Nanotubular oxide layers formed on the Ti-based implants surfaces-application and possible damages: a review

Authors

Dragana Ranko Barjaktarević University of Belgrade, Faculty of Technology and Metallurgy
Veljko R Djokić Innovation Centre of the Faculty of Technology and Metallurgy, University of Belgrade, Karnegijeva 4 11120 Belgrade, Serbia
Ivana D. Damnjanović Faculty of Technology and Metallurgy, University of Belgrade, Karnegijeva 4 11120 Belgrade, Serbia
Marko P. Rakin Faculty of Technology and Metallurgy, University of Belgrade, Karnegijeva 4 11120 Belgrade, Serbia

DOI:

https://doi.org/10.30544/401

Keywords:

application of nanotubular oxide layer, biocompatibility, damage of nanotubular oxide layer, Ti-based implants, osseointegration

Abstract

Implant surface properties define the interaction of the implant with the surrounding tissue. To obtained advanced biological, mechanical and physical properties, metallic implants are often exposed to different kinds of surface modification. The electrochemical anodization process is an efficient method for nanostructured surface modification, which leads to the formation of nanotubular oxide layers on metallic surfaces. These obtained layers could be applied in biomedicine due to their chemical stability, biocompatibility and non-toxic nature in the human body. As a part of different kinds of medical implants such as dental implants, artificial hip joints, bone plates, screws, spinal fixation devices or stents, an oxide layer significantly increases cells adhesion and plays a significant role in improving the rate of osseointegration. However, an important topic in research of implants with a nanotubular oxide layer is integrity during fixation and exploitation and possible damage initiation and development. This review article aims to present the application of nanotubular oxide layers in biomedicine and to explain their influence on the biocompatibility and osseointegration of medical implants. Influence of the layers properties, such as roughness or contact angle, and the influence of their morphology on biocompatibility and osseointegration, as well as the influence of fixation and exploitation on the damage of the nanotubular oxide layer, are considered.

References

M. Zaki, Nanotechnology and Advances in Medicine, Nova Science Publishers, 2011.

C. Schmidt, J. Storsberg: Biomedic, 3 (2015) 203-223.

M. Obradović, S. Miljković, L .Matija, J. Munćan, Đ. Koruga: Sec. Cong. of Doc. of Med., Serbia, Book of Abstract, (2011) 1-12.

M. Goldberg, R. Langer, X. Jia: J Biomater Sci Polymer Edn, 18 (2007) 241-268.

J. Jung, H. Kobayashi, C. van Bommel, S. Shinkai, T. Shimizu: Chem Mater, 14 (2002) 1445-1447.

J. Lee, C. Leu, C. Hsu, W. Chung, H. Hon: J Phys Chem B, 109 (2005) 13056-13059

T. Kasuga, M. Hiramatsu, A. Hoson, T. Sekino, K. Niihara: Langmuir, 14 (1998) 3160-3163.

S. Zhang, W. Li, Z. Jin, J. Yang, J. Zhang, Z. Du, Z. Zhang: J Solid State Chem, 177 (2004) 1365-1371.

C. Tsai, N. Nian, H. Teng: Appl Surf Sci, 253(2006) 1898-1902.

D. Barjaktarević, I. Cvijović-Alagić, I. Dimić, V. Đokić, M. Rakin: Metall Mater Eng, 22 (2016) 129-143.

A. Gao, R. Hang, L. Bai, B. Tang, P. K. Chu: Electrochem Acta, 271 (2018) 699-718.

D. Portan, G. Papanicolaou, G. Jiga, M. Caposi: J Appl Electrochem, 42 (2012) 1013-1024.

M. Kulkarni, A. Mazare, E. Gongadze, Š. Perutkova, V. Kralj-Iglič, I. Milošev, P. Schmuki, A. Iglič, M. Mozetič: Titanium Nanotech, 26 (2015) 1-18.

K. Kim, N. Ramaswamy: Dent Mater J, 28 (2009) 20-36.

J. Hernández-López, A. Conde, J. Damborenea, M.A. Arenas: Corr Sci, 112 (2016) 194-203.

A. Tan, B. Pingguan-Murphy, R. Ahmad, S. Akbar: Ceramics Inter, 38 (2012) 4421-4435

M. Assefpour-dezfuly, C. Vlachos, E. Andrews: J Mater Sci, 19 (1984) 3626-3639.

V. Zwilling, E. Darque-Ceretti, A. Boutry-Forveille, D. David, M. Perrin, M. Aucouturier: Surf Interface Anal, 27 (1999) 629-637.

