Effect of precursor's solubility on the mechanical property of hydroxyapatite formed by dissolution-precipitation reaction of tricalcium phosphate

Dental Materials Journal

Volumn 31, Issue 6, 2012, Pages 995-1000

  Ahmad, Nurazreena ^a   Tsuru, Kanji ^a   Munar, Melvin L ^a   Maruta, Michito ^b   Matsuya, Shigeki ^b   Ishikawa, Kunio ^a  

^a KYUSHU UNIVERSITY   (Japan)

^b FUKUOKA DENTAL COLLEGE   (Japan)

Author keywords

Dissolution precipitation; Hydroxyapatite; Mechanical property; Precursor solubility; Tricalcium phosphate

Indexed keywords

AMMONIA SOLUTION; BETA TRICALCIUM PHOSPHATE; BONE SUBSTITUTES; DIAMETRAL TENSILE STRENGTH; DISSOLUTION-PRECIPITATION; HYDROTHERMALLY; TRI-CALCIUM PHOSPHATES; XRD ANALYSIS;

DISSOLUTION; HYDROXYAPATITE; MECHANICAL PROPERTIES;

SOLUBILITY;

CALCIUM PHOSPHATE; HYDROXYAPATITE;

ARTICLE; BONE PROSTHESIS; CHEMISTRY; DENTAL PROCEDURE; POROSITY; SOLUBILITY; SYNTHESIS; TENSILE STRENGTH; X RAY CRYSTALLOGRAPHY;

BONE SUBSTITUTES; CALCIUM PHOSPHATES; CRYSTALLOGRAPHY, X-RAY; DENTAL STRESS ANALYSIS; DURAPATITE; POROSITY; SOLUBILITY; TENSILE STRENGTH;

EID: 84871171295     PISSN: 02874547     EISSN: 18811361     Source Type: Journal    
DOI: 10.4012/dmj.2012-176     Document Type: Article

References (13)

1. Aoki H, Kato K, Shiba M. Synthesis of hydroxyapatite under hydrothermal condition. Part I. Kinetics analysis of the reaction process from monetite into hydroxyapatite. J Jpn Soc Dent 1972; 13: 170-176.
2. Hench LL. Bioceramics. J Am Ceram Soc 1998; 81: 1705-1728.
3. 4treatment. Dent Mater J 2005; 24: 515-521.
4. Karashima S, Takeuchi A, Matsuya S, Udoh K, Koyano K, Ishikawa K. Fabrication of low-crystallinity hydroxyapatite foam based on the setting reaction of α-tricalcium phosphate foam. J Biomed Mater Res Part A 2009; 88A: 628-633.
5. Ishikawa K, Matsuya S, Lin X, Lei Z, Yuasa T, Miyamota Y. Fabrication of low-crystalline B-type carbonate apatite block from low crystalline calcite block. J Ceram Soc Jpn 2010; 118: 341-344.
6. Wakae H, Takeuchi A, Udoh K, Matsuya S, Munar ML, LeGeros RZ, Nakasima A, Ishikawa K. Fabrication of macroporous carbonate apatite foam by hydrothermal conversion of α-tricalcium phosphate in carbonate solutions. J Biomed Mater Res Part A 2008; 87A: 957-963.
7. Maruta M, Matsuya S, Nakamura S, Ishikawa K. Fabrication of low-crystalline carbonate apatite foam bone replacement based on phase transformation of calcite foam. Dent Mater J 2011; 30: 14-20.
8. Obadia L, Rouillon T, Bujoli B, Daculsi G, Bouler JM. Calcium-deficient apatite synthesized by ammonia hydrolysis of dicalcium phosphate dihydrate: influence of temperature, time and pressure. J Biomed Mater Res Part B 2006; 80B: 32-42.
9. LeGeros RZ. Biodegradation and bioresorption of calcium phosphate ceramics. Clin Mater 1993; 14: 65-88.
10. Ginebra MP, Driessens FCM, Planell JA. Effect of the particle size on the micro and nanostructural features of calcium phosphate cement: A kinetic analysis. Biomaterials 2004; 25: 3453-3462.
11. Wang L, Nancollas GH. Calcium orthophosphate: crystallization and dissolution. Chem Rev 2008; 108: 4628-4669.
12. Ishikawa K, Asaoka K. Estimation of ideal mechanical strength and critical porosity of calcium phosphate cement. J Biomed Mater Res 1995; 29: 1537-1543.
13. Okuda T, Ioku K, Yonezawa I, Minagi H, Gonda Y, Kawachi G, Kamitakahara M, Shibata Y, Murayama H, Kurosawa H, Ikeda T. The slow resorption with replacement by bone of a hydrothermally synthesized pure calcium-deficient hydroxyapatite. Biomaterials 2008; 29: 2719-2728.