Stepwise assembly of micropatterned co-cultures using photoresponsive culture surfaces and its application to hepatic tissue arrays.

Cell micropatterning, a method to place cells at arbitrary regions, is becoming an essential tool to conduct cell biology and tissue engineering. Conventional cell patterning techniques usually allow only single patterning with single cell type on the same culture surface. However, biomedical research today requires even sophisticated fabrication methods that require spatiotemporal control of multiple cell arrangements. Here we introduce in situ cell micropatterning system which enables stepwise cell patterning using a photoresponsive cell culture surface (PRCS) whose cell adhesiveness could be altered by the UV irradiation. To demonstrate an application to tissue engineering, a liver-mimic tissue array was fabricated and liver-specific gene expressions were quantified with real time PCR. Patterned co-culture systems composed of HepG2 spheroids with Balb/3T3 were fabricated, and the optimum spheroid diameter, which yielded the highest cellular functions, was determined to be 150 microm. After 20 days of patterned co-culture of HepG2 spheroids and Balb/3T3, CYP3A4 expression increased 50-fold higher than conventionally cultured HepG2; CYP3A4 expression was 20% higher than randomly co-cultured HepG2 and Balb/3T3. Thus the combination of PRCS and the photomask-free irradiation apparatus showed the versatility of experimental setups and proved to be a powerful tool for biomedical studies.

Selective separation and co-culture of cells by photo-induced enhancement of cell adhesion (PIECA).

Taking advantage of the phenomenon that animal cells adhering to a culture substrate are temporarily immobilized by light irradiation, we established a technique to manipulate the cells adhering to a culture substrate under microscopic observation. Using this technique, we demonstrated a separation of cells adhering to a culture substrate and fabrication of an elaborately patterned co-culture system.

Pressure-driven perfusion culture microchamber array for a parallel drug cytotoxicity assay.

This article reports a pressure-driven perfusion culture chip developed for parallel drug cytotoxicity assay. The device is composed of an 8 x 5 array of cell culture microchambers with independent perfusion microchannels. It is equipped with a simple interface for convenient access by a micropipette and connection to an external pressure source, which enables easy operation without special training. The unique microchamber structure was carefully designed with consideration of hydrodynamic parameters and was fabricated out of a polydimethylsiloxane by using multilayer photolithography and replica molding. The microchamber structure enables uniform cell loading and perfusion culture without cross-contamination between neighboring microchambers. A parallel cytotoxicity assay was successfully carried out in the 8 x 5 microchamber array to analyze the cytotoxic effects of seven anticancer drugs. The pressure-driven perfusion culture chip, with its simple interface and well-designed microfluidic network, will likely become an advantageous platform for future high-throughput drug screening by microchip.

Surface modification of polydimethylsiloxane with photo-grafted poly(ethylene glycol) for micropatterned protein adsorption and cell adhesion.

In this study, we applied photo-induced graft polymerization to micropatterned surface modification of polydimethylsiloxane (PDMS) with poly(ethylene glycol). Two types of monomers, polyethylene glycol monoacrylate (PEGMA) and polyethylene glycol diacrylate (PEGDA), were tested for surface modification of PDMS. Changes in the surface hydrophilicity and surface element composition were characterized by contact angle measurement and electron spectroscopy for chemical analysis. The PEGMA-grafted PDMS surfaces gradually lost their hydrophilicity within two weeks. In contrast, the PEGDA-grafted PDMS surface maintained stable hydrophilic characteristics for more than two months. Micropatterned protein adsorption and micropatterned cell adhesion were successfully demonstrated using PEGDA-micropatterned PDMS surfaces, which were prepared by photo-induced graft polymerization using photomasks. The PEGDA-grafted PDMS exhibited useful characteristics for microfluidic devices (e.g. hydrophilicity, low protein adsorption, and low cell attachment). The technique presented in this study will be useful for surface modification of various research tools and devices.

Manipulation of living cells by using PC-controlled micro-pattern projection system.

In order to meet the diversifying demand for the cell manipulation in the rapid progress of cell engineering, we developed a novel technique to capture the living cells on a culture substrate by irradiating light in a multiple manner. In clear contrast to the conventional cell patterning using the previously patterned substrate, the cell-retaining area can be defined even after cell seeding, and the captured cells can continue to grow freely beyond the defined area afterwards. After the light irradiation in arbitrary micropattern by using a newly developed apparatus and the process to remove non-captured cells including EDTA treatment, the highly contrasted cell patterns were formed with the precision of single cell size. Moreover, it was determined that the cell capturing arose just after light irradiation and diminished gradually in a time scale of 10h. It was confirmed that the cells maintained their viability well after the manipulation process including photo-induced cell capturing.

Phenylpropanoid metabolite supports cell aggregate formation in strawberry cell suspension culture.

