Kohji Nakazawa

Formation of a spherical multicellular aggregate (spheroid) of animal cells in the pores of polyurethane foam as a cell culture substratum and its application to a hybrid artificial liver

Monkey kidney cells (Vero), human embryonic kidney cells (293), human liver cells (PLC/PRF/5), and primary rat, dog, and porcine hepatocytes formed spherical multicellular aggregates (spheroids) in the pores of polyurethane foam which was used as a cell culture substratum. These spheroids of various cell types express high cell activity for a long period. A practical hybrid artificial live support system composed of a multi-capillary polyurethane foam packed-bed type cell culture module including primary hepatocyte spheroids was developed. The success of the system is indicated by an 80% recovery rate in hepatic failure rats which died in control experiments.

Comparative Analysis of Gene Expression in Rat Liver Tissue and Monolayer- and Spheroid-Cultured Hepatocytes

A culture system with spherical multicellular aggregates (spheroids), which are formed by the rearrangement and compaction of cell aggregates, is reported to be more useful than the traditional monolayer culture system for the culture of primary hepatocytes. By performing real-time polymerase chain reaction, we analyzed the expression of genes encoding key molecules involved in liver-specific functions, namely, cell adhesion molecules (integrin 3, cadherin 1 and connexin 32), transcription factors (hepatic nuclear factor 4α and CCAAT/enhancer-binding protein β), protein and metabolic enzymes (albumin, glucose-6-phosphatase, tryptophan 2,3-dioxygenase, arginase 1 and cytochrome P450 7A1) and transporters (organic anion transporting peptide 1, multidrug resistance-associated protein 2 and bile salt export pump), in spheroids derived from rat hepatocytes. Further, we compared these expression levels with those in a hepatocyte monolayer and in liver tissue. Only the gene encoding glucose-6-phosphatase (required for sugar metabolism) was expressed at a similar level in both the monolayer culture and liver tissue for 10 days of culture; the expression of all the other genes in the monolayer culture either rapidly decreased or completely disappeared as the culture duration increased. Although the expression levels of all the genes in the spheroids tended to decrease gradually with culture time, they were consistently higher than those in the monolayer culture for at least 10 days of culture. These results suggest that hepatocyte spheroids acquire intercellular organization and largely maintain many intercellular metabolic functions. Thus, the hepatocyte spheroid culture system seems to be promising for various in vitro cell-based assays.

Efficacy of a polyurethane foam/spheroid artificial liver by using human hepatoblastoma cell line (Hep G2)

We investigated the availability of human hepatoblastoma cell line (Hep G2), compared with human primary hepatocytes (HH) and porcine primary hepatocytes (PH), as a cell source for the hybrid artificial liver support system (HALSS) by using polyurethane foam (PUF). All three kinds of hepatocytes spontaneously formed spherical multicellular aggregates (spheroids) of 100–200 μm diameter in the pores of PUF within 3 days of culture. In a PUF stationary culture, Hep G2 spheroids recovered the ammonia removal activity that was lost in monolayer culture, although the removal for each unit cell number was about one tenth that of HH spheroids and about one eighth of PH spheroids. The synthesis activities of albumin and fibrinogen of each unit cell number of Hep G2 were also upregulated by PUF spheroid culture, and were about twice as high as in monolayer culture. The albumin secretion activity of Hep G2 spheroids was almost the same as that of PH spheroids. HH scarcely secreted these proteins in this experiment, probably because they were cultured in a serum-free medium. In the PUF module in a circulation culture, HH had high ammonia removal and low synthesis activities similar to stationary culture. Hep G2 proliferated to a high cell density, such as about 4.8 × 107 cells/cm3-module at 10 days of culture. Although Hep G2 spheroids had low ammonia removal activity in each cell, the removal rate in the PUF module was almost the same as for PH at 7 days of culture because of the high cell density culture by cell proliferation. The albumin secretion rate by Hep G2 in the PUF module also increased with cell proliferation and was about 10 times higher than the initial rate for PH at 7 days of culture. These results suggest that Hep G2 is a potential cell source for the PUF-HALSS.

Hepatocyte spheroid culture on a polydimethylsiloxane chip having microcavities.

