Hepatocyte culture on biodegradable polymeric substrates

The interactions of primary rat liver cells with biodegradable polymeric substrates were investigated in vitro to assess the suitability of the polymer materials for use in cell transplantation devices. The kinetics of cell adhesion to, and the growth and biochemical function of cells maintained on, films formed from poly (D,L-lactic-co-glycolic acid, 88: 12) (PLGA) or from a 50/50 (w/w) blend of PLGA and poly (L-lactic acid) (PLLA) were evaluated in comparison to two control substrates, matrigel coated or collagen-coated polystyrene petri dishes. The rate of cell adhesion to both types of polymeric substrates was similar to the rate of adhesion to the collagen control substrate, but of the two polymers, only the blend was suitable for extended culture. Hepatocytes maintained on the polymer blend films showed retention of differentiated cell function as measured by the rate of albumin secretion-the rate of albumin secretion by cells on the films was the same as the rate for cells on matrigel and reached a level in the range of reported in vivo levels (140-160 mug/10(6) cells/24 h). In contrast, albumin secretion by hepatocytes maintained on collagen-coated polystyrene culture dishes declined over five days to a level one third that of the initial level and one fifth that of cells maintained on the polymer blend films on day five. Such retention of differentiated cell function by hepatocytes in culture has previously been observed only when hepatocytes were cultured in the presence of exogenous extracellular matrix proteins or were cocultured with another cell type. In addition to retention of differentiated function, the cells maintained on the polymer blend films also displayed rates of DNA synthesis similar to controls maintained on collagen-coated polystyrene, a substrate optimal for DNA synthesis.     

Spheroid formation and expression of liver specific functions of primary rat hepatocytes co-cultured with bone marrow cells

We have developed a new co-culture system consisting of adhesive bone marrow cells (A-BMCs), non-adhesive bone marrow cells (NA-BMCs) and hepatocytes with improved hepatocyte immobilization efficiency and better maintenance of liver specific functions. The composition of the inoculated cells affected the morphology of hepatocytes. Spheroids formed spontaneously when rat hepatocytes were co-cultured with bone marrow cells (BMCs). However, the addition of NA-BMCs to existing hepatocyte monolayers did not change their morphologies to spheroids. On the other hand, NA-BMCs dramatically increased hepatocyte immobilization efficiency. Hepatocytes co-cultured with either NA-BMCs or A-BMCs maintained their albumin production activities significantly better than hepatocyte culture alone. Interestingly, the two fractions of BMCs appear to have combination effects on hepatocytes to maintain albumin production activity. We conclude that co-culture of hepatocytes and BMCs is an effective strategy to enhance hepatocyte immobilization efficiency and functions in vitro.     

Chitosan nanofiber scaffold enhances hepatocyte adhesion and function

To enhance cell attachment and promote liver functions of hepatocytes cultured in bioreactors, a chitosan nanofiber scaffold was designed and prepared via electrospinning. Effects of the scaffold on hepatocyte adhesion, viability and function were then investigated. Data showed that hepatocytes on chitosan nanofiber scaffold exhibited better viability and tighter cell-substrate contact than cells on regular chitosan film. In addition, urea synthesis, albumin secretion and cytochrome P450 activity of hepatocytes on chitosan nanofiber scaffold were all 1.5 to 2 folds higher than the controls. Glycogen synthesis was also increased as compared with the controls. These results suggested the potential application of this chitosan nanofiber scaffold as a suitable substratum for hepatocyte culturing in bioreactors.     

