Expression of organ-specific structures and functions in long-term cultures of aggregates from adult rat liver cells

Detection of nanocarrier potentiation on drug induced phospholipidosis in cultured cells and primary hepatocyte spheroids by high content imaging and analysis

Considerable effort has been made to develop nanocarriers for controlled drug delivery over the last decade, while it remains unclear how the strength of adverse drug effect will be altered when a drug is loaded on the nanocarrier. Drug-induced phospholipidosis (DIP) is characterized with excessive accumulation of phospholipids in cells and is common for cationic amphiphilic drugs (CAD). Previously, we have reported that PEGylated graphene oxide (PEG-GO) loaded with several CAD can potentiate DIP. In current study, we extended our study on newly identified phospholipidosis (PLD) inducers that had been identified from the Library of Pharmacologically Active Compounds (LOPAC), to investigate if PEO-GO loaded with these CAD can alter DIP. Twenty-two CAD were respectively loaded on PEG-GO and incubated with RAW264.7, a macrophage cell line. The results showed that when a CAD was loaded on PEG-GO, its strength of PLD induction can be enhanced, unchanged or attenuated. PEG-GO loaded with Ifenprodil exhibited the highest PEG-GO potentiation effect compared to Ifenprodil treatment alone in RAW264.7 cells, and this effect was confirmed in human hepatocellular carcinoma HepG2, another cell line model for PLD induction. Primary hepatocyte culture and spheroids mimicking in vivo conditions were used to further validate nanocarrier potentiation on DIP by Ifenprodil. Stronger phospholipid accumulation was found in PEG-GO/Ifenprodil treated hepatocytes or spheroids than Ifenprodil treatment alone. Therefore, evidences were provided by us that nanocarriers may increase the adverse drug effects and guidance by regulatory agencies need to be drafted for the safe use of nanotechnology in drug delivery.

The Use of Long-term Hepatocyte Cultures for Detecting Induction of Drug Metabolising Enzymes: The Current Status

In this report, metabolically competent in vitro systems have been reviewed, in the context of drug metabolising enzyme induction. Based on the experience of the scientists involved, a thorough survey of the literature on metabolically competent long-term culture models was performed. Following this, a prevalidation proposal for the use of the collagen gel sandwich hepatocyte culture system for drug metabolising enzyme induction was designed, focusing on the induction of the cytochrome P450 enzymes as the principal enzymes of interest. The ultimate goal of this prevalidation proposal is to provide industry and academia with a metabolically competent in vitro alternative for long-term studies. In an initial phase, the prevalidation study will be limited to the investigation of induction. However, proposals for other long-term applications of these systems should be forwarded to the European Centre for the Validation of Alternative Methods for consideration. The prevalidation proposal deals with several issues, including: a) species; b) practical prevalidation methodology; c) enzyme inducers; and d) advantages of working with independent expert laboratories. Since it is preferable to include other alternative tests for drug metabolising enzyme induction, when such tests arise, it is recommended that they meet the same level of development as for the collagen gel sandwich long-term hepatocyte system. Those tests which do so should begin the prevalidation and validation process.

Towards a more representative in vitro method for fish ecotoxicology: morphological and biochemical characterisation of three-dimensional spheroidal hepatocytes

The use of fish primary cells and cell lines offer an in vitro alternative for assessment of chemical toxicity and the evaluation of environmental samples in ecotoxicology. However, their uses are not without limitations such as short culture periods and loss of functionality, particularly with primary tissue. While three-dimensional (spheroid) technology is now established for in vitro mammalian toxicity studies, to date it has not been considered for environmental applications in a model aquatic species. In this study we report development of a reproducible six-well plate, gyratory-mediated method for rainbow trout (Oncorhynchus mykiss) hepatocyte spheroid culture and compare their functional and biochemical status with two-dimensional (2D) monolayer hepatocytes. Primary liver spheroid formation was divided into two stages, immature (1-5 days) and mature (≥6 days) according to size, shape and changes in functional and biochemical parameters (protein, glucose, albumin and lactate dehydrogenase). Mature spheroids retained the morphological characteristics (smooth outer surface, tight cell-cell contacts) previously described for mammalian spheroids as demonstrated by light and scanning electron microscopy. Glucose production and albumin synthesis were significantly higher in mature spheroids when compared to conventional 2D monolayer cultures (P < 0.01) and increased as spheroids matured (P < 0.01). Basal lactate dehydrogenase (LDH) leakage significantly decreased during spheroid formation and was significantly lower than 2D cultures (P < 0.01). It is therefore suggested that mature spheroids can maintain a high degree of functional, biochemical and morphological status over-time in culture that is superior to conventional 2D models and can provide realistic organotypic responses in vitro. Trout spheroids that take ~6-8 days to reach maturity would be suitable for use in acute toxicological tests and since it is possible to culture individual spheroids for over a month, there is potential for this work to lead towards in vitro bioaccumulation alternatives and to conduct high throughput screens of chronic exposure. This is an important step forward for developing alternative in vitro tools in future fish ecotoxicological studies.

