Nanocrystalline Tetracalcium Phosphate Cement

Nanocrystalline Tetracalcium Phosphate Cement

Calcium hydroxide cements can lack long-term stability and achieve sustained release by matrix-controlled diffusion of hydroxyl ions. Tetracalcium phosphate (TTCP) hydrolyzes slowly to form calcium hydroxide and a thin insoluble apatite layer that prevents further reaction. In this study, mechanical...

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Bibliographic Details
Published in:Journal of dental research Vol. 83; no. 5; pp. 425 - 428
Main Authors: Gbureck, U., Barralet, J.E., Hofmann, M.P., Thulĺ, R.
Format: Journal Article
Language:English
Published: United States SAGE Publications 01-05-2004
SAGE PUBLICATIONS, INC
Subjects:
Anti-Bacterial Agents - chemistry
Apatites - chemistry
Calcium Hydroxide - chemistry
Calcium Phosphates - chemical synthesis
Calcium Phosphates - chemistry
Compressive Strength
Crystallography
Dental Cements - chemical synthesis
Dental Cements - chemistry
Dentistry
Hardness
Humans
Hydrogen-Ion Concentration
Hydroxides - chemistry
Materials Testing
Nanotechnology
Salicylates - chemistry
Solubility
Stress, Mechanical
Surface Properties
Time Factors
Water - chemistry
X-Ray Diffraction
calcium hydroxide
tetracalcium phosphate
hydrolysis
calcium phosphate cement
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Summary:Calcium hydroxide cements can lack long-term stability and achieve sustained release by matrix-controlled diffusion of hydroxyl ions. Tetracalcium phosphate (TTCP) hydrolyzes slowly to form calcium hydroxide and a thin insoluble apatite layer that prevents further reaction. In this study, mechanical amorphization was used to create a setting calcium-hydroxide-releasing cement from TTCP. The effect of high-energy ball milling of TTCP on the mechanical properties of the cement was investigated. X-ray diffraction data were used to determine the phase composition of the set cements. An accelerated in vitro test compared pH of water after prolonged boiling of nanocrystalline TTCP cements and a calcium salicylate material. As milling time increased, cement compressive strength and degree of conversion increased. Hydroxyl ion release from the cement was comparable with that from a calcium salicylate material. This new cement system offers the antimicrobial potential of calcium salicylate materials combined with the long-term stability of insoluble apatite cements.
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ISSN:0022-0345
1544-0591
DOI:10.1177/154405910408300514