CHARACTERISTICS OF ADHESION AND PROLIFERATION OF MOUSE NIH/3T3 FIBROBLASTS ON THE POLY(3-HYDROXYBUTYRATE-CO-3-HYDROXYVALERATE) FILMS WITH DIFFERENT SURFACE ROUGHNESS VALUES

Adhesion and proliferation of NIH/3Т3 mouse fibroblasts on the surfaces of bacterial copolymer poly(3-hydroxy- butyrate-co-3-hydroxyvalerate) films with different roughness was investigated. Atomic force microscopic analysis showed that surface roughness values of all films were significantly greater (92.0 ± 7.0; 290.8 ± 7.0; 588.8 ± 16.0 nm) than that of the cultural plastic control (9.5 ±0.6 nm). It was revealed that adhesion and metabolic activity of the cells decreases with the increase of surface roughness values. NIH/3Т3 mouse fibroblasts attached weakly to the surface of copolymer films and washed away the substrate during rinsing and staining. 

1. Волова Т.Г., Севастьянов В.И., Шишацкая Е.И. Полиоксиалканоаты – биоразрушаемые полимеры для медицины: Монография. 2-е изд., дополн. и перера- бот. Красноярск, 2006. 288 с.

2. Севастьянов В.И., Перова Н.В., Немец Е.А. и др. Примеры экспериментально-клинического применения биосовместимых материалов в регенеративной медицине // Биосовместимые материалы (учебное пособие); под ред. В.И. Севастьянова, М.П. Кирпичникова. Часть II. Глава 3. М.: МИА, 2011. С. 237–252.

3. Сургученко В.А. Матриксы для тканевой инженерии и гибридных органов // Биосовместимые материалы (учебное пособие); под ред. В.И. Севастьяно- ва, М.П. Кирпичникова. Часть II. Глава 1. М.: МИА, 2011. С. 199–228.

4. Bartolo L.D., Rende M., Morelli S. et al. Influence of membrane surface properties on the growth of neuronal cells isolated form hippocampus // Journal of Membrane Science. 2008. Vol. 325. Р. 139–149.

5. Chang1 H.-I., Wang Y. Cell responses to surface and architecture of tissue engineering scaffolds in Regenerative medicine and tissue engineering – Cells and Biomaterials ed. By Daniel Eberli. 2011. Р. 569–588.

6. Chung T.-W., Liu D.-Z., Wang S.-Y. et al. Enhancement of the growth of human endothelial cells by surface roughness at nanometer scale // Biomaterials. 2003. Vol. 24. Р. 4655–4661.

7. Dalby1 M.J., Riehle M.O., Sutherland D.S. et al. Morphological and microarray analysis of human fibroblasts cultured on nanocolumns produced by colloidal lithography // European Cells and Materials. 2005. Vol. 9. Р. 1–8.

8. Kikuchi M., Kanama D. Current status of biomaterial research focused on regenerative medicine // Quarterly Review. 2007. 24. Р. 51–67.

9. Kumbar S.G., Kofron M.D., Nair L.S. et al. Cell behavior toward nanostructured surfaces in Biomedical Nanostructures / Edited by Kenneth E. Gonsalves, Craig R. Halberstadt, Cato T. Laurencin, Lakshmi S. Nair. 2008. Р. 261–287.

10. Lim J.Y., Hansen J.C., Siedlecki C.A. et al. Human foetal osteoblastic cell response to polymer-demixed nanotopographic interfaces // Journal of Royal Society Interface. 2005. Vol. 2. Р. 97–108.

11. Singhvi R., Stephanopoulos G., Wang D.I.C. Effects of substratum morphology on cell physiology // Biotechnol. and Bioeng. 1994. Vol. 43 (8). Р. 764–771.

12. Xu H., Bhavsar Z.A., Nguyen K.T. Nanoparticles- incorporated scaffolds for tissue engineering applications in Nanotechnology in tissue engineering and regenerative medicine / Edited by Ketul Popat. 2011. Part 14. Р. 14-1 – 14-17.