Functional three-dimensional HepG2 aggregate cultures generated from an ultrasound trap: comparison with HepG2 spheroids

Three-dimensional culture systems are an ideal in vitro model being capable of sustaining cell functionalities in a manner that resembles the in vivo conditions. In the present study, we developed an ultrasound trap-based technique to rapidly produce HepG2 hepatocarcinoma cell aggregates within 30 min. Enhanced junctional F-actin was observed at the points of cell-cell contact throughout the aggregates. HepG2 aggregates prepared by the ultrasound trap can be maintained in culture on a P-HEMA-coated surface for up to 3 weeks. The cells in these aggregates proliferated during the initial 3 days and cell number was consistent during the following maintenance period. Albumin secretion from these HepG2 aggregates recovered after 3 days of aggregate formation and remained relatively stable for the following 12 days. Cytochrome P450-1A1 activity was significantly enhanced after 6 days with maximal enzyme activity observed between 9 and 18 days. In addition, comparison experiments demonstrated that HepG2 aggregates generated by the ultrasound trap had comparable functional characterizations with HepG2 spheroids formed by a traditional gyrotatory-mediated method. Our results suggest that HepG2 aggregate cultures prepared through the ultrasound trap-based technique may provide a novel approach to produce in vitro models for hepatocyte functional studies.

Isolation and primary culture of Necturus maculosus (Amphibia: Urodela) hepatocytes

In order to evaluate their suitability for physiological and ecotoxicological studies, hepatocytes were isolated from the common mudpuppy (Necturus maculosus) using a two-step collagenase perfusion. Hepatocytes in primary culture were investigated for 14 d using light and electron microscopy and biochemical analyses. A typical perfusion yielded 1.7 x 10(5) viable hepatocytes per gram body weight with an average viability of 86 +/- 5%. The majority of isolated cells remained in suspension and formed aggregates. The viability of hepatocytes in primary culture was dependent on a fetal calf serum (FCS) concentration and incubation temperature. Viability was best at 8 degrees C in Leibovitz L-15 medium supplemented with 5% FCS. The ultrastructural characteristics of freshly isolated hepatocytes resembled those of N. maculosus hepatocytes in vivo. Whereas hepatocyte viability remained relatively stable (around 80%) up to 14 d in culture, electron microscopic analyses revealed changes at ultrastructural level. The majority of hepatocytes retained similar structural characteristics to those in vivo up to 4 d. Loss of cellular polarity, fractionation of rough endoplasmic reticulum, formation of autophagosomes, and successive exhaustion of cellular glycogen deposits were observed with increased time in culture. Functional integrity, as estimated by tyrosine aminotransferase induction, decreased during the culture period. Ultrastructural and biochemical analyses indicate the need for further improvement of culture conditions. Nevertheless, isolated hepatocytes in primary culture for up to 4 d can be recommended as a model for physiological and toxicological studies in lower vertebrates.

High functional hollow fiber membrane modified with phospholipid polymers for a liver assist bioreactor

For practical application of a liver assist system with a tissue-conjugated hollow fiber membrane (HFM) bioreactor used in an extracorporeal therapy, it would require a highly sophisticated HFM which has both hemocompatibility on one side and cytocompatibility on the other side. In this study, we present a cellulose acetate (CA) HFM modified with 2-methacryloyloxyethyl phosphorylcholine (MPC) copolymers (PMB30 (MPC-co-n-butyl methacrylate) and PMA30 (MPC-co-methacrylic acid) for preparing a novel liver assist HFM bioreactor. A CA/PMB-PMA30 HFM modified asymmetrically on the inner and outer surface with the PMB30 and PMA30 was prepared successfully. Analysis with an X-ray photoelectron spectroscope showed that the intensity of the phosphorus atom attributed to the MPC units on the outer surface of the modified HFM was stronger than that of the inner surface. The PMA30 was immobilized on the outer surface of the CA/PMB30 blend HFM by a chemical condensation reaction. The CA/PMB-PMA30 HFM showed good water and solute permeability in comparison with the CA HFM. The morphologies of the adherent hepatocytes were round in shape in comparison with the cells that adhered on CA HFM. Furthermore, hepatocytes cultured on the inner surface of the CA/PMB-PMA30 HFM showed higher functional expression in terms of urea synthesis and albumin synthesis than that of the CA HFM.

