Mechanical properties, corrosion behavior, and in vitro and in vivo biocompatibility of hot-extruded Zn-5RE (RE = Y, Ho, and Er) alloys for biodegradable bone-fixation applications

IF 9.4 1区医学 Q1 ENGINEERING, BIOMEDICAL

Acta Biomaterialia Pub Date : 2024-09-01 DOI:10.1016/j.actbio.2024.07.006

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引用次数: 0

Abstract

Biodegradable Zn alloys have significant application potential for hard-tissue implantation devices owing to their suitable degradation behavior and favorable biocompatibility. Nonetheless, pure Zn and its alloys in the as-cast state are mechanically instable and low in strength, which restricts their clinical applicability. Here, we report the exceptional mechanical, corrosion, and biocompatibility properties of hot-extruded Zn-5RE (wt.%, RE = rare earth of Y; or Ho; or Er) alloys intended for use in biodegradable bone substitutes. The microstructural characteristics, mechanical behavior, corrosion resistance, cytocompatibility, osteogenic differentiation, and capacity of osteogenesis in vivo of the Zn-5RE alloys are comparatively investigated. The Zn-5Y alloy demonstrates the best tensile properties, encompassing a 138 MPa tensile yield strength, a 302 MPa ultimate tensile strength, and 63% elongation, while the Zn-5Ho alloy shows the highest compression yield strength of 260 MPa and Vickers hardness of 104 HV. The Zn-5Er alloy shows a 126 MPa tensile yield strength, a 279 MPa ultimate tensile strength, 52% elongation, a 196 MPa compression yield strength, and a 101 HV Vickers microhardness. Further, the Zn-5Er alloy has a 130 µm per year corrosion rate in electrochemical tests and a 26 µm per year degradation rate in immersion tests, which is the lowest among the tested alloys. It also has the best in vitro osteogenic differentiation ability and capacity for osteogenesis and osteointegration in vivo after implantation in rat femurs among the Zn-5RE alloys, indicating promising potential in load-bearing biodegradable internal bone-fixation applications.

Statement of significance

This work reports the exceptional mechanical, corrosion, and biocompatibility properties of hot-extruded (HE) Zn-5 wt.%–rare earth (Zn-5RE) alloys using single yttrium (Y), holmium (Ho), and erbium (Er) alloying for biodegradable bone-implant applications. Our findings demonstrate that the HE Zn-5Er alloy showed σ_uts of 279 MPa, tensile yield strength of 126 MPa, elongation of 51.6%, compression yield strength of 196 MPa, and microhardness of 101.2 HV. Further, HE Zn-5Er showed the lowest electrochemical corrosion rate of 130 µm/y and lowest degradation rate of 26 µm/y, and the highest in vitro osteogenic differentiation ability, in vivo osteogenesis, and osteointegration ability after implantation in rat femurs among the Zn-5RE alloys, indicating promising potential in load-bearing biodegradable internal bone-fixation applications.

Abstract Image

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用于生物降解骨固定应用的热挤压 Zn-5RE（RE = Y、Ho 和 Er）合金的机械性能、腐蚀行为以及体外和体内生物相容性。

可生物降解锌合金具有合适的降解行为和良好的生物相容性，因此在硬组织植入装置方面具有巨大的应用潜力。然而，纯锌及其合金在铸造状态下机械性能不稳定且强度低，这限制了它们在临床上的应用。在此，我们报告了热挤压 Zn-5RE（重量百分比，RE = Y 或 Ho 或 Er 稀土）合金的特殊机械、腐蚀和生物相容性能，这些合金将用于生物可降解骨替代物。比较研究了 Zn-5RE 合金的微观结构特征、机械行为、耐腐蚀性、细胞相容性、成骨分化和体内成骨能力。Zn-5Y 合金的拉伸性能最好，拉伸屈服强度为 138 兆帕，极限拉伸强度为 302 兆帕，伸长率为 63%；Zn-5Ho 合金的压缩屈服强度最高，为 260 兆帕，维氏硬度为 104 HV。Zn-5Er 合金的拉伸屈服强度为 126 兆帕，极限拉伸强度为 279 兆帕，伸长率为 52%，压缩屈服强度为 196 兆帕，维氏硬度为 101 HV。此外，Zn-5Er 合金在电化学测试中的腐蚀率为每年 130 微米，在浸泡测试中的降解率为每年 26 微米，是所有测试合金中最低的。在 Zn-5RE 合金中，它的体外成骨分化能力以及植入大鼠股骨后的体内成骨和骨整合能力也是最好的，这表明它在承重型生物可降解内固定骨应用中具有广阔的发展前景。意义说明：这项研究报告了热挤压（HE）Zn-5 wt.%-稀土（Zn-5RE）合金在生物可降解骨植入应用中使用单一钇（Y）、钬（Ho）和铒（Er）合金所获得的优异机械、腐蚀和生物相容性能。我们的研究结果表明，HE Zn-5Er 合金的σ值为 279 兆帕，拉伸屈服强度为 126 兆帕，伸长率为 51.6%，压缩屈服强度为 196 兆帕，显微硬度为 101.2 HV。此外，在Zn-5RE合金中，HE Zn-5Er的电化学腐蚀率最低，为130微米/年，降解率最低，为26微米/年，其体外成骨分化能力、体内成骨能力和植入大鼠股骨后的骨整合能力均为最高，表明其在承重型生物可降解内固定骨应用中具有广阔的发展前景。

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来源期刊

Acta Biomaterialia 工程技术-材料科学：生物材料

CiteScore

16.80

自引率

3.10%

发文量

776

审稿时长

30 days

期刊介绍： Acta Biomaterialia is a monthly peer-reviewed scientific journal published by Elsevier. The journal was established in January 2005. The editor-in-chief is W.R. Wagner (University of Pittsburgh). The journal covers research in biomaterials science, including the interrelationship of biomaterial structure and function from macroscale to nanoscale. Topical coverage includes biomedical and biocompatible materials.