A novel biodegradable bone repair biomaterial of bone-like carbonated apatite with porous structurewas prepared by using self-hardening calcium phosphate cement. Cell culture, degradation in simulated body liq-uid (SB...A novel biodegradable bone repair biomaterial of bone-like carbonated apatite with porous structurewas prepared by using self-hardening calcium phosphate cement. Cell culture, degradation in simulated body liq-uid (SBF) and as a carrier for bone morphogenic protein (BMP) controllable releasing experiments were performedto evaluate the biocompatibility, degradation and BMP carrier properties of the porous scaffold. The results revealthat the degradation property of the carbonated apatite is better than hydroxyapatite, the more the content of CO32-in apatite, the faster the degradation of the materials, the cell could attach, proliferate and differentiate on theporous scaffold, indicating that the bone like apatites not only have excellent biocompatibility but are alsobiodegradable and can be used as carriers for BMP controlling release.展开更多
为研究钙离子、镁离子在体内环境中对自硬性玻璃结晶行为的影响,为自硬性生物活性玻璃的临床应用提供依据,本文设计了CaO-P2O5-SiO2-CaF2(Ca-glass)和CaO-MgO-P2O5-SiO2-CaF2(CaMg-glass)系统玻璃并使用模拟体液(simulated body flu id,...为研究钙离子、镁离子在体内环境中对自硬性玻璃结晶行为的影响,为自硬性生物活性玻璃的临床应用提供依据,本文设计了CaO-P2O5-SiO2-CaF2(Ca-glass)和CaO-MgO-P2O5-SiO2-CaF2(CaMg-glass)系统玻璃并使用模拟体液(simulated body flu id,SBF)进行了研究。首先采用磷酸氢二氨[(NH4)2HPO4]/[NH4H2PO4]硬化液与Ca-glass、CaMg-glass制成硬化体,然后使用X射线衍射(XRD)、扫描电镜(SEM)、失重、力学分析等方法,研究硬化体在SBF中的结晶性、降解性和力学性能。实验结果表明,玻璃粉末与磷酸铵缓冲溶液反应形成了磷酸铵钙[(NH4)2.Ca(HPO4)2.H2O]硬化体。硬化体经过SBF浸泡,Ca-glass系统硬化体中部分磷酸铵钙转化成羟基磷灰石,而CaMg-glass系统硬化体仍然为磷酸铵钙。Ca-glass与CaMg-glass硬化体在SBF中浸泡28天分别降解19.4%和31.3%,抗压强度分别为93.14MPa和64.52MPa。镁离子的歧化作用是导致Ca-glass、CaMg-glass硬化体结晶性能、降解性能以及力学性能差别的主要原因。展开更多
文摘A novel biodegradable bone repair biomaterial of bone-like carbonated apatite with porous structurewas prepared by using self-hardening calcium phosphate cement. Cell culture, degradation in simulated body liq-uid (SBF) and as a carrier for bone morphogenic protein (BMP) controllable releasing experiments were performedto evaluate the biocompatibility, degradation and BMP carrier properties of the porous scaffold. The results revealthat the degradation property of the carbonated apatite is better than hydroxyapatite, the more the content of CO32-in apatite, the faster the degradation of the materials, the cell could attach, proliferate and differentiate on theporous scaffold, indicating that the bone like apatites not only have excellent biocompatibility but are alsobiodegradable and can be used as carriers for BMP controlling release.
文摘为研究钙离子、镁离子在体内环境中对自硬性玻璃结晶行为的影响,为自硬性生物活性玻璃的临床应用提供依据,本文设计了CaO-P2O5-SiO2-CaF2(Ca-glass)和CaO-MgO-P2O5-SiO2-CaF2(CaMg-glass)系统玻璃并使用模拟体液(simulated body flu id,SBF)进行了研究。首先采用磷酸氢二氨[(NH4)2HPO4]/[NH4H2PO4]硬化液与Ca-glass、CaMg-glass制成硬化体,然后使用X射线衍射(XRD)、扫描电镜(SEM)、失重、力学分析等方法,研究硬化体在SBF中的结晶性、降解性和力学性能。实验结果表明,玻璃粉末与磷酸铵缓冲溶液反应形成了磷酸铵钙[(NH4)2.Ca(HPO4)2.H2O]硬化体。硬化体经过SBF浸泡,Ca-glass系统硬化体中部分磷酸铵钙转化成羟基磷灰石,而CaMg-glass系统硬化体仍然为磷酸铵钙。Ca-glass与CaMg-glass硬化体在SBF中浸泡28天分别降解19.4%和31.3%,抗压强度分别为93.14MPa和64.52MPa。镁离子的歧化作用是导致Ca-glass、CaMg-glass硬化体结晶性能、降解性能以及力学性能差别的主要原因。