Design of functional hollow fiber membranes modified with phospholipid polymers for application in total hemopurification system

In this study, we prepared cellulose acetate (CA) hollow fiber membranes (HFMs) modified with poly (2-methacryloyloxyethyl phosphorylcholine (MPC)-co-n-butyl methacrylate)(PMB30 and PMB80) by the dry-jet wet spinning process. The physical and chemical structures of the HFMs were controlled in order to design highly functional HFMs that had suitable performance to each targeting HFM device used in a total hemopurification system. The CA HFMs modified with the MPC polymer, such as CA/PMB30, CA/PMB80, and CA/PMB30-80 HFMs, were successfully prepared by controlling the spinning conditions. The modified HFMs showed an improved performance in solute and water permeability, due to the modification by the hydrophilic MPC polymers. The CA/PMB30 and CA/PMB80 showed a high potential in an application for a high performance hemocompatible plasmapheresis and hemofilter device. Furthermore, CA/PMB30-80 HFM, modified asymmetrically with PMB30 and PMB80, showed a potential for application in an advanced total hemopurification system as a highly functional scaffold for a biohybrid renal tubule, or a liver assist bioreactor device, because of their enhanced permeability, hemocompatibility, and cytocompatibility.

Perfusion of medium with supplemented growth factors changes metabolic activities and cell morphology of hepatocyte-nonparenchymal cell coculture

To develop a feasible perfusion-type bioartificial liver device, perfusion of hepatocyte-nonparenchymal cell (NPC) cocultures with medium supplemented with hepatocyte growth factor (HGF) and heparin-binding epidermal growth factor-like growth factor (HB-EGF) was carried out. On day 1 of culture, perfusion at a constant shear stress of 1.3 dyn/cm2 enhanced ammonia metabolic and urea synthetic activities of hepatocytes. These enhanced activities were sustained up to day 7 only when growth factors were present. In contrast, no beneficial effects of growth factors on these activities were observed in static cultures. In perfusion cultures, three-dimensional cell aggregates were formed. On the surface of these aggregates, flattened cell layers composed mainly of NPCs were found, and the central cluster of cell aggregates was composed of round-shaped hepatocytes and reticulin fibrils. These observations strongly suggested that the reconstruction of different types of liver cells and connective tissues formed tissue-mimicking cell aggregates in the perfusion culture that was able to modulate the liver-specific functions of hepatocytes. Thus, perfusion culture conditions of the hepatocyte--NPC coculture system should be appropriately designed to induce suitable reconstruction of the cultured cells for use as a bioartificial liver device.

Biochemical and functional changes of rat liver spheroids during spheroid formation and maintenance in culture: I. morphological maturation and kinetic changes of energy metabolism, albumin synthesis, and activities of some enzymes

In the process of isolated single liver cells coming together to form three-dimensional spheroids, cells undergo dramatic environmental changes. How liver cells respond to these changes has not been well studied before. This study characterized the functional and biochemical changes during liver spheroid formation and maintenance. Spheroids were prepared in 6-well plates from freshly isolated liver cells from male Sprague rats by a gyrotatory-mediated method. Morphological formation, and functional and biochemical parameters of liver spheroids were evaluated over a period of 21 days in culture. Liver spheroid formation was divided into two stages, immature (1-5 days) and mature (>5 days), according to their size and shape, and changes in their functionality. Galactose and pyruvate consumption was maintained at a relatively stable level throughout the period of observation. However, glucose secretion and cellular GPT and GOT activities were higher in immature spheroids, decreased upto day 5 and remained stable thereafter. Cellular gamma-glutamyltransferase (gamma-GT) and lactate dehydrogenase (LDH) activities were initially undetectable or low and increased as spheroids matured. Albumin secretion decreased rapidly within the first 2 days and increased as spheroids matured. It is concluded that cells undergo functional and biochemical changes during spheroid formation following isolation of liver cells from intact tissue. Functionality and biochemical properties recovered and were maintained in mature spheroids. A relatively stable period (6-15 days) of functionality in mature spheroids was identified and is recommended for applications of the model.

