The Finite Element Study of the Subsequent Injury in a MCL Deficient Knee

Jie Yao; Yubo Fan; Ming Zhang

doi:10.1007/978-3-642-03882-2-257

The Finite Element Study of the Subsequent Injury in a MCL Deficient Knee

Jie Yao
, Yubo Fan^*
, Ming Zhang

^*Corresponding author for this work

Hong Kong Polytechnic University

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

The medial collateral ligament (MCL) tears frequently in sports and is commonly accompanied by ACL and medial meniscus injuries. Experimental and clinical studies have been widely carried out, but were limited to obtaining stress distribution and conducting parametric studies. The purposes of this study were to develop a validated three dimensional finite element model of knee joint, and to analyze the subsequent changes of the kinematics and stress distribution of corresponding structures induced by different levels of MCL rupture. The model was developed from magnetic resonance images and validated by published experimental data. A loading and boundary condition of passive knee flexion (0∼60 degrees) were applied to the knee with an intact MCL, superficial MCL torn, deep MCL torn and complete MCL torn. The most significant differences found were the deformation within medial meniscus as well as the valgus degree of the knee between pre- and post-injury MCL condition. The computational results indicated that the deep MCL prevents excessive translation of medial meniscus, while the superficial MCL provides most of the restraining valgus moment. This study could help to understand the various subsequent injuries led by MCL injuries, and to predict the risk positions in the joint. Furthermore, this model could shed some light on the mechanism of MCL injuries and the treatments.

Original language	English
Title of host publication	World Congress on Medical Physics and Biomedical Engineering
Subtitle of host publication	Image Processing, Biosignal Processing, Modelling and Simulation, Biomechanics
Pages	966-969
Number of pages	4
Edition	4
DOIs	https://doi.org/10.1007/978-3-642-03882-2-257
State	Published - 2009
Event	World Congress on Medical Physics and Biomedical Engineering: Image Processing, Biosignal Processing, Modelling and Simulation, Biomechanics - Munich, Germany Duration: 7 Sep 2009 → 12 Sep 2009

Publication series

Name	IFMBE Proceedings
Number	4
Volume	25
ISSN (Print)	1680-0737

Conference

Conference	World Congress on Medical Physics and Biomedical Engineering: Image Processing, Biosignal Processing, Modelling and Simulation, Biomechanics
Country/Territory	Germany
City	Munich
Period	7/09/09 → 12/09/09

Keywords

Deep MCL
Finite element model
Injury
Superficial MCL
Valgus degree

Access to Document

10.1007/978-3-642-03882-2-257

Cite this

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title = "The Finite Element Study of the Subsequent Injury in a MCL Deficient Knee",

abstract = "The medial collateral ligament (MCL) tears frequently in sports and is commonly accompanied by ACL and medial meniscus injuries. Experimental and clinical studies have been widely carried out, but were limited to obtaining stress distribution and conducting parametric studies. The purposes of this study were to develop a validated three dimensional finite element model of knee joint, and to analyze the subsequent changes of the kinematics and stress distribution of corresponding structures induced by different levels of MCL rupture. The model was developed from magnetic resonance images and validated by published experimental data. A loading and boundary condition of passive knee flexion (0∼60 degrees) were applied to the knee with an intact MCL, superficial MCL torn, deep MCL torn and complete MCL torn. The most significant differences found were the deformation within medial meniscus as well as the valgus degree of the knee between pre- and post-injury MCL condition. The computational results indicated that the deep MCL prevents excessive translation of medial meniscus, while the superficial MCL provides most of the restraining valgus moment. This study could help to understand the various subsequent injuries led by MCL injuries, and to predict the risk positions in the joint. Furthermore, this model could shed some light on the mechanism of MCL injuries and the treatments.",

keywords = "Deep MCL, Finite element model, Injury, Superficial MCL, Valgus degree",

author = "Jie Yao and Yubo Fan and Ming Zhang",

year = "2009",

doi = "10.1007/978-3-642-03882-2-257",

language = "英语",

isbn = "9783642038815",

series = "IFMBE Proceedings",

number = "4",

pages = "966--969",

booktitle = "World Congress on Medical Physics and Biomedical Engineering",

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note = "World Congress on Medical Physics and Biomedical Engineering: Image Processing, Biosignal Processing, Modelling and Simulation, Biomechanics ; Conference date: 07-09-2009 Through 12-09-2009",