Modulation of protein synthesis and secretion by substratum in primary cultures of rat hepatocytes

Hepatocytes isolated by perfusion of adult rat liver and cultured on substrata consisting of one or more of the major components of the liver biomatrix (fibronectin, laminin, type IV collagen) have been examined for the synthesis of defined proteins. Under these conditions, tyrosine amino transferase, a marker of hepatocyte function, is maintained at similar levels in response to dexamethasone over 5 days in culture on each substratum, and total cellular protein synthesis remains constant. By contrast, there is a rapid decrease in synthesis and secretion of albumin and a 3-7-fold increase in synthesis and secretion of alpha-fetoprotein which are most marked on a laminin substratum, but least evident on type IV collagen, and an increased synthesis of fibronectin and type IV collagen. The newly synthesized matrix proteins are present in the cell layer as well as in cell secretions. The enhanced synthesis of fibronectin is less in cells seeded onto a fibronectin substratum than on laminin or type IV collagen substrata, and its synthesis by hepatocytes seeded onto a mixed substratum of laminin and fibronectin is down-regulated by fibronectin in a dose-related manner. Similarly, type IV collagen synthesis is less when the cells are seeded on the homologous matrix protein substratum than on heterologous substrata. These results indicate that hepatocytes cultured in serum-free medium on substrata composed of components of the liver biomatrix maintain certain functions of the differentiated state (tyrosine amino transferase), lose others (albumin secretion) and switch to increased synthesis of matrix components as well as fetal markers such as alpha-fetoprotein. The magnitude of these effects depends on the substratum on which the hepatocytes are cultured.     

Functional engineering of hepatocytes via heterocellular presentation of a homoadhesive molecule, E-cadherin.

Engineering functional activity of liver cell cultures requires the modulation of specific cell-cell interactions. We have investigated the quantitative role of systematically varied presentation of the cell-cell adhesion molecule, E-cadherin, on the differentiated function of cocultured parenchymal liver cells, hepatocytes. Specifically, we incorporated different proportions of E-cadherin transfected L-929 chaperone cells and untransfected chaperone cells, within cultures of primary rat hepatocytes on a collagen substrate. By using a strongly adhesive substrate that restricted cadherin-induced variations in cell spreading and growth-arresting chaperone cells, we could carefully isolate the potential role of cell-cell adhesion on cell differentiation. Using immunofluorescence microscopy, we confirmed that cadherins expressed at hepatocyte-hepatocyte contacts as well as hepatocyte-chaperone contacts were crossreactive. However, hepatocytes cocultured with cadherin-presenting chaperone cells had a 55-65% increase in longterm function over hepatocytes cocultured with control, nonpresenting chaperone cells. Notably, the cadherin-induced increase in function occurred over and above the basal, coculture-induced functional elevation. Further, we quantified the stoichiometric importance of cadherin contacts by comparing established markers of hepatocyte functional activity across a graded range of E-cadherin presentation. At low levels of cadherin-mediated contacts, the induction of differentiated function was weak, while high levels of contacts elicited a marked increase in function. Thus, hepatocyte biochemical functions (albumin and urea secretion) were biphasically governed by the degree of cadherin-based contacts presented during culture. Overall, our results demonstrate the unequivocal role of cell-cell adhesion molecules in hepatocyte functional engineering, through the graded use of cadherin presentation from functionally incompetent, heterotypic chaperone cells.     

Maintaining hepatocyte differentiation in vitro through co-culture with hepatic stellate cells

Primary hepatocytes lose their differentiated functions rapidly when in culture. Our aim was to maintain the differentiated status of hepatocytes in vitro by means of vital hepatic stellate cells (HSCs), their soluble and particulate factors and lipid extracts. Hepatocytes were placed into collagen-coated culture dishes in the presence of HSCs at different ages of pre-culture, with or without direct cell to cell contacts, at different cell ratios and in monoculture with cellular HSC components in place of vital cells. Changes in morphology and enhancement of phosphoenolpyruvate carboxykinase (PCK) activity by glucagon were used to determine the differentiated status of hepatocytes in 2d-short-term culture. HSCs proved able to maintain the differentiated function of hepatocytes in co-culture either by direct cell contacts or via factors derived from HSC-conditioned medium. In comparison, however, without cellular contact to hepatocytes five to ten times as many HSCs were necessary to increase the PCK activity to the same degree as in the presence of intercellular contacts. Whereas stimulation in the presence of HSC/hepatocyte contacts was independent of HSC culture age only quiescent, resting HSCs (precultured for 1–2 d) were able to stimulate hepatocytes significantly via soluble factors. Culturing of hepatocytes with a lipid extract or a particulate fraction from HSCs clearly displayed a very strong beneficial effect on enzyme activity and morphology. HSCs maintain hepatocyte function and structure through preferentially cell-bound signalling and transfer of lipids.     

