A Review on Fabrication Methods of Porous Titanium Dental Implant

Authors

  • Manmeet Goyal PG Student, Industrial Materials & Metallurgical Engineering Department, PEC University of Technology, Chandigarh

Keywords:

Osseointegration, Nanotube, Anodization, Topography, Biocompatibility, TIPS

Abstract

Titanium has got excellent mechanical and biological properties. It is nearly inert biologically as due to its biocompatibility. But titanium and its alloys have a high Young’s modulus compared to the bone. To improve osseo integration of Titanium alloy with bone tissues, various fabrications techniques are used to increase its roughness as well as porosity. In this review, the latest fabrication techniques like laser micro machining, anodization, additive manufacturing etc have been discussed along with their pros and cons. Techniques like laser micro machining, anodization and additive manufacturing gives us a promising modification of titanium topography by the formation of nanotubes on titanium surface. And help to understand the surface topography of titanium better. An attempt has been made to understand the potential of these advance manufacturing methods.

References

1. Alkhodary, M. A. (2014). Laser micro-grooved, Arginine-Glycine-Apspartic acid (RGD) coated dental implants, a 5 years radiographic follow-up. International journal of health sciences, 8(4), 361.
2. Çelen, S., & Özden, H. (2012). Laser-induced novel patterns: As smart strain actuators for new-age dental implant surfaces. Applied Surface Science, 263, 579-585.
3. Elias, C. N. (2011). Factors affecting the success of dental implants. INTECH Open Access Publisher.
4. Kim, K., Lee, B. A., Piao, X. H., Chung, H. J., & Kim, Y. J. (2013). Surface characteristics and bioactivity of an anodized titanium surface. Journal of periodontal & implant science, 43(4), 198-205.
5. Krishna, B. V., Bose, S., & Bandyopadhyay, A. (2007). Low stiffness porous Ti structures for loadbearing implants. Acta biomaterialia, 3(6), 997- 1006.
6. Li, Y., Yang, C., Zhao, H., Qu, S., Li, X., & Li, Y. (2014). New developments of Ti-based alloys for biomedical applications. Materials, 7(3), 1709-1800.
7. Otsuki, B., Takemoto, M., Fujibayashi, S., Neo, M., Kokubo, T., & Nakamura, T. (2006). Pore throat size and connectivity determine bone and tissue ingrowth into porous implants: three-dimensional micro-CT based structural analyses of porous bioactive titanium implants. Biomaterials, 27(35), 5892-5900.
8. Özcan, M., & Hämmerle, C. (2012). Titanium as a reconstruction and implant material in dentistry: advantages and pitfalls. Materials, 5(9), 1528-1545.
9. Özcan, M., & Hämmerle, C. (2012). Titanium as a reconstruction and implant material in dentistry: advantages and pitfalls. Materials, 5(9), 1528-1545.
10. Rack, H. J., & Qazi, J. I. (2006). Titanium alloys for biomedical applications. Materials Science and Engineering: C, 26(8), 1269-1277.
11. Sourav Bhatia, et al Modeling and Fabrication of Verte Brae Bioimplant Using Rapid Prototyping Journal Of Advanced Research In Production And Industrial Engineering, VOL 3, NO 3&4 (2016) pp 22- 34.
12. Thareja P. Concording building blocks for customised manufacture. Presented at the Seminar on Manufacturing Challenges for 21st Century, Institution of Engineers. 1995.
13. Thareja, Priyavrat, Competitive Foundry Through Integration of TIPS. Indian Foundry Journal, Vol 58, No. 1, p. 37, January 2012. Available at SSRN: https://ssrn.com/abstract=2015296.
14. Thareja Priyavrat Exploring Qualte-k-nology for a Breakthrough Tomorrow (Quality of, say, Particulate Technology Knowledge) OmniScience : A Multi-disciplinary Journal Vol 3, No 2 (2013), pp 12- 26.
15. Thareja Priyavrat Chasing Competence – A Journey through Metamorphosis Using Six Sigma Journal of Advanced Research in Production and Industrial Engineering. Vol 1, No 1 (2014), (1-11).
16. Thareja Priyavrat (2015) “Directions In Production Engineering Research” Part -3, Journal of Advanced Research in Production and Industrial Engineering 2(2), pp 17-28.
17. Thareja Priyavrat (2015) “Directions In Production Engineering Research” Part -IV, Journal of Advanced Research in Production and Industrial Engineering Vol 3, No 2 (2016) pp 30-52.
18. Tunchel, S., Blay, A., Kolerman, R., Mijiritsky, E., & Shibli, J. A. (2016). 3D Printing/Additive Manufacturing Single Titanium Dental Implants: A Prospective Multicenter Study with 3 Years of Follow-Up. International Journal of Dentistry, 2016.
19. van Grunsven, W. (2014). Porous metal implants for enhanced bone ingrowth and stability (Doctoral dissertation, University of Sheffield).
20. Wally, Z. J., van Grunsven, W., Claeyssens, F., Goodall, R., & Reilly, G. C. (2015). Porous titanium for dental implant applications. Metals, 5(4), 1902- 1920.
21. Yi, Y. A., Park, Y. B., Choi, H., Lee, K. W., Kim, S. J., Kim, K. M., & Shim, J. S. (2015). The evaluation of osseointegration of dental implant surface with different size of TiO 2 nanotube in rats. Journal of Nanomaterials, 2015, 2.

Published

2017-06-28