Generation of Scalable Hepatic Micro-Tissues as a Platform for Toxicological Studies
Tissue Engineering and Regenerative Medicine
; (6): 459-475, 2020.
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in En
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| ID: wpr-896289
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ABSTRACT
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.
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Language:
En
Journal:
Tissue Engineering and Regenerative Medicine
Year:
2020
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Article