Plant cells in suspension culture tend to aggregate and form large clumps. In suspension culture, large cell aggregates are frequently subjected to hydrodynamic shear stress; however, a certain degree of cell aggregation is often required for cell growth and metabolite production. Thus, controlling cell-aggregate size is desired to establish high productivity of useful products using plant cell suspension culture. In this study, we focused on the relationship between cell-aggregate formation and secondary metabolism. We found that anthocyanin concentration showed a good correlation with cell-aggregate size in the cultured strawberry cell line FAR (Fragaria ananassa R), which produces anthocyanin and other phenylpropanoid metabolites constitutively without illumination. This result suggests that there is a relationship between cell-aggregate formation and the accumulation of phenylpropanoid metabolites. To investigate the direct effect of phenylpropanoid metabolism on cell-aggregate formation, the time course of cell-aggregate size was monitored when phenylpropanoid metabolism was suppressed by a metabolic inhibitor, L-alpha-aminooxy-beta-phenylpropionic acid (AOPP), a specific inhibitor of phenylalanine ammonia lyase which is the starting and key enzyme of the phenylpropanoid pathway. In the absence of AOPP, the average diameter of cell aggregates increased on day 8 of culture. This increase in cell-aggregate size was completely suppressed by the addition of 0.1 mM AOPP, without any reduction in cell growth rate or soluble protein content. These results indicate that cell-aggregate formation is directly supported by a secondary metabolite produced from the phenylpropanoid pathway, suggesting that cell-aggregate size can be controlled by AOPP without inhibition of primary metabolism.

Photoresponse of an aqueous two-phase system composed of photochromic dextran.

A novel aqueous two-phase system, which exhibits a reversible photoinduced phase separation, has been developed with photochromic dextran synthesized by substituting 0.3 mol % of the hydroxyl groups with the photochromic chromophore, 6-nitrospiropyran (NSp). For an aqueous solution containing this photochromic dextran and poly(ethylene glycol), it was observed that the solution, which had been uniform in the dark, quickly separated into two phases through blue light irradiation within 1 min and returned to the former uniform state spontaneously after heating at 50 degrees C for 1 h. Photoisomerization of NSp was confirmed to shift the phase separation temperature of this aqueous two-phase system by up to 30 degrees C.

Separation of cultured strawberry cells producing anthocyanins in aqueous two-phase system.

A rapid and simple selection method of high-yield cells has been desired to establish highly productive cell lines for useful secondary metabolites. For this purpose, a new attempt was made to partition cultured plant cells in a poly(ethylene glycol)-dextran aqueous two-phase system (ATPS). The applicability of the ATPS in partitioning cultured strawberry cells (designated FAW) was investigated. The result of single-step partitioning in the ATPS supplemented with 0.4 mmol/kg lithium sulfate showed that FAW cells cultivated for 7 d under light-irradiation were separated into two cell populations with significantly different anthocyanin content. Additionally, the analysis technique of microscopic cell images showed that cells accumulating a high level of anthocyanin were partitioned completely into the bottom phase in a partitioning experiment of FAW cells cultivated for 10 d under light-irradiation in the ATPS supplemented with 1.8 mmol/kg potassium phosphate buffer. These results indicated that cell partitioning in ATPS increased the intracellular anthocyanin content and that the cultured strawberry cell population was heterogeneous in terms of cell surface properties. This is the first report of partitioning based on the heterogeneity of the cell surface properties correlated with the intracellular secondary metabolism in cultured plant cells. Our results also suggested that the ATPS was appropriate as a large-scale method for selecting useful cell lines among the cultured plant cells.

Enhanced accumulation of anthocyanin in cultured strawberry cells by repetitive feeding of L-phenylalanine into the medium.

L-Phenylalanine (Phe), biosynthetic precursor of anthocyanin, was repetitively added into a suspension culture of strawberry cells, constantly producing anthocyanins. In the repetitive feeding culture, the maximum anthocyanin accumulation per culture was 30% and 81% higher than those in a single Phe-feeding culture and non-feeding culture, respectively. This means that the inhibitory effect of Phe on cell growth was successfully avoided and its intracellular free-state concentration was maintained at a higher level by the repetitive feeding of L-phenylalanine at relatively lower intra-medium concentration. These results support the phenylalanine pool hypothesis which states that the intracellular L-phenylalanine level determines anthocyanin production. However, it was also suggested that there exist other restrictions controlling intracellular anthocyanin accumulation.

In situ control of cell adhesion using photoresponsive culture surface.

A photoresponsive culture surface (PRCS) allowing photocontrol of cell adhesion was prepared with a novel polymer material composed of poly(N-isopropylacrylamide) having spiropyran chromophores as side chains. Cell adhesion of the surface was drastically enhanced by the irradiation with ultraviolet (UV) light (wavelength: 365 nm); after subsequent cooling and washing on ice, many cells remained in the irradiated region, whereas most cells were removed from the nonirradiated region. The cell adhesion of the PRCS, which had been enhanced by previous UV irradiation, was reset by the visible light irradiation (wavelength 400-440 nm) and the annealing at 37 degrees C for 2 h. Also it was confirmed that the regional control of cell adhesion was induced several times by repeating the same series of operations. Further, living cell patterning with the 200 microm line width was produced readily by projecting UV light along a micropattern on the PRCS on which the living cells had been seeded uniformly in advance. By using a fluorescent probe that stains living cells only, it was confirmed that the cells maintained sufficient viability even after UV light irradiation followed by cooling and washing.

Continuous cell partitioning using an aqueous two-phase flow system in microfluidic devices.

We present a novel microfluidic system in which an aqueous two-phase laminar flow is stably formed, and the continuous partitioning of relatively large cells can be performed, eliminating the influence of gravity. In this study, plant cell aggregates whose diameters were 37-96 microm were used as model particles. We first performed cell partitioning using a simple straight microchannel having two inlets and two outlets and examined the effects of the flow rate and the phase width on partitioning efficiency. Second, by using a microchannel with a pinched segment, the partitioning efficiency was successfully improved. This microscale aqueous two-phase flow system can further be incorporated into micro total analysis systems (microTAS) or lab-on-a-chip technology, owing to its simplicity, applicability, and biocompatibility.