Development of the central nervous system (CNS) occurs normally in mammalian fetus despite lower temperature in the brain region than in the heart. To investigate the effects of temperature niche on the neural differentiation of stem cells in vitro, P19 embryonic carcinoma (EC) stem cells and N2a neuroblastoma stem cells were induced to undergo neural differentiation by retinoic acid and LiCl, respectively. The cells were analyzed for the expression of neural marker genes during 12 days differentiation. Although there were Map2 and NCAM expressions in both groups, no clear difference was found. Similarly, expression patterns of Tuj1 and NF-M were not different in both groups, showing more intensive staining patterns at day 12 than those at days 4 and 8, respectively. However, more cells expressed GFAP markedly at day 12 in 37℃ group. There was little expression of the above markers in N2a cells during differentiation except for Ngn2 and Tuj1. It was found that Ngn2 was expressed more intensely at days 6 and 9 in 33℃ group. Tuj1 expression showed a similar pattern to those of P19 EC cells. RT-PCR analysis also showed that the expressed transcripts did not quite different in both groups, although they were different among the days of differentiation. Thus, it appears that neural differentiation occurs normally with a slight delay and probably less cell death in the cells at 33℃ than that at 37℃.

Use of nature-derived matrices of a part of body tissues has been used to repair damaged tissues in practical terms. Recently, the same idea has also been applied to regenerate whole organs including the heart, liver, lung, and pancreas etc. Thus, so-called bio-artificial organ technology becomes a promising way of overcoming the lack of donor organs and immune rejections in organ transplantation if we can obtain recipient stem cells. Although the regenerated heart in vitro so far may demonstrate some typical organ's responses in vitro and vivo, it is still far from a fully functional organ for transplantation. We initiated a study to look at changes occurring during the generation of bio-artificial organ using the mouse model. Adult hearts were dissected out and perfused for acellularization with SDS-containing buffer and washed several times. Enzymatic treatment also evaluated the acellular purity by isolating genomic DNA and total RNA before and after DNase and RNase treatments. For recellularization, differentiating H9C2 cell or cells derived from P19 EC cells along with mesenchymal stem cells were seeded on the finally obtained heart matrix several times before submerging culture for generating the heart. Histological analyses revealed that complete removal of cellular components. The intensive staining of alcian blue (pH 1.5 and 2.5) suggests that acid mucopolysaccharides, glycocomponents and sulfate-containing saccharides are widely spread within the heart matrix. There was little DNA and RNA in the heart matrix after the enzymatic treatments as judging by the DAPI or PI staining. Cell seeding and subsequent submerging culture showed substantial heart tissue development as evidenced by immunocytochemistry and RT-PCR in the recellularized and grown heart. From these results, we suggest that each procedure for bio-artificial organ has to be carefully examined to improve the entire process.