Improved long-term culture of hepatocytes in a hydrogel containing Arg-Gly-Asp (RGD)

Freshly harvested primary rat hepatocytes, which had been entrapped in a synthetic extracellular matrix, were examined for differentiated morphology and enhanced liver-specific functions for long-term culture. A copolymer of N-isopropylacrylamide (98 mol % in the feed) and acrylic acid [poly(NiPAAm-co-AAc)], and the adhesion molecule, Arg-Gly-Asp (RGD), incorporated into a hydrogel, were used to entrap hepatocytes. Over 28 days' culture, the hepatocytes in the RGD-incorporated gel maintained higher viability and produced albumin and urea at constant rates, while there was lower cell viability and less albumin secretion by hepatocytes in poly(NiPAAm-co-AAc). Hepatocytes cultured in the gel with RGD incorporated into it constitutes a potentially useful three-dimensional cell system for application in a bio-artificial liver device.     

Stabilizing Hepatocellular Phenotype Using Optimized Synthetic Surfaces

Currently, one of the major limitations in cell biology is maintaining differentiated cell phenotype. Biological matrices are commonly used for culturing and maintaining primary and pluripotent stem cell derived hepatocytes. While biological matrices are useful, they permit short term culture of hepatocytes, limiting their widespread application. We have attempted to overcome the limitations using a synthetic polymer coating. Polymers represent one of the broadest classes of biomaterials and possess a wide range of mechanical, physical and chemical properties, which can be fine-tuned for purpose. Importantly, such materials can be scaled to quality assured standards and display batch-to-batch consistency. This is essential if cells are to be expanded for high through-put screening in the pharmaceutical testing industry or for cellular based therapy. Polyurethanes (PUs) are one group of materials that have shown promise in cell culture. Our recent progress in optimizing a polyurethane coated surface, for long-term culture of human hepatocytes displaying stable phenotype, is presented and discussed.     

Human liver model systems in a dish

The human adult liver has a multi‐cellular structure consisting of large lobes subdivided into lobules containing portal triads and hepatic cords lined by specialized blood vessels. Vital hepatic functions include filtering blood, metabolizing drugs, and production of bile and blood plasma proteins like albumin, among many other functions, which are generally dependent on the location or zone in which the hepatocyte resides in the liver. Due to the liver's intricate structure, there are many challenges to design differentiation protocols to generate more mature functional hepatocytes from human stem cells and maintain the long‐term viability and functionality of primary hepatocytes. To this end, recent advancements in three‐dimensional (3D) stem cell culture have accelerated the generation of a human miniature liver system, also known as liver organoids, with polarized epithelial cells, supportive cell types and extra‐cellular matrix deposition by translating knowledge gained in studies of animal organogenesis and regeneration. To facilitate the efforts to study human development and disease using in vitro hepatic models, a thorough understanding of state‐of‐art protocols and underlying rationales is essential. Here, we review rapidly evolving 3D liver models, mainly focusing on organoid models differentiated from human cells.     

Phenotype of hepatocyte spheroids in Arg-GLY-Asp (RGD) containing a thermo-reversible extracellular matrix

The spheroid of specific cells is often regarded as the better form in artificial organs and mammalian cell bioreactors for improved cell-specific functions. In this study, freshly harvested primary rat hepatocytes, which had been cultivated as spheroids and entrapped in a synthetic thermo-reversible extracellular matrix, were examined for differentiated morphology and enhanced liver-specific functions as compared to a control set (hepatocytes in single-cell form). A copolymer of N-isopropylacrylamide (98 mole % in the feed) and acrylic acid (poly(NiPAAm-co-AAc)), and the adhesion molecule, an Arg-Gly-Asp (RGD)-incorporated thermo-reversible matrix, were used to entrap hepatocytes in the form of either spheroids or single cells. In a 28-day culture period, the spheroids in the RGD-incorporated gel maintained higher viability and produced albumin and urea at constant rates, while there was lower cell viability and less albumin secretion by the spheroids in p(NiPAAm-co-AAc). Hepatocytes cultured as spheroids in the RGD-incorporated gel would constitute a potentially useful three-dimensional cell system for application in a bio-artificial liver device.     

