Long-term culture of primary rat hepatocytes with high albumin secretion using membrane-supported collagen sandwich

Primary cultured rat hepatocytes in a membrane-supported collagen sandwich maintained their normal cell morphology and high level of albumin secretion for over 56 days. It was found that the existence of an upper layer of collagen gel is crucial for long-term culture and that the transference of cellular nutrients between the culture media and hepatocytes from both the upper and the lower sides of gel layers promotes albumin secretion. These facts suggest that the membrane-supported collagen sandwich mimics well thein vivo environment of hepatocytes. This method has great potential for the long-term culture of primary cells.     

Effects of L-proline on phase I and phase II xenobiotic biotransformation capacities of rat and human hepatocytes in long-term collagen gel cultures

L-Proline supplementation of the medium for collagen gel cultures of hepatocytes has been shown to improve albumin secretion. A study was made as to whether L-proline is also essential for the maintenance of xenobiotic biotransformation capacities in collagen gel sandwich and immobilisation cultures of rat and human hepatocytes. Key phase I (cytochrome P450-dependent monooxygenase [CYP)] and microsomal epoxide hydrase [mEH]) and phase II (glutathione S-transferase [GST]) biotransformation enzyme activities and the secretion of albumin in the culture medium were assessed in the absence and presence of L-proline. CYP and mEH activities were not affected by the addition of L-proline, whereas phase II alpha-Class GST activity of rat hepatocytes in collagen cultures was decreased. Species differences were demonstrated, as human hepatocytes showed a better maintenance of GST activities than their rat counterparts in the presence of L-proline. Albumin secretion, often considered to be a marker for differentiated cell function, does not parallel the biotransformation capacities of the hepatocytes in culture. Additional results demonstrated an L-proline-mediated enhancement of the proliferation rate of contaminating stellate cells in conventional monolayer culture. Transdifferentiation of stellate cells to proliferating myofibroblasts, along with an increased albumin secretion and collagen synthesis, are characteristic of fibrotic liver. Since the last two phenomena have been observed in L-proline-supplemented collagen gel cultures, it can be concluded that when stable collagen gel cultures of rat hepatocytes are needed for long-term pharmacotoxicological studies, it is preferable to use an L-proline-free culture medium. Further studies on medium optimisation are required for hepatocytes from species other than rat.     

Primary culture of rat hepatocytes using membrane-supported collagen sandwich with hormone-free medium

Summary Primary culture of rat hepatocytes in hormone-free medium using membrane-supported collagen sandwich maintained their cellular morphology and expressed albumin secretion for about 3 weeks in vitro. It was reconfirmed that mimicking the cellular environment in vivo was effective for cellular maintenance.     

Hepatocyte function and extracellular matrix geometry: long-term culture in a sandwich configuration

Adult rat hepatocytes cultured in a collagen sandwich system maintained normal morphology and a physiological rate of albumin secretion for at least 42 days. Hepatocytes cultured on a single layer of collagen gel essentially ceased albumin secretion within 1 wk but could recover function with the overlay of a second layer of collagen gel. This culture configuration more closely mimics the hepatocytes' in vivo environment and provides a simple method for their long-term maintenance.     

A new approach to the cryopreservation of hepatocytes in a sandwich culture configuration

Current methods of cryopreservation of hepatocytes in single cell suspensions result in low overall yields of hepatocytes, demonstrating long-term preservation of hepatocellular functions. A novel culture method has recently been developed to culture liver cells in a sandwich configuration of collagen layers in order to stabilize the phenotypic expression of these cells in vitro (J. C. Y. Dunn, M. L. Yarmush, H. G. Koebe, and R. G. Tompkins, FASEB J. 3, 174, 1989). Using this culture system, rat hepatocytes were frozen with 15% (v/v) Me2SO to -70 degrees C, and stored at approximately -100 degrees C. Following rapid thawing, long-term function was assessed by measuring albumin secretion in culture for 7-14 days postfreezing. Comparison was made with cryopreservation of liver cells in single cell suspensions. Cryopreservation of liver cells in suspension resulted in only a 2% yield of cells which could be successfully cultured; albumin secretion rates in these cultured cells over 48 hr were 26-30% of secretion rates for nonfrozen hepatocytes. Freezing cultured liver cells in the sandwich configuration after 3, 7, and 11 days in culture maintained 0, 26, and 19% of the secretion rates of nonfrozen hepatocytes, respectively. Morphology of the cryopreserved cells appeared grossly similar to cells without freezing; however, this morphological result was patchy and represented approximately 30% of the cells in culture. These results represent the first demonstration of any quantitative long-term preservation of hepatocellular function by cryopreservation, suggesting that cultured hepatocytes can survive freezing and maintain function.     