A two-dimensional microarray technique of spherical multicellular aggregates (spheroids) using a microfabricated polydimethylsiloxane (PDMS) chip and the expression of liver-specific functions of primary rat hepatocytes on the chip were investigated. The PDMS chip, which was fabricated by a photolithography-based technique, consisted of approximately 2500 cylindrical microcavities (approximately 1100 cavities/cm2) in a triangular arrangement of 330 μm pitch on a PDMS plate (20 × 20 mm); each cavity measured 300 μm in diameter and 100 μm in depth. Most hepatocytes on the PDMS chip gradually gathered and subsequently formed a single spheroid in each cavity until 3 days of culture. A part of the spheroid was attached to the bottom or wall surface of the microcavity, and the spheroid configuration was maintained for at least 14 days of culture. Albumin secretion, ammonia removal and ethoxyresorufin O-dealkylase (EROD) activity, which is a cytochrome P-450-dependent reaction, of hepatocytes on the PDMS chip were higher than those of a monolayer dish or a flat PDMS dish without microcavities, and were maintained for at least 10 days of culture. The spheroid microarray technique appears to be promising in the development of cell chips and microbioreactors.

Embryoid body culture of mouse embryonic stem cells using microwell and micropatterned chips.

The proliferation and differentiation properties of embryoid bodies (EB) from mouse embryonic stem (ES) cells were compared under two microchip conditions: microwell chip and micropatterned chip. The microwell chip contained 270 microwells (diameter, 600 μm; depth, 600 μm) on a polymethylmethacrylate plate and was surface-modified with polyethylene glycol (PEG) to render it non-adhesive. The micropatterned chip contained 270 gelatin spots (diameter, 200 μm) as the cell adhesion area on a glass plate; the region lacking these spots was PEG-modified to render it non-adhesive. The ES cells spontaneously formed the EBs from cell aggregates in each microwell in the chip. In contrast, cells inoculated onto the patterned chip formed a monolayer on the gelatin spots and gradually proliferated to form EBs. The EBs in the patterned chip maintained the high cell growth rate and the expression of endoderm (TTR and AFP) and mesoderm (Nkx2.5, αMHC, Flk1, and PDGFRβ) markers was increased, and these cell properties were similar to the previous methods (hanging drop and round-bottomed 96-well plate cultures). In contrast, the proliferation of ES cells in the microwell chip was lower than in the patterned chip and previous methods, and the EB differentiation proceeded slowly and only formed a small amount of endoderm. These results indicate that the difference of EB generating process in the microchip cultures may affect to the proliferation and differentiation of ES cells, and the existence of microwell structure in the microchip downregulates the cell proliferation and the differentiated progress of ES cells.

Polyurethane foam/spheroid culture system using human hepatoblastoma cell line (Hep G2) as a possible new hybrid artificial liver.

The risk of xenozoonosis infections poses the greatest obstacle against the clinical application of hybrid artificial liver support system (HALSS). Primary human hepatocytes are an ideal source for HALSS, but the shortage of human livers available for hepatocyte isolation limits this modality. To resolve this issue, we used human hepatocytes with replication capacity (fetal hepatocytes, Hep G2, and Huh 7) in a polyurethane foam (PUF)/spheroid culture system in vitro, and analyzed liver functions such as ammonia removal and albumin synthesis capacity; results were compared to those of porcine hepatocytes. Human fetal hepatocytes, Hep G2, and Huh 7 formed spheroids spontaneously within 24 h in a PUF/spheroid culture system; ammonia removal activity (μmol/106 nuclei/h) was upregulated, as was albumin synthesis activity (μg/106 nuclei/day). In particular, Hep G2 spheroids demonstrated high ammonia removal and albumin synthesis activities: 85% of the ammonia removal activity and 171.7% of the albumin synthesis activity of porcine hepatocytes in the monolayer culture. These results indicate the possibility of the development of a multicapillary PUF (MC-PUF) packed-bed culture system of hepatocyte spheroids as a HALSS using Hep G2.

Micropatterned Organoid Culture of Rat Hepatocytes and HepG2 Cells

The culture of liver cell organoids (multicellular aggregates) such as spheroids or cylindroids, which can strongly express liver functions, has been advocated as a useful technique that has advantages over monolayer culture. This paper describes a micropatterning technique for obtaining spheroids and cylindroids by using rat hepatocytes or HepG2 cells. We developed culture chips that comprised multiple, circular or rectangular microwells; the bottom surface of each microwell was modified with collagen to create a cell adhesion area, and the entire microwell, excluding the collagen-coated spots, was modified with polyethylene glycol (PEG) to create a nonadhesive area. Rat hepatocytes and HepG2 cells formed uniform spheroids and cylindroids on the circular and rectangular chips, respectively. Consequently, two-dimensional micropatterned chips containing homogeneous spheroids or cylindroids were generated. The expression of liver functions (protein secretion and ammonia removal) was greater in the spheroids and cylindroids than in the monolayer culture, and this expression was maintained for at least 2 weeks of culture. Thus, this chip technology has potential for use in various applications that involve organoid culture.