Direct analysis of growth factor requirements for isolated human fetal hepatocytes

Summary Hepatocytes were isolated from human fetal liver in order to analyze the direct effects of growth factors and hormones on human hepatocyte proliferation and function. Mechanical fragmentation and then dissociation of fetal liver tissue with a collagenase/dispase mixture resulted in high yield and viability of hepatocytes. Hepatocytes were selected in arginine-free, ornithine-supplemented medium and defined by morphology, albumin production and ornithine uptake into cellular protein. A screen of over twenty growth factors, hormones, mitogenic agents and crude organ and cell extracts for effect on the stimulation of hepatocyte growth revealed that EGF, insulin, dexamethasone, and factors concentrated in bovine neural extract and hepatoma cell-conditioned medium supported attachment, maintenance and growth of hepatocytes on a collagen-coated substratum. The population of cells selected and defined as differentiated hepatocytes had a proliferative potential of about 4 cumulative population doublings. EGF and insulin synergistically stimulated DNA synthesis in the absence of other hormones and growth factors. Although neural extracts enhanced hepatocyte number, no effect on DNA synthesis of neural extracts or purified heparin-binding growth factors from neural extracts could be demonstrated in the absence or presence of defined hormones, hepatoma-conditioned medium or serum. Hepatoma cell-conditioned medium had the largest impact on both hepatocyte cell number and DNA synthesis under all conditions. Dialyzed serum protein (1 mg/ml) at 10 times higher protein concentration had a similar effect to hepatoma cell-conditioned medium (100 μg/ml). The results suggest that hepatoma cell conditioned medium may be a concentrated and less complicated source than serum for purification and characterization of additional normal hepatocyte growth factors. This work was supported by NIH grant DK35310. Editor’s statement Many investigators have struggled with the special problems associated with culture of differentiated hepatocytes. In this paper attention is given to the specific growth factor requirements for fetal human hepatocytes. The observation that factors from hepatoma conditioned medium or neural extracts enhanced the growth of the cells may indicate that additional growth factors are to be identified that are important in the survival and proliferation of hepatocytes, and may also indicate that the malignant transformation of these cells may involve the production of autocrine growth stimulators.     

Effects of medium composition on the morphology and function of rat hepatocytes cultured as spheroids and monolayers

Primary hepatocytes cultured as monolayers or as spheroids were studied to compare the effects of four different culture media (Williams' E, Chee's, Sigma Hepatocyte, and HepatoZYME medium). Rat hepatocytes were cultured as conventional monolayers for 3 d or as spheroids for 2 wk. For spheroid formation a method was emplOyed that combined the use of a nonadherent substratum with rotation of cultures. Hepatocyte integrity and morphology were assessed by light and electron microscopy and by reduced glutathione content. Hepatocyte function was measured by albumin secretion and 7-ethoxycoumarin metabolism. Chee's medium was found to be optimal for maintenance of hepatocyte viability and function in monolayers, but it failed to support spheroid formation. For spheroid formation and for the maintenance of spheroid morphology and function, Sigma HM was found to be optimal. These results demonstrate that the medium requirements of hepatocytes differ markedly depending on the culture model employed. Spheroid culture allowed better preservation of morphology and function of hepatocytes compared with conventional monolayer culture. Hepatocytes in spheroids formed bile canaliculi. and expressed an actin distribution resembling that found in hepatocytes in vivo. Albumin secretion was maintained at the same level as that found during the first d in primary culture, and 7-ethoxycoumarin metabolism was maintained over 2 wk in culture at approximately 30% of the levels found in freshly isolated hepatocytes. The improved morphology and function of hepatocyte cultures as spheroids may provide a more appropriate in vitro model for certain applications where the maintenance of liver-specific functions in long-term culture is crucial.     

