Kompozyt na bazie tytanu – potencjalny materiał implantacyjny

• Autorzy: Deptuła P. , Dąbrowski J. R. , Sobolewski A.

Warianty tytułu

EN

Titanium composite – potential implant biomaterial

• Języki publikacji: PL EN

Słowa kluczowe

PL

kompozyty; tytan; biomateriały; implanty

EN

composites; titanium; biomaterials; implants

• Wydawca: Polish Society for Biomaterials in Cracow
• Czasopismo: Engineering of Biomaterials
• Rocznik: 2011
• Tom: Vol. 14, no. 106-108
• Strony: 129--132
• Opis fizyczny: Bibliogr. 12 poz., tab., zdj.

Twórcy

autor

Deptuła P.

• Politechnika Białostocka, Wiejska 45C, 15-351 Białystok

autor

Dąbrowski J. R.

• Politechnika Białostocka, Wiejska 45C, 15-351 Białystok

autor

Sobolewski A.

• ChM, Lewickie 3b, 16-061 Juchnowiec Kościelny

Bibliografia

• [1] Long M., Rack H.J.: Titanium alloys in total joint replacement – a materials science perspective, Biomaterials, 19 (1998): 1621-1639.
• [2] Niinomi Mitsuo: Mechanical properties of biomedical titanium alloys, Materials Science and Engineering, A243 (1998), 231-236.
• [3] Eliopoulos D., Zinelis S., PapadopoulosT.: Porosity of cpTi casting with four different casting machines, The Journal of Prosthetic Dentisry, 4 (2004) Vol. 92, 377-381.
• [4] Semiatin S.L., Seetharaman V., Weiss I.: Hot workability of titanium and titanium aluminide alloys - an overview, Materials Science and Engineering, A243 (1998), 1-24.
• [5] Seagle S.R., Yu K.O., Giangiordano S.: Consideration in processing titanium, Materials Science and Engineering A243 (1999), 237-242.
• [6] Fujita T.,Ogawa A., Ouchi Ch., Tajima H.: Microstructure and properties of titanium alloy produced in the newly developed blened elemental powder metallurgy process, Materials Science and Engineering, A213 (1996), 148-153
• [7] Henriques V.A.R., Bellinati C.E., da Silva C.R.M.: Production of Ti-6%Al-7%Nb alloy by powder metallurgy (P/M), Journal of Materials Processing Technology, 118 (2001), 212-215.
• [8] Azevedo C.R. F., Rodrigues D., Beneduce Neto F.: Ti-Al-V powder metallurgy (PM) via the hydrogeneration – dehydrogeneration (HDH) process, Journal of Alloys and Compounds, 353 (2003), 217-227.
• [9] Broomfield R.W., Turner N.G., Leat B. I.: Application of advanced powder process technology to titanium aeroengine components, Powder Metallurgy, 1 (1985) Vol.28.
• [10] Hagiwara M., Kim S. J., Emura S.: Blended elemental P/M synthesis of Ti-6Al-1.7Fe-0.1Si alloy with improved high cycle fatigue strengh, Scripta Materialia, 39 (1998), 1185-1190.
• [11] Anokhin V.M., Ivasishin O.M., Petrunko A.N.: Structure and properties of sintered titanium alloyed with aluminium, molybdenum and oxygen, Materials Science and Engineering, A243 (1998), 269-272.
• [12] Kim Y. J., Kang S. J. L.: In situ formation of titanium carbide in titanium powder compacts by gas–solid reaction, Composites, A32 (2001): 731-738.