Powders Synthesized from Solutions of Calcium Chloride, Sodium Hydrogen Phosphate, and Sodium Sulfate for Bioceramics Production

IF 2.7 Q1 MATERIALS SCIENCE, CERAMICS
T. Safronova, Alexander S. Khantimirov, T. Shatalova, Y. Filippov, I. Kolesnik, A. Knotko
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引用次数: 1

Abstract

Fine powders of brushite CaHPO4·2H2O, ardealite Ca(HPO4)x(SO4)1−x·2H2O (Ca(HPO4)0.5(SO4)0.5·2H2O), and calcium sulfate dihydrate CaSO4·2H2O—all containing sodium chloride NaCl as a reaction by-product—were synthesized from 0.5 M aqueous solution of calcium chloride CaCl2, sodium hydrophosphate Na2HPO4 and/or sodium sulfate Na2SO4. Powder of ardealite Ca(HPO4)x(SO4)1−x·2H2O (Ca(HPO4)0.5(SO4)0.5·2H2O) was synthesized by precipitation from aqueous solution of calcium chloride CaCl2 and mixed-anionic solution simultaneously containing the hydrogen phosphate anion HPO42− (Na2HPO4) and sulfate anion SO42− (Na2SO4). Sodium chloride NaCl, presenting in compacts based on synthesized powders of brushite CaHPO4·2H2O, ardealite Ca(HPO4)x(SO4)1−x·2H2O (Ca(HPO4)0.5(SO4)0.5·2H2O) and calcium sulfate dihydrate CaSO4·2H2O, was responsible for both low-temperature melt formation and the creation of phase composition of ceramics. Heterophase interaction of components led to the resulting phase composition of the ceramic samples during heating, including the formation of chlorapatite Ca5(PO4)3Cl in powders of brushite and ardealite. The phase composition of the ceramics based on the powder of brushite CaHPO4·2H2O containing NaCl as a by-product after firing at 800–1000 °C included β-Ca2P2O7, and Ca5(PO4)3Cl. The phase composition of ceramics based on the powder of ardealite Ca(HPO4)x(SO4)1−x·2H2O (Ca(HPO4)0.5(SO4)0.5·2H2O) containing NaCl as a by-product after firing at 800 and 900 °C included β-Ca2P2O7, CaSO4, and Ca5(PO4)3Cl; after firing at 1000 °C, it includedCaSO4, Ca5(PO4)3Cl and Ca3(PO4)2/Ca10Na(PO4)7, and after firing at 1100 °C, it included CaSO4 and Ca5(PO4)3Cl. The phase composition of ceramics based on powder of calcium sulfate dihydrate CaSO4·2H2O containing NaCl as a by-product after firing at 800–1100 °C included CaSO4 as the predominant phase. The phase composition of all ceramic samples under investigation consisted of biocompatible crystalline phases with different abilities to biodegrade. For this reason, the created ceramics can be recommended for testing as materials for treatment of bone defects using regenerative medicine methods.
用氯化钙、磷酸氢钠和硫酸钠溶液合成生物陶瓷用粉末
以氯化钙CaCl2、磷酸氢钠Na2HPO4和/或硫酸钠Na2SO4的0.5M水溶液为原料,合成了磷石膏CaHPO4·2H2O、方钠石Ca(HPO4)x。以氯化钙CaCl2水溶液和同时含有磷酸氢阴离子HPO42-(Na2HPO4)和硫酸根阴离子SO42-(Na 2SO4)的混合阴离子溶液为原料,通过沉淀法合成了方钠石Ca(HPO4)x(SO4)1−x·2H2O(Ca(HPSO4)0.5(SO4)0.5·2H2O。氯化钠-氯化钠在基于合成的刷石CaHPO4·2H2O、方钠石Ca(HPO4)x(SO4)1−x·2H2O(Ca(HPSO4)0.5(SO4)0.5·2H2O)和二水硫酸钙CaSO4·2H2O的粉末的压块中存在,负责陶瓷的低温熔体形成和相组成的产生。在加热过程中,组分的异相相互作用导致了陶瓷样品的相组成,包括在孔雀石和方钠石粉末中形成氯磷灰石Ca5(PO4)3Cl。在800–1000°C下烧制后,以含有NaCl作为副产物的刷石CaHPO4·2H2O粉末为基础的陶瓷的相组成包括β-Ca2P2O7和Ca5(PO4)3Cl。在800和900°C下烧制后,以副产物为NaCl的方钠石Ca(HPO4)x(SO4)1−x·2H2O(Ca(HPSO4)0.5(SO4)0.5·2H2O)粉末为基础的陶瓷的相组成包括β-Ca2P2O7、CaSO4和Ca5(PO4)3Cl;在1000°C焙烧后,它包括CaSO4、Ca5(PO4)3Cl和Ca3(PO4。基于二水硫酸钙CaSO4·2H2O粉末的陶瓷在800–1100°C下烧制后的相组成包括CaSO4作为主要相。所研究的所有陶瓷样品的相组成由具有不同生物降解能力的生物相容性晶相组成。出于这个原因,可以推荐使用再生医学方法将所产生的陶瓷作为治疗骨缺损的材料进行测试。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
3.00
自引率
7.10%
发文量
66
审稿时长
10 weeks
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