The Effects of Initial Hemostatic Period on the Mechanical Strength and Transformation of Apatite Cement
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概要
- 論文の詳細を見る
It is well known that apatite cement causes inflammatory response if it is exposed to blood before setting. In this respect, the hemostatic procedure is very important. However, it has not been clarified how initial hemostasis affects the other basic properties of apatite cement. In the present study, the effect of initial hemostasis on the setting reaction was simulated by allowing the apatite cement paste to be hardened in an incubator for 1 to 30 minutes and then immersed in saline up to 7 days. We found faster transformation of apatite cement to apatitic mineral and higher mechanical strength of the set mass when the cement paste underwent a longer pre-hardening period. We also found that earlier exposure of apatite cement to saline resulted in a set mass with larger porosity. It is thought that the larger porosity of the cement is caused by the penetration of liquid into the cement paste, thus leading to lower mechanical strength and slower transformation of the apatite cement to apatitic mineral. We concluded, therefore, that hemostatic procedure is important not only to prevent inflammatory response but also to obtain a set mass with higher mechanical strength and faster transformation to apatitic mineral.
- 日本歯科理工学会の論文
著者
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MATSUYA Shigeki
Department of Biomaterials, Faculty of Dental Science, Kyushu University
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ISHIKAWA Kunio
Department of Biomaterials, Faculty of Dental Science, Kyushu University
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MATSUYA Shigeki
Section of Bioengineering, Department of Dental Engineering, Fukuoka Dental College
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Ishikawa Kunio
Department Of Biomaterials Faculty Of Dental Science Kyushu University
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Ishikawa Kunio
九州大学 歯学部口腔機能修復学講座
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Matsuya Shigeki
Department Of Biomaterials Faculty Of Dental Science Kyushu University
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Matsuya Shigeki
日本歯科先端技術研究所
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SHIGA Yasuaki
Japan Institute for Advanced Dentistry
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SHIMOGORYO Ryoji
Japan Institute for Advanced Dentistry
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OKA Tatsuo
Japan Institute for Advanced Dentistry
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Ishikawa Kunio
Department Of Biomaterials
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Ishikawa Kunio
Department of Applied Chemistry, Faculty of Engineering, Osaka Univeristy
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