Q. Cai, M. Paulose, K. Varghese, A. Grimes: J of Mater Res, 20 (2005) 230-236.

C. Ruan, M. Paulose, M., K. Varghese, K. Mor, A. Grimes: The J of Phys Chem B, 109 (2005) 15754-15759.

M. Macak, H. Tsuchiya, P. Schmuki, P. Angewandte: Chem Inter Edition, 44 (2005) 7463-7465.

A. Ghicov, H. Tsuchiya, M. Macak, P. Schmuki: Electrochem Comm, 7 (2005). 505-509.

R. Aguirre, F. Echeverria: Appl Surf Sci, 445 (2018), 308-319.

P. Roy, S. Berger, P. Schmuki: Chem Int Ed, 50 (2011) 2904-2939.

T. Li, K. Gulati, N. Wangc Z. Zhang, S. Ivanovski: Mater Sci Eng C, 88 (2018) 182-195.

H. Tsuchiya, J. Macak, A. Ghicov, Y. Tang, S. Fujimoto, M. Niinomi, T. Noda, P. Schmuki: Electroch Acta, 52 (2006) 94-101.

DOT America, High-Tech Surfaces to Enhance Device Performance Link Accessed 12 December 2018.

M. Jungner, P. Lundqvist, S. Lundgren: Clin Oral Impl Res, 16 (2005) 308-312.

M. Jungner, P. Lundqvist, S. Lundgren: Clin Imp Dent Rel Res, 16 (2014) 230-237.

Titanium Anodizing Equipment & Information for Professionals Link Accessed 12 December 2018.

N. Kumar, N. Chauhan, A. Mittal, S. Sharma: Biometals, 31 (2018) 147-159.

S. Prasad, M. Ehrensberger, M. Gibson, H. Kim, E. Monaco: J of Oral Biosci, 57 (2015) 192-199.

R. Aguirre, M. Echeverry, D. Quintero, J. Castano, M. Harmsen, S. Robledo, F. Echeverr: J Biomed Mater Part A, 106 (2018) 1341-1354.

P. Branemark, R. Adell, T. Albrektsson, U. Lekholm, S. Lundkvist, B. Rockler: Biomater, 4 (1983) 25-28.

Y. Yi, Y. Park, H. Choi, K. Lee, S. Kim, K. Kim, S. Oh, J. Shim: J of Nanomater, (2015) 1-11.

T. Webster, C. Ergun, R. Doremus, R. Siegel, R. Bizios: Biomater, 21 (2000) 1803-1810.

N. Ergun, J. Liu, T. Webster, E. Olcay, S. Yilmaz, F. Sahin: J Biomed Mater Res Part A, 85 (2008) 236-241.

C. Yao, E. Slamovich, T. Webster: J Biomed Mater Res Part A, 85 (2008) 157-166.

K. Brammer, C. Frandsen, S. Jin: Trend in Biotechn, 30 (2012) 315-322.

W. Yu, X. Jiang, F. Zhang, L. Xu: J Biomed Mater Res Part A, 94 (2010) 1012-1022.

K. Brammer, S. Oh, C. Cobb, L. Bjursten, H. Heyde, S. Jin: Acta Biomater, 5 (2009) 3215-3223.

S. Oh, K. Brammer, Y. Li, D. Teng, A. Engler, S. Chien, S. Jin: PNAS, 106 (2009) 2130-2135.

D. Khudhair, A. Bhatti, Y. Li , H. Hamedani, H. Garmestani, P. Hodgson, S. Nahavandi: Mater Sci Engin, C 59 (2016) 1125-1142.

S. Minagar, J. Wang, C. Berndt, E. Ivanova, C. Wen: J Biomed Mater Res Part A, 101 (2013) 2726-2739.

J. Park, S. Bauer, K. Mark, P. Schmuki: Nano Lett, 7 (2007)1686-1691.

D. Barjaktarević, Đ. Veljović, I. Dimić, V. Đokić, M. Rakin: Conf Advan Ceram Applic VII, Book of Abstracts, 2018, p. 85,

S. Oh, C. Daraio, L. Chen, T. Pisanic, R. Fi˜nones, S. Jin: J of Biomed Mater Res Part A, 78 (2006) 97-103.

K. Brammer, S. Oh, C. Frandsen, S. Jin: Biomater Sci Engin, 405 (2011) 193-211.

S. Moon, S. Lee, I. Park, M. Lee, Y. Soh, T. Bae, H. Kim: Biomed Mater Res Part B, 100 (2012) 2053-2059.

E. Oh, T. Nguyen, S. Lee, Y. Jeon, T. Bae, J. Kim: The Kor J Orthod, 44 (2014) 246-253.

A. Ossowska, S. Sobieszczyk, M. Supernak, A. Zielinski: Sur & Coat Techn, 258 (2014) 1239-1248.

T. Shokuhfar, G. Arumugam, P. Heiden, R. Yassar, C. Friedrich, ACS Nano, 3 (2009) 3098-3102.

Y. Bai, Y. Deng, Y. Zheng, Y. Li, R. Zhang, Y. Lv, Q. Zhao, Sh. Wei: Mater Sci and Eng C, 59 (2016) 565-576.

G. Crawford, N. Chawla, J. Houston: J Mech Behav Biomed Mater, 2 (2009) 580 -587.

G. Crawford, N. Chawla, K. Das, S. Bose, A. Bandyopadhyay: Acta Biomater. 3 (2007) 359-367.

Y. Xu, M. Liu, M. Wang, A. Oloyede, J. Bell, C. Yan: J of Appl Phys, 118 (2015) 145301-145307.

A. Zielin’ski, P. Antoniuk, K. Krzysztofowicz: Surf Eng 30 (2014) 643-648.

S. Alves, A. Rossi, A. Ribeiro, F. Toptan, A. Pinto, T. Shokuhfar, J. Celis, L. Rocha: J of the Mech Behav of Biomed Mater 80 (2018) 143-154.

