Analysis of the ammonia metabolism of rat primary hepatocytes and a human hepatocyte cell line Huh 7

A mechanobiological mathematical model of liver metabolism

The liver plays a complex role in metabolism and detoxification, and better tools are needed to understand its function and to develop liver-targeted therapies. In this study, we establish a mechanobiological model of liver transport and hepatocyte biology to elucidate the metabolism of urea and albumin, the production/detoxification of ammonia, and consumption of oxygen and nutrients. Since hepatocellular shear stress (SS) can influence the enzymatic activities of liver, the effect of SS on the urea and albumin synthesis are empirically modeled through the mechanotransduction mechanisms. The results demonstrate that the rheology and dynamics of the sinusoid flow can significantly affect liver metabolism. We show that perfusate rheology and blood hematocrit can affect urea and albumin production by changing hepatocyte mechanosensitive metabolism. The model can also simulate enzymatic diseases of the liver such as hyperammonemia I, hyperammonemia II, hyperarginemia, citrollinemia, and argininosuccinicaciduria, which disrupt the urea metabolism and ammonia detoxification. The model is also able to predict how aggregate cultures of hepatocytes differ from single cell cultures. We conclude that in vitro perfusable devices for the study of liver metabolism or personalized medicine should be designed with similar morphology and fluid dynamics as patient liver tissue. This robust model can be adapted to any type of hepatocyte culture to determine how hepatocyte viability, functionality, and metabolism are influenced by liver pathologies and environmental conditions.

A novel evaluation system for whole-organ-engineered liver graft by ex vivo application to a highly reproducible hepatic failure rat model

In recent years, studies on liver graft construction using the decellularized liver as a template for transplantation therapy have attracted much attention. However, the therapeutic effect of constructed liver grafts in hepatic failure has not been evaluated. Therefore, we aimed to develop a novel evaluation system demonstrating the curative effect of a constructed liver graft in animals with hepatic failure. First, we developed a highly reproducible rat model of hepatic failure by combining 80% partial hepatectomy with warm ischemia. In this model, severity could be controlled by the warm ischemic period. We also constructed a liver graft by recellularization of decellularized liver, and confirmed the ammonia metabolic function in the graft in vitro as one of the most important functions for recovery from hepatic failure. The graft was then applied to our developed hepatic failure rat model using a blood extracorporeal circulation system. In this application, the graft metabolized the ammonia in the blood of animals with hepatic failure and was thus suggested to be effective for the treatment of hepatic failure. In summary, a novel evaluation system for whole-organ-engineered liver graft as a preliminary stage of transplantation was developed. This system was expected to provide much information about the curative effect of a constructed liver graft.

Computational fluid model incorporating liver metabolic activities in perfusion bioreactor

The importance of in vitro hepatotoxicity testing during early stages of drug development in the pharmaceutical industry demands effective bioreactor models with optimized conditions. While perfusion bioreactors have been proven to enhance mass transfer and liver specific functions over a long period of culture, the flow-induced shear stress has less desirable effects on the hepatocytes liver-specific functions. In this paper, a two-dimensional human liver hepatocellular carcinoma (HepG2) cell culture flow model, under a specified flow rate of 0.03 mL/min, was investigated. Besides computing the distribution of shear stresses acting on the surface of the cell culture, our numerical model also investigated the cell culture metabolic functions such as the oxygen consumption, glucose consumption, glutamine consumption, and ammonia production to provide a fuller analysis of the interaction among the various metabolites within the cell culture. The computed albumin production of our 2D flow model was verified by the experimental HepG2 culture results obtained over 3 days of culture. The results showed good agreement between our experimental data and numerical predictions with corresponding cumulative albumin production of 2.9 × 10(-5) and 3.0 × 10(-5)  mol/m(3) , respectively. The results are of importance in making rational design choices for development of future bioreactors with more complex geometries.

