欢迎登录材料期刊网

材料期刊网

中国科学院金属研究所 科学出版社
高级检索
  1. 首页
  2. 期刊
  3. 材料科学技术(英文)
  4. Influence of 3D Microgrooves on C2C12 Cell Proliferation, Migration, Alignment, F-actin Protein Expression and Gene Expression

材料科学技术(英文), 2016, 32(9): 901-908. doi: 10.1016/j.jmst.2016.01.011

Influence of 3D Microgrooves on C2C12 Cell Proliferation, Migration, Alignment, F-actin Protein Expression and Gene Expression

Gao Huichang 1,2,3, , Cao Xiaodong 2,3, , Dong Hua 1,2,*,, , Fu Xiaoling 1,2,3, , Wang Yingjun 1,2,3,*,,

1. Department of Biomedical Engineering, School of Materials Science and Engineering, South China University of Technology, Guangzhou 510641, China

2. National Engineering Research Center for Tissue Restoration and Reconstruction, Guangzhou 510006, China

3. Guangdong Province Key Laboratory of Biomedical Engineering, South China University of Technology, Guangzhou 510006, China

Correspondence author: Dong Hua, donghua@scut.edu.cnCorrespondence author: Wang Yingjun,

  

Keywords: Cell behaviors , 3D microgroove , Poly(lactic-co-glycolic acid) , Cytoskeleton , Gene microarray , Real-time living cell monitoring

In this paper, we fabricated three kinds of 3D microgrooves with different depth on biocompatible poly(lactic-co-glycolic acid) (PLGA) substrate via combination of soft-lithography and melt-casting methods, and investigated in detail their influence on C2C12 cell behaviors. It is found that cell proliferation, migration, alignment, spatial distribution, F-actin protein expression and gene expression are all remarkably distinct on these microgrooved samples and the smooth control PLGA substrate. The associated underlying mechanisms were further analyzed and discussed using real-time living cell monitoring, confocal laser scanning microscopy and gene microarray. Our preliminary results suggested that 3D microstructure could affect cell behaviors in a much more extensive manner than what we had understood before.