L. Lin, H. Wang, M. Ni, Y. Rui, T. Cheng, C. Cheng, X. Pan, G. Li, C. Lin: J of Orthop Transl, 2 (2014) 35-42.

H. Cheng, W. Xiong, Z. Fang, H. Guan, W. Wu, Y. Li, Y. Zhang, M. Alvarez, B. Gao, K. Huo, J. Xu, N. Xu, C. Zhang, J. Fu, A. Khademhosseini, F. Li: Acta Biomater. 31 (2016) 388-400.

H. Nuhn, C. Blanco, T. Desai: Appl Mater Interfaces, 9 (2017) 19677-19686.

I. Jang, S. Shim, D. Choi, B. Cha, J. Lee, B. Choe, W. Choi: Biomed Microdev, 17 (2015) 76-83.

K. Kubo, N. Tsukimura, F. Iwasa, T. Ueno, L. Saruwatari, H. Aita: Biomater, 30 (2009) 5319-329.

Y. Sul: Int J Nanomed, 5 (2010) 87-100.

Q. Wang, J. Huang, H. Li, A. Zhao, Y. Wang, K. Zhang, H. Sun, Y. Lai: Inter J of Nanomed, 12 (2017) 151-164.

L. Yang, B. Sheldon, T. Webster: American Ceram Soc Bull, 89 (2010) 24-32.

C. Yao, T. Webster: J of Biomed Mater Res Part B: Appl Biomater, 91(2009) 587-595.

K. Popat, M. Eltgroth, T. Tempa, C. Grimes, T. Desai: Biomater, 28 (2007) 4880-4888.

G. Balasundaram, C. Yao, T. Webster: J of Biomed Mater Res Part A, 84 (2008) 447-453.

S. Alvesa, A. Rossic, A. Ribeirob, F. Toptana, A. Pintoa, J. Celisg, T. Shokuhfari, L. Rochaa: Wear, 384 (2017) 28-42.

M. Sarra, B. Razak1, R. Crum, C. Gámez, B. Ramirez, N. Hayaty, B. Kasim, B. Nasiri-Tabriz, V. Gupta, N. Sukiman, W. Basirun: Process Appl Ceram, 11 (2017) 311-321.

K. Yonan, D. Rittel: J Mech Beh Biomed Mater, 49 (2015) 290 - 299.

T. Li, K. Gulati, N. Wang, Z. Zhang, S. Ivanovski: J of Coll and Interface Sci, 529 (2018) 452-463.

A. Shivaram, S. Bose, A. Bandyopadhyay: J Mech Beh Biomed Mater, 59 (2016) 508 -518.

A. Shivaram, S. Bose: A Surf Sci 317 (2014) 573-580.

D. Mints, C. Elias, P. Funkenbusch., L. Meirelles: Int J Oral Maxillofac Implant, 29 (2014) 97-104.

Z. Chen, W. Wang, Y. Takao, T. Matsubara, L. Ren: Appl Surf Sci, 262 (2012) 2-7.

L. Pazosa, P. Corengia, H. Svoboda: J Mech Beh Biomed Mater, 3 (2010) 416-424.

E. Urbańczyk, A. Krząkała, A. Kazek-Kęsik, J. Michalska, A. Stolarczyk, G. Dercz, W. Simka: Surf & Coat Technol, 291 (2016) 79-88.

A. Al-Swayih: Orient J Chem, 32 (2016) 2841-2856.

V. Saji, H. Choe: Corr Sci, 51 (2009) 1658-166.

D. Barjaktarević, J. Bajat, I. Cvijović-Alagić, I. Dimić, A. Hohenwarter, V. Đokić, M. Rakin: Proceedings of ECF22-Loading and Environmental effects on Structural Integrity, 2018, p. 494,

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2018-12-20

How to Cite

Barjaktarević, Dragana Ranko, Veljko R Djokić, Ivana D. Damnjanović, and Marko P. Rakin. 2018. “Nanotubular Oxide Layers Formed on the Ti-Based Implants Surfaces-Application and Possible Damages: A Review”. Metallurgical and Materials Engineering 24 (4). https://doi.org/10.30544/401.

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Issue

Vol. 24 No. 4 (2018): Nanomaterials: Synthesis, Characterization, and Applications

Section

Nanomaterials: Synthesis, Characterization and Applications

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Copyright (c) 2018 Dragana Ranko Barjaktarević, Veljko R Djokić, Ivana D. Damnjanović, Marko P. Rakin

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