Elevated expression of hormone-regulated rat hepatocyte functions in a new serum-free hepatocyte-stromal cell coculture model

Summary The specific performance of the adult hepatic parenchymal cell is maintained and controlled by factors deriving from the stromal bed; the chemical nature of these factors is unknown. This study aimed to develop a serum-free hierarchical hepatocyte-nonparenchymal (stromal) cell coculture system. Hepatic stromal cells proliferated on crosslinked collagen in serum-free medium with epidermal growth factor, basic fibroblast growth factor, and hepatocyte-conditioned medium; cell type composition changed during the 2-wk culture period. During the first wk, the culture consisted of proliferating sinusoidal endothelial cells with well-preserved sieve plates, proliferating hepatic stellate cells, and partially activated Kupffer cells. The number of endothelial cells declined thereafter; stellate cells and Kupffer cells became the prominent cell types after 8 d. Hepatocytes were seeded onto stromal cells precultured for 4–14 d; they adhered to stellate and Kupffer cells, but spared the islands of endothelial cells. Stellate cells spread out on top of the hepatocytes; Kupffer cell extensions established multiple contacts to hepatocytes and stellate cells. Hepatocyte viability was maintained by coculture; the positive influence of stromal cell signals on hepatocyte differentiation became evident after 48 h; a strong improvement of cell responsiveness toward hormones could be observed in cocultured hepatocytes. Hierarchial hepatocyte coculture enhanced the glucagon-dependent increases in phosphoenolpyruvate carboxykinase activity and messenger ribonucleic acid (mRNA) content three- and twofold, respectively; glucagon-activated urea production was elevated twofold. Coculturing also stimulated glycogen deposition; basal synthesis was increased by 30% and the responsiveness toward insulin and glucose was elevated by 100 and 55%, respectively. The insulin-dependent rise in the glucokinase mRNA content was increased twofold in cocultured hepatocytes. It can be concluded that long-term signals from stromal cells maintain hepatocyte differentiation. This coculture model should, therefore, provide the technical basis for the investigation of stroma-derived differentiation factors.     

Chronic iron overload inhibits protein secretion by adult rat hepatocytes maintained in long-term primary culture

Short-term pure cultures and long-term cocultures of adult rat hepatocytes with rat liver epithelial cells, presumably derived from primitive biliary cells, were used to define in vitro models of iron overloaded hepatocytes in order to understand the molecular mechanism responsible for liver damage occurring in patients with hemochromatosis. In vitro iron overload was obtained by daily addition of ferric nitrilotriacetate to the culture medium. A concentration of 20 microM ferric salt induced hepatocyte iron overload with minimal cytotoxicity as evaluated by cell viability, morphological changes of treated cells and cytosolic enzyme leakage into the culture medium. The effects of iron overload on protein biosynthesis and secretion were studied in both short-term pure cultures and long-term cocultures of hepatocytes. The amounts of intracellular and newly synthesized proteins were never modified by the iron treatment. Furthermore, neither the relative amounts of transferrin and albumin mRNAs nor their translational products were altered by iron overload. Moreover, no change in the transferrin isomeric forms were observed in treated cells. In contrast, a prolonged exposure of cocultured hepatocytes to 20 microM ferric salt led to a significant decrease in the amount of proteins secreted in the medium. This decrease included the two major secreted proteins, namely albumin and transferrin, and probably all other secreted proteins. These results demonstrate that iron loading alters neither the total nor the liver specific protein synthesis activity of cultured hepatocytes. They suggest that chronic overload may impede the protein secretion process.     