Hepatocyte differentiation

Increasingly, research suggests that for certain systems, animal models are insufficient for human toxicology testing. The development of robust, in vitro models of human toxicity is required to decrease our dependence on potentially misleading in vivo animal studies. A critical development in human toxicology testing is the use of human primary hepatocytes to model processes that occur in the intact liver. However, in order to serve as an appropriate model, primary hepatocytes must be maintained in such a way that they persist in their differentiated state. While many hepatocyte culture methods exist, the two-dimensional collagen "sandwich" system combined with a serum-free medium, supplemented with physiological glucocorticoid concentrations, appears to robustly maintain hepatocyte character. Studies in rat and human hepatocytes have shown that when cultured under these conditions, hepatocytes maintain many markers of differentiation including morphology, expression of plasma proteins, hepatic nuclear factors, phase I and II metabolic enzymes. Functionally, these culture conditions also preserve hepatic stress response pathways, such as the SAPK and MAPK pathways, as well as prototypical xenobiotic induction responses. This chapter will briefly review culture methodologies but will primarily focus on hallmark hepatocyte structural, expression and functional markers that characterize the differentiation status of the hepatocyte.

Quantitative determination of urea concentrations in cell culture medium

Urea is the major nitrogenous end product of protein metabolism in mammals. Here, we describe a quantitative, sensitive method for urea determination using a modified Jung reagent. This assay is specific for urea and is unaffected by ammonia, a common interferent in tissue and cell cultures. We demonstrate that this convenient colorimetric microplate-based, room temperature assay can be applied to determine urea synthesis in cell culture.

LIVER-SPECIFIC PHYSIOLOGY OF IMMORTAL, FUNCTIONALLY DIFFERENTIATED HEPATOCYTES AND OF DEFICIENT HEPATOCYTE-LIKE VARIANTS

Five different immortalized transgenic hepatocyte cell lines derived from mice were investigated with respect to their potential to maintain the physiological properties of primary hepatocytes using chemically defined medium. This research completes a previous study by Klocke and coworkers in 2002, using gene expression analysis of the same cell lines by the respective physiological analysis for investigating the hepatocyte-like function. Three transgenic cell lines harboring a fusion gene derivative (construct 202) consisting of the complete SV40 early region, including the coding sequences for the transforming large and small tumor antigens, placed under the control of the murine metallothioneine 1-promotor/enhancer element, showed a hepatocyte-like function and physiology. They grew as a monolayer with a polygonal cell shape, consumed lactate, and secreted albumin at a cell-specific rate of 1.5 pg/h, which is in the range of primary hepatocytes. In addition, the potential of detoxifying ammonium could be maintained. Ammonium was metabolized and urea was produced and released into the medium. A complete urea cycle could be determined. A cell line established from neonatal transgenic mice and expressing a secretory variant of the human epidermal growth factor (IgEGF) under the control of the albumin promoter was characterized by an incomplete urea cycle. Another cell line isolated from the liver of homozygote neonatal p53-knockout mice showed no hepatocyte-specific functions but only properties of continuous cell lines. Specific nucleoside triphosphate (NTP) and uridine (U) ratios were used to characterize the differentiation status of the particular cell lines. A low NTP-U value was found for the three cell lines containing construct 202, which was identical to that observed for primary hepatocytes. In contrast, the cell line harvested from the liver of homozygote neonatal p53-knockout mice presented a NTP-U ratio characteristic for continuous cell lines. This study demonstrates that the four transgenic and the p53-knockout hepatocyte-derived cell lines can be used as models for investigating the conservation of tissue-specific functions in immortalized cells.

Effect of sugar residues in a glycolipid coated onto a dish on ammonia consumption and gluconeogenesis activity of primary rat hepatocytes

Coating of 3,4,5-tris(dodecyloxy)benzyl-beta-D-galactopyranoside (TDOB-Gal) on a dish for suspension culture increased the specific ammonia consumption rate of primary rat hepatocytes to 2.4 times that in the case of rat hepatocytes cultured in a dish without coating while there was no increase in the specific urea production rate. TDOB-beta-D-glucopyranoside (TDOB-Glc), -alpha-D-mannnoside, -beta-D-mannoside, 2-acetamido-2-deoxy-beta-D-glucopyranoside, and 2-acetamido-2-deoxy-beta-D-galactopyranoside had almost no influence on the above-mentioned specific rates. In the ammonia loading assay, cells on the dish with TDOB-Gal and -Glc coatings produced glucose, suggesting gluconeogenesis.