3-fold enhancement in activity per cell was seen for converting ethoxyresorufin to resorufin compared to C3A cell monolayers. The spheroids responded to the inducer beta-naphthoflavone and to the inhibitor furafylline of CYP1A2. Enhanced metabolizing activity of CYP3A4, measured by the amount 6beta-testosterone formed from testosterone, and that of the phase II enzyme glucuronosyltransferases (UGT) further indicated that the tissue-engineered C3A spheroids may provide an efficient experimental tool for predicting drug activities by these CYPs. Moreover, the maintenance of constant cell number, as well as the elevated hepatocellular functions and drug metabolism activities, suggest that the tissue-engineered C3A may be applicable in replacement therapies.

Exposure to diazinon alters in vitro retinogenesis: retinospheroid morphology, development of chicken retinal cell types, and gene expression.

Developing embryos are more vulnerable than adults to acute cholinergic intoxication by anticholinesterases, including organophosphorus pesticides. These agents affect the process of neural development itself, leading to permanent deficits in the architecture of the nervous system. Recent evidence on direct roles of acetylcholinesterase (AChE) on neuronal differentiation provides additional grounds for investigating the developmental toxicity of anticholinesterases. Therefore, the effect of the organophosphate diazinon on the development of chick retinal differentiation was studied by an in vitro reaggregate approach. Reaggregated spheres from dissociated retinal cells of the E6 chick embryo were produced in rotation culture. During the whole culture period of 10 days, experimental cultures were supplemented with different concentrations of the pesticide, from 20 to 120 microM diazinon. The pesticide-treated spheres were reduced in size, and their outer surface was irregular. More importantly, inner structural distortions could be easily traced because the structure of control spheroids can be well characterized by a histotypical arrangement of laminar parts homologous to the normal retina. Acetylcholinesterase activity in diazinon-treated spheres was reduced when compared with controls. As a dramatic effect of exposure to the pesticide, inner plexiform layer (IPL)-like areas in spheroids were not distinguishable anymore. Similarly, photoreceptor rosettes and Müller radial glia were strongly decreased, whereas apoptosis was stimulated. The expression of transcripts for choline-acetyltransferase and muscarinic receptors was affected, revealing an effect of diazinon on the cholinergic system. This further proves the significance of cholinesterases and the cholinergic system for proper nervous system development and shows that further studies of debilitating diazinon actions on development are necessary.