Fretting-Induced Formation of Nanocrystalline CoSx Tribomaterial at the Hip Implant Taper Junction

IF 4.7 Q2 MATERIALS SCIENCE, BIOMATERIALS

ACS Applied Bio Materials Pub Date : 2025-10-03 DOI:10.1021/acsabm.5c01185

Adrian Wittrock, , , Christian Beckmann, , , Markus A. Wimmer, , , Alfons Fischer, , , Saurabh M. Das, , , Christian H. Liebscher, , and , Jörg Debus*,

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Abstract

Gross-slip fretting corrosion occurs frequently inside taper joints of endoprosthetic implants and is expected to be accompanied by the formation of a metal-organic tribomaterial, which may influence the friction and wear behavior of implants. While it is hypothesized that it contains compounds of the surrounding human body fluid and worn particles of the implant materials, its structure, composition, formation mechanism, and distribution inside the wear area remain elusive. In a multiscale structural-chemical study using Raman scattering spectroscopy and transmission electron microscopy, we reveal the tribological formation of nanocrystalline cobalt sulfide for a CoCrMo/TiAlV couple that was subjected to in vitro gross-slip fretting in bovine calf serum. We demonstrate that sulfur atoms released from the mechanochemical decomposition of cysteine/cystine disulfide bonds in serum proteins ─ as evidenced by the complete absence of characteristic S–S Raman modes and concurrent protein unfolding from α-helix to β-sheet structures ─ react with cobalt ions released tribocorrosively from the alloy to form the CoS_x tribomaterial. The resulting tribofilm is substoichiometric (x < 2) with a primary cubic structure partially mixed by a hexagonal phase. It perfectly adheres to the Co alloy through mechanical mixing, thus exhibiting the structural features of extreme-pressure antiwear additives. The CoS_x tribofilm covers 12.2% of the fretting track in the CoCrMo alloy, while maintaining a consistent thickness of approximately 15 nm. Multiple mechanisms driving this transformation are discussed: mechanical protein unfolding exposes disulfide bonds to forces that reduce their cleavage activation energy, local temperatures allow for thermal decomposition, and the acidic crevice environment facilitates chemical cleavage. The observations on the fretting-generated CoS_x tribomaterial provide the first comprehensive structural-chemical insight into tribologically beneficial features of transition metal sulfides formed in medical alloys through protein-derived sulfur. Understanding this mechanism may enable strategies to deliberately promote such protective film formation to improve the longevity of taper junctions in medical applications.

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微动诱导纳米晶CoSx摩擦材料在髋关节植入体锥面交界处的形成。

粗滑移微动腐蚀是人工种植体锥面接头内常见的腐蚀现象，并可能伴随金属-有机摩擦材料的形成，影响种植体的摩擦磨损行为。虽然假设它含有周围人体体液和植入材料磨损颗粒的化合物，但其结构、组成、形成机制和在磨损区域内的分布尚不清楚。在一项使用拉曼散射光谱和透射电子显微镜的多尺度结构化学研究中，我们揭示了CoCrMo/TiAlV对在牛犊牛血清中受到体外总滑移微动的纳米晶硫化钴的摩擦学形成。我们证明，血清蛋白中半胱氨酸/半胱氨酸二硫键的机械化学分解释放出的硫原子──完全没有特征的S-S拉曼模式和同时从α-螺旋结构向β-片结构展开的蛋白质──与合金中释放的钴离子发生摩擦腐蚀反应，形成CoSx摩擦材料。所得摩擦膜是亚化学计量（x < 2）的，初生立方结构部分由六方相混合。通过机械混合与Co合金完美结合，呈现出极压抗磨添加剂的结构特征。CoSx摩擦膜覆盖了CoCrMo合金中12.2%的微动轨迹，同时保持了约15 nm的厚度。本文讨论了驱动这一转变的多种机制：机械蛋白质展开使二硫键暴露于降低其裂解活化能的力下，局部温度允许热分解，酸性缝隙环境有利于化学裂解。对微动产生的CoSx摩擦材料的观察提供了第一个全面的结构化学见解，了解通过蛋白质衍生的硫在医用合金中形成的过渡金属硫化物的摩擦学有益特征。了解这一机制可以使策略有意促进这种保护膜的形成，以提高锥度连接在医疗应用中的寿命。

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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来源期刊

ACS Applied Bio Materials Chemistry-Chemistry (all)

CiteScore

9.40

自引率

2.10%

发文量

464

期刊介绍： ACS Applied Bio Materials is an interdisciplinary journal publishing original research covering all aspects of biomaterials and biointerfaces including and beyond the traditional biosensing, biomedical and therapeutic applications. The journal is devoted to reports of new and original experimental and theoretical research of an applied nature that integrates knowledge in the areas of materials, engineering, physics, bioscience, and chemistry into important bio applications. The journal is specifically interested in work that addresses the relationship between structure and function and assesses the stability and degradation of materials under relevant environmental and biological conditions.