参考文献

[1] E.K. Yim, S.W. Pang, K.W. Leong.Exp. Cell Res, 313(2007), pp. 1820-1829
[2] L. Moroni, L.P. Lee. J. Biomed. Mater.Res. A, 88(2009), pp. 644-653
[3] D.W. Hamilton, C. Oakley, N.A. Jaeger, D.M. Brunette.Cell Motil. Cytoskeleton, 66(2009), pp. 260-271
[4] Y. Yang, K. Kusano, H. Frei, F. Rossi, D.M. Brunette, E.E. Putnins. J. Biomed. Mater.Res. A, 95(2010), pp. 294-304
[5] B.J. Papenburg, L. Vogelaar, L.A.Bolhuis-Versteeg, R.G. Lammertink, D. Stamatialis, M. Wessling. Biomaterials, 28(2007), pp. 1998-2009
[6] D. Kim, K. Han, K. Gupta, K.W. Kwon, K. Suh, A. Levchenko.Biomaterials, 30(2009), pp. 5433-5444
[7] D.E. Discher, P. Janmey, Y. Wang.Science, 310(2005), pp. 1139-1143
[8] D.J. Behonick, Z. Werb. Mech.Develop, 120(2003), pp. 1327-1336
[9] M.J. Dalby, M.O. Riehle, D.S. Sutherland, H. Agheli, A.S. Curtis.Eur. J. Cell Biol, 83(2004), pp. 159-169
[10] Y.N. Xia, G.M. Whitesides.Ann. Rev. Mater. Sci, 28(1998), pp. 153-184
[11] P. Clark, P. Connolly, A.S. Curtis, J.A. Dow, C.D. Wilkinson.J. Cell Sci, 99(1991), pp. 73-77
[12] N. Gadegaard, S. Thoms, D.S. Macintyre, K. McGhee, J. Gallagher, B. Casey, C. Wilkinson. Microelectron.Eng, 67-68(2003), pp. 162-168
[13] C.L. Haynes, A.D. McFarland, M.T. Smith, J.C. Hulteen, R.P. Van Duyne. J. Phys. Chem. B, 106(2002), pp. 1898-1902
[14] S.M. Yang, S.G. Jang, D.G. Choi, S. Kim, H.K. Yu.Small, 2(2006), pp. 458-475
[15] G. Zhang, D. Wang. Chem.Asian J., 4(2009), pp. 236-245
[16] N.W. Karuri, T.J. Porri, R.M. Albrecht, C.J. Murphy, P.F. Nealey.IEEE Trans. Nanobioscience, 5(2006), pp. 273-280
[17] K.W. Kwon, H. Park, K.H. Song, J. Choi, H. Ahn, M.J. Park, K.Y. Suh, J. Doh. J.Immunol, 189(2012), pp. 2266-2273
[18] H. Jeon, C.G. Simon, G. Kim. J.Biomed. Mater. Res. Part B Appl. Biomater, 102(2014), pp. 1580-1594
[19] D. Kim, J. Kim, H. Hyun, K. Kim, S. Roh. Arch.Oral Biol, 59(2014), pp. 765-774
[20] M.J. Dalby, N. Gadegaard, R. Tare, A. Andar, M.O. Riehle, P. Herzyk, C.D. Wilkinson, R.O. Oreffo.Nat. Mater, 6(2007), pp. 997-1003
[21] C. Cha, W.B. Liechty, A. Khademhosseini, N.A. Peppas.ACS Nano, 6(2012), pp. 9353-9358
[22] W. Chen, S.J. Singer.J. Cell Biol, 95(1982), pp. 205-222
[23] R.E. Baier, A.E. Meyer.Int. J. Oral Max. Impl, 3(1988), pp. 9-20
[24] A.J. Banes, M. Tsuzaki, J. Yamamoto, T. Fischer, B. Brigman, T. Brown, L. Miller. Biochem.Cell Biol, 73(1995), pp. 349-365
[25] R.G. Flemming, C.J. Murphy, G.A. Abrams, S.L. Goodman, P.F. Nealey.Biomaterials, 20(1999), pp. 573-588
[26] R. Singhvi, G. Stephanopoulos, D.I. Wang.Biotechnol. Bioeng, 43(1994), pp. 764-771
[27] X. Yao, R. Peng, J. Ding. Adv. Mater, 25(2013), pp. 5257-5286
[28] P. Clark, P. Connolly, A.S. Curtis, J.A. Dow, C.D. Wilkinson.Development, 99(1987), pp. 439-448
[29] A. Curtis, C. Wilkinson.Biomaterials, 18(1997), pp. 1573-1583
[30] K.J. McHugh, M. Saint Geniez, S.L. Tao. J. Biomed. Mater. Res. Part B Appl. Biomater, 101(2013), pp. 1571-1584
[31] A.F. von Recum, T.G. van Kooten. J. Biomater. Sci. Polym. Ed, 7(1995), pp. 181-198
[32] J.L. Charest, A.J. Garcia, W.P. King.Biomaterials, 28(2007), pp. 2202-2210
