激光增材制造铁基生物复合材料：微观结构、降解及细胞行为

Laser Additively Manufactured Iron-Based Biocomposite: Microstructure, Degradation, and Cell Behavior.

作者信息

Yang Youwen, Cai Guoqing, Yang Mingli, Wang Dongsheng, Peng Shuping, Liu Zhigang, Shuai Cijun

机构信息

Institute of Additive Manufacturing, Jiangxi University of Science and Technology, Nanchang, China.

Key Laboratory of Construction Hydraulic Robots of Anhui Higher Education Institutes, Tongling University, Tongling, China.

出版信息

Front Bioeng Biotechnol. 2021 Dec 2;9:783821. doi: 10.3389/fbioe.2021.783821. eCollection 2021.

DOI:10.3389/fbioe.2021.783821

PMID:34926428

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8675104/

Abstract

A too slow degradation of iron (Fe) limits its orthopedic application. In this study, calcium chloride (CaCl) was incorporated into a Fe-based biocomposite fabricated by laser additive manufacturing, with an aim to accelerate the degradation. It was found that CaCl with strong water absorptivity improved the hydrophilicity of the Fe matrix and thereby promoted the invasion of corrosive solution. On the other hand, CaCl could rapidly dissolve once contacting the solution and release massive chloride ion. Interestingly, the local high concentration of chloride ion effectively destroyed the corrosion product layer due to its strong erosion ability. As a result, the corrosion product layer covered on the Fe/CaCl matrix exhibited an extremely porous structure, thus exhibiting a significantly reduced corrosion resistance. Besides, cell testing proved that the Fe/CaCl biocomposite also showed favorable cytocompatibility.

摘要

铁（Fe）降解过慢限制了其在骨科领域的应用。在本研究中，将氯化钙（CaCl）引入通过激光增材制造制备的铁基生物复合材料中，旨在加速其降解。研究发现，具有强吸水性的CaCl提高了铁基体的亲水性，从而促进了腐蚀性溶液的侵入。另一方面，CaCl一旦与溶液接触就能迅速溶解并释放大量氯离子。有趣的是，局部高浓度的氯离子因其强大的侵蚀能力有效地破坏了腐蚀产物层。结果，覆盖在Fe/CaCl基体上的腐蚀产物层呈现出极其多孔的结构，因此其耐腐蚀性显著降低。此外，细胞测试证明Fe/CaCl生物复合材料也表现出良好的细胞相容性。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/0f85/8675104/31cdb4bca5e5/fbioe-09-783821-g001.jpg

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激光增材制造铁基生物复合材料：微观结构、降解及细胞行为

Laser Additively Manufactured Iron-Based Biocomposite: Microstructure, Degradation, and Cell Behavior.

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