Ti3C2T x -UHMWPE Nanocomposites-Towards an Enhanced Wear-Resistance of Biomedical Implants.

Benedict Rothammer, Klara Feile, Siegfried Werner, Rainer Frank, Marcel Bartz, Sandro Wartzack, Dirk W Schubert, Dietmar Drummer, Rainer Detsch, Bo Wang, Andreas Rosenkranz, Max Marian
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Abstract

There is an urgent need to enhance the mechanical and biotribological performance of polymeric materials utilized in biomedical devices such as load-bearing artificial joints, notably ultrahigh molecular weight polyethylene (UHMWPE). While two-dimensional (2D) materials like graphene, graphene oxide (GO), reduced GO, or hexagonal boron nitride (h-BN) have shown promise as reinforcement phases in polymer matrix composites (PMCs), the potential of MXenes, known for their chemical inertness, mechanical robustness, and wear-resistance, remains largely unexplored in biotribology. This study aims to address this gap by fabricating Ti3C2T x -UHMWPE nanocomposites using compression molding. Primary objectives include enhancements in mechanical properties, biocompatibility, and biotribological performance, particularly in terms of friction and wear resistance in cobalt chromium alloy pin-on-UHMWPE disk experiments lubricated by artificial synovial fluid. Thereby, no substantial changes in the indentation hardness or the elastic modulus are observed, while the analysis of the resulting wettability and surface tension as well as indirect and direct in vitro evaluation do not point towards cytotoxicity. Most importantly, Ti3C2T x -reinforced PMCs substantially reduce friction and wear by up to 19% and 44%, respectively, which was attributed to the formation of an easy-to-shear transfer film.

Ti3C2Tx-UHMWPE 纳米复合材料--增强生物医学植入物的耐磨性。
目前迫切需要提高用于生物医学设备(如承重人工关节)的聚合物材料(尤其是超高分子量聚乙烯 (UHMWPE))的机械和生物ribological 性能。虽然石墨烯、氧化石墨烯(GO)、还原 GO 或六方氮化硼(h-BN)等二维(2D)材料有望成为聚合物基复合材料(PMC)的增强相,但以化学惰性、机械坚固性和耐磨性著称的 MXenes 在生物分布学方面的潜力在很大程度上仍未得到开发。本研究旨在利用压缩成型技术制造 Ti3C2Tx-UHMWPE 纳米复合材料,以填补这一空白。主要目标包括提高机械性能、生物相容性和生物ribological 性能,特别是在人工滑液润滑的钴铬合金针-UHMWPE 盘实验中的摩擦和耐磨性。因此,在压痕硬度或弹性模量方面没有观察到实质性变化,而对所产生的润湿性和表面张力的分析以及间接和直接的体外评估也没有发现细胞毒性。最重要的是,Ti3C2Tx 增强 PMC 可大幅减少摩擦和磨损,分别减少了 19% 和 44%,这归因于形成了易于剪切的转移膜。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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