Biochemical and functional changes of rat liver spheroids during spheroid formation and maintenance in culture: II. nitric oxide synthesis and related changes

Liver cells isolated from intact tissue can reaggregate to form three-dimensional, multicellular spheroids in vitro. During this process, cells undergo a histological and environmental change. How cells respond biochemically to this change has not been studied in detail previously. We have investigated some biochemical changes in rat liver cells during the formation and maintenance of spheroids. Liver cells were isolated from male Sprague rats and spheroids cultured by a gyrotatory-mediated method. Liver cells were shown to respond to the isolation procedure and the formation of spheroids triggered histological environmental changes that increased arginine uptake, nitric oxide (NO) and urea syntheses, as well as raised levels of GSH, GSSG, glutamic acid and aspartic acid secretion within the first couple of days after cell isolation. Levels were maintained at a relatively stable level in the mature spheroids (>5 days) over the 3 week period of observation. P450 1A1 activity was lost in the first 2 days and gradually recovered thereafter. This study, for the first time, shows that liver cells after isolation and during spheroid formation actively uptake arginine and increase NO and urea syntheses. A high level of NO is likely to play an important role in modulating a series of biochemical changes in liver cells. It is considered that liver cells actively respond to the 'challenge' induced by the isolation procedure and subsequent histological environmental changes, and biochemical modulation and instability result. The stable cell-cell contacts and histological environment in mature spheroids permit and support functional recovery and maintenance in vitro. This period of stability permits the use of spheroids in toxicity studies to establish acute and chronic paradigms.

Characterisation of some cytotoxic endpoints using rat liver and HepG2 spheroids as in vitro models and their application in hepatotoxicity studies. I. Glucose metabolism and enzyme release as cytotoxic markers

Cytotoxicity endpoints, spontaneous glucose secretion/consumption and LDH and gamma-GT release, were characterised in rat liver and HepG2 spheroids as in vitro models for toxicology studies. Preprepared rat liver spheroids and HepG2 spheroids cultured in a six-well plate format were exposed to varying concentrations of galactosamine, propranolol, diclofenac, and paracetamol. All four model toxins significantly affected glucose secretion, which agreed well with LDH and/or gamma-GT release in rat liver spheroids. These toxins also significantly increased LDH and/or gamma-GT release in HepG2 spheroids. Whereas glucose consumption in HepG2 spheroids did not show conclusive results, LDH activities in both types of spheroids were similar and their levels were relatively high. Accordingly, the level of LDH leakage in both types of spheroids was much higher than gamma-GT after exposure to the toxins. In contrast, gamma-GT activity in HepG2 spheroids was sixfold higher than that in rat liver spheroids. This study revealed that galactosamine interfered with the gamma-GT assay and paracetamol interfered with the LDH assay. It demonstrated, for the first time, that glucose secretion by liver spheroids can be used as a functional indicator of cytotoxicity. Test compounds may interfere with enzymatic assays as indicated by LDH and gamma-GT release in this study. Combining functional parameters together with two or more indicators of enzyme releases can provide a reliable cytotoxicity evaluation. Liver and HepG2 spheroids as in vitro models showed good predictions in chemical-induced hepatic cytotoxicity.

Cytochrome P450 activity in control and induced long-term cultures of rat hepatocyte spheroids

Long-term events such as enzyme induction or chronic toxicity require long-term liver culture models that maintain activity of xenobiotic metabolising enzymes. The levels of these enzyme activities and their responsiveness to chemical induction was studied in rat hepatocyte spheroids, a potential long-term hepatocyte culture model. In comparison with other long-term liver culture models, the basal metabolic activity of spheroids has not been well studied. Additionally, no existing data on the induction of CYP3A activity in spheroids could be found. The basal xenobiotic metabolising activity of rat hepatocyte spheroids was monitored over 14 days in culture, using testosterone as a probe substrate. When spheroids from days 2-14 in culture were compared to 24-h control spheroids, there was a differential maintenance of basal CYP activity. CYP2A and CYP3A activities were maintained over the culture period, while there were time-related decreases in CYP2C11 and CYP2C/CYP2B1/2 activities. The responsiveness of rat hepatocyte spheroids to chemical induction was studied following treatment with phenobarbitone (PB) or dexamethasone (DEX). PB treatment induced CYP2A, CYP2C, CYP2B1/2 and CYP3A activities. DEX treatment resulted in an induction of CYP3A and CYP2C11 activities. The results demonstrate that rat hepatocyte spheroids retained some of the liver-specific functions essential in a long-term hepatocyte culture model, thus making spheroids comparable to other long-term culture models available.