Hormonal and pharmacological alteration of angiotensinogen secretion from rat hepatocytes

Isolated hepatocytes were prepared from rat liver by collagenase perfusion and density gradient centrifugation. The hepatocyte preparation released angiotensinogen at a basal rate of 50-120 pmol/g wet weight per h. Release was linear with time for at least 4 h. Angiotensinogen secretion was reduced in the presence of actinomycin D, and inhibited by cycloheximide, puromycin, colchicine and vinblastine. In the presence of tunicamycin, an inhibitor of N-glycosylation, the secretion of angiotensinogen as well as total protein and albumin secretion were diminished. Hepatocytes from nephrectomized rats exhibit an increased secretion rate of angiotensinogen, whereas total protein secretion was unaltered. Preincubation of hepatocytes with hydrocortisone (0.1 mM) or angiotensin II (10 nM) induced an increase of angiotensinogen release. There was no concomitant increase of total protein or albumin secretion, indicating that these effects are not the expression of a general stimulation of protein synthesis and secretion.     

肝星型细胞分离方法和功能研究进展

肝星型细胞(Hepatic stellate cells,HSCs),又叫储脂细胞(Fat-storing cells,FSCs)或脂肪细胞(lipocytes),是肝脏固有的非实质细胞类型之一,存在于狄氏腔内,以脂滴的形式储存人体维生素A总量的50%–80%。原代HSCs分离方法,目前主要集中于密度梯度离心法结合离心淘洗、HSCs高侧向角的流式分选法、紫外激发的自发荧光或特异性抗体标记的流式细胞术等,将为HSCs生理和病理研究提供坚实的基础。近年来,HSCs的研究蓬勃发展,合作领域不断拓宽。生理状态下,HSCs处于静息状态,合成细胞外基质(Extracellular matrix,ECM)并维持其稳态,同时广泛摄取和储存维生素A,并具有调节肝细胞再生的功能;而病理状态下,HSCs在肝损伤和持续性刺激条件下被激活,增殖活性明显增强,脂滴减少或消失,ECM合成也明显增加,具有收缩性,同时分泌多种促炎因子和粘附分子,并向肌成纤维细胞转变,表明HSCs的活化是肝纤维化发生发展过程中的关键环节之一。有关HSCs的分离和功能研究一直是肝脏细胞学和肝脏病理学研究的热点之一。文中我们将系统总结和探讨HSCs的分离方法和改进策略,及其功能研究进展和具有潜在价值的研究方向。     

Receptor phenotype underlies differential response of hepatocytes and nonparenchymal cells to heparin-binding fibroblast growth factor type 1 (aFGF) and type 2 (bFGF)

Summary Heparin-binding fibroblast growth factors (HBGF) have been implicated in the regeneration of both parenchymal and nonparenchymal cells of the liver. The response to and phenotype of hepatocyte receptors for HBGF-1 (acidic fibroblast growth factor) and HBGF-2 (basic fibroblast growth factor) were compared to keratinocytes, fibroblasts, and endothelial cells. HBGF-1 stimulated DNA synthesis in hepatocytes, keratinocytes, fibroblasts, and endothelial cells whereas activity of HBGF-2 was limited to fibroblasts and endothelial cells. HBGF-2 antagonized the mitogenic activity of HBGF-1 for hepatocytes and keratinocytes. Hepatocytes and keratinocytes exhibited both high- and low-affinity, nonmatrix receptor sites for HBGF-1, but only low-affinity sites for HBGF-2. The mesenchymal cells displayed only high-affinity sites for both HBGF-1 and HBGF-2. Northern blot and immunochemical analysis revealed that the expression of HBGF receptor genesbek andflg are partitioned between normal hepatocytes and nonparenchymal cells, respectively. Expression of epithelial cell-specific, mesenchymal cell-derived HBGF-7 (keratinocyte growth factor) mRNA in regenerating liver tissue was undetectable relative to HBGF-1. The results support a multifunctional role of HBGF-1 acting through different receptor phenotypes in hepatocyte and nonparenchymal cells during liver regeneration.     

