Bone cell adhesion on titanium implants with nanoscale surface features

被引:0
|
作者
Ejiofor, Jeremiah U. [1 ]
Webster, Thomas J. [1 ]
机构
[1] Biomedical Engineering, Purdue University, Dept. of Biomedical Engineering, 500 Central Drive, West Lafayette, IN 47907, United States
来源
International Journal of Powder Metallurgy (Princeton, New Jersey) | 2004年 / 40卷 / 02期
关键词
Adhesion - Biocompatibility - Bone - Grain size and shape - Microscopic examination - Nanostructured materials - Particle size analysis - Substrates - Titanium;
D O I
暂无
中图分类号
学科分类号
摘要
The topography and morphology of participate Ti-6AL-4V and ASTM Grade II Ti were investigated in relation to their effects on cellular functions in orthopedic applications. Osteoblasts (bone-forming cells) were seeded onto substrates in order to assess the influence of particle size, particle shape and substrate grain size on cytocompatibility. Cells were cultured before seeding and were fixated and stained after adhesion and proliferation bioactivities. Fluorescent microscopy was utilized for cell counting and the mechanisms of adhesion were determined by scanning electron microscopy. Observations confirm the potential of submicron particles or nanoparticles in improving the biocompatibility of titanium implants.
引用
收藏
页码:43 / 53
相关论文
共 50 条
  • [21] Bone cell adhesion on ion implanted titanium alloys
    Braceras, I
    Onate, JI
    Goikoetxea, L
    Viviente, JL
    Alava, JI
    de Maeztu, MA
    SURFACE & COATINGS TECHNOLOGY, 2005, 196 (1-3): : 321 - 326
  • [22] Titanium Surface Coating with a Laminin-Derived Functional Peptide Promotes Bone Cell Adhesion
    Min, Seung-Ki
    Kang, Hyun Ki
    Jang, Da Hyun
    Jung, Sung Youn
    Kim, O. Bok
    Min, Byung-Moo
    Yeo, In-Sung
    BIOMED RESEARCH INTERNATIONAL, 2013, 2013
  • [23] Micro/nanoscale surface engineering to enhance hemocompatibility and reduce bacterial adhesion for cardiovascular implants
    Rahvar M.
    Ahmadi Lakalayeh G.
    Nazeri N.
    Karimi R.
    Borzouei H.
    Ghanbari H.
    Materials Chemistry and Physics, 2022, 289
  • [24] Myelointegration of titanium implants:: B lymphopoiesis and hemopoietic cell proliferation in mouse bone marrow exposed to titanium implants
    Rahal, MD
    Delorme, D
    Brånemark, PI
    Osmond, DG
    INTERNATIONAL JOURNAL OF ORAL & MAXILLOFACIAL IMPLANTS, 2000, 15 (02) : 175 - 184
  • [25] Bone-implant contact of surface-modified titanium implants
    Kim, Nam Gyu
    Park, Il Song
    Yi, Ho Keun
    Ahn, Seung Geun
    Song, Kwang Yeob
    Bae, Tae Sung
    Lee, Min Ho
    MULTI-FUNCTIONAL MATERIALS AND STRUCTURES, PTS 1 AND 2, 2008, 47-50 : 1294 - 1297
  • [26] The influence of surface bioactivated modification on titanium percutaneous implants anchored in bone
    Wu, Y.
    Yang, B. C.
    Deng, C. L.
    Tan, Y. F.
    Zhang, X. D.
    INTERNATIONAL JOURNAL OF ARTIFICIAL ORGANS, 2006, 29 (06): : 630 - 638
  • [27] A role for surface topography in creating and maintaining bone at titanium endosseous implants
    Cooper, LF
    JOURNAL OF PROSTHETIC DENTISTRY, 2000, 84 (05): : 522 - 534
  • [28] The influence of surface bioactivated modification on titanium percutaneous implants anchored in bone
    Wu, Yao
    Yang, B.C.
    Deng, C.L.
    Tan, Y.F.
    Zhang, X.D.
    International Journal of Artificial Organs, 2006, 29 (06): : 630 - 638
  • [29] Nanoscale Modification of Titanium Implants Improves Behaviors of Bone Mesenchymal Stem Cells and Osteogenesis In Vivo
    Li, Huangdi
    Huang, Jinghui
    Wang, Yanpeng
    Chen, Ziyuan
    Li, Xing
    Wei, Qiuping
    Liu, Xifeng
    Wang, Zi
    Wen, Bin
    Zhao, Yuetao
    Liu, Jing
    Zuo, Jun
    OXIDATIVE MEDICINE AND CELLULAR LONGEVITY, 2022, 2022
  • [30] Hindrance of osteoblast cell adhesion on titanium by surface nanostructuring
    Knapic, Dominik
    Minenkov, Alexey
    Luczak, Wiktor
    Zrinski, Ivana
    Kleber, Christoph
    Hild, Sabine
    Weth, Agnes
    Hassel, Achim Walter
    Mardare, Andrei Ionut
    SURFACES AND INTERFACES, 2024, 46
12345