Preclinical study on the application of biodegradable pure magnesium mesh in abdominal wall defect repair: Material characterization, biocompatibility, and regenerative mechanisms.

IF 2.5 4区医学 Q3 ENGINEERING, BIOMEDICAL

Journal of Biomaterials Applications Pub Date : 2025-09-30 DOI:10.1177/08853282251383875

Qi Zheng, Zequn Zhuang, Yonglin Li, Rongwei Wei, Jing Wang, Xiaojing Lu, Chengyu Wu, Ziliang Zong, Haidong Xu, Chenguang Wei, Hui Shen, Jun Yan, Xiaonong Zhang, Yigang Chen

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引用次数: 0

Abstract

This study evaluates a novel biodegradable magnesium (Mg) mesh for abdominal wall repair. Current synthetic meshes present clinical limitations, while Mg alloys offer favorable mechanical properties and biodegradability that remain underexplored. The Mg mesh was characterized through tensile/burst testing and finite element analysis, demonstrating sufficient strength (initial: 167.2 ± 5.9 N/cm; 1 month: 55.9 ± 1.6 N/cm) to withstand tensile breaking strength of abdominal wall (16 N/cm). Degradation studies revealed faster rates in simulated body fluid (2.62 mm/year) versus Hanks' solution (1.14 mm/year), with 60% structural integrity maintained after 8 weeks in vivo. Biocompatibility assessment using human skin fibroblasts showed >60% viability (Grade 0-1 cytotoxicity) across extract concentrations, with 60% concentration enhancing proliferation. In rat abdominal wall defect models, the Mg mesh exhibited superior performance to polypropylene meshes, demonstrating reduced foreign body reaction and upregulated collagen III/V expression. Proteomic analysis (TMT), PCR, and Western blot confirmed enhanced wound healing mechanisms. The mesh maintained tight tissue integration throughout degradation while providing mechanical support matching physiological demands. These findings collectively indicate that the biodegradable Mg mesh combines: (1) appropriate time-dependent mechanical properties, (2) controlled degradation matching tissue regeneration timelines, (3) excellent cytocompatibility with pro-proliferative effects, and (4) improved healing outcomes compared to standard polypropylene meshes. The results support its potential as a next-generation material for abdominal wall reconstruction, addressing key limitations of permanent synthetic meshes through its optimal balance of biomechanical performance and bioresorbability. Further clinical studies are warranted to validate these promising preclinical outcomes.

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生物可降解纯镁网在腹壁缺损修复中的临床前研究：材料表征、生物相容性及再生机制

本研究评估了一种用于腹壁修复的新型可生物降解镁（Mg）补片。目前的合成网存在临床局限性，而镁合金具有良好的机械性能和生物降解性仍未得到充分开发。通过拉伸/破裂试验和有限元分析对Mg网进行了定性，其强度（初始：167.2±5.9 N/cm； 1个月：55.9±1.6 N/cm）足以承受腹壁的拉伸断裂强度（16 N/cm）。降解研究显示，模拟体液中的降解速率（2.62 mm/年）比汉克斯溶液（1.14 mm/年）更快，体内8周后结构完整性保持60%。使用人皮肤成纤维细胞进行生物相容性评估显示，在不同的提取物浓度下，成纤维细胞的活力为60%（0-1级细胞毒性），60%的浓度可促进细胞增殖。在大鼠腹壁缺损模型中，Mg网状物表现出优于聚丙烯网状物的性能，其异物反应减少，胶原III/V表达上调。蛋白质组学分析（TMT）、PCR和Western blot证实了伤口愈合机制的增强。网状结构在整个降解过程中保持紧密的组织整合，同时提供符合生理需求的机械支持。这些研究结果共同表明，可生物降解的Mg网结合了：(1)适当的随时间变化的力学性能，(2)与组织再生时间表相匹配的可控降解，(3)具有促增殖作用的优异细胞相容性，(4)与标准聚丙烯网相比，愈合效果更好。结果支持其作为下一代腹壁重建材料的潜力，通过其生物力学性能和生物可吸收性的最佳平衡，解决了永久性合成网的关键局限性。需要进一步的临床研究来验证这些有希望的临床前结果。

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来源期刊

Journal of Biomaterials Applications 工程技术-材料科学：生物材料

CiteScore

5.10

自引率

3.40%

发文量

144

审稿时长

1.5 months

期刊介绍： The Journal of Biomaterials Applications is a fully peer reviewed international journal that publishes original research and review articles that emphasize the development, manufacture and clinical applications of biomaterials. Peer-reviewed articles by biomedical specialists from around the world cover: New developments in biomaterials, R&D, properties and performance, evaluation and applications Applications in biomedical materials and devices - from sutures and wound dressings to biosensors and cardiovascular devices Current findings in biological compatibility/incompatibility of biomaterials The Journal of Biomaterials Applications publishes original articles that emphasize the development, manufacture and clinical applications of biomaterials. Biomaterials continue to be one of the most rapidly growing areas of research in plastics today and certainly one of the biggest technical challenges, since biomaterial performance is dependent on polymer compatibility with the aggressive biological environment. The Journal cuts across disciplines and focuses on medical research and topics that present the broadest view of practical applications of biomaterials in actual clinical use. The Journal of Biomaterial Applications is devoted to new and emerging biomaterials technologies, particularly focusing on the many applications which are under development at industrial biomedical and polymer research facilities, as well as the ongoing activities in academic, medical and applied clinical uses of devices.