多孔Fe-Mn合金表面微纳形貌调控及其生物相容性评价  

作　　者：陈智坤 袁波 聂涌[3] 彭华备[4] 朱向东[1,2] 张兴栋 Chen Zhikun;Yuan Bo;Nie Yong;Peng Huabei;Zhu Xiangdong;Zhang Xingdong(National Biomedical Materials Engineering and Technology Research Center,Chengdu 610064,China;College of Biomedical Engineering,Sichuan University,Chengdu 610064,China;West China Hospital,Sichuan University,Chengdu 610041,China;College of Mechanical Engineering,Sichuan University,Chengdu 610064,China)

机构地区：[1]国家生物医学材料工程技术研究中心,四川成都610064 [2]四川大学生物医学工程学院,四川成都610064 [3]四川大学华西医院,四川成都610041 [4]四川大学机械工程学院,四川成都610064

出　　处：《稀有金属材料与工程》2022年第12期4705-4713,共9页Rare Metal Materials and Engineering

基　　金：四川省科技计划项目(2019JDTD0008,2021YFS0020);四川大学华西医学学科卓越发展1.3.5工程项目(ZYJC21040)。

摘　　要：铁基可降解金属因其良好的生物相容性和优异的机械性能,在骨科植入物领域具有广阔的应用前景,但必须突破其降解速率过慢的瓶颈问题。本研究通过电化学技术对3D打印多孔铁锰合金(Fe-30Mn)支架表面进行去合金化处理。通过扫描电镜观察发现,以盐酸和氯化钠分别作为去合金化处理介质溶液,可以在支架表面形成多微孔网络结构和片状纳米结构。接触角和粗糙度测试显示,2种微纳结构的构建均显著改善了Fe-30Mn支架表面亲水性,并提升了其表面粗糙度,多微孔网络结构更加粗糙并且亲水性更好。利用静态浸泡法和电化学耐腐蚀实验评估合金化处理前后支架的腐蚀速率,发现表面微纳结构的形成可加速Fe-30Mn支架的降解。建立体外成骨细胞培养模型,通过激光共聚焦观察及细胞增殖测试发现,经合金化处理的2种支架均能支撑细胞的贴附和增殖,具有良好的细胞相容性。结果表明,经电化学去合金化处理后,Fe-30Mn支架的降解速度得以增强,同时保持了良好的生物相容性,有望在骨修复领域得到较好应用。Fe-based biodegradable metals having good biocompatibility and excellent mechanical property exhibit great promise for applications in orthopedic implants, while the slow degradation rate is a major bottleneck. In this study, the surface of the porous Fe-30Mn scaffold was dealloyed by electrochemical technology. When using hydrochloric acid and sodium chloride as medium solution in dealloying treatment, micro-nano porous network and sheet-like structures were formed on the surface of the scaffolds, respectively. The contact angle and surface roughness tests show that the two micro-nano structure significantly improves the hydrophilicity of the Fe-30Mn scaffold and enhances its roughness. The Fe-30Mn with micro-nano porous network exhibits higher roughness and hydrophlicity than that of the Fe-30Mn with sheet-like structures. The degradation rate of the scaffolds before and after alloying were evaluated by the static immersion method and electrochemical corrosion test. The results show that the construction of surface micro-nano structure can accelerate the degradation of the scaffold. The in vitro cell culture using MC3T3-E1 cells shows that all porous Fe-30Mn scaffolds has good cytocompatibility. The above results confirm that the Fe-30Mn scaffold has a suitable degradation rate and good biocompatibility after electrochemical dealloying treatment, suggesting its great clinical application prospect in the fields of bone repair.

关 键 词：Fe-30Mn支架 去合金化 表面微纳结构 降解性能 生物相容性 

分 类 号：TG145[一般工业技术—材料科学与工程]