国内全髋关节置换磨损测试及数值模拟研究进展
In-vitro Wear Test and Computational Wear Prediction of Total Hip Replacement in China
查看参考文献93篇
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文摘
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髋关节假体磨损及磨损颗粒所导致的无菌性松动是髋关节置换失败的重要原因.本文作者对国内髋关节磨损研究时采用的运动学与力学曲线以及针对国人测绘的相应曲线进行了差异性分析,并对国内发表的全髋关节磨损体外模拟机测试试验及结果,数值模拟模型及结果进行了总结、对比和分析.结果显示:1)国人测绘的运动学与力学曲线不能直接用于全髋关节磨损评估的加载条件,国内关节力的测量方法仍有待进一步改进;2)国内体外磨损测试的研究结论与国外发表的结论相似,但不同机构间的测试结果存在一定差异;3)国内髋关节磨损仿真研究还处于起步阶段,仿真计算得到的磨损率普遍低于体外测试结果.因此,建立基于国人行为力学的磨损评估标准、对磨损模型进行合理优化并采用有限元和骨肌多体动力学相耦合的分析方法对髋关节假体临床前磨损性能进行评估是未来的研究方向. |
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其他语种文摘
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The wear particles of hip prosthesis will cause osteolysis, which in return triggers aseptic loosening in the prosthesis itself. It is reported that one of the major reasons for revision total hip replacement is wear and the aseptic loosening caused by it. Under such a background, the pre-clinical evaluation on wear performance of hip prosthesis is becoming increasingly important. Currently, the major approaches of the pre-clinical wear assessments are the in-vitro wear test and the computational simulation. Compared with other countries, the domestic pre-clinical wear study of hip prosthesis is in the primary stage where there are very few articles on the above two approaches. Therefore, it is very important to understand the basic research status of friction and wear of hip prosthesis in China. This article firstly compared the kinematic and dynamic input of gait curves that are used in domestic hip wear assessments with the Chinese measurement gait curves. Then this article summarized, compared and analyzed the results from both domestic in-vitro simulator test and the computational simulation. And lastly this article discussed the limitations and future development directions of the hip pre-clinical wear assessments. The main findings were: 1) The gait motion curves of the Chinese were similar to the Western. The main difference lied in the gait joint force curves. And the Chinese measurement curves cannot be directly used in hip wear evaluate tests as the measurement method of hip joint force needs to be improved. 2) The domestic and the international research findings of in-vitro wear tests conducted according to the ISO 14242-1 standard were similar but the results according to other testing standards (e.g., ISO 14242-3) showed differences. This meant the accuracy of domestic in-vitro wear test results were influenced by the testing standards and testing equipment. 3) The simplified dynamic curves according to the ISO 14242-1 can be input to the finite element model to reduce the computational time. The wear rates of the domestic computational simulation were generally lower than those of the in-vitro wear tests. As a result, the accuracy of domestic computational wear models needed further improving. There were also some limitations on the current domestic wear assessments and researches. The first one was the gap between the Chinese standards and international standards. Some extreme conditions like third body wear, edge load and micro separation were not considered in current Chinese standards. Secondly there was still no gold standard on extraction of wear debris. Thirdly it was difficult to consider simultaneously the factors from patients, doctors and manufacturers that impacted on the wear performance of hip prosthesis. In order to catch up the international wear research progress of hip prosthesis, the future domestic pre-clinical wear assessments should focus on: 1) Building the national wear assessment standard that is appropriate for domestic patients; 2) Improving the extraction method of wear debris; 3) Promoting the accuracy of computational model by adopting more realistic dynamics inputs and by optimizing the wear models; 4) Combining the approaches of finite element analysis and force dependent kinematics to study the impact of patients' situations, doctor's techniques, products parameters on the wear performance of hip prosthesis. |
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来源
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摩擦学学报(中英文)
,2021,41(6):1004-1018 【核心库】
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DOI
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10.16078/j.tribology.2020261
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关键词
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人工髋关节
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磨损
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体外磨损测试
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计算机磨损仿真
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步态加载条件
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地址
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1.
西南交通大学机械工程学院摩擦学研究所, 四川, 成都, 610031
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北京市春立正达医疗器械股份有限公司, 北京, 101100
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浙江省医疗器械检验研究院, 浙江, 杭州, 310018
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长安大学工程机械学院, 道路施工技术与装备教育部重点实验室, 陕西, 西安, 710064
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语种
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中文 |
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文献类型
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综述型 |
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ISSN
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1004-0595 |
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学科
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机械、仪表工业 |
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基金
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四川省科技计划项目
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国家自然科学基金项目
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文献收藏号
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CSCD:7139857
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