Modeling the Human Mandible Under Masticatory Loads: Which Input Variables are Important?
Identifieur interne : 003956 ( Main/Exploration ); précédent : 003955; suivant : 003957Modeling the Human Mandible Under Masticatory Loads: Which Input Variables are Important?
Auteurs : Flora Gröning [Royaume-Uni] ; Michael Fagan [Royaume-Uni] ; Paul O'Higgins [Royaume-Uni]Source :
- The Anatomical Record: Advances in Integrative Anatomy and Evolutionary Biology [ 1932-8486 ] ; 2012-05.
English descriptors
- KwdEn :
- Alveolar bone, Basic input variables, Biomech, Bone surface, Cancellous, Cancellous bone, Cancellous bone tissue, Cancellous bone tissue material, Compliant, Compliant material, Condyle, Constraint, Cortical bone, Cortical bone tissue, Different model properties, Different values, Digital speckle pattern interferometry, Element model, Fagan, Finite element analysis, Finite element model, Finite element models, Form differences, Future studies, Geometric morphometrics, Hannam, Human mandible, Human mandibles, Human mandibular condyle, Korioth, Large degree, Large holes, Ligament, Macaque mandible, Mandible, Mandible models, Mandibular, Mandibular corpus, Mandibular function, Mandibular stiffness, Manual segmentation, Masticatory, Masticatory apparatus, Masticatory loads, Masticatory muscles, Masticatory system, Material properties, Mechanical properties, Mises strain, Model properties, Model surface, Modeling, Modulus, Muscle force orientation, Muscle force orientations, Muscle force vectors, Muscle forces, Muscle vectors, Neutral axis, Occlusal surface, Periodontal, Periodontal ligament, Phys, Phys anthropol, Point constraints, Previous studies, Procrustes distances, Reaction forces, Relative importance, Same material properties, Sampling points, Second moment, Sensitivity analyses, Sensitivity analysis, Several modeling decisions, Similar results, Simplified models, Soft tissue, Strain differences, Strain directions, Strain magnitude differences, Strain magnitudes, Temporal bone, Tooth roots, Total variance, Trabecular thickness, Validation study, Voxel, Voxel size, Whole mandibles, Wiley periodicals.
- Teeft :
- Alveolar bone, Basic input variables, Biomech, Bone surface, Cancellous, Cancellous bone, Cancellous bone tissue, Cancellous bone tissue material, Compliant, Compliant material, Condyle, Constraint, Cortical bone, Cortical bone tissue, Different model properties, Different values, Digital speckle pattern interferometry, Element model, Fagan, Finite element analysis, Finite element model, Finite element models, Form differences, Future studies, Geometric morphometrics, Hannam, Human mandible, Human mandibles, Human mandibular condyle, Korioth, Large degree, Large holes, Ligament, Macaque mandible, Mandible, Mandible models, Mandibular, Mandibular corpus, Mandibular function, Mandibular stiffness, Manual segmentation, Masticatory, Masticatory apparatus, Masticatory loads, Masticatory muscles, Masticatory system, Material properties, Mechanical properties, Mises strain, Model properties, Model surface, Modeling, Modulus, Muscle force orientation, Muscle force orientations, Muscle force vectors, Muscle forces, Muscle vectors, Neutral axis, Occlusal surface, Periodontal, Periodontal ligament, Phys, Phys anthropol, Point constraints, Previous studies, Procrustes distances, Reaction forces, Relative importance, Same material properties, Sampling points, Second moment, Sensitivity analyses, Sensitivity analysis, Several modeling decisions, Similar results, Simplified models, Soft tissue, Strain differences, Strain directions, Strain magnitude differences, Strain magnitudes, Temporal bone, Tooth roots, Total variance, Trabecular thickness, Validation study, Voxel, Voxel size, Whole mandibles, Wiley periodicals.
Abstract
Finite element analyses (FEA) that have simulated masticatory loadings of the human mandible differ significantly with regard to their basic input variables such as material properties, constraints, and applied forces. With sensitivity analyses it is possible to assess how the choice of different input values and the degree of model simplification affect FEA results. However, published FEA studies are rarely accompanied by sensitivity analyses so that the robusticity of their results is impossible to assess. Here, we conduct a sensitivity analysis with an FE model of a human mandible to quantify the relative importance of several modeling decisions: (1) the material properties assigned to the cancellous bone tissue; (2) the inclusion or not of the periodontal ligament; (3) the constraints at the joints and bite point; and (4) the orientation of applied muscle forces. We study the effects of varying these properties by analysing the strain magnitudes and directions across the model surface. In addition, we perform a geometric morphometric analysis of the deformation resulting from the loading of each model. The results show that the effects of altering the different model properties can be significant and that most effects are potentially large enough to cause problems for the biological interpretation of FEA results. We therefore recommend that researchers conduct more sensitivity analyses than at present to assess the robusticity of their FEA results and their biological conclusions. Anat Rec, 2012. © 2012 Wiley Periodicals, Inc.
