韧带建模技术对膝关节运动学影响的有限元研究。

Ata M Kiapour, Vikas Kaul, Ali Kiapour, Carmen E Quatman, Samuel C Wordeman, Timothy E Hewett, Constantine K Demetropoulos, Vijay K Goel
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引用次数: 50

摘要

有限元(FE)分析已经成为人类关节生物力学研究中越来越流行的技术,因为它可以详细分析关节/组织在复杂的临床相关载荷条件下的行为。各种各样的建模技术已经被用来模拟膝关节韧带。然而,选择本构模型来模拟韧带对膝关节运动学的影响仍不清楚。本研究的目的是确定在功能负荷条件下,两种最常用的膝关节韧带建模技术对关节运动学的影响。我们假设具有各向异性超弹性特性的膝关节韧带的解剖表征将导致更真实的运动学。使用了先前开发的,广泛验证的健康年轻女运动员膝关节解剖FE模型。采用具有三维解剖和简化的膝关节主要韧带单轴表示的有限元模型来模拟四种功能加载条件。胫骨股骨关节运动学的模型预测与实验测量进行了比较。结果表明,膝关节韧带的解剖表征(三维几何形状以及各向异性超弹性材料)能够对人体膝关节运动进行更多的生理预测,与实验结果具有很强的相关性(所有比较的r≥0.9)和最小偏差(0.9º≤RMSE≤2.29°)。相反,韧带的非生理性单轴弹性表示导致较低的相关性(所有比较的r≤0.6)和与实验结果的较大偏差(2.6°≤RMSE≤4.2°)。目前的研究结果支持了我们的假设,并强调了软组织建模技术在所得的有限元预测关节运动学中的关键作用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

The Effect of Ligament Modeling Technique on Knee Joint Kinematics: A Finite Element Study.

The Effect of Ligament Modeling Technique on Knee Joint Kinematics: A Finite Element Study.

The Effect of Ligament Modeling Technique on Knee Joint Kinematics: A Finite Element Study.

The Effect of Ligament Modeling Technique on Knee Joint Kinematics: A Finite Element Study.

Finite element (FE) analysis has become an increasingly popular technique in the study of human joint biomechanics, as it allows for detailed analysis of the joint/tissue behavior under complex, clinically relevant loading conditions. A wide variety of modeling techniques have been utilized to model knee joint ligaments. However, the effect of a selected constitutive model to simulate the ligaments on knee kinematics remains unclear. The purpose of the current study was to determine the effect of two most common techniques utilized to model knee ligaments on joint kinematics under functional loading conditions. We hypothesized that anatomic representations of the knee ligaments with anisotropic hyperelastic properties will result in more realistic kinematics. A previously developed, extensively validated anatomic FE model of the knee developed from a healthy, young female athlete was used. FE models with 3D anatomic and simplified uniaxial representations of main knee ligaments were used to simulate four functional loading conditions. Model predictions of tibiofemoral joint kinematics were compared to experimental measures. Results demonstrated the ability of the anatomic representation of the knee ligaments (3D geometry along with anisotropic hyperelastic material) in more physiologic prediction of the human knee motion with strong correlation (r ≥ 0.9 for all comparisons) and minimum deviation (0.9º ≤ RMSE ≤ 2.29°) from experimental findings. In contrast, non-physiologic uniaxial elastic representation of the ligaments resulted in lower correlations (r ≤ 0.6 for all comparisons) and substantially higher deviation (2.6° ≤ RMSE ≤ 4.2°) from experimental results. Findings of the current study support our hypothesis and highlight the critical role of soft tissue modeling technique on the resultant FE predicted joint kinematics.

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