When designing an extracorporeal hybrid liver support device, special attention should be paid to providing the architectural basis for reconstructing a proper cellular microenvironment that ensures highest and prolonged functional activity of the liver cells. The common goal is to achieve high cell density culture and to design the bioreactor for full-scale primary liver cell cultures under adequate mass transfer conditions. An important aim of this study was to evaluate the biochemical performance of a flat membrane bioreactor that permits high-density hepatocyte culture and simultaneously to culture cells under sufficient oxygenation availability conditions comparable to the in vivo-like microenvironment. In such a bioreactor pig liver cells were cultured within an extracellular matrix between oxygen-permeable flat-sheet membranes. In this investigation we used a novel scaled-up prototype consisting of up to 20 modules in a parallel mode. Each module was seeded with 2 x 10(8) cells. Microscopic examination of the hepatocytes revealed morphological characteristics as found in vivo. Cell concentration increased in the first days of culture, as indicated by DNA measurements. The performance of the bioreactor was monitored for 18 days in terms of albumin synthesis, urea synthesis, ammonia elimination, and diazepam metabolism. The ability of the hepatocytes to synthesize albumin and urea increased during the first days of culture. Higher rates of albumin synthesis were obtained at day 9 and remained at a value of 1.41 pg/h/cell until day 18 of culture. The rate of urea synthesis increased from 23 ng/h/cell to 28 ng/h/cell and then remained constant. Cells eliminated ammonia at a rate of about 56 pg/h/cell, which was constant over the experimental period. Hepatocytes in the bioreactor metabolized diazepam and generated three different metabolites: nordiazepam, temazepam, and oxazepam. The production of such metabolites was sustained until 18 days of culture. These results demonstrated that the scale-up of the bioreactor was assessed, and it could be demonstrated that the device design aimed at the reconstruction of the liver-specific tissue architecture supported the expression of liver-specific functions of primary pig liver cells.
New Zn(II)-curcumin based heteroleptic complexes (1-5) have been synthesized and fully characterized, with the aim to improve the bioactivity of the precursor derivative [(bpy-9)Zn(curc)Cl] (A), a potentially intercalating antitumor agent recently reported. Some structural changes have been made starting from the reference complex A, in order to introduce new functionalities, such as electrostatic and/or covalent interactions. In particular, keeping the same N,N chelating ligand, namely bpy-9, two completely different Zn(II) species have been obtained: a tetracoordinated Zn(II) cation with tetrafluoroborate as counterion (1) and a dimeric neutral complex in which the sulfate anion acts as a bridging group through two Zn(II) centres (2). Moreover, by changing the N,N chelating unit, [(L(n))Zn(curc)Cl] complexes (3-5), in which the Zn(II) ion shows the same pentacoordination seen in the precursor complex A, have been obtained. The antitumour activity of all new Zn(II) complexes was tested in vitro against the human neuroblastoma cell line SH-SY5Y in a biohybrid membrane system and the results indicate that all species exhibit strong cytotoxic activity. In particular the ionic tetrafluoroborate Zn(II) complex, 1, and the neutral phenanthroline based Zn(II) derivative, 4, show the strongest growth inhibition, being even more effective than the model complex A. Both complexes have a dose-dependent anti-proliferative effect on cells as demonstrated by the decrease of viability and the increase of Annexin V and PI-positive cells with the increase of their concentration. Cells treated with complexes 1 and 4 undergo apoptosis that involves the activation of JNK, caspase 3 and MMP changes. Finally, complex 1 is more effective in the induction of caspase-3 activation demonstrating its ability to trigger the execution-phase of cell apoptosis.
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