Long-term in vitro function of adult hepatocytes in a collagen sandwich configuration.

In an effort to reconstruct the cellular polarity normally found in the liver, adult rat hepatocytes were sandwiched between two layers of hydrated rat tail tendon collagen matrix. Functionally, sandwiched hepatocytes maintained the secretion of albumin, transferrin, fibrinogen, bile acids, and urea for at least 6 weeks, whereas cells cultured on a single layer of collagen gel ceased such secretion in 1-2 weeks. After 1 week of culture on a single layer of collagen gel, hepatocytes could still recover these lost functions when a second layer of collagen gel was applied. The exact nature of the substrate for constructing the sandwich system appeared to be unimportant as long as it allowed cellular attachment. Hepatocytes cultured in the sandwich system appeared to maintain a distribution of actin filaments similar to the in vivo state, whereas cells cultured on a single layer of collagen gel showed abnormal formation of stress fibers. These studies suggest that simple manipulations of the configuration of extracellular elements can dramatically alter the behavior of cultured hepatocytes.     

Collagen sandwich culture affects intracellular polyamine levels of human hepatocytes

Abstract. Extracellular matrices, like collagen layers, play an important role in preventing dedifferentiation of hepatocytes in long-term culture experiments. It has also been shown that polyamines are crucial for cell growth and liver differentiation – regeneration. Primary cultured hepatocytes with their low mitotic activity might be a valuable tool in studying the role of polyamines in differentiation. Here, our goal was to investigate whether an extracellular cell culture matrix can influence intracellular polyamine levels in human hepatocytes during long-term culture. Primary human hepatocytes were isolated from surgical tissue resections and were maintained either in single collagen (SG) or double collagen gel (DG) layer (sandwich) culture systems. Cell viability and function were examined and intracellular polyamine levels were measured using a highly sensitive high performance liquid chromatography (HPLC) method. Hepatocytes showed high viability in both culture systems used, but albumin secretion was diminished in SG cultured hepatocytes after 14 days. In general, total intracellular polyamine levels of hepatocytes decreased markedly in both SG and DG within the first days of culture, but remained constant until day 21 with a SG/DG ratio of about 1.4. Individual polyamines levels were dependent on the culture time and system, where spermine decreased and putrescine increased in both SG and DG over time (day 14), but spermidine increased only in DG. Our results suggest that polyamine levels, in particular putrescine, might be important regulators of hepatocyte specific function in vitro and therefore serve as a marker of differentiation for cultivated human hepatocytes.     

Influence of collagen gel substrata on certain biochemical activities of hepatocytes in primary culture

In order to study the influence of cell shape as modulated by the extracellular matrix on the cellular activity, hepatocytes isolated from liver were maintained on collagen I coated plastic substrata and collage I gel substrata and certain hepatocyte specific functions were investigated. The incorporation of³[H]-leucine into total proteins and albumin secreted by cells maintained on collagen gel was found to be significantly higher compared to those maintained on a collagen coated plastic substrata, indicating that hepatocytes on collagen gel have an enhanced albumin synthesizing capacity. Increased incorporation of³⁵[S]-sulphate into total proteoglycans (PG) and a relatively higher fraction of the³⁵[S]-PG in the extracellular space showed an increased rate of synthesis and secretion of sulphated PGs by cells maintained on collagen gels. But in contrast to the above results, the incorporation of³[H]-leucine into cytokeratins C₈, C₁₈ and actin were significantly low in cells maintained on collagen gel. The tyrosine amino transferase activity exhibited by hepatocytes preincubated with dexamethasone on collagen gel was also significantly low. The different forms of collagen substrata appeared to have no effect on the amino acid transport by hepatocytes, further suggesting that the various hepatocyte specific functions are not uniformly altered when hepatocytes are maintained on three-dimensional collagen gel substrata. These results indicate that the shape of the cell as determined by the nature of the matrix substratum influences the synthetic activity of secretory proteins and those remaining intracellularly, differently.     