Long-term culture of adult rat hepatocyte spheroids

Hepatocytes from adult rats were cultured on poly-HEMA-coated surface to form spheroids in hormonally defined media as previously shown with newborn rat hepatocytes. Spheroidal aggregates of adult rat hepatocytes were morphologically similar to those of newborn rat hepatocytes and could also form a monolayer of uniform liver parenchyma-like cells when transferred on collagen-coated surfaces even after 2 months of culture. Under these culture conditions, albumin and transferrin secreted in vitro by adult rat hepatocyte spheroids were detectable by immunoprecipitation method at least until 2 months of culture. The production of proteins by hepatocyte spheroids could be regulated in vitro by IL-6: the secretion of alpha 2-macroglobulin was increased and the secretion of albumin was decreased in the presence of this cytokine. In addition, cytochrome P450 IA1 was strongly induced by methylcholanthrene in adult rat hepatocyte spheroids, and the induction remained relatively constant up to 22 days of culture. These cells were also able to metabolize lidocaine to monoethylglycinexylidine when measured up to 14 days of culture, showing the presence of a relatively high level of P450 IIIA2. The UDP-glucuronyltransferase activity, specific for bilirubin conjugation, decreased to 18% of the initial value after 2 weeks of culture. This work showed that adult rat hepatocytes in long-term spheroid culture kept differentiated functions, providing a new model for the in vitro study of hepatocyte functions and complementing that of newborn rat hepatocytes using the same system.     

Trefoil factor 2 secreted from damaged hepatocytes activates hepatic stellate cells to induce fibrogenesis

Liver fibrosis is a common characteristic of chronic liver diseases. The activation of hepatic stellate cells (HSCs) plays a key role in fibrogenesis in response to liver injury, yet the mechanism by which damaged hepatocytes modulate the activation of HSCs is poorly understood. Our previous studies have established that liver-specific deletion of O-GlcNAc transferase (OGT)leads to hepatocyte necroptosis and spontaneous fibrosis. Here, we report that OGT-deficient hepatocytes secrete trefoil factor 2 (TFF2) that activates HSCs and contributes to the fibrogenic process. The expression and secretion of TFF2 are induced in OGT-deficient hepatocytes but not in WT hepatocytes. TFF2 activates the platelet-derived growth factor receptor beta signaling pathway that promotes the proliferation and migration of primary HSCs. TFF2 protein expression is elevated in mice with carbon tetrachloride-induced liver injury. These findings identify TFF2 as a novel factor that mediates intercellular signaling between hepatocytes and HSCs and suggest a role of the hepatic OGT–TFF2 axis in the process of fibrogenesis.     

Long-term maintenance of hepatocyte functional activity in co-culture: requirements for sinusoidal endothelial cells and dexamethasone

Sinusoidal cells isolated from adult rat liver have been established in primary culture and in cell line. The presence of factor VIII R:Ag and peroxidatic/phagocytosis activities were the criteria used to distinguish in freshly isolated cells the endothelial cells from the Kupffer cells and suggested the endothelial origin of the cell line. Using a co-culture system, the effect of sinusoidal liver cells on hepatocyte functional activity was characterized. A plateau in which the state of differentiation was stabilized could be generated for co-cultured hepatocytes isolated from adult rat and a disappearance of the initial expression of alpha 1-fetoprotein (AFP) and the increase and/or maintenance of albumin secretion were measured with co-cultured hepatocytes isolated from suckling rat. The presence of dexamethasone was required for such beneficial effect. The hepatocyte-stabilizing activity was also produced by a pulmonary endothelial cell line.     

