The Influence of Articular Cartilage Thickness Reduction on Meniscus Biomechanics

Evaluation of the biomechanical interaction between meniscus and cartilage in medial compartment knee osteoarthritis. The finite element method was used to simulate knee joint contact mechanics. Three knee models were created on the basis of knee geometry from the Open Knee project. We reduced the t...

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Veröffentlicht in:	PloS one 2016-12, Vol.11 (12), p.e0167733-e0167733
Hauptverfasser:	Łuczkiewicz, Piotr, Daszkiewicz, Karol, Chróścielewski, Jacek, Witkowski, Wojciech, Winklewski, Pawel J
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Sprache:	eng
Schlagworte:	Analysis Arthritis Biocompatibility Biology and Life Sciences Biomechanical Phenomena Biomechanics Biomedical materials Bones Care and treatment Cartilage Cartilage (articular) Cartilage diseases Cartilage, Articular - anatomy & histology Cartilage, Articular - pathology Compressive properties Computer simulation Contact stresses Degeneration Design of experiments Diagnosis Engineering Environmental engineering Extrusion Finite Element Analysis Finite element method Geometry Humans Knee Knee Joint - anatomy & histology Knee Joint - pathology Ligaments Mathematical models Medicine and Health Sciences Meniscus Meniscus - anatomy & histology Meniscus - pathology Models, Anatomic Nonlinear analysis Osteoarthritis Osteoarthritis, Knee - pathology Pathology Physical Sciences Reduction Skin & tissue grafts Stress, Mechanical Studies Tibia - anatomy & histology Tibia - pathology Weight-Bearing
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description	Evaluation of the biomechanical interaction between meniscus and cartilage in medial compartment knee osteoarthritis. The finite element method was used to simulate knee joint contact mechanics. Three knee models were created on the basis of knee geometry from the Open Knee project. We reduced the thickness of medial cartilages in the intact knee model by approximately 50% to obtain a medial knee osteoarthritis (OA) model. Two variants of medial knee OA model with congruent and incongruent contact surfaces were analysed to investigate the influence of congruency. A nonlinear static analysis for one compressive load case was performed. The focus of the study was the influence of cartilage degeneration on meniscal extrusion and the values of the contact forces and contact areas. In the model with incongruent contact surfaces, we observed maximal compressive stress on the tibial plateau. In this model, the value of medial meniscus external shift was 95.3% greater, while the contact area between the tibial cartilage and medial meniscus was 50% lower than in the congruent contact surfaces model. After the non-uniform reduction of cartilage thickness, the medial meniscus carried only 48.4% of load in the medial compartment in comparison to 71.2% in the healthy knee model. We have shown that the change in articular cartilage geometry may significantly reduce the role of meniscus in load transmission and the contact area between the meniscus and cartilage. Additionally, medial knee OA may increase the risk of meniscal extrusion in the medial compartment of the knee joint.
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The finite element method was used to simulate knee joint contact mechanics. Three knee models were created on the basis of knee geometry from the Open Knee project. We reduced the thickness of medial cartilages in the intact knee model by approximately 50% to obtain a medial knee osteoarthritis (OA) model. Two variants of medial knee OA model with congruent and incongruent contact surfaces were analysed to investigate the influence of congruency. A nonlinear static analysis for one compressive load case was performed. The focus of the study was the influence of cartilage degeneration on meniscal extrusion and the values of the contact forces and contact areas. In the model with incongruent contact surfaces, we observed maximal compressive stress on the tibial plateau. In this model, the value of medial meniscus external shift was 95.3% greater, while the contact area between the tibial cartilage and medial meniscus was 50% lower than in the congruent contact surfaces model. 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The finite element method was used to simulate knee joint contact mechanics. Three knee models were created on the basis of knee geometry from the Open Knee project. We reduced the thickness of medial cartilages in the intact knee model by approximately 50% to obtain a medial knee osteoarthritis (OA) model. Two variants of medial knee OA model with congruent and incongruent contact surfaces were analysed to investigate the influence of congruency. A nonlinear static analysis for one compressive load case was performed. The focus of the study was the influence of cartilage degeneration on meniscal extrusion and the values of the contact forces and contact areas. In the model with incongruent contact surfaces, we observed maximal compressive stress on the tibial plateau. In this model, the value of medial meniscus external shift was 95.3% greater, while the contact area between the tibial cartilage and medial meniscus was 50% lower than in the congruent contact surfaces model. After the non-uniform reduction of cartilage thickness, the medial meniscus carried only 48.4% of load in the medial compartment in comparison to 71.2% in the healthy knee model. We have shown that the change in articular cartilage geometry may significantly reduce the role of meniscus in load transmission and the contact area between the meniscus and cartilage. Additionally, medial knee OA may increase the risk of meniscal extrusion in the medial compartment of the knee joint.</abstract><cop>United States</cop><pub>Public Library of Science</pub><pmid>27936066</pmid><doi>10.1371/journal.pone.0167733</doi><tpages>e0167733</tpages><oa>free_for_read</oa></addata></record>
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subjects	Analysis Arthritis Biocompatibility Biology and Life Sciences Biomechanical Phenomena Biomechanics Biomedical materials Bones Care and treatment Cartilage Cartilage (articular) Cartilage diseases Cartilage, Articular - anatomy & histology Cartilage, Articular - pathology Compressive properties Computer simulation Contact stresses Degeneration Design of experiments Diagnosis Engineering Environmental engineering Extrusion Finite Element Analysis Finite element method Geometry Humans Knee Knee Joint - anatomy & histology Knee Joint - pathology Ligaments Mathematical models Medicine and Health Sciences Meniscus Meniscus - anatomy & histology Meniscus - pathology Models, Anatomic Nonlinear analysis Osteoarthritis Osteoarthritis, Knee - pathology Pathology Physical Sciences Reduction Skin & tissue grafts Stress, Mechanical Studies Tibia - anatomy & histology Tibia - pathology Weight-Bearing
title	The Influence of Articular Cartilage Thickness Reduction on Meniscus Biomechanics
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