Contact
    Start Publications Structural, physical, chemical, and biological surface ...
    ←  Publication Finder
    Attension

    Structural, physical, chemical, and biological surface characterization of thermomechanically treated Ti-Nb-based alloys for bone implants

    Year: 2020

    Journal: J. Biomed. Mater. Res. Part B, Volume 108, APR, page 647–662

    Authors: Sheremetyev, Vadim; Petrzhik, Mikhail; Zhukova, Yulia; Kazakbiev, Alibek; Arkhipova, Anastasia; Moisenovich, Mikhail; Prokoshkin, Sergey; Brailovski, Vladimir

    Keywords: bone implants; controlled oxidation; in vitro vitality of osteoblasts; mechanical and corrosion behavior; Ni-free shape memory alloys; surface characterization; thermomechanical treatment; wettability

    Metastable near-beta Ti-21.8Nb-6Zr and Ti-19.7Nb-5.8Ta (at%) alloys were subjected to a thermomechanical treatment comprising cold rolling (CR) with a true strain of e = 0.3 and post-deformation annealing (PDA) in the 500-900 degrees C temperature range to ensure the superelastic behavior which is important for bone implants. It was found that PDA resulted in formation of about 1-2 mu m-thick oxide layer on the Ti-Nb-Zr and Ti-Nb-Ta alloy samples; the layer was mainly composed of TiO2, in rutile and anatase modifications. The structure, the phase and chemical compositions, and some surface-sensitive properties of the alloys were compared to those of Ti-50.7Ni and Ti-Grade2 reference materials. These surface layers (especially that of the Ti-Nb-Zr alloy) demonstrated a promising combination of high cohesion strength (load causing surface layer fracture is over 25 N), hardness (similar to 12 GPa), and hydrophilicity (contact angle similar to 40 degrees). Surface modification by controlled oxidation during air annealing increases corrosion resistance and enhances in vivo osteoinductive properties of Ti-Nb-Zr alloys by changing the surface microrelief, increasing the surface wettability, and improving the mechanical characteristics, thus laying the foundation for the development of medical implants with prolonged service life. So, it was confirmed that the same thermomechanical treatment, which creates conditions for the superelastic behavior of the bulk metal (CR: e = 0.3 + PDA = 500-700 degrees C for 1 hr), would also create a strong, protective and biocompatible layer on the implant surface.
    View publication