Xiaomei Wang, Feng Shi, Dechuan Zhao, Yonggang Yan
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引用次数: 2
摘要
磷酸镁骨水泥成骨能力不足限制了其进一步应用。开发具有成骨功能的生物活性MPC具有重要意义。在这项工作中,氧化锌纳米颗粒(ZnO-NPs)增强了MPCs。对ZnO-NPs/MPCs (ZNMPCs)的组成、微观结构、凝固时间、抗压强度和降解性能进行了评价。结果表明,MPCs的凝固时间由8.2 min (5.0ZNMPC)延长至25.3 min (5.0ZNMPC)。放热温度由45.8±0.4℃(mpc)降至39.3±0.5℃(1.0ZNMPC)。添加1 wt. % ZnO-NPs (1.0ZNMPC)的ZNMPC复合水泥抗压强度最高,达到42.9 MPa。此外,ZNMPCs与小鼠骨髓间充质干细胞(mBMSCs)一起培养。结果表明,ZNMPCs表现出良好的细胞相容性,增强了mBMSCs的分化、增殖和矿化,并显著提高了成骨相关基因和蛋白的表达。这些发现表明,ZNMPCs可以驱动mBMSCs向成骨和矿化方向分化,为MPC增强成骨提供了一种简单的方法,可用于进一步的骨科应用。
Effect of ZnO-doped magnesium phosphate cements on osteogenic differentiation of mBMSCs in vitro.
The insufficient osteogenesis of magnesium phosphate cements (MPCs) limits its further application. It is significant to develop a bioactive MPC with osteogenic properties. In this work, MPCs were reinforced by zinc oxide nanoparticles (ZnO-NPs). The composition, microstructure, setting time, compressive strength and degradation of ZnO-NPs/MPCs (ZNMPCs) were evaluated. The results showed that the setting times of MPCs were prolonged from 8.2 to 25.3 min (5.0ZNMPC). The exothermic temperatures were reduced from 45.8 ± 0.4℃ (MPCs) to 39.3 ± 0.5℃ (1.0ZNMPC). The compressive strength of ZNMPC composite cement with 1 wt. % ZnO-NPs (1.0ZNMPC) was the highest (42.9 MPa) among all the composite cements. Furthermore, the ZNMPCs were cultured with mouse bone marrow mesenchymal stem cells (mBMSCs). The results yielded that the ZNMPCs exhibited good cytocompatibility with enhanced differentiation, proliferation, and mineralization on mBMSCs, and it also pronouncedly elevated the expressions of genes and proteins involving osteogenesis. These findings suggested that ZNMPCs could drive the differentiation toward osteogenesis and mineralization of mBMSCs, providing a simple way to the MPC with enhanced osteogenesis for further orthopedic applications.
期刊介绍:
The Journal of Applied Biomaterials & Functional Materials (JABFM) is an open access, peer-reviewed, international journal considering the publication of original contributions, reviews and editorials dealing with clinical and laboratory investigations in the fast growing field of biomaterial sciences and functional materials.
The areas covered by the journal will include:
• Biomaterials / Materials for biomedical applications
• Functional materials
• Hybrid and composite materials
• Soft materials
• Hydrogels
• Nanomaterials
• Gene delivery
• Nonodevices
• Metamaterials
• Active coatings
• Surface functionalization
• Tissue engineering
• Cell delivery/cell encapsulation systems
• 3D printing materials
• Material characterization
• Biomechanics