股骨植入物关节表面的磨损、蠕变和摩擦加热及其对长期性能的影响——第二部分,摩擦、加热和扭矩。

J A Davidson, G Schwartz, G Lynch, S Gir
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摘要

第一部分,J.A. Davidson和G. Schwartz,“股骨假体关节表面的磨损、蠕变和摩擦加热及其对长期性能的影响——第一部分,综述”,J. Biomed。板牙。Res., 21 000-000(1987)表明,人工髋关节的润滑是复杂的,其长期性能受关节材料的磨损、蠕变和较小程度的氧化降解的综合影响。重要的是,研究表明,在髋关节的关节中存在加热的趋势,升高的温度会增加UHMWPE的磨损、蠕变和氧化降解率。目前的研究是在髋关节模拟器中进行的,以仔细检查在关节过程中产生热量的倾向。所研究的体系是抛光Co-Cr-Mo合金与UHMWPE粘合,抛光氧化铝陶瓷与UHMWPE粘合,抛光氧化铝与自身粘合。还评估了每个系统在不同水平的施加载荷下的摩擦扭矩。在摩擦加热和扭矩试验中都使用了行走负荷历史。大多数试验是用5毫升水润滑剂进行的。然而,不同浓度的透明质酸的影响也进行了评估。结果显示,所有三个系统都发生摩擦加热,在大约30分钟的接合时间后达到平衡。与钴合金-超高分子量聚乙烯系统相比,陶瓷系统显示出较低的加热水平。每个系统的摩擦扭矩水平与其各自产生热量的倾向相似。透明质酸几乎没有影响,而干燥条件和少量骨水泥粉在水润滑剂中的存在显着增加了摩擦扭矩。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Wear, creep, and frictional heating of femoral implant articulating surfaces and the effect on long-term performance--Part II, Friction, heating, and torque.

In Part I, (J.A. Davidson and G. Schwartz, "Wear, creep, and frictional heating of femoral implant articulating surfaces and the effect on long-term performance--Part I, A review," J. Biomed. Mater. Res., 21, 000-000 (1987) it was shown that lubrication of the artificial hip joint was complex and that long-term performance is governed by the combined wear, creep, and to a lesser extent, oxidation degradation of the articulating materials. Importantly, it was shown that a tendency for heating exists during articulation in the hip joint and that elevated temperatures can increase the wear, creep, and oxidation degradation rate of UHMWPE. The present study was performed to examine closely the propensity to generate heat during articulation in a hip joint simulator. The systems investigated were polished Co-Cr-Mo alloy articulating against UHMWPE, polished alumina ceramic against UHMWPE, and polished alumina against itself. Frictional torque was also evaluated for each system at various levels of applied loads. A walking load history was used in both the frictional heating and torque tests. The majority of tests were performed with 5 mL of water lubricant. However, the effect of various concentrations of hyaluronic acid was also evaluated. Results showed frictional heating to occur in all three systems, reaching an equilibrium after roughly 30 min articulation time. Ceramic systems showed reduced levels of heating compared to the cobalt alloy-UHMWPE system. The level of frictional torque for each system ranked similar to their respective tendencies to generate heat. Hyaluronic acid had little effect, while dry conditions and the presence of small quantities of bone cement powder in water lubricant significantly increased frictional torque.

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