Mammalian hepatocytes as a foundation for treatment in human liver failure.

Technological advances in the separation and culture of mammalian hepatocytes have facilitated the use of these cells as the foundation for either hepatocyte transplantation or hepatocyte-seeded hollow fiber liver assist devices (LAD). To fully appreciate the practical applications of these tissue engineering solutions, it is necessary to understand the types of human liver failure as well as the corresponding animal models. The most immediate application of this type of technology is the treatment of hepatic encephalopathy (HE), an acute and highly fatal complication of fulminant hepatic failure. Although the pathogenesis of HE is unknown, failure of the detoxification function of the liver is accepted as playing an important role in this disorder. Consequently, the assaying and preservation of P450 activity in the grafted cells or in the LAD must be among the main targets of this research. This review explores the problems in hepatocyte transplantation and culture that deserve special consideration and emphasizes the conditions contributing to the in vitro maintenance of phenotypic expression of these cells.     

胚胎干细胞分化为肝细胞的研究进展

目前 ,细胞移植作为终末期肝病的辅助治疗方法 ,移植的细胞必须满足在受体肝脏中存活、增殖并可分化为成熟肝细胞两个重要条件 ,但目前应用的肝细胞来源有限 ,其功能随着培养时间的延长而逐渐下降等问题限制了这一治疗策略的广泛开展。作为具有发育全能性和无限增殖能力的细胞 ,胚胎干细胞向肝细胞的分化研究近年来引起了广泛的关注 ,并取得了较大的进展 ,寻找合适、高效的分化诱导方法是目前研究的热点之一。胚胎干细胞向肝细胞的分化研究既可以为临床细胞替代治疗提供合适的细胞来源 ,也可以在药物评估和肝脏发育分化基础研究方面起到重要的作用。通过概括肝脏和拟胚体分化发育的分子机制 ,对体外胚胎干细胞向肝细胞分化的几种诱导体系作了介绍 ,并对分化肝细胞的应用前景和存在的问题进行了讨论。     

Characterization of the three-compartment gel-entrapment porcine hepatocyte bioartificial liver

A hybrid bioartificial liver device supporting a large mass of cells expressing differentiated hepatocyte metabolic capabilities is necessary for the successful treatment of fulminant hepatic failure. The three-compartment gel-entrapment porcine hepatocyte bioartificial liver was designed to provide "bridge" support to transplantation or until native liver recovery is achieved for patients with acute liver failure. The device is an automated mammalian cell culture system supporting 6-7 × 109 porcine hepatocytes entrapped in a collagen matrix and inoculated into the capillary lumen spaces of two 100 kDa molecular mass cut-off hollow fiber bioreactors. Gel contraction recreates a small lumen space within the hollow fiber which allows for the delivery of a nutrient medium. This configuration supported hepatocyte viability and differentiated phenotype as measured by albumin synthesis, ureagenesis, oxygen consumption, and vital dye staining during both cell culture and ex vivo application. The hollow fiber membrane was also shown to isolate the cells from xenogenic immunoglobulin attack. The gel-entrapment bioartificial liver maintained a large mass of functional hepatocytes by providing a three-dimensional cell culture matrix, by delivering basal nutrients through lumen media perfusion, and by preventing rejection of the xenocytes. These features make this device a favorable candidate for the treatment of clinical fulminant hepatic failure.     