Fabrication of oxygen-carrying microparticles functionalized with liver ECM-proteins to improve phenotypic three-dimensional in vitro liver assembly,function, and responses

Oxygen and extracellular matrix (ECM)-derived biopolymers play vital roles in regulating many cellular functions in both the healthy and diseased liver. This study highlights the significance of synergistically tuning the internal microenvironment of three-dimensional (3D) cell aggregates composed of hepatocyte-like cells from the HepG2 human hepatocellular carcinoma cell line and hepatic stellate cells (HSCs) from the LX-2 cell line to enhance oxygen availability and phenotypic ECM ligand presentation for promoting the native metabolic functions of the human liver. First, fluorinated (PFC) chitosan microparticles (MPs) were generated with a microfluidic chip, then their oxygen transport properties were studied using a custom ruthenium-based oxygen sensing approach. Next, to allow for integrin engagements the surfaces of these MPs were functionalized using liver ECM proteins including fibronectin, laminin-111, laminin-511, and laminin-521, then they were used to assemble composite spheriods along with HepG2 cells and HSCs. After in vitro culture, liver-specific functions and cell adhesion patterns were compared between groups and cells showed enhanced liver phenotypic responses to laminin-511 and 521 as evidenced via enhanced E-cadherin and vinculin expression, as well as albumin and urea secretion. Furthermore, hepatocytes and HSCs exhibited more pronounced phenotypic arrangements when cocultured with laminin-511 and 521 modified MPs providing clear evidence that specific ECM proteins have distinctive roles in the phenotypic regulation of liver cells in engineering 3D spheroids. This study advances efforts to create more physiologically relevant organ models allowing for well-defined conditions and phenotypic cell signaling which together improve the relevance of 3D spheroid and organoid models.     

Kinetics of albumin- and alpha-fetoprotein-production during rat liver development

Synthesis of most of the plasma proteins is one of the main functions of the hepatocytes. Albumin synthesis is quantitatively the most abundant. In the present study we investigated albumin- and alpha-fetoprotein-gene-expression, and the function of the secretory apparatus during rat liver development. To this purpose we used the method of radioactive biosynthetic labeling of newly synthesized albumin and alpha-fetoprotein (AFP) to monitor the secretory capacity of endodermal cells derived from ventral foregut region (embryonic day 10, E10), and of embryonic and fetal hepatoblasts. Synthesis and secretion of albumin and AFP were already detected in the low numbered ventral foregut endodermal cells; fibrinogen synthesis was detectable in the E12 hepatoblasts, which were in higher number. The whole secretory machinery was functional from the earliest stages of liver development, and the speed of secretion was comparable with that of the adult hepatocytes. There was almost 4-fold increase of hepatoblasts cell volume in fetal stage compared with embryonic stage. The model used suggests that the hepatocyte secretory apparatus is already functional before the emergence of the liver bud. This is the first comparative report to analyze the hepatocyte secretory function, cell proliferation and cell volume during liver development.     

Metabolic pre-conditioning of cultured cells in physiological levels of insulin: generating resistance to the lipid-accumulating effects of plasma in hepatocytes

Understanding the regulation of hepatocyte lipid metabolism is important for several biotechnological applications involving liver cells. During exposure of hepatocytes to plasma, as is the case in extracorporeal bioartificial liver assist devices, it has been reported that hepatic-specific functions, e.g., albumin and urea synthesis and diazepam removal, are dramatically compromised and hepatocytes progressively accumulate cytoplasmic lipid droplets. We hypothesized that the composition of hepatocyte culture medium significantly affects lipid metabolism during subsequent plasma exposure. Rat hepatocytes were cultured in medium containing either physiological (50 microU/mL) or supra-physiological (500 mU/mL) insulin levels for 1 week and then exposed to human plasma supplemented with or without amino acids. We found that insulin's anabolic effects, such as stimulation of triglyceride storage, were carried over from the pre-conditioning to the plasma exposure period. While hepatocytes cultured in high insulin medium accumulated large quantities of triglycerides during subsequent plasma exposure, culture in low insulin medium largely prevented lipid accumulation. Urea and albumin secretion, as well as the ammonia removal rate, were largely unaffected by insulin but increased with amino acid supplementation. Thus, hepatocyte metabolism during plasma exposure can be modulated by medium pre-conditioning and supplements added to plasma.