Calcium Phosphate Cement Modified with Silicon Nitride/Tricalcium Phosphate Microgranules

Q4 Materials Science Powder Metallurgy Progress Pub Date : 2020-06-01 DOI:10.2478/pmp-2020-0006

Ľ. Medvecký, R. Stulajterova, M. Giretová, T. Sopčák, M. Fáberová, M. Hnatko, T. Fenclová

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Abstract

Abstract Tetracalcium phosphate/monetite biocement was modified with 10 and 30 wt. % addition of highly porous silicon nitride/α-tricalcium phosphate (αTCP) microgranules with various content of αTCP. A composite cement powder mixture was prepared using mechanical homogenization of basic components. The accelerated release of dexamethasone from composite cement was revealed, which indicates their possible utilization for controlled drug release. The wet compressive strength of cements (<17 MPa) was significantly reduced (more than 30%) in comparison with the unmodified cement and both compressive strength and setting time were influenced by the content of αTCP in microgranules. The addition of microgranules caused a 20% decrease in final cement density. Microgranules with a higher fraction of αTCP showed good in vitro SBF bioactivity with precipitation of hydroxyapatite particles. Microstructure analysis of fractured cements demonstrated excellent interconnection between microgranules and cement calcium phosphate matrix, but also showed lower mechanical strength of microgranule cores.

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氮化硅/磷酸三钙微颗粒改性磷酸钙水泥

摘要以10和30wt%的高孔氮化硅/α-磷酸三钙（αTCP）微颗粒为原料，对磷酸四钙/莫奈石生物水泥进行了改性。利用基本组分的机械均匀化制备了复合水泥粉体混合物。地塞米松从复合水泥中的加速释放被揭示，这表明它们可能用于控制药物释放。与未改性水泥相比，水泥的湿抗压强度（<17MPa）显著降低（超过30%），抗压强度和凝结时间都受到微粒中αTCP含量的影响。微粒的加入使最终水泥密度降低了20%。αTCP含量较高的微颗粒随着羟基磷灰石颗粒的沉淀显示出良好的体外SBF生物活性。断裂水泥的微观结构分析表明，微粒和水泥磷酸钙基质之间具有良好的相互连接，但也表明微粒芯的机械强度较低。

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Powder Metallurgy Progress Materials Science-Metals and Alloys

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