[33] Y. Zhao, H. Zeng, J. Nam, S. Agarwal. Biotechnol.Bioeng, 102(2009), pp. 624-631
[34] M.T. Lam, S. Sim, X. Zhu, S. Takayama.Biomaterials, 27(2006), pp. 4340-4347
[35] N.F. Huang, S. Patel, R.G. Thakar, J. Wu, B.S. Hsiao, B. Chu, R.J. Lee, S. Li.Nano Lett, 6(2006), pp. 537-542
[36] G.E. Park, M.A. Pattison, K. Park, T.J. Webster.Biomaterials, 26(2005), pp. 3075-3082
[37] S. Cei, A. Legitimo, S. Barachini, R. Consolini, G. Sammartino, L. Mattii, M. Gabriele, F. Graziani.Implant Dent, 20(2011), pp. 285-291
[38] W. Su, Z. Li, F. Li, X. Chen, Q. Wan, D. Liang. Invest.Ophth. Vis. Sci, 54(2013), pp. 783-788
[39] X. Liu, Q. Feng, A. Bachhuka, K. Vasilev.ACS Appl. Mater. Inter, 6(2014), pp. 9733-9741
[40] J. Zhang, M. Wang, Z. Zhang, Z. Luo, F. Liu, J. Liu. Mol.Med. Rep, 11(2015), pp. 3021-3026
[41] X. Zou, L. Zou, C. Foldager, M. Bendtsen, W. Feng, C.E. Bünger.Biomaterials, 30(2009), pp. 991-1004
[42] H. Tsai, C. Kuo, S. Su, D. Wang, J. Lai. J.Memb. Sci, 345(2009), pp. 288-297
[43] J. Sutherland, M. Denyer, S. Britland. J.Anat, 206(2005), pp. 581-587
[44] T.J. Mitchison, L.P. Cramer.Cell, 84(1996), pp. 371-379
[45] J.V. Small, K. Anderson, K. Rottner. Biosci. Rep, 16(1996), pp. 351-368
[46] X.F. Walboomers, H. Croes, L.A. Ginsel, J.A. Jansen.Biomaterials, 19(1998), pp. 1861-1868
[47] C.J. Bettinger, B. Orrick, A. Misra, R. Langer, J.T. Borenstein.Biomaterials, 27(2006), pp. 2558-2565
[48] A.I. Teixeira, G.A. Abrams, P.J. Bertics, C.J. Murphy, P.F. Nealey.J. Cell Sci, 116(2003), pp. 1881-1892
[49] B. Dalton, X.F. Walboomers, M. Dziegielewski, M.D. Evans, S. Taylor, J.A. Jansen, J.G. Steele. J. Biomed. Mater.Res, 56(2001), pp. 195-207
[50] M.J. Dalby, M.O. Riehle, H. Johnstone, S. Affrossman, A. Curtis.Biomaterials, 23(2002), pp. 2945-2954
[51] P. Clark, P. Connolly, A.S. Curtis, J.A. Dow, C.D. Wilkinson.Development, 108(1990), pp. 635-644
[52] A. Curitis. F.Lyall, A.J. El Haj (Eds.), Biomechanics and Cells, Cambridge University Press, Cambridge(1994), pp. 121-130
[53] A. Curtis, G.M. Seehar.Nature, 274(1978), pp. 52-53
[54] M.J. Dalby, M.O. Riehle, S.J. Yarwood, C.D. Wilkinson, A.S. Curtis.Exp. Cell Res, 284(2003), pp. 274-282
[55] J.Y. Yang, Y.C. Ting, J.Y. Lai, H.L. Liu, H.W. Fang, W.B. Tsai. J. Biomed. Mater.Res. A, 90(2009), pp. 629-640
[56] L.E.McNamara, R. Burchmore, M.O. Riehle, P. Herzyk, M.J. Biggs, C.D. Wilkinson, A.S. Curtis, M.J. Dalby. Biomaterials, 33(2012), pp. 2835-2847
[57] M.J. Dalby, S.J. Yarwood, M.O. Riehle, H.J. Johnstone, S. Affrossman, A.S. Curtsi.Exp. Cell Res, 276(2002), pp. 1-9
[58] K. Katoh, Y. Kano, M. Amano, H. Onishi, K. Kaibuchi, K. Fujiwara. J.Cell Biol, 153(2001), pp. 569-583
[59] K. Katoh, Y. Kano, M. Amano, K. Kaibuchi, K. Fujiwara. Am. J. Physiol.Cell Physiol, 280(2001), pp. C1669-C1679
[60] A.J. Putnam, J.J. Cunningham, B.B.L.Pillemer, D.J. Mooney. Am. J. Physiol. Cell Physiol, 284(2003), pp. C627-C639
上一张 下一张
上一张 下一张
计量
  • 下载量()
  • 访问量()
作者相关
文章评分
  • 您的评分:
  • 1
    0%
  • 2
    0%
  • 3
    0%
  • 4
    0%
  • 5
    0%

版权所有©2010中国科学院金属研究所中国科技出版传媒股份有限公司

本系统由北京仁和汇智信息技术有限公司设计开发

技术支持:info@rhhz.net