Collagen type I gel cultures of adult rat hepatocytes as a screening induction model for cytochrome P450-dependent enzymes

Albumin secretion, expression of cytochrome P450 dependent mono-oxygenases (CYPs) and their inducibility by well-known inducers were evaluated during 1 week in collagen type I gel sandwich and immobilisation cultures of adult primary rat hepatocytes. Albumin secretion increased during culture time and, following an initial decrease, CYP biotransformation activities remained stable for at least 7 days. Better preservation results were observed in the collagen gel sandwich culture than in the immobilisation model. The inducibility of CYPs by beta-naphthoflavone (beta-NF), 3- methylcholanthrene (3-MC), phenobarbital (PB) and dexamethasone (DEX) was studied in both collagen gel hepatocyte cultures. Exposure of the cells to either 5microM 3-MC or 25 microM beta-NF, added to the culture medium, resulted in strong increases of CYP1A1/2 activity in both culture models. Treatment with PB (3.2 mM) resulted in an increase in the CYP2B activity and a higher hydroxylation of testosterone in the 16alpha-position (CYP2B1/2 and CYP2C11), the 7alpha-position (CYP2A1/2), and the 6beta-position (CYP3A1). DEX (10 microM) markedly increased testosterone 6beta- and 7alpha-hydroxylation. Expression and induction experiments of CYP proteins exposed to these molecules confirmed the results of the CYP activity measurements. The patterns of CYP induction in collagen gel cultures of rat hepatocytes were similar to those observed in vivo. Consequently, collagen gel cultures and, more specifically, collagen gel sandwich cultures seem to be suitable as in vitro models for evaluating xenobiotics as potential inducers of CYP-enzymes.     

Hollow fiber bioartificial liver utilizing collagen-entrapped porcine hepatocyte spheroids

A xenogeneic hollow fiber bioreactor utilizing collagen-entrapped dispersed hepatocytes has been developed as an extracorporeal bioartificial liver (BAL) for potential treatment of acute human fulminant hepatitis. Prolonged viability, enhanced liver-specific functions, and differentiated state have been observed in primary porcine hepatocytes cultivated as spheroids compared to dispersed hepatocytes plated on a monolayer. Entrapment of spheroids into the BAL can potentially improve performance over the existing device. Therefore, studies were conducted to evaluate the feasibility of utilizing spheroids as the functionally active component of our hybrid device. Confocal microscopy indicated high viability of spheroids entrapped into cylindrical collagen gel. Entrapment of spheroids alone into collagen gel showed reduced ability to contract collagen gel. By mixing spheroids with dispersed cells, the extent of collagen gel contraction was increased. Hepatocyte spheroids collagen-entrapped into BAL devices were maintained for over 9 days. Assessment of albumin synthesis and ureagenesis within a spheroid-entrapment BAL indicated higher or at least as high activity on a per-cell basis compared to a dispersed hepatocyte-entrapment BAL device. Clearance of 4-methylumbelliferone to its glucuronide was detected throughout the culture period as a marker of phase II conjugation activity. A spheroid-entrapment bioartificial liver warrants further studies for potential human therapy. (c) 1996 John Wiley & Sons, Inc.     

Functional properties of hepatocytes in vitro are correlated with cell polarity maintenance

Exploring the cell biology of hepatocytes in vitro could be a powerful strategy to dissect the molecular mechanisms underlying the structure and function of the liver in vivo. However, this approach relies on appropriate in vitro cell culture systems that can recapitulate the cell biological and metabolic features of the hepatocytes in the liver whilst being accessible to experimental manipulations. Here, we adapted protocols for high-resolution fluorescence microscopy and quantitative image analysis to compare two primary hepatocyte culture systems, monolayer and collagen sandwich, with respect to the distribution of two distinct populations of early endosomes (APPL1 and EEA1-positive), endocytic capacity, metabolic and signaling activities. In addition to the re-acquisition of hepatocellular polarity, primary hepatocytes grown in collagen sandwich but not in monolayer culture recapitulated the apico-basal distribution of EEA1 endosomes observed in liver tissue. We found that such distribution correlated with the organization of the actin cytoskeleton in vitro and, surprisingly, was dependent on the nutritional state in vivo. Hepatocytes in collagen sandwich also exhibited faster kinetics of low-density lipoprotein (LDL) and epidermal growth factor (EGF) internalization, showed improved insulin sensitivity and preserved their ability for glucose production, compared to hepatocytes in monolayer cultures. Although no in vitro culture system can reproduce the exquisite structural features of liver tissue, our data nevertheless highlight the ability of the collagen sandwich system to recapitulate key structural and functional properties of the hepatocytes in the liver and, therefore, support the usage of this system to study aspects of hepatocellular biology in vitro.     

