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Microalloy Mg-based degradation implant for intra-osteal fixation.

Niu, Tingting; Zhang, Yange; Liu, Shengqiang; Li, Shuntao; Yang, Hongtao; Lu, Tongtong; Sun, Yong; Sun, Hongxia; Wang, Youde; Zhang, Liying; Ren, Liqun; Jin, Yu; Suo, Tao; Zan, Rui; Wang, Yimin; Zou, Guodong; Fernandez, Carlos; Peng, Qiuming

Authors

Tingting Niu

Yange Zhang

Shengqiang Liu

Shuntao Li

Hongtao Yang

Tongtong Lu

Yong Sun

Hongxia Sun

Youde Wang

Liying Zhang

Liqun Ren

Yu Jin

Tao Suo

Rui Zan

Yimin Wang

Guodong Zou

Qiuming Peng



Abstract

The bottleneck for Mg-based degradable implants lies in the mismatching relationship between mechanical properties and degradable rate, resulting in the rapid failure during the in-vivo degradable process and potential toxic role. Herein microalloy-conception has been involved to rectify the equilibrium effects among several aspects. Microstructure, mechanical properties, degradable properties and in-vitro/in-vivo biocompatibility properties of as-extruded pure Mg, Mg-0.15Ca, and Mg-0.15Ca-0.10Mn samples have been investigated. The results show that the Mg-0.15Ca-0.1Mn alloy exhibits a high yield strength (110 MPa) and a low degradable rate (0.82 mm/y). Attractively, the mechanical integrity has been remained in Mg-0.15Ca-0.1Mn alloy after 14 weeks in the rat femoral mode, and a homogenous degradable rate with 0.92 mm/y has been confirmed, which is basically equivalent to the in vitro value. Simultaneously, the low concentration of ions also reveals satisfactory biocompatibility equal to pure Mg, based on organ function and pathological morphology. Our findings reveal that microalloy paves a possible route to design high performance Mg-based intra-osteal fixation implants, resolving the contradictions among the degradable requirements under different body environments.

Citation

NIU, T., ZHANG, Y., LIU, S., et al. 2024. Microalloy Mg-based degradation implant for intra-osteal fixation. Materialia [online], 38, article number 102258. Available from: https://doi.org/10.1016/j.mtla.2024.102258

Journal Article Type Article
Acceptance Date Oct 7, 2024
Online Publication Date Oct 9, 2024
Publication Date Dec 31, 2024
Deposit Date Oct 14, 2024
Publicly Available Date Oct 10, 2025
Journal Materialia
Electronic ISSN 2589-1529
Publisher Elsevier
Peer Reviewed Peer Reviewed
Volume 38
Article Number 102258
DOI https://doi.org/10.1016/j.mtla.2024.102258
Keywords Mg alloys; Mechanical property; Corrosion; Biocompatibility; Osteogenic ability
Public URL https://rgu-repository.worktribe.com/output/2525192

Files

This file is under embargo until Oct 10, 2025 due to copyright reasons.

Contact publications@rgu.ac.uk to request a copy for personal use.



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