The differential cytotoxicity of methotrexate in rat hepatocyte monolayer and spheroid cultures

It is important to assess the usefulness of long-term in vitro liver models for studying chronic toxicity, since acute assays may not reflect the in vivo situation. A potential long-term hepatocyte culture (i.e. liver spheroids) was investigated and compared to primary rat hepatocyte monolayer cultures following exposure to methotrexate (MTX), a well-documented chronic hepatotoxin. Following up to 7 days' treatment with MTX, cultures were morphologically assessed and assayed for enzyme leakage, intracellular reduced glutathione (GSH) and adenosine triphosphate (ATP). Spheroids maintained higher concentrations of GSH over the 14-day culture and ATP was maintained, but at a concentration not significantly different from monolayer cultures. Treatment of monolayer cultures resulted in concentration-related decreases in GSH and ATP, accompanied by enzyme leakage. In contrast, only ATP was affected following treatment of spheroids for 7 days. Spheroids appeared to be less sensitive to exposure to MTX, when compared with monolayer cultures. This may result from the maintenance of cellular functions, or from the lack of compound penetration into the three-dimensional spheroid structure. Therefore, the usefulness of spheroids to chronic in vitro toxicity testing may be limited.

The use of liver spheroids as an in vitro model for studying induction of the stress response as a marker of chemical toxicity

Stress protein induction has been advocated as a sensitive indicator of compound-induced toxicity. In monolayer cultures of primary hepatocytes, however, the two stress proteins, Hsp25 and Hsp72/3 are up-regulated, probably due to the effect of the isolation procedure and adaptation of the cells to the culture conditions. The aim of the current studies was to determine whether liver spheroids would provide an improved experimental model for the study of heat shock protein induction in vitro. Primary rat hepatocytes were cultured as liver spheroids and the expression of Hsp25 and Hsp72/3 measured along with the levels of ATP, GSH and albumin secretion. Hsp72/3 was initially increased in spheroid culture but returned to in vivo levels after 3 days of culture. Hsp25 was maintained at in vivo levels until day 6 of culture, after which levels increased slightly. The effects of the two hepatotoxins, hydrazine and cadmium chloride (CdCl(2)), were therefore measured on day 6 of spheroid culture. CdCl(2) had no effect on Hsp25 but increased Hsp72/3 at concentrations that affected other biochemical parameters. Hydrazine caused a rapid reduction in ATP levels and albumin secretion, but did not affect Hsp72/3. Hsp25 was slightly induced by hydrazine at later sampling times at concentrations, however, that affected other biochemical parameters. It can be concluded that liver spheroids provide a model for studying stress protein expression. However, the increase in stress proteins appears to be a relatively insensitive parameter compared to other more conventionally used toxicity endpoints and the response appears to vary with individual toxins under study.

Kupffer cell-mediated differential down-regulation of cytochrome P450 metabolism in rat hepatocytes

Nonparenchymal cells, particularly Kupffer cells, might play an important role in the modulation of xenobiotic metabolism in liver and its pharmacological and toxicological consequences. This intercellular communication via the exchange of soluble factors was investigated in primary rat Kupffer cells and hepatocytes. Freshly isolated rat Kupffer cells were seeded onto cell culture inserts and cocultured with 5 day old serum-free rat hepatocyte monolayer cultures at a ratio of 1:1 for 2 days. Hepatocyte cultures, Kupffer cell cultures or cocultures were treated with 0.1 ng/ml-10 microg/ml lipopolysaccharide (LPS). Within this concentration range, no significant toxicity was observed in either cell type. In LPS-exposed cocultures, tumor necrosis factor alpha (TNFalpha) levels rose up to 5 ng/ml within 5 h; nitric oxide (NO) levels increased up to 70 microM within 48 h of treatment, both in a dose-dependent fashion. The release of negative (albumin) and positive (alpha1-acid-glycoprotein) acute phase proteins from the hepatocytes was strongly down- and up-regulated, respectively. The simultaneous treatment of the cocultures with phenobarbital and LPS (10 ng/ml) or 3-methylcholanthrene and LPS (10 ng/ml) resulted in a strong down-regulation (85%) of the phenobarbital-induced cytochrome P450 (CYP) isoform CYP2B1 in the hepatocytes whereas the 3-methylcholanthrene-induced isoform CYP1A1 was only weakly affected (15%). This specific down-regulation of CYP2B1 was mediated exclusively by TNFalpha, released from the Kupffer cells. It was not linked with NO release from or inducible NO synthase activity in the hepatocytes. The TNFalpha release was not affected by the two xenobiotics. Acetaminophen tested in these cocultures showed no direct interaction with the Kupffer cells. The use of liver cell cocultures is therefore a useful approach to investigate the influence of intercellular communication on xenobiotic metabolism in liver.