Effects of dimethyl sulfoxide on cultured rat hepatocytes in sandwich configuration.

A recently developed sandwich culture system, in which hepatocytes are sandwiched between two layers of collagen, has been shown to be capable of maintaining long-term expression of hepatocellular function (J. C. Y. Dunn et al., Biotechnol. Prog. 7, 237-245, 1991). The development of an adequate technique for the cryopreservation of hepatocytes in such a stable culture configuration would ensure a ready supply of hepatocytes for use in bioreactors or bioartificial liver support devices. This report describes the effects of exposing hepatocytes in sandwich culture to different concentrations of the cryoprotectant dimethyl sulfoxide (Me2SO) at 22 degrees C on Day 7 of culture. Cell function, morphology, and cytoskeletal organization were followed for 14 days after exposure. Hepatocellular morphology and albumin secretion remained normal when cultures were exposed for up to 120 min to predicted final Me2SO concentrations up to 1.33 M. Exposure for less than 60 min to equilibrium concentrations of up to 3.33 M Me2SO did not adversely affect cell morphology or albumin secretion rate, but at the highest concentration (3.33 M), increase of the exposure time to 60 or 120 min resulted in dramatic, irreversible cell damage and loss of function. Actin filament organization was shown to be undisturbed when the cells were exposed to 1.33 M Me2SO for 60 min, but was irreversibly disrupted by exposure to 3.33 M for 120 min. Based on these results, a simple and safe procedure is suggested for the addition of Me2SO to hepatocytes in a sandwich culture configuration and its subsequent removal, which will be valuable for studies on hepatocyte cryopreservation.     

Long-term culture of functional hepatocytes on chemically modified collagen gels

For long-term maintenance of functional hepatocytes in primary culture, a new culture system with chemically modified type-I collagen gel was developed. Isolated hepatocytes spread as flat cells and rapidly lost their viability and functions when cultured on native collagen gel. In contrast, they survived for several weeks when cultured on collagen gels that had been modified by treatment with sodium-borohydride (NaBH₄) or by digestion with pepsin, which resulted in destruction of crosslinking of collagen fibers and marked decrease in meachanical strength of the gels. These long-lived cells were round and aggregated and maintained high levels of various differentiated liver functions including albumin secretion and activities of tyrosine aminotransferase and P450. Moreover on collagen gels modified by treatment with NaBH₄ or pepsin, the cell showed less DNA synthesis in response to mitogenic stimulation than cells cultures on gel containing native collagen. Interestingly, crosslinking of these chemically modified gels with D-ribose resulted in changes in various phenotypes of hepatocytes cultures on them including shape, longevity, and functions expressed when the cells were cultured on native collagen gel, suggesting that the effect of modification of the collagen gel is reversible. Thus the structure of collagen gels, probably due to the degree of crosslinking, seems to affect the morphology, maintenance of differentiated functions, and growth of primary cultured hepatocytes.     

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.     

Metabolic profiling based quantitative evaluation of hepatocellular metabolism in presence of adipocyte derived extracellular matrix

The elucidation of the effect of extracellular matrices on hepatocellular metabolism is critical to understand the mechanism of functional upregulation. We have developed a system using natural extracellular matrices [Adipogel] for enhanced albumin synthesis of rat hepatocyte cultures for a period of 10 days as compared to collagen sandwich cultures. Primary rat hepatocytes isolated from livers of female Lewis rats recover within 4 days of culture from isolation induced injury while function is stabilized at 7 days post-isolation. Thus, the culture period can be classified into three distinct stages viz. recovery stage [day 0-4], pre-stable stage [day 5-7] and the stable stage [day 8-10]. A Metabolic Flux Analysis of primary rat hepatocytes cultured in Adipogel was performed to identify the key metabolic pathways modulated as compared to collagen sandwich cultures. In the recovery stage [day 4], the collagen-soluble Adipogel cultures shows an increase in TriCarboxylic Acid [TCA] cycle fluxes; in the pre-stable stage [day 7], there is an increase in PPP and TCA cycle fluxes while in the stable stage [day 10], there is a significant increase in TCA cycle, urea cycle fluxes and amino acid uptake rates concomitant with increased albumin synthesis rate as compared to collagen sandwich cultures throughout the culture period. Metabolic analysis of the collagen-soluble Adipogel condition reveals significantly higher transamination reaction fluxes, amino acid uptake and albumin synthesis rates for the stable vs. recovery stages of culture. The identification of metabolic pathways modulated for hepatocyte cultures in presence of Adipogel will be a useful step to develop an optimization algorithm to further improve hepatocyte function for Bioartificial Liver Devices. The development of this framework for upregulating hepatocyte function in Bioartificial Liver Devices will facilitate the utilization of an integrated experimental and computational approach for broader applications of Adipogel in tissue e engineering and regenerative medicine.     