}

Yao, J , Fan, Y & Zhang, M 2009, The Finite Element Study of the Subsequent Injury in a MCL Deficient Knee. in World Congress on Medical Physics and Biomedical Engineering: Image Processing, Biosignal Processing, Modelling and Simulation, Biomechanics. 4 edn, IFMBE Proceedings, no. 4, vol. 25, pp. 966-969, World Congress on Medical Physics and Biomedical Engineering: Image Processing, Biosignal Processing, Modelling and Simulation, Biomechanics, Munich, Germany, 7/09/09. https://doi.org/10.1007/978-3-642-03882-2-257

The Finite Element Study of the Subsequent Injury in a MCL Deficient Knee. / Yao, Jie ; Fan, Yubo; Zhang, Ming.
World Congress on Medical Physics and Biomedical Engineering: Image Processing, Biosignal Processing, Modelling and Simulation, Biomechanics. 4. ed. 2009. p. 966-969 (IFMBE Proceedings; Vol. 25, No. 4).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - The Finite Element Study of the Subsequent Injury in a MCL Deficient Knee

AU - Yao, Jie

AU - Fan, Yubo

AU - Zhang, Ming

PY - 2009

Y1 - 2009

N2 - The medial collateral ligament (MCL) tears frequently in sports and is commonly accompanied by ACL and medial meniscus injuries. Experimental and clinical studies have been widely carried out, but were limited to obtaining stress distribution and conducting parametric studies. The purposes of this study were to develop a validated three dimensional finite element model of knee joint, and to analyze the subsequent changes of the kinematics and stress distribution of corresponding structures induced by different levels of MCL rupture. The model was developed from magnetic resonance images and validated by published experimental data. A loading and boundary condition of passive knee flexion (0∼60 degrees) were applied to the knee with an intact MCL, superficial MCL torn, deep MCL torn and complete MCL torn. The most significant differences found were the deformation within medial meniscus as well as the valgus degree of the knee between pre- and post-injury MCL condition. The computational results indicated that the deep MCL prevents excessive translation of medial meniscus, while the superficial MCL provides most of the restraining valgus moment. This study could help to understand the various subsequent injuries led by MCL injuries, and to predict the risk positions in the joint. Furthermore, this model could shed some light on the mechanism of MCL injuries and the treatments.

AB - The medial collateral ligament (MCL) tears frequently in sports and is commonly accompanied by ACL and medial meniscus injuries. Experimental and clinical studies have been widely carried out, but were limited to obtaining stress distribution and conducting parametric studies. The purposes of this study were to develop a validated three dimensional finite element model of knee joint, and to analyze the subsequent changes of the kinematics and stress distribution of corresponding structures induced by different levels of MCL rupture. The model was developed from magnetic resonance images and validated by published experimental data. A loading and boundary condition of passive knee flexion (0∼60 degrees) were applied to the knee with an intact MCL, superficial MCL torn, deep MCL torn and complete MCL torn. The most significant differences found were the deformation within medial meniscus as well as the valgus degree of the knee between pre- and post-injury MCL condition. The computational results indicated that the deep MCL prevents excessive translation of medial meniscus, while the superficial MCL provides most of the restraining valgus moment. This study could help to understand the various subsequent injuries led by MCL injuries, and to predict the risk positions in the joint. Furthermore, this model could shed some light on the mechanism of MCL injuries and the treatments.

KW - Deep MCL

KW - Finite element model

KW - Injury

KW - Superficial MCL

KW - Valgus degree

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BT - World Congress on Medical Physics and Biomedical Engineering

T2 - World Congress on Medical Physics and Biomedical Engineering: Image Processing, Biosignal Processing, Modelling and Simulation, Biomechanics

Y2 - 7 September 2009 through 12 September 2009

ER -

The Finite Element Study of the Subsequent Injury in a MCL Deficient Knee

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