Critical Examination of Methods to Determine Tibiofemoral Kinematics and Tibial Contact Kinematics Based on Analysis of Fluoroscopic Images.

IF 1.7 4区 医学 Q4 BIOPHYSICS Journal of Biomechanical Engineering-Transactions of the Asme Pub Date : 2024-11-01 DOI:10.1115/1.4065878
Maury L Hull
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Abstract

Goals of knee replacement surgery are to restore function and maximize implant longevity. To determine how well these goals are satisfied, tibial femoral kinematics and tibial contact kinematics are of interest. Tibiofemoral kinematics, which characterize function, is movement between the tibia and femur whereas tibial contact kinematics, which is relevant to implant wear, is movement of the location of contact by the femoral implant on the tibial articular surface. The purposes of this review article are to describe and critique relevant methods to guide correct implementation. For tibiofemoral kinematics, methods are categorized as those which determine (1) relative planar motions and (2) relative three-dimensional (3D) motions. Planar motions are determined by first finding anterior-posterior (A-P) positions of each femoral condyle relative to the tibia and tracking these positions during flexion. Of the lowest point (LP) and flexion facet center (FFC) methods, which are common, the lowest point method is preferred and the reasoning is explained. 3D motions are determined using the joint coordinate system (JCS) of Grood and Suntay. Previous applications of this JCS have resulted in motions which are largely in error due to "kinematic crosstalk." Requirements for minimizing kinematic crosstalk are outlined followed by an example, which demonstrates the method for identifying a JCS that minimizes kinematic crosstalk. Although kinematic crosstalk can be minimized, the need for a JCS to determine 3D motions is questionable based on anatomical constraints, which limit varus-valgus rotation and compression-distraction translation. Methods for analyzing tibial contact kinematics are summarized and validation of methods discussed.

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对基于透视图像分析确定胫骨运动学和胫骨接触运动学的方法进行批判性研究。
膝关节置换手术的目标是恢复功能并最大限度地延长植入物的寿命。为了确定这些目标的实现情况,胫骨股骨运动学和胫骨接触运动学是非常重要的。胫骨股骨运动学是胫骨和股骨之间的运动,而胫骨接触运动学是股骨在胫骨关节面上接触位置的运动,与假体磨损有关。这篇综述文章的目的是描述和评论相关方法,以指导正确的实施。对于胫骨-股骨运动学,可将方法分为确定 1) 相对平面运动和 2) 相对 3D 运动的方法。平面运动的确定首先要找到股骨髁相对于胫骨的AP位置,并在屈曲过程中跟踪这些位置。在常用的最低点法和屈曲面中心法中,我们更倾向于最低点法,并解释了其中的原因。三维运动是使用 Grood 和 Suntay 的关节坐标系(JCS)确定的。以往应用这种关节坐标系时,由于 "运动串扰",运动会产生很大误差。本文概述了最大限度减少运动学串扰的要求,并通过一个示例演示了识别最大限度减少运动学串扰的 JCS 的方法。虽然运动学串扰可以降到最低,但由于解剖学上的限制,曲-瓣旋转和压缩-牵引平移都受到了限制,因此是否需要联合运动控制系统来确定三维运动还值得商榷。本文总结了分析胫骨接触运动学的方法,并讨论了方法的验证。
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
CiteScore
3.40
自引率
5.90%
发文量
169
审稿时长
4-8 weeks
期刊介绍: Artificial Organs and Prostheses; Bioinstrumentation and Measurements; Bioheat Transfer; Biomaterials; Biomechanics; Bioprocess Engineering; Cellular Mechanics; Design and Control of Biological Systems; Physiological Systems.
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