Prolongation of liver-specific function for primary hepatocytes maintenance in 3D printed architectures

Isolated primary hepatocytes from the liver are very similar to in vivo native liver hepatocytes, but they have the disadvantage of a limited lifespan in 2D culture. Although a sandwich culture and 3D organoids with mesenchymal stem cells (MSCs) as an attractive assistant cell source to extend lifespan can be used, it cannot fully reproduce the in vivo architecture. Moreover, long-term 3D culture leads to cell death because of hypoxic stress. Therefore, to overcome the drawback of 2D and 3D organoids, we try to use a 3D printing technique using alginate hydrogels with primary hepatocytes and MSCs. The viability of isolated hepatocytes was more than 90%, and the cells remained alive for 7 days without morphological changes in the 3D hepatic architecture with MSCs. Compared to a 2D system, the expression level of functional hepatic genes and proteins was higher for up to 7 days in the 3D hepatic architecture. These results suggest that both the 3D bio-printing technique and paracrine molecules secreted by MSCs supported long-term culture of hepatocytes without morphological changes. Thus, this technique allows for widespread expansion of cells while forming multicellular aggregates, may be applied to drug screening and could be an efficient method for developing an artificial liver.     

Clonal expansion of adult rat hepatic stem cell lines by suppression of asymmetric cell kinetics (SACK)

Adult stem cells have potential use for several biomedical applications, including cell replacement therapy, gene therapy, and tissue engineering. However, such applications have been limited due to difficulties encountered in expanding functional adult stem cells. We have developed a new approach to the problem of adult stem cell expansion based on the suppression of asymmetric cell kinetics (SACK). We postulated that asymmetric cell kinetics, required for adult stem cell function, were a major barrier to their expansion in culture. As such, conversion of adult stem cells from asymmetric cell kinetics to symmetric cell kinetics would promote their exponential expansion and longterm propagation in culture. The purine nucleoside xanthosine (Xs), which promotes guanine ribonucleotide biosynthesis, can be used to reversibly convert cells from asymmetric cell kinetics to symmetric cell kinetics. We used Xs supplementation to derive clonal epithelial cell lines from adult rat liver that have properties of adult hepatic stem cells. The properties of two Xs-derived cell lines, Lig-8 and Lig-13, are described in detail and compared to properties of adult rat hepatic cell lines derived without Xs supplementation. The Xs-derived cell lines exhibit Xs-dependent asymmetric cell kinetics and Xs-dependent expression of mature hepatic differentiation markers. Interestingly, Lig-8 cells produce progeny with properties consistent with hepatocyte differentiation, while Lig-13 progeny cells have properties consistent with bile duct epithelium differentiation. A stable adult cholangiocyte stem cell line has not been previously described. Consistent with the principles of their derivation, the SACK-derived hepatic cell lines exhibit neither senescence nor tumorigenic properties, and their differentiation properties are stable after longterm culture. These characteristics of SACK-derived stem cell lines underscore asymmetric cell kinetics as an essential adult stem cell property with potential to be the basis for a general approach to expansion and propagation of diverse adult stem cells.     

Oval cell proliferation in p16INK4a expressing mouse liver is triggered by chronic growth stimuli.

Terminal differentiation requires molecules also involved in aging such as the cell cycle inhibitor p16(INK4a).Like other organs, the adult liver represents a quiescent organ with terminal differentiated cells, hepatocytes and cholangiocytes. These cells retain the ability to proliferate in response to liver injury or reduction of liver mass. However, under conditions which prevent mitotic activation of hepatocytes, regeneration can occur instead from facultative hepatic stem cells.For therapeutic application a non-toxic activation of this stem cell compartment is required. We have established transgenic mice with conditional overexpression of the cell cycle inhibitor p16(INK4a) in hepatocytes and have provoked and examined oval cell activation in adult liver in response to a range of proliferative stimuli.We could show that the liver specific expression of p16(INK4a) leads to a faster differentiation of hepatocytes and an activation of oval cells already in postnatal mice without negative consequences on liver function.     

