生物医用含锡元素钛合金的研究和进展

Effect of Zr and Sn on Young's modulus and superelasticity of Ti–Nb-based alloys[J] Y.L. Hao;S.J. Li;S.Y. Sun;R. Yang Materials Science & Engineering A 2006,

Microstructural and mechanical characterization of biomedical Ti–Nb–Zr(–Ta) alloys[J] L.M. Elias;S.G. Schneider;S. Schneider;H.M. Silva;F. Malvisi Materials Science & Engineering A 2006,

Bioactive ceramic composites sintered from hydroxyapatite and silica at 1200<Superscript>∘</Superscript>C: preparation; microstructures and <Emphasis Type="Italic">in vitro</Emphasis> bone-like layer growth[J] X. W. Li;H. Y. Yasuda;Y. Umakoshi Journal of Materials Science: Materials in Medicine 2006,

Quenched-in vacancies in a β Ti–Nb–Sn alloy studied by positron lifetime spectroscopy[J] Y. Nagai;T. Toyama;Z. Tang;M. Hasegawa;H. Matsumoto;S. Hanada Scripta Materialia 2006,

Effect of Ta content on mechanical properties of Ti–30Nb– X Ta–5Zr[J] Nobuhito Sakaguchi;Mitsuo Niinomi;Toshikazu Akahori;Junji Takeda;Hiroyuki Toda Materials Science & Engineering C 2005,

Corrosion behavior of a low modulus β-Ti-45%Nb alloy for use in medical implants[J] R. Godley;D. Starosvetsky;I. Gotman Journal of Materials Science: Materials in Medicine 2006,

Composition dependence of the microstructure and the mechanical properties of nano/ultrafine-structured Ti–Cu–Ni–Sn–Nb alloys[J] Acta Materialia 2004,

Fatigue performance and cyto-toxicity of low rigidity titanium alloy; Ti–29Nb–13Ta–4.6Zr[J] Mitsuo Niinomi Biomaterials 2003,

Recent Metallic Materials for Biomedical Applications[J] Mitsuo Niinomi Metallurgical and Materials Transactions; A. Physical Metallurgy and Materials Science 2002,

Theoretical study of the effects of alloying elements on the strength and modulus of β -type bio-titanium alloys[J] Y. Song;D.S. Xu;R. Yang;D. Li;W.T. Wu;Z.X. Guo Materials Science & Engineering A 1999,

Effect of Zr and Sn on Young's modulus and superelasticity of Ti–Nb-based alloys[J] Y.L. Hao;S.J. Li;S.Y. Sun;R. Yang Materials Science & Engineering A 2006,

Microstructural and mechanical characterization of biomedical Ti–Nb–Zr(–Ta) alloys[J] L.M. Elias;S.G. Schneider;S. Schneider;H.M. Silva;F. Malvisi Materials Science & Engineering A 2006,

Bioactive ceramic composites sintered from hydroxyapatite and silica at 1200<Superscript>∘</Superscript>C: preparation; microstructures and <Emphasis Type="Italic">in vitro</Emphasis> bone-like layer growth[J] X. W. Li;H. Y. Yasuda;Y. Umakoshi Journal of Materials Science: Materials in Medicine 2006,

Quenched-in vacancies in a β Ti–Nb–Sn alloy studied by positron lifetime spectroscopy[J] Y. Nagai;T. Toyama;Z. Tang;M. Hasegawa;H. Matsumoto;S. Hanada Scripta Materialia 2006,

Effect of Ta content on mechanical properties of Ti–30Nb– X Ta–5Zr[J] Nobuhito Sakaguchi;Mitsuo Niinomi;Toshikazu Akahori;Junji Takeda;Hiroyuki Toda Materials Science & Engineering C 2005,

Corrosion behavior of a low modulus β-Ti-45%Nb alloy for use in medical implants[J] R. Godley;D. Starosvetsky;I. Gotman Journal of Materials Science: Materials in Medicine 2006,

Composition dependence of the microstructure and the mechanical properties of nano/ultrafine-structured Ti–Cu–Ni–Sn–Nb alloys[J] Acta Materialia 2004,

Fatigue performance and cyto-toxicity of low rigidity titanium alloy; Ti–29Nb–13Ta–4.6Zr[J] Mitsuo Niinomi Biomaterials 2003,

Recent Metallic Materials for Biomedical Applications[J] Mitsuo Niinomi Metallurgical and Materials Transactions; A. Physical Metallurgy and Materials Science 2002,

Theoretical study of the effects of alloying elements on the strength and modulus of β -type bio-titanium alloys[J] Y. Song;D.S. Xu;R. Yang;D. Li;W.T. Wu;Z.X. Guo Materials Science & Engineering A 1999,