Near-IR laser-triggered target cell collection using a carbon nanotube-based cell-cultured substrate.

Unique near-IR optical properties of single-walled carbon nanotube (SWNTs) are of interest in many biological applications. Here we describe the selective cell detachment and collection from an SWNT-coated cell-culture dish triggered by near-IR pulse laser irradiation. First, HeLa cells were cultured on an SWNT-coated dish prepared by a spraying of an aqueous SWNT dispersion on a glass dish. The SWNT-coated dish was found to show a good cell adhesion behavior as well as a cellular proliferation rate similar to a conventional glass dish. We discovered, by near-IR pulse laser irradiation (at the laser power over 25 mW) to the cell under optical microscopic observation, a quick single-cell detachment from the SWNT-coated surface. Shockwave generation from the irradiated SWNTs is expected to play an important role for the cell detachment. Moreover, we have succeeded in catapulting the target single cell from the cultured medium when the depth of the medium was below 150 μm and the laser power was stronger than 40 mW. The captured cell maintained its original shape. The retention of the genetic information of the cell was confirmed by the polymerase chain reaction (PCR) technique. A target single-cell collection from a culture medium under optical microscopic observation is significant in wide fields of single-cell studies in biological areas.

Hepatocyte spheroid arrays inside microwells connected with microchannels

Spheroid culture is a preferable cell culture approach for some cell types, including hepatocytes, as this type of culture often allows maintenance of organ-specific functions. In this study, we describe a spheroid microarray chip (SM chip) that allows stable immobilization of hepatocyte spheroids in microwells and that can be used to evaluate drug metabolism with high efficiency. The SM chip consists of 300-μm-diameter cylindrical wells with chemically modified bottom faces that form a 100-μm-diameter cell adhesion region surrounded by a nonadhesion region. Primary hepatocytes seeded onto this chip spontaneously formed spheroids of uniform diameter on the cell adhesion region in each microwell and these could be used for cytochrome P-450 fluorescence assays. A row of microwells could also be connected to a microchannel for simultaneous detection of different cytochrome P-450 enzyme activities on a single chip. The miniaturized features of this SM chip reduce the numbers of cells and the amounts of reagents required for assays. The detection of four cytochrome P-450 enzyme activities was demonstrated following induction by 3-methylcholantlene, with a sensitivity significantly higher than that in conventional monolayer culture. This microfabricated chip could therefore serve as a novel culture platform for various cell-based assays, including those used in drug screening, basic biological studies, and tissue engineering applications.

Effect of microwell chip structure on cell microsphere production of various animal cells.

The formation of three-dimensional cell microspheres such as spheroids, embryoid bodies, and neurospheres has attracted attention as a useful culture technique. In this study, we investigated a technique for effective cell microsphere production by using specially prepared microchip. The basic chip design was a multimicrowell structure in triangular arrangement within a 100-mm(2) region in the center of a polymethylmethacrylate (PMMA) plate (24x24 mm(2)), the surface of which was modified with polyethylene glycol (PEG) to render it nonadhesive to cells. We also designed six similar chips with microwell diameters of 200, 300, 400, 600, 800, and 1000 microm to investigate the effect of the microwell diameter on the cell microsphere diameter. Rat hepatocytes, HepG2 cells, mouse embryonic stem (ES) cells, and mouse neural progenitor/stem (NPS) cells formed hepatocyte spheroids, HepG2 spheroids, embryoid bodies, and neurospheres, respectively, in the microwells within 5 days of culture. For all the cells, a single microsphere was formed in each microwell under all the chip conditions, and such microsphere configurations remained throughout the culture period. Furthermore, the microsphere diameters of each type of cell were strongly positively correlated with the microwell diameters of the chips, suggesting that microsphere diameter can be factitiously controlled by using different chip conditions. Thus, this chip technique is a promising cellular platform for tissue engineering or regenerative medicine research, pharmacological and toxicological studies, and fundamental studies in cell biology.