Liver normal cells and cancer cells co-cultured on surfaces modified by different chemical functional groups, including mercapto (-SH), hydroxyl (-OH) and methyl (-CHz) groups. The results showed that different ...Liver normal cells and cancer cells co-cultured on surfaces modified by different chemical functional groups, including mercapto (-SH), hydroxyl (-OH) and methyl (-CHz) groups. The results showed that different cells exhibited changes in response to different surfaces. Normal cells on -SH surface exhibited the smallest contact area with mostly rounded morphology, which led to the death of cancer cells, while cancer cells could not grow on -CH3 groups, which also died. In the co-culture system, the -CH3 group exhibited its unique effect that could trigger the death of cancer cells and had no effects on normal cells. Our findings provide useful information on strategies for the design of efficient and safe regenerative medicine materials.展开更多
Hepatoma cells (Hepg2s) as typical cancer cells cultured on hydroxyl (-OH) and methyl (- CH3) group surfaces were shown to exhibit different proliferation and morphological changes. Hepg2s cells on OH surfaces g...Hepatoma cells (Hepg2s) as typical cancer cells cultured on hydroxyl (-OH) and methyl (- CH3) group surfaces were shown to exhibit different proliferation and morphological changes. Hepg2s cells on OH surfaces grew much more rapidly than those on -CH3 surfaces. Hepg2s cells on -OH surfaces had the larger contact area and the more flattened morphology, while those on CH3 surfaces exhibited the smaller contact area and the more rounded morphology. After 7 days of culture, the migration of Hepg2s cells into clusters on the CH3 surfaces behaved significantly slower than that on the OH surfaces. These chemically modified surfaces exhibited regulation of Hepg2s cells on proliferation, adhesion, and migration, providing a potential treatment of liver cancer.展开更多
基金Acknowledgements This work was in part supported by the National Basic Research Program of China (Grant No. 2011 CB606205), the National Natural Science Foundation of China (Grant No. 51272236), and the Program for 521 Excellent Talents ofZhejiang Sci-Tech University.
文摘Liver normal cells and cancer cells co-cultured on surfaces modified by different chemical functional groups, including mercapto (-SH), hydroxyl (-OH) and methyl (-CHz) groups. The results showed that different cells exhibited changes in response to different surfaces. Normal cells on -SH surface exhibited the smallest contact area with mostly rounded morphology, which led to the death of cancer cells, while cancer cells could not grow on -CH3 groups, which also died. In the co-culture system, the -CH3 group exhibited its unique effect that could trigger the death of cancer cells and had no effects on normal cells. Our findings provide useful information on strategies for the design of efficient and safe regenerative medicine materials.
文摘Hepatoma cells (Hepg2s) as typical cancer cells cultured on hydroxyl (-OH) and methyl (- CH3) group surfaces were shown to exhibit different proliferation and morphological changes. Hepg2s cells on OH surfaces grew much more rapidly than those on -CH3 surfaces. Hepg2s cells on -OH surfaces had the larger contact area and the more flattened morphology, while those on CH3 surfaces exhibited the smaller contact area and the more rounded morphology. After 7 days of culture, the migration of Hepg2s cells into clusters on the CH3 surfaces behaved significantly slower than that on the OH surfaces. These chemically modified surfaces exhibited regulation of Hepg2s cells on proliferation, adhesion, and migration, providing a potential treatment of liver cancer.
