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Finite Element Modelling Simulated Meniscus Translocation and Deformation during Locomotion of the Equine Stifle

SIMPLE SUMMARY: Meniscal tears are one of the most common soft tissue injuries in the equine stifle joint. To date no optimal treatment strategy to heal meniscal tissue is available. Accordingly, there is a need to improve treatment for meniscal injuries and thus to identify appropriate translationa...

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Autores principales: Zellmann, Pasquale, Ribitsch, Iris, Handschuh, Stephan, Peham, Christian
Formato: Online Artículo Texto
Lenguaje:English
Publicado: MDPI 2019
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6720206/
https://www.ncbi.nlm.nih.gov/pubmed/31370196
http://dx.doi.org/10.3390/ani9080502
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author Zellmann, Pasquale
Ribitsch, Iris
Handschuh, Stephan
Peham, Christian
author_facet Zellmann, Pasquale
Ribitsch, Iris
Handschuh, Stephan
Peham, Christian
author_sort Zellmann, Pasquale
collection PubMed
description SIMPLE SUMMARY: Meniscal tears are one of the most common soft tissue injuries in the equine stifle joint. To date no optimal treatment strategy to heal meniscal tissue is available. Accordingly, there is a need to improve treatment for meniscal injuries and thus to identify appropriate translational animal models. A possible alternative to animal experimentation is the use of finite element modelling (FEMg). FEMg allows simulation of time dependent changes in tissues resulting from biomechanical strains. We developed a finite element model (FEM) of the equine stifle joint to identify pressure peaks and simulate translocation and deformation of the menisci at different joint angles under loading conditions. The FEM model was tested across a range of motion of approximately 30°. Pressure load was higher overall in the lateral meniscus than in the medial meniscus. Accordingly, the simulation showed higher translocation and deformation throughout the whole range of motion in the lateral compared to the medial meniscus. The results encourage further refinement of this FEM model for studying loading patterns on menisci and articular cartilages as well as the resulting mechanical stress in the subchondral bone. A functional FEM model can not only help identify segments in the femoro–tibial joint which are predisposed to injury, but also provide better understanding of the progression of certain stifle disorders, simulate treatment/surgery effects and to optimize implant/transplant properties in order to most closely resemble natural tissue. ABSTRACT: We developed a finite element model (FEM) of the equine stifle joint to identify pressure peaks and simulate translocation and deformation of the menisci. A series of sectional magnetic resonance images (1.5 T) of the stifle joint of a 23 year old Shetland pony gelding served as basis for image segmentation. Based on the 3D polygon models of femur, tibia, articular cartilages, menisci, collateral ligaments and the meniscotibial ligaments, an FEM model was generated. Tissue material properties were assigned based on data from human (Open knee(s) project) and bovine femoro-tibial joint available in the literature. The FEM model was tested across a range of motion of approximately 30°. Pressure load was overall higher in the lateral meniscus than in the medial. Accordingly, the simulation showed higher translocation and deformation in the lateral compared to the medial meniscus. The results encourage further refinement of this model for studying loading patterns on menisci and articular cartilages as well as the resulting mechanical stress in the subchondral bone (femur and tibia). A functional FEM model can not only help identify segments in the stifle which are predisposed to injury, but also to better understand the progression of certain stifle disorders, simulate treatment/surgery effects and to optimize implant/transplant properties.
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spelling pubmed-67202062019-10-30 Finite Element Modelling Simulated Meniscus Translocation and Deformation during Locomotion of the Equine Stifle Zellmann, Pasquale Ribitsch, Iris Handschuh, Stephan Peham, Christian Animals (Basel) Article SIMPLE SUMMARY: Meniscal tears are one of the most common soft tissue injuries in the equine stifle joint. To date no optimal treatment strategy to heal meniscal tissue is available. Accordingly, there is a need to improve treatment for meniscal injuries and thus to identify appropriate translational animal models. A possible alternative to animal experimentation is the use of finite element modelling (FEMg). FEMg allows simulation of time dependent changes in tissues resulting from biomechanical strains. We developed a finite element model (FEM) of the equine stifle joint to identify pressure peaks and simulate translocation and deformation of the menisci at different joint angles under loading conditions. The FEM model was tested across a range of motion of approximately 30°. Pressure load was higher overall in the lateral meniscus than in the medial meniscus. Accordingly, the simulation showed higher translocation and deformation throughout the whole range of motion in the lateral compared to the medial meniscus. The results encourage further refinement of this FEM model for studying loading patterns on menisci and articular cartilages as well as the resulting mechanical stress in the subchondral bone. A functional FEM model can not only help identify segments in the femoro–tibial joint which are predisposed to injury, but also provide better understanding of the progression of certain stifle disorders, simulate treatment/surgery effects and to optimize implant/transplant properties in order to most closely resemble natural tissue. ABSTRACT: We developed a finite element model (FEM) of the equine stifle joint to identify pressure peaks and simulate translocation and deformation of the menisci. A series of sectional magnetic resonance images (1.5 T) of the stifle joint of a 23 year old Shetland pony gelding served as basis for image segmentation. Based on the 3D polygon models of femur, tibia, articular cartilages, menisci, collateral ligaments and the meniscotibial ligaments, an FEM model was generated. Tissue material properties were assigned based on data from human (Open knee(s) project) and bovine femoro-tibial joint available in the literature. The FEM model was tested across a range of motion of approximately 30°. Pressure load was overall higher in the lateral meniscus than in the medial. Accordingly, the simulation showed higher translocation and deformation in the lateral compared to the medial meniscus. The results encourage further refinement of this model for studying loading patterns on menisci and articular cartilages as well as the resulting mechanical stress in the subchondral bone (femur and tibia). A functional FEM model can not only help identify segments in the stifle which are predisposed to injury, but also to better understand the progression of certain stifle disorders, simulate treatment/surgery effects and to optimize implant/transplant properties. MDPI 2019-07-31 /pmc/articles/PMC6720206/ /pubmed/31370196 http://dx.doi.org/10.3390/ani9080502 Text en © 2019 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (http://creativecommons.org/licenses/by/4.0/).
spellingShingle Article
Zellmann, Pasquale
Ribitsch, Iris
Handschuh, Stephan
Peham, Christian
Finite Element Modelling Simulated Meniscus Translocation and Deformation during Locomotion of the Equine Stifle
title Finite Element Modelling Simulated Meniscus Translocation and Deformation during Locomotion of the Equine Stifle
title_full Finite Element Modelling Simulated Meniscus Translocation and Deformation during Locomotion of the Equine Stifle
title_fullStr Finite Element Modelling Simulated Meniscus Translocation and Deformation during Locomotion of the Equine Stifle
title_full_unstemmed Finite Element Modelling Simulated Meniscus Translocation and Deformation during Locomotion of the Equine Stifle
title_short Finite Element Modelling Simulated Meniscus Translocation and Deformation during Locomotion of the Equine Stifle
title_sort finite element modelling simulated meniscus translocation and deformation during locomotion of the equine stifle
topic Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6720206/
https://www.ncbi.nlm.nih.gov/pubmed/31370196
http://dx.doi.org/10.3390/ani9080502
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