The Effect of Surface Conditions on Corrosion Resistance of a Cobalt-Chromium Alloy

[1] M.B. Nasab and M.R. Hassan, Metallic Biomaterials of Knee and Hip-A Review, Trends in Biomaterials and Artificial Organs. vol. 24 (2010) 69-82.

Google Scholar

[2] M. Navarro, A. Michiardi, O. Castano, and J. Planell, Biomaterials in orthopaedics. Journal of the Royal Society Interface. vol. 5 (2008) 1137-1158.

DOI: 10.1098/rsif.2008.0151

Google Scholar

[3] R. Narayan, Biomedical materials: Springer, (2009).

Google Scholar

[4] J.R. Davis, Handbook of materials for medical devices: ASM international, (2003).

Google Scholar

[5] J.B. Brunski, Chapter i.2.3. Metals: Basic Principles, in Biomaterials Science (Third Edition), D. R. Buddy, et al., Eds., ed: Academic Press. (2013) 111-119.

Google Scholar

[6] J.J. Ramsden, D.M. Allen, D.J. Stephenson, J.R. Alcock, G. Peggs, G. Fuller, and G. Goch, The design and manufacture of biomedical surfaces, CIRP Annals-Manufacturing Technology. vol. 56 (2007) 687-711.

DOI: 10.1016/j.cirp.2007.10.001

Google Scholar

[7] R. Singh and N.B. Dahotre, Corrosion degradation and prevention by surface modification of biometallic materials, Journal of Materials Science: Materials in Medicine. vol. 18 (2007) 725-751.

DOI: 10.1007/s10856-006-0016-y

Google Scholar

[8] A.M. Mamonov, A.P. Neiman, N.S. Gavryushenko, E.O. Agarkova, Theoretical and experimental analysis of standardized methods and results of technical tests of friction pairs of endoprostheses made of titanium alloy, Titan. No. 2(36) (2012) 26-30.

Google Scholar

[9] A.A. Ilyin, D.E. Gusev, Yu.V. Chernyshova, V.N. Karpov, E.A. Roshchina, Investigation of the corrosion resistance of biomaterials based on titanium and titanium nickelide, Technology of light alloys. 3 (2007) 123-130.

Google Scholar

[10] S.S. Slezov, A.M. Mamonov, A.A. Lidzhiev, E.O. Agarkova, Yu.V. Chernyshov, The influence of processing technology on the structure and corrosion resistance of an experimental titanium alloy with a high aluminum content, Titan. No. 4 (66) (2019) 12-16.

Google Scholar

[11] A.M. Mamonov, S.V. Skvortsova, V.S. Spektor, A.P. Neiman, E.A. Lukina, N.G. Mitropolskaya, Principles of construction of complex technological processes for the production of implants from titanium alloys, including vacuum ion-plasma nanotechnology, Titan. No. 3 (37) (2012) 45-50.

Google Scholar

[12] M. Geetha, A. Singh, R. Asokamani, and A. Gogia, Ti based biomaterials, the ultimate choice for orthopaedic implants–A review, Progress in Materials Science. vol. 54 (2009) 397-425.

DOI: 10.1016/j.pmatsci.2008.06.004

Google Scholar

[13] A.G. Au, V. James Raso, A. Liggins, and A. Amirfazli, Contribution of loading conditions and material properties to stress shielding near the tibial component of total knee replacements, Journal of biomechanics. vol. 40 (2007) 1410-1416.

DOI: 10.1016/j.jbiomech.2006.05.020

Google Scholar

[14] Yu.N. Petrov, G.I. Prokopenko, B.N. Mordyuk, M.A. Vasylyev, S.M. Voloshko, V.S. Skorodzievski, V.S. Filatova, Influence of microstructural modifications induced by ultrasonic impact treatment on hardening and corrosion behavior of wrought Co-Cr-Mo biomedical alloy, Materials Science and Engineering: C, Vol. 58 (2016) 1024-1035.

DOI: 10.1016/j.msec.2015.09.004

Google Scholar

[15] Kenta Yamanaka, Manami Mori, Ika Kartika, Moch. Syaiful Anwar, Koji Kuramoto, Shigeo Sato, Akihiko Chiba, Effect of multipassthermomechanical processing on the corrosion behaviour of biomedical Co–Cr–Mo alloys, Corrosion Science. Vol. 148 (2019) 178-187.

DOI: 10.1016/j.corsci.2018.12.009

Google Scholar

[16] Daixiu Wei, Yuichiro Koizumi, Akihiko Chiba, Kosuke Ueki, Kyosuke Ueda, Takayuki Narushima, Yusuke Tsutsumi, Takao Hanawa, Heterogeneous microstructures and corrosion resistance of biomedical Co-Cr-Mo alloy fabricated by electron beam melting (EBM), Additive Manufacturing. Vol. 24 (2018) 103-114.

DOI: 10.1016/j.addma.2018.09.006

Google Scholar

[17] S. Yang, D.A. Puleo, O.W. Dillon, and I.S. Jawahir, Surface Layer Modifications in Co-Cr-Mo Biomedical Alloy from Cryogenic Burnishing, Procedia Engineering. vol. 19 (2011) 383-388.

DOI: 10.1016/j.proeng.2011.11.129

Google Scholar

[18] Yu Yan, Anne Neville, Duncan Dowson, Tribo-corrosion properties of cobalt-based medical implant alloys in simulated biological environments, Wear. vol. 263 (2007) 1105–1111.

DOI: 10.1016/j.wear.2007.01.114

Google Scholar

[19] A. Oladokun, R.M. Hall b, A. Neville, M.G. Bryant, The evolution of subsurface micro-structure and tribo-chemical processes in cocrmo-ti6al4v fretting-corrosion contacts: What lies at and below the surface? Wear, vol. 440-441 (2019) 203095.

DOI: 10.1016/j.wear.2019.203095

Google Scholar

[20] Alfons Fischera, Sabine Wei ß, Markus A Wimmer, The tribological difference between biomedical steels and CoCrMo-alloys, Journal of the mechanical behavior of bimedical materials. vol. 9 (2012) 50-62.

DOI: 10.1016/j.jmbbm.2012.01.007

Google Scholar

[21] GOST R 9.905-2007 Unified system of protection against corrosion and aging. Corrosion test methods. General requirements., Moscow: Standartinform. (2007) 37.

Google Scholar

[22] P. Sunil Kumar, S.G. Acharyya, Controlling chloride induced stress corrosion cracking of AISI 316L stainless steel by application of buffing, Materials today: Proceedings. vol. 15, part 1 (2019) 138-144.

DOI: 10.1016/j.matpr.2019.05.036

Google Scholar

[23] R. A. Ibragimov, E. V. Korolev, T. R. Deberdeev, V. V. Leksin, D. B. Solovev, Energy Parameters of the Binder during Activation in the Vortex Layer Apparatus, Materials Science Forum, Vol. 945 (2019) 98-103. [Online]. Available: https://doi.org/10.4028/www.scientific.net/MSF.945.98.

DOI: 10.4028/www.scientific.net/msf.945.98

Google Scholar