School of Materials Science and Engineering, Zhengzhou University, Zhengzhou 450003, China.
School of Materials Science and Engineering, Peking University, No. 5 Yi-He-Yuan Road, Hai-Dian District, Beijing 100871, China.
Acta Biomater. 2022 Oct 15;152:1-18. doi: 10.1016/j.actbio.2022.08.041. Epub 2022 Aug 24.
Zinc based biodegradable metals (BMs) show great potential to be used in various biomedical applications, owing to their superior biodegradability and biocompatibility. Some high-strength (ultimate tensile strength > 600 MPa) Zn based BMs have already been developed through alloying and plastic working, making their use in load-bearing environments becomes a reality. However, different from Mg and Fe based BMs, Zn based BMs exhibit significant "strain-softening" effect that leads to limited uniform deformation. Non-uniform deformation is detrimental to Zn based devices or implants, which will possibly lead to unexpected failure. People might be misled by the considerable fracture elongation of Zn based BMs. Thus, it is important to specify uniform elongation as a term of mechanical requirements for Zn based BMs. In this review, recent advances on the mechanical properties of Zn based BMs have been comprehensively summarized, especially focusing on the strain softening phenomenon. At first, the origin and evaluation criteria of strain softening were introduced. Secondly, the effects of alloying elements (including element type, single or multiple addition, and alloying content) and microstructural characteristics (grain size, constituent phase, phase distribution, etc.) on mechanical properties (especially for uniform elongation) of Zn based BMs were summarized. Finally, how to get a good balance between strength and uniform elongation was generally discussed based on the service environment. In addition, possible ways to minimize or eliminate the strain softening effect were also proposed, such as controlling of twins, solute clusters, and grain boundary characteristics. All these items above would be helpful to understand the mechanical instability of Zn based BMs, and to make the full usage of them in the future medical device design. STATEMENT OF SIGNIFICANCE: Biodegradable metals (BMs) is a hotspot in the field of metallic biomaterials. Fracture elongation is normally adopted to quantify the deformability of Mg and Fe based BMs owing to their negligible necking strain, yet the strain softening would occur in Zn based BMs, which is extremely detrimental to performance of their medical device. In this review paper, a better understanding the mechanical performance of Zn-based BMs with the term "uniform elongation" instead of "fracture elongation" was depicted, and possible ways to minimize or eliminate the strain softening effect were also proposed, such as twins, solute clusters, self-stable dislocation network, and grain boundary characteristics. It would be helpful to understand the mechanical instability of Zn based BMs and making full usage of it in the future medical device design.
基于锌的可生物降解金属(BMs)由于其优异的生物降解性和生物相容性,在各种生物医学应用中显示出巨大的潜力。一些高强度(极限拉伸强度>600MPa)的基于锌的 BMs 通过合金化和塑性加工已经被开发出来,使得它们在承载环境中的应用成为现实。然而,与 Mg 和 Fe 基 BMs 不同,基于锌的 BMs 表现出显著的“应变软化”效应,导致其均匀变形有限。非均匀变形对基于锌的器件或植入物不利,这可能导致意外失效。人们可能会被基于锌的 BMs 相当大的断裂伸长率所误导。因此,指定均匀伸长率作为基于锌的 BMs 机械性能的术语非常重要。在这篇综述中,全面总结了基于锌的 BMs 的力学性能的最新进展,特别是重点介绍了应变软化现象。首先,介绍了应变软化的起源和评价标准。其次,总结了合金元素(包括元素类型、单一或多种添加以及合金含量)和微观结构特征(晶粒尺寸、组成相、相分布等)对基于锌的 BMs 的力学性能(特别是均匀伸长率)的影响。最后,基于服役环境,一般讨论了如何在强度和均匀伸长率之间取得良好的平衡。此外,还提出了一些可能的方法来最小化或消除应变软化效应,例如控制孪晶、溶质团簇和晶界特征。所有这些项目都有助于理解基于锌的 BMs 的力学不稳定性,并为未来在医疗器械设计中充分利用它们提供帮助。
可生物降解金属(BMs)是金属生物材料领域的一个热点。由于其颈缩应变可忽略不计,通常采用断裂伸长率来量化 Mg 和 Fe 基 BMs 的变形能力,但应变软化会出现在基于锌的 BMs 中,这对其医疗器械的性能极为不利。在这篇综述论文中,用“均匀伸长率”而不是“断裂伸长率”来更好地理解基于锌的 BMs 的力学性能,并提出了一些可能的方法来最小化或消除应变软化效应,例如孪晶、溶质团簇、自稳定位错网络和晶界特征。这有助于理解基于锌的 BMs 的力学不稳定性,并为未来在医疗器械设计中充分利用它们提供帮助。
