The Behaviour of Electrochemical Deposition of Phosphate Coating on CoCr Bio Alloys

D. Ionita; I. Man; Ioana Demetrescu

doi:10.4028/www.scientific.net/KEM.330-332.545

Paper Titles

Fabrication of Porous Titania and Porous Calcium Phosphate Coatings on Titanium Surface
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Surface Modification of Vacuum Plasma Sprayed Titanium Coating via Two Different Treatments
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The Behavior of SiC Films Fabricated by Hybrid Laser-Magnetron Deposition after Immersion
p.537

Grafting Collagen on the Plasma Sprayed Titania Coating Treated by Sodium Hydroxide
p.541

The Behaviour of Electrochemical Deposition of Phosphate Coating on CoCr Bio Alloys
p.545

Calcium Phosphate Coatings on Titanium Alloy via an Electrodeposition Method
p.549

Early Peri-Implant Osteogenesis with Functionally Graded Nanophase Hydroxyapatite/Bioglass Coating on Ti Alloys
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Bloodcompatibility Improvement of Titanium Oxide Film Modified by Hydrogen Plasma Reduction
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In Vitro Dissolution of Amorphous Calcium Phosphate (ACP) Increased the Wear Particle Generation of Plasma-Sprayed HA Coatings
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The Behaviour of Electrochemical Deposition of Phosphate Coating on CoCr Bio Alloys

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Key Engineering Materials (Volumes 330-332)

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545-548

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https://doi.org/10.4028/www.scientific.net/KEM.330-332.545

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Online since:

February 2007

Authors:

D. Ionita, I. Man, Ioana Demetrescu

Keywords:

Biocompatibility, Cell Culture, CoCr Alloy, Electrochemical Deposition, Phosphate

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References

[1] Y. Okazaki, E. Gotoh, Biomaterials Vol.26 (2005), p.11

Google Scholar

[2] Silva RA, Barbosa MA, Vilar R, Conde O, Cunha Belo M, J. Mater. Sci.: Mater. in Medicine Vol.5 (1994), p.353

Google Scholar

[3] Sitting C., Textor M., Spencer ND, Wieland M., Wallotton P.H., J. Mater Sci. Mater Med, Vol.10 (1999), p.35

Google Scholar

[4] C.C. Ribeiro, M.A. Barbosa, A.A.S.C. Machado, A. Tudor and M.C. Davies, J. Mater Sci. Mater Med, Vol. 6 (1995) p.829

Google Scholar

[5] Ionescu D. Popescu B., Demetrescu I. Rev. Rom. De Chimie, Vol. 47 (2002), p.99

Google Scholar

[6] Jinno T., Kirk S.K., Morito S., Goldberg V.M., J.Arthroplasty, Vol.19 (2004), p.102

Google Scholar

[7] P.Y. Eschler1, L. Reclaru1, H. Lüthy2, A. Blatter1, C. Larue1, C. Süsz3, J. Bösch, European Cells and Materials, Vol. 9 (2005), p.64

Google Scholar

[8] A. Kocijan, I. Milos EV, D.K. Merl and B. Pihlar, J. Applied Electrochemistry Vol. 34(2004), p.517

Google Scholar

[9] T. Hanawa, S. Hiromoto and K. Asami, Appl. Surf. Sci. Vol. 183 (2001), p.68 MTT test after 24 h 0 50 100 150 200 Samples Vyability test(% from control) Control reference sample 3.5V,60min,room temperat 3.5V,20min,60C

Google Scholar