Biomedical Engineering Reference
In-Depth Information
57. Mohapatra, S.K., Raja, K.S., Misra, M., Mahajan, V.K., and Ahmadian,
M. (2007). Synthesis of self-organized mixed oxide nanotubes by
sonoelectrochemical anodization of Ti-8Mn alloy,
Electrochim
.
Acta
,
53
, pp. 590-597.
58. Mor, G.K., Varghese, O.K., Paulose, M., Mukherjee, N., and Grimes, C.A.
(2003). Fabrication of tapered, conical-shaped titania nanotubes,
J
.
Mater
.
Res
.,
18
, pp. 2588-2593.
59. Muñoz, A.G. (2007). Semiconducting properties of self-organized TiO
2
nanotubes,
Electrochim
.
Acta
,
52
, pp. 4167-4176.
60. Narayanan, R., Seshadri, S.K., Kwon, T.Y., and Kim, K.H. (2007).
Electrochemical nano-grained calcium phosphate coatings on Ti-6Al-
4V for biomaterial applications,
Scripta Mater
.,
56
, pp. 229-232.
61. Niespodziana, K., Jurczyk, K., and Jurczyk, M. (2006). The manufacturing
of Ti-hydroxyapatite nanocomposites for bone implant applications,
Nanopages
,
1
, pp. 219-229.
62. Oh, H.-J., Lee, J.-H., Jeong, Y., Kim, Y.-J., and Chi, C.-S. (2005).
Microstructural characterization of biomedical titanium oxide ilm
fabricated by electrochemical method
,
Surf
.
Coat
.
Technol
.,
198
,
pp. 247-252.
63. Oh, H.-J., Lee, J.-H., Kim, Y.-J., Suh, S.-J., Lee, J.-H., and Chi, Ch.-S. (2008).
Surface characteristics of porous anodic TiO
2
layer for biomedical
applications,
Mat
.
Chem
.
Phys
.,
109
, pp. 10-14.
64. Oh, I.-H., Nomura, N., and Hanada, S. (2002). Microstructures and
mechanical properties of porous titanium compacts prepared by
powder sintering,
Mater
.
Trans
.,
43
, pp. 443-446.
65. Oh, I.-H., Nomura, N., Masahashi, N., and Hanada, S. (2003). Mechanical
properties of porous titanium compacts prepared by powder sintering,
Scripta Mater
.,
49
, pp. 1197-1202.
66. Oh, S., and Jin, S. (2006). Titanium oxide nanotubes with controlled
morphology for enhanced bone growth,
Mater
.
Sci
.
Eng
.
C
,
26
,
pp. 1301-1306.
67. Oh, S.H., Finones, R.R., Daraio, C., and Chen, L.H. (2005). Growth of
nano-scale hydroxyapatite using chemically treated titanium oxide
nanotubes,
Biomaterials
,
26
, pp. 4938-4943.
68. Oh, S.H., Daraio, C., Chen, L.H., and Pisanic, T. (2006).
Signiicantly
accelerated osteoblast cell growth on aligned TiO
2
nanotubes,
J
.
Biomed
.
Mater
.
Res
.,
78A
, pp. 97-103.
69. Okazaki, Y., Nishimura, E., Nakada, H., and Kobayashi, K. (2001).
Surface analysis of Ti-15Zr-4Nb-4Ta alloy after implantation in rat
tibia,
Biomaterials
,
22
, pp. 599-607.