BACKGROUND: Currently, there is an urgent need for scalable and reliable in vitro models to assess the effects oftherapeutic entities on the human liver. Hepatoma cell lines, including Huh-7, show weakly resemblance to humanhepatocytes, limiting their significance in toxicity studies. Co-culture of hepatic cells with non-parenchymal cells, and thepresence of extracellular matrix have been shown to influence the biological behavior of hepatocytes. The aim of this studywas to generate the scalable and functional hepatic micro-tissues (HMTs). METHODS: The size-controllable HMTs were generated through co-culturing of Huh-7 cells by mesenchymal stem cellsand human umbilical vein endothelial cells in a composite hydrogel of liver-derived extracellular matrix and alginate, usingan air-driven droplet generator. RESULTS: The generated HMTs were functional throughout a culture period of 28 days, as assessed by monitoringglycogen storage, uptake of low-density lipoprotein and indocyanine green. The HMTs also showed increased secretionlevels of albumin, alpha-1-antitrypsin, and fibrinogen, and production of urea. Evaluating the expression of genes involvedin hepatic-specific and drug metabolism functions indicated a significant improvement in HMTs compared to two-dimensional(2D) culture of Huh-7 cells. Moreover, in drug testing assessments, HMTs showed higher sensitivity tohepatotoxins compared to 2D cultured Huh-7 cells. Furthermore, induction and inhibition potency of cytochrome P450enzymes confirmed that the HMTs can be used for in vitro drug screening. CONCLUSION Overall, we developed a simple and scalable method for generation of liver micro-tissues, using Huh-7,with improved hepatic-specific functionality, which may represent a biologically relevant platform for drug studies.

BACKGROUND: Currently, there is an urgent need for scalable and reliable in vitro models to assess the effects oftherapeutic entities on the human liver. Hepatoma cell lines, including Huh-7, show weakly resemblance to humanhepatocytes, limiting their significance in toxicity studies. Co-culture of hepatic cells with non-parenchymal cells, and thepresence of extracellular matrix have been shown to influence the biological behavior of hepatocytes. The aim of this studywas to generate the scalable and functional hepatic micro-tissues (HMTs). METHODS: The size-controllable HMTs were generated through co-culturing of Huh-7 cells by mesenchymal stem cellsand human umbilical vein endothelial cells in a composite hydrogel of liver-derived extracellular matrix and alginate, usingan air-driven droplet generator. RESULTS: The generated HMTs were functional throughout a culture period of 28 days, as assessed by monitoringglycogen storage, uptake of low-density lipoprotein and indocyanine green. The HMTs also showed increased secretionlevels of albumin, alpha-1-antitrypsin, and fibrinogen, and production of urea. Evaluating the expression of genes involvedin hepatic-specific and drug metabolism functions indicated a significant improvement in HMTs compared to two-dimensional(2D) culture of Huh-7 cells. Moreover, in drug testing assessments, HMTs showed higher sensitivity tohepatotoxins compared to 2D cultured Huh-7 cells. Furthermore, induction and inhibition potency of cytochrome P450enzymes confirmed that the HMTs can be used for in vitro drug screening. CONCLUSION Overall, we developed a simple and scalable method for generation of liver micro-tissues, using Huh-7,with improved hepatic-specific functionality, which may represent a biologically relevant platform for drug studies.

Endometriosis is a common, benign gynecological disease which is determined as an overspreading of endometrial tissue in exterior region of the uterine cavity. Evidence suggests that retrograde menstrual blood which contains mesenchymal stem cells with differential gene expression compared to healthy women may play a role in endometriosis creation. We aimed to identify whether the conditioned medium (CM) from menstrual blood-derived mesenchymal stem cells (MenSCs) of healthy women can affect the expression level of inf lammatory and stemness genes of MenSCs from endometriosis women. Endometriosis-derived MenSCs (E-MenSCs) were treated with CM derived from healthy women’s MenSCs (non-endometriosis derived MenSCs [NE-MenSCs]). Some CD markers were analyzed by flow cytometer before and after treatment compared with NE-MenSCs, and the expression level of inflammatory and stemness genes was evaluated by real-time PCR. E-MenSCs show different morphology in vitro culture in comparison with NE-MenSCs, which were changed in the presence of CM, into a morphology more similar to normal cells and showed significant decrease expression of CD10 after CM treatment. In our results, the interleukin-1, cyclooxygenase-2, and hypoxia-inducible factor 1α as inflamaturay genes and octamer-binding transcription factor 4, NANOG, and sex determining region Y-box 2 as stemness genes showed significantly different expression level in E-MenSCs after treating with CM. Our study indicates that the expression level of some inflammatory- and stemness-related genes which have differential expression in E-MenSCs compared with NEMenSCs, could be changed to normal status by using CM derived from NE-MenSCs.