Activation, isolation, identification and culture of hepatic stem cells from porcine liver tissues

Objectives: Utility of hepatic stem cells could provide a novel solution to the severe shortage of human donor livers, for treatment of liver‐related diseases, due to their ability to proliferate and differentiate into functional hepatocytes. Porcine liver tissues also offer an alternative source from human donor livers. However, morphology, phenotype, successful isolation and culture of porcine hepatic stem cells still require much investigation. Materials and methods: In the present study, we performed partial hepatectomy to activate hepatic oval cells and developed a procedure utilizing enzymatic digestion and density gradient centrifugation to isolate and purify oval cells derived from porcine livers. We identified ovoid cells by their morphological characteristics and phenotypic properties, thereby providing definitive evidence for the presence of hepatic stem cells in porcine livers. Moreover, we established a culture system, using various growth factors, to provide nourishment for these cells. Results and conclusions: By transmission electron microscopy, oval‐shaped cells with ovoid nuclei, a high nucleus/cytoplasm ratio and few organelles were demonstrated. Flow cytometry and immunocytochemistry showed that freshly isolated oval cells expressed albumin, cytokeratin 19, alpha fetoprotein (AFP) and OV6 at high levels. Immunofluorescence revealed that porcine hepatic oval cells after culture expressed stem‐cell factor, c‐kit, Thy‐1, CK19, OV6, and AFP. Taken together, this study provides a novel insight into morphological and phenotypic characteristics of porcine hepatic stem cells. Our ability for isolation and culturing porcine hepatic stem cells offers an abundant source of cells for transplantation and tissue engineering to help alleviate liver disease.     

胎肝干细胞的分离、培养与鉴定

目的体外扩增培养大鼠胎肝干细胞,研究其形态、生物学特性及表面标志物,探讨胎肝干细胞的性质。方法分离培养胎龄12-16d的胎肝细胞,SABC法检测原代、传代后及细胞克隆中的肝干细胞特异表面标志物OV-6、CK-19及nestin的表达。结果原代、传代培养的胎肝细胞部分表达OV-6、CK-19及nestin;培养3d开始出现小细胞团,1个月即形成肉眼可见的细胞集落,5-7d传代一次;细胞克隆几乎全部为干细胞标志阳性细胞。结论胎肝干细胞可通过克隆筛选法进行体外扩增,胎肝内存在nestin阳性干细胞,可能是一种更为原始的干细胞,在胚胎发育中起重要作用。     

Long-term culture of hepatocytes from human adults

A long-term primary human hepatocyte culture retraining liver-specific functions is important and essential for basic research and for the future development of hepatocyte-based applications. We established a normal hepatocyte culture system from excess normal tissues obtained from adult liver cancer patients who received partial liver resection. Hepatocytes were isolated after perfusion and enzymatic disaggregation, and were first maintained in hormonally defined media on a Matrigel matrix, and then transferred to collagen sandwich gel. The hepatocytes formed clusters on the Matrigel matrix and increased in size and numbers with time of culture and eventually grew into spheroids of variable sizes. After being transferred to collagen gel, the cells migrated outward from spheroids to form a monolayer with cuboidal or polygonal cell shapes with granular cytoplasm and continued to proliferate. Cellular functions specific for hepatocytes were analyzed using immunoblot assay for proteins specifically secreted by the liver cells on different days of culture. The cells secreted albumin, transferrin and -fetoprotein consistently for more than 100 days, to a maximum of 150 days. Thus, we have established a long-term culture of hepatocytes from human adults, which will be useful for basic studies of liver physiology such as metabolism and morphogenesis, as well as for other applications in the study of infectious hepatitis, pharmacology, pharmacokinetics, and toxicology.     

