In vitro bioactive nano-crystalline TiO2 layers grown at glass-coating/titanium interface

Yongxing Liu; Kanji Tsuru; Satoshi Hayakawa; Akiyoshi Osaka

doi:10.2109/jcersj.112.452

In vitro bioactive nano-crystalline TiO₂ layers grown at glass-coating/titanium interface

Yongxing Liu, Kanji Tsuru, Satoshi Hayakawa, Akiyoshi Osaka

Research output: Contribution to journal › Article › peer-review

8 Citations (Scopus)

Abstract

A new approach is presented to prepare a rutile layer on titanium substrates. According to this approach, pulverized glass, composed of 3CaO·4B₂O₃·3TiO₂, is first developed on the substrate, heated up to 700 to 850°C, and then removed by soaking in hot water. During the heating process, rutile grew at the glass coating-substrate interface to form nano-sized crystallites. The rutile layer induced apatite formation within 3 d when soaked in simulated body fluid of the Kokubo recipe. Such in vitro bioactivity was attributed to many Ti-OH groups on the crystallite surface derived from hydrolysis of bonds at the crystallite-flux (matrix) interface like (rutile) -Ti-O-B or Ti-O-Ca-(the borate matrix).

Original language	English
Pages (from-to)	452-457
Number of pages	6
Journal	Journal of the Ceramic Society of Japan
Volume	112
Issue number	1308
DOIs	https://doi.org/10.2109/jcersj.112.452
Publication status	Published - Aug 2004

Keywords

Apatite
Bioactivity
Glass coating
Rutile
Titania
Titanium

ASJC Scopus subject areas

Ceramics and Composites
Chemistry(all)
Condensed Matter Physics
Materials Chemistry

Access to Document

10.2109/jcersj.112.452

Cite this

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title = "In vitro bioactive nano-crystalline TiO2 layers grown at glass-coating/titanium interface",

abstract = "A new approach is presented to prepare a rutile layer on titanium substrates. According to this approach, pulverized glass, composed of 3CaO·4B2O3·3TiO2, is first developed on the substrate, heated up to 700 to 850°C, and then removed by soaking in hot water. During the heating process, rutile grew at the glass coating-substrate interface to form nano-sized crystallites. The rutile layer induced apatite formation within 3 d when soaked in simulated body fluid of the Kokubo recipe. Such in vitro bioactivity was attributed to many Ti-OH groups on the crystallite surface derived from hydrolysis of bonds at the crystallite-flux (matrix) interface like (rutile) -Ti-O-B or Ti-O-Ca-(the borate matrix).",

keywords = "Apatite, Bioactivity, Glass coating, Rutile, Titania, Titanium",

author = "Yongxing Liu and Kanji Tsuru and Satoshi Hayakawa and Akiyoshi Osaka",

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AB - A new approach is presented to prepare a rutile layer on titanium substrates. According to this approach, pulverized glass, composed of 3CaO·4B2O3·3TiO2, is first developed on the substrate, heated up to 700 to 850°C, and then removed by soaking in hot water. During the heating process, rutile grew at the glass coating-substrate interface to form nano-sized crystallites. The rutile layer induced apatite formation within 3 d when soaked in simulated body fluid of the Kokubo recipe. Such in vitro bioactivity was attributed to many Ti-OH groups on the crystallite surface derived from hydrolysis of bonds at the crystallite-flux (matrix) interface like (rutile) -Ti-O-B or Ti-O-Ca-(the borate matrix).

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