The importance of proline on long-term hepatocyte function in a collagen gel sandwich configuration: regulation of protein secretion

A serum-free culture system for primary hepatocytes which maintains stabel high-level hepatocyte function for prolonged periods in culture has been developed. Isolated rat primary hepatocytes were cultured in serum-free media between two layer of gelled collagen in a sandwich configuration which reinstates the cellular polarity necessary for long-term function in vitro. Thsee serum-free hepatocyte cultures maintained near physiological rates of albumin and transferrin secretion for a minimum of 26 days in culture. L-Proline was shown to be critical for both the approach to steady state and maximal level of protein secretion. Analysis of does-response data gave K(m) values of 2.9 and 1.7 mug/mL for albumin and transferrin secretion, respectively.     

Quantitative comparison of rat hepatocyte functions in two improved culture systems with or without rat liver epithelial cell line

We quantitatively evaluated two recently-developed novel techniques for hepatocyte cultivation in a dish level; that is, spheroid culture and membrane-supported collagen (CN) gel sandwich culture, in terms of cellular maintenance, albumin secretion and 7-ethoxycoumarin (7EC) metabolism to 7-hydroxycoumarin (7HC) as a marker for cytochrome P450 IA1 activity in the presence and absence of rat liver epithelial cell line (RLEC) during one month of culture, together with conventional coculture with RLEC in CN-coated dishes as a control. RLEC prevented spheroid loss caused by its detachment from the culture dishes often occurring in pure culture. CN-gel sandwich by itself improved remarkably hepatocyte maintenance when compared with CN-gel free systems, thereby resulting in enhancement of overall functional expressions as compared with CN-gel free systems. RLEC in CN-gel sandwhich, however, reduced cellular sustainment probably due to its suppression of hepatocyte growth. Although there were no significant differences in albumin secretion per cell among the five cultures examined, CN-gel sandwich expressed markedly higher 7EC metabolizing activity per cell, where RLEC presence had a preferable influence. Consequently, membrane-supported CN-gel sandwich was the most superior technique for hepatocyte cultivation from the standpont of both cellular maintenance and its functional expressions per cell.     

Composition of culture medium is more important than co-culture with hepatic non-parenchymal cells in albumin production activity of primary rat hepatocytes,and the effect was enhanced by hepatocytes spheroid culture in collagen gel

Co-culture of primary rat hepatocytes with hepatic non-parenchymal cells or sinusoidal endothelial cells for albumin production activity as an index of liver-specific function was studied. The co-cultures were effective for the expression and maintenance of albumin production activity. However, the co-culture effect was not observed when we used a suitable culture medium, which had already been reported to be sufficient for albumin production activity. Albumin production of dispersed cells in collagen gel culture was higher than that of spheroid culture. In addition, albumin production of spheroids in collagen gel culture was higher than that of spheroid culture and dispersed cell collagen gel culture with a suitable culture medium. We found that culture medium composition was more important than co-culture for expression and maintenance of albumin production. Furthermore, we found that cell–cell interaction was effective for the expression of albumin production, but heterotypic cell–cell interaction was not necessary.     

Cell-cell interactions are essential for maintenance of hepatocyte function in collagen gel but not on matrigel

The objective of this study was to examine the importance of cellular aggregation for the maintenance of liver-specific functions in hepatocytes. We used two culture matrix systems (collagen sandwich and Matrigel) to examine the responsiveness of albumin secretory function in cultured rat hepatocytes under various seeding conditions. With high cell seeding, both culture systems elicited comparable levels of elevated function. Under conditions of sparse seeding, however, their responses were quite distinct: collagen sandwiched cells exhibited a significant deterioration in secretion, while Matrigel-cultured cells retained their basal levels of function. This indicates that a critical degree of cell-cell interactions is essential for promoting function in the collagen sandwich, and in the Matrigel-cultured cells functions may be preserved by constitutive matrix-related phenomena, even in the absence of aggregation. (c) 1997 John Wiley & Sons, Inc. Biotechnol Bioeng 56: 706-711, 1997.