AI Article Synopsis
- Insufficient bonding between bone and orthopedic/dental implants may stem from material surface properties that hinder bone growth, making the development of bio-compatible surfaces crucial for future implants.
- Titanium and titanium alloys, while commonly used, face issues like poor bone integration and potential clinical failures due to fibrous capsule formation and material wear.
- The application of electrolytic hydroxyapatite/titanium dioxide (HA/TiO2) double layers on titanium has shown promise, improving adhesion strength significantly and promoting better cell differentiation and bioactivity in tests.
Article Abstract
Insufficient bonding of juxtaposed bone to an orthopedic/dental implant could be caused by material surface properties that do not support new bone growth. For this reason, fabrication of biomaterials surface properties, which support osteointegration, should be one of the key objectives in the design of the next generation of orthopedic/dental implants. Titanium and titanium alloy have been widely used in several bioimplant applications, but when implanted into the human body, these still contain some disadvantages, such as poor osteointegration (forming a fibrous capsule), wear debris and metal ion release, which often lead to clinical failure. Electrolytic hydroxyapatite/titanium dioxide (HA/TiO2) double layers were successfully deposited on titanium substrates in TiCl4 solution and subsequently in the mixed solution of Ca(NO3)2 and NH4H2PO4, respectively. After annealing at 300 degrees C for 1 h in the air, the coated specimens were evaluated by dynamic cyclic polarization tests, immersion tests, tensile tests, surface morphology observations, XRD analyses and cells culture. The adhesion strength of the HA coating were improved by the intermediate coating of TiO2 from 11.3 to 46.7 MPa. From cell culture and immersion test results, the HA/TiO2 coated specimens promoted not only cells differentiation, but also appeared more bioactive while maintaining non-toxicity.
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| http://dx.doi.org/10.1007/s10856-004-5678-8 | DOI Listing |
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View Article and Find Full Text PDFCharacterization and bond strength of electrolytic HA/TiO2 double layers for orthopaedic applications.
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Insufficient bonding of juxtaposed bone to an orthopaedic/dental implant could be caused by material surface properties that do not support new bone growth. For this reason, fabrication of biomaterials surface properties, which support osteointegration, should be one of the key objectives in the design of the next generation of orthopaedic/dental implants. Titanium and titanium alloy have been widely used in several bioimplant applications, but when implanted into the human body, these still contain some disadvantages, such as poor osteointegration (forming a fibrous capsule), wear debris and metal ion release, which often lead to clinical failure.
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Article Synopsis
- Insufficient bonding between bone and orthopedic/dental implants may stem from material surface properties that hinder bone growth, making the development of bio-compatible surfaces crucial for future implants.
- Titanium and titanium alloys, while commonly used, face issues like poor bone integration and potential clinical failures due to fibrous capsule formation and material wear.
- The application of electrolytic hydroxyapatite/titanium dioxide (HA/TiO2) double layers on titanium has shown promise, improving adhesion strength significantly and promoting better cell differentiation and bioactivity in tests.
Hydroxyapatite coating on titanium substrate with titania buffer layer processed by sol-gel method.
Biomaterials
June 2004
School of Materials Science and Engineering, Seoul National University, Seoul 151-742, South Korea.
Hydroxyapatite (HA) was coated onto a titanium (Ti) substrate with the insertion of a titania (TiO2) buffer layer by the sol-gel method. The HA layer was employed to enhance the bioactivity and osteoconductivity of the Ti substrate, and the TiO2 buffer layer was inserted to improve the bonding strength between the HA layer and Ti substrate, as well as to prevent the corrosion of the Ti substrate. The HA layer coated over the TiO2 showed a typical apatite phase at 400 degrees C and the phase intensity increased above 450 degrees C.
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