Pluripotent stem cell-derived hepatocyte-like cells

Liver disease is an important clinical problem, impacting over 30 million Americans and over 600 million people worldwide. It is the 12th leading cause of death in the United States and the 16th worldwide. Due to a paucity of donor organs, several thousand Americans die yearly while waiting for liver transplantation. Unfortunately, alternative tissue sources such as fetal hepatocytes and hepatic cell lines are unreliable, difficult to reproduce, and do not fully recapitulate hepatocyte phenotype and functions. As a consequence, alternative cell sources that do not have these limitations have been sought. Human embryonic stem (hES) cell- and induced pluripotent stem (iPS) cell-derived hepatocyte-like cells may enable cell based therapeutics, the study of the mechanisms of human disease and human development, and provide a platform for screening the efficacy and toxicity of pharmaceuticals. iPS cells can be differentiated in a step-wise fashion with high efficiency and reproducibility into hepatocyte-like cells that exhibit morphologic and phenotypic characteristics of hepatocytes. In addition, iPS-derived hepatocyte-like cells (iHLCs) possess some functional hepatic activity as they secrete urea, alpha-1-antitrypsin, and albumin. However, the combined phenotypic and functional traits exhibited by iHLCs resemble a relatively immature hepatic phenotype that more closely resembles that of fetal hepatocytes rather than adult hepatocytes. Specifically, iHLCs express fetal markers such as alpha-fetoprotein and lack key mature hepatocyte functions, as reflected by drastically reduced activity (~ 0.1%) of important detoxification enzymes (i.e. CYP2A6, CYP3A4). These key differences between iHLCs and primary adult human hepatocytes have limited the use of stem cells as a renewable source of functional adult hepatocytes for in vitro and in vivo applications. Unfortunately, the developmental pathways that control hepatocyte maturation from a fetal into an adult hepatocyte are poorly understood, which has hampered the field in its efforts to induce further maturation of iPS-derived hepatic lineage cells. This review analyzes recent developments in the derivation of hepatocyte-like cells, and proposes important points to consider and assays to perform during their characterization. In the future, we envision that iHLCs will be used as in vitro models of human disease, and in the longer term, provide an alternative cell source for drug testing and clinical therapy.     

Notch is the key factor in the process of fetal liver stem/progenitor cells differentiation into hepatocytes

Cell transplantation is efficient method to therapy end-stage liver disease (ESLD). How to punctually induce stem cell differentiation into hepatocyte is still a challenge. Notch plays important roles in embryonic development and cell differentiation. However, during the differentiation process from fetal liver stem/progenitor cells (FLSPCs) to mature hepatocytes, the contribution of Notch, especially which Notch receptor is primarily responsible, is unknown. First, specific Notch receptor responsible for FLSPCs differentiation was identified. On both tissue level and cell level, we found that Notch3 was the only receptor greater expressed in liver tissue at embryonic day (ED) 14 and FLSPCs, compared with the adult liver and BRL cells, respectively. Second, morphological phenotypic and functional aspects were analyzed to evaluate whether Notch inhibition by GSIs (γ-secretase inhibitors, inhibitor of Notch) promotes the differentiation of FLSPCs into hepatocytes. Results showed that N-[N-(3, 5-Difluorophenacetyl)-L-alanyl]-S-phenylglycine t-butyl ester (DAPT) as GSIs was able to induce FLSPCs differentiation into hepatocytes. The differentiated FLSPCs showed similar morphology to mature hepatocytes, expressed hepatic markers indicative of a mature developmental stage, and displayed similar functionality to mature hepatocytes. The differentiation efficiency by GSIs was similar to that by hepatocyte growth factor (HGF) induction. More specifically, as the differentiation of FLSPCs progressed towards hepatocytes, the expression of Notch3 was gradually down-regulated, consistent with the down-regulation of other stem cell markers. These findings imply that Notch3 may not only be a regulator of FLSPCs differentiation into hepatocytes, but also be a potential marker of FLSPCs.     

Embryonic liver cells and permanent lines as models for hepatocyte and bile duct cell differentiation

Analysis of liver cells during development is facilitated by the possibility of complementing in vivo analysis with experiments on cultured cells. In this review, we discuss results from several laboratories concerning bipotential hepatic stem cells from mouse (HBC-3, H-CFU-C, MMH and BMEL), rat (rhe14321) and primate (IPFLS) embryos. Several groups have used fluorescence-activated cell sorting to identify clonogenic bipotential cells; others have derived bipotential cell lines by plating liver cell suspensions and cloning. The bipotential cells, which probably originate from hepatoblasts, can differentiate as hepatocytes or bile duct cells, and undergo morphogenesis in culture. Disparities in differentiation can be explained by distinct medium compositions, extracellular matrix coated culture surfaces, and gene expression detection methods. Potential applications of these cell lines are discussed.