Increased bone apposition on a titanium oxide surface incorporating phosphate and strontium

Clinical Oral Implants Research

Volumn 22, Issue 2, 2011, Pages 230-234

  Park, Jin Woo ^a  

^a Kyungpook National University   (South Korea)

Author keywords

Histomorphometry; Osseointegration; Phosphate and strontium chemistry; Surface modification; Titanium implant

Indexed keywords

OXIDE; STRONTIUM; STRONTIUM TITANIUM OXIDE; TITANIUM; TITANIUM PHOSPHATE;

ANIMAL; ARTICLE; BONE REGENERATION; CHEMISTRY; FEMUR; MALE; NONPARAMETRIC TEST; PHYSIOLOGY; RABBIT; SCANNING ELECTRON MICROSCOPY; SURFACE PROPERTY; TIBIA; TOOTH IMPLANTATION;

ANIMALS; DENTAL IMPLANTS; FEMUR; MALE; MICROSCOPY, ELECTRON, SCANNING; OSSEOINTEGRATION; OXIDES; RABBITS; STATISTICS, NONPARAMETRIC; STRONTIUM; SURFACE PROPERTIES; TIBIA; TITANIUM;

EID: 78651355632     PISSN: 09057161     EISSN: 16000501     Source Type: Journal    
DOI: 10.1111/j.1600-0501.2010.01974.x     Document Type: Article

References (13)

1. Beck, G.R. (2003) Inorganic phosphate as a signaling molecule in osteoblast differentiation. Journal of Cellular Biochemistry 90: 234-243.
2. Buser, D., Broggini, N., Wieland, M., Schenk, R.K., Denzer, A.J., Cochran, D.L., Hoffmann, B., Lussi, A. & Steinemann, S.G. (2004) Enhanced bone apposition to a chemically modified SLA titanium surface. Journal of Dental Research 83: 529-533.
3. Eriksson, C., Nygren, H. & Ohlson, K. (2004) Implantation of hydrophilic and hydrophobic titanium discs in rat tibia: cellular reactions on the surfaces during the first 3 weeks in bone. Biomaterials 25: 4759-4766.
4. Park, J.-W., Jang, J.-H., Lee, C.-S. & Hanawa, T. (2009) Osteoconductivity of hydrophilic microstructured titanium implants with phosphate ion chemistry. Acta Biomaterialia 5: 2311-2321.
5. Park, J.-W., Kim, Y.-J. & Jang, J.-H. (2010a) Enhanced osteoblast response to hydrophilic strontium and/or phosphate ions-incorporated oxide surface. Clinical Oral Implants Research 21: 398-408.
6. Park, J.-W., Kim, Y.-J., Jang, J.-H., Kwon, T.-G., Bae, Y.-C. & Suh, J.-Y. (2010b) Effects of phosphoric acid treatment of titanium surfaces on surface properties, osteoblast response and removal torque forces. Acta Biomaterialia 6: 1661-1670.
7. Pi, M. & Quarles, D. (2004) A novel cation-sensing mechanism in osteoblasts is a molecular target for strontium. Journal of Bone and Mineral Research 19: 862-869.
8. Shibata, Y., Hosaka, M., Kawai, H. & Miyazaki, T. (2002) Glow discharge plasma treatment to titanium plates enhances adhesion of osteoblast-like cells to the plates through the integrin-mediated mechanism. The International Journal of Oral & Maxillofacial Implants 17: 771-777.
9. Sul, Y.-T. (2003) The significance of the surface properties of oxidized titanium to the bone response: special emphasis on potential biochemical bonding of oxidized implant. Biomaterials 24: 3893-3907.
10. Sul, Y.-T., Johansson, C. & Albrektsson, T. (2006) Which surface properties enhance bone response to implants? Comparison of oxidized magnesium, TiUnite, and Osseotite implant surfaces. The International Journal of Prothodontics 19: 319-328.
11. Sul, Y.-T., Johansson, C.B. & Albrektsson, T. (2002) Oxidized titanium screws coated with calcium ions and their performance in rabbit bone. The International Journal of Oral & Maxillofacial Implants 17: 625-634.
12. Susin, C., Qahash, M., Hall, J., Sennerby, J. & Wikesjo, U.M.E. (2008) Histological and biomechanical evaluation of phosphorylcholine-coated titanium implants. Journal of Clinical Periodontology 35: 270-275.
13. Yamamoto, H., Shibata, Y. & Miyazaki, T. (2005) Anode glow discharge plasma treatment of titanium plates facilitates adsorption of extracellular matrix proteins to the plates. Journal of Dental Research 84: 668-671.