Modulation of porosity in apatitic cements by the use of α-tricalcium phosphate—calcium sulphate dihydrate mixtures

Calcium phosphate bone cements are injectable biomaterials that are being used in dental and orthopaedic applications through minimally invasive surgery techniques. Nowadays, apatitic bone cements based on α-tricalcium phosphate ( α-TCP) are of special interest due to their self-setting behaviour wh...

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Bibliographic Details
Published in:Biomaterials 2005-06, Vol.26 (17), p.3395-3404
Main Authors: Fernández, Enrique, Vlad, Maria Daniela, Gel, Maria Montserrat, López, Jose, Torres, Ricardo, Cauich, Juan V., Bohner, Marc
Format: Article
Language:English
Subjects:
Apatites - analysis
Apatites - chemistry
Bone Cements - analysis
Bone Cements - chemistry
Calcium phosphate
Calcium Phosphates - analysis
Calcium Phosphates - chemistry
Calcium Sulfate - analysis
Calcium Sulfate - chemistry
Calcium sulphate
Cement
Complex Mixtures - analysis
Complex Mixtures - chemistry
Compressive Strength
Hardness
Materials Testing
Physico-chemical properties
Porosity
Powders
Surface Properties
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Summary:Calcium phosphate bone cements are injectable biomaterials that are being used in dental and orthopaedic applications through minimally invasive surgery techniques. Nowadays, apatitic bone cements based on α-tricalcium phosphate ( α-TCP) are of special interest due to their self-setting behaviour when mixed with an aqueous liquid phase. In this study, a new method to improve osteointegration of α-TCP-based cements is presented. This method consists in the modification of the cement's powder phase with different amounts of calcium sulphate dihydrate (CSD). The resulting hardening properties of the new biphasic cements are a combination between the progressive hardening due to the main α-TCP reactant and the progressive dissolution of the CSD phase, which render a porous material. It was observed that the maximum compressive strength of Biocement-H © (45 MPa) decreased as the amount of CSD increased in the cement powder mixture (≈30 MPa for 25 wt% of CSD). It was also observed that after complete dissolution of the CSD phase a porous apatitic structure appears with a mechanical compressive strength suitable for cancellous bone applications (10 MPa).
ISSN:0142-9612
1878-5905
DOI:10.1016/j.biomaterials.2004.09.023