Url:
DOI: 10.1002/ar.22455
Affiliations:
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Services, Inc., A Wiley Company</publisher><pubPlace>Hoboken</pubPlace><date type="published" when="2012-05">2012-05</date></imprint><idno type="ISSN">1932-8486</idno></series></biblStruct></sourceDesc><seriesStmt><idno type="ISSN">1932-8486</idno></seriesStmt></fileDesc><profileDesc><textClass><keywords scheme="KwdEn" xml:lang="en"><term>Alveolar bone</term><term>Basic input variables</term><term>Biomech</term><term>Bone surface</term><term>Cancellous</term><term>Cancellous bone</term><term>Cancellous bone tissue</term><term>Cancellous bone tissue material</term><term>Compliant</term><term>Compliant material</term><term>Condyle</term><term>Constraint</term><term>Cortical bone</term><term>Cortical bone tissue</term><term>Different model properties</term><term>Different values</term><term>Digital speckle pattern interferometry</term><term>Element model</term><term>Fagan</term><term>Finite element analysis</term><term>Finite element model</term><term>Finite element models</term><term>Form differences</term><term>Future studies</term><term>Geometric morphometrics</term><term>Hannam</term><term>Human mandible</term><term>Human mandibles</term><term>Human mandibular condyle</term><term>Korioth</term><term>Large degree</term><term>Large holes</term><term>Ligament</term><term>Macaque mandible</term><term>Mandible</term><term>Mandible models</term><term>Mandibular</term><term>Mandibular corpus</term><term>Mandibular function</term><term>Mandibular stiffness</term><term>Manual segmentation</term><term>Masticatory</term><term>Masticatory apparatus</term><term>Masticatory loads</term><term>Masticatory muscles</term><term>Masticatory system</term><term>Material properties</term><term>Mechanical properties</term><term>Mises strain</term><term>Model properties</term><term>Model surface</term><term>Modeling</term><term>Modulus</term><term>Muscle force orientation</term><term>Muscle force orientations</term><term>Muscle force vectors</term><term>Muscle forces</term><term>Muscle vectors</term><term>Neutral axis</term><term>Occlusal surface</term><term>Periodontal</term><term>Periodontal ligament</term><term>Phys</term><term>Phys anthropol</term><term>Point constraints</term><term>Previous studies</term><term>Procrustes distances</term><term>Reaction forces</term><term>Relative importance</term><term>Same material properties</term><term>Sampling points</term><term>Second moment</term><term>Sensitivity analyses</term><term>Sensitivity analysis</term><term>Several modeling decisions</term><term>Similar results</term><term>Simplified models</term><term>Soft tissue</term><term>Strain differences</term><term>Strain directions</term><term>Strain magnitude differences</term><term>Strain magnitudes</term><term>Temporal bone</term><term>Tooth roots</term><term>Total variance</term><term>Trabecular thickness</term><term>Validation study</term><term>Voxel</term><term>Voxel size</term><term>Whole mandibles</term><term>Wiley periodicals</term></keywords><keywords scheme="Teeft" xml:lang="en"><term>Alveolar bone</term><term>Basic input variables</term><term>Biomech</term><term>Bone surface</term><term>Cancellous</term><term>Cancellous bone</term><term>Cancellous bone tissue</term><term>Cancellous bone tissue material</term><term>Compliant</term><term>Compliant material</term><term>Condyle</term><term>Constraint</term><term>Cortical bone</term><term>Cortical bone tissue</term><term>Different model properties</term><term>Different values</term><term>Digital speckle pattern interferometry</term><term>Element model</term><term>Fagan</term><term>Finite element analysis</term><term>Finite element model</term><term>Finite element models</term><term>Form differences</term><term>Future studies</term><term>Geometric morphometrics</term><term>Hannam</term><term>Human mandible</term><term>Human mandibles</term><term>Human mandibular condyle</term><term>Korioth</term><term>Large degree</term><term>Large holes</term><term>Ligament</term><term>Macaque mandible</term><term>Mandible</term><term>Mandible models</term><term>Mandibular</term><term>Mandibular corpus</term><term>Mandibular function</term><term>Mandibular stiffness</term><term>Manual segmentation</term><term>Masticatory</term><term>Masticatory apparatus</term><term>Masticatory loads</term><term>Masticatory muscles</term><term>Masticatory system</term><term>Material properties</term><term>Mechanical properties</term><term>Mises strain</term><term>Model properties</term><term>Model surface</term><term>Modeling</term><term>Modulus</term><term>Muscle force orientation</term><term>Muscle force orientations</term><term>Muscle force vectors</term><term>Muscle forces</term><term>Muscle vectors</term><term>Neutral axis</term><term>Occlusal surface</term><term>Periodontal</term><term>Periodontal ligament</term><term>Phys</term><term>Phys anthropol</term><term>Point constraints</term><term>Previous studies</term><term>Procrustes distances</term><term>Reaction forces</term><term>Relative importance</term><term>Same material properties</term><term>Sampling points</term><term>Second moment</term><term>Sensitivity analyses</term><term>Sensitivity analysis</term><term>Several modeling decisions</term><term>Similar results</term><term>Simplified models</term><term>Soft tissue</term><term>Strain differences</term><term>Strain directions</term><term>Strain magnitude differences</term><term>Strain magnitudes</term><term>Temporal bone</term><term>Tooth roots</term><term>Total variance</term><term>Trabecular thickness</term><term>Validation study</term><term>Voxel</term><term>Voxel size</term><term>Whole mandibles</term><term>Wiley periodicals</term></keywords></textClass></profileDesc></teiHeader><front><div type="abstract" xml:lang="en">Finite element analyses (FEA) that have simulated masticatory loadings of the human mandible differ significantly with regard to their basic input variables such as material properties, constraints, and applied forces. With sensitivity analyses it is possible to assess how the choice of different input values and the degree of model simplification affect FEA results. However, published FEA studies are rarely accompanied by sensitivity analyses so that the robusticity of their results is impossible to assess. Here, we conduct a sensitivity analysis with an FE model of a human mandible to quantify the relative importance of several modeling decisions: (1) the material properties assigned to the cancellous bone tissue; (2) the inclusion or not of the periodontal ligament; (3) the constraints at the joints and bite point; and (4) the orientation of applied muscle forces. We study the effects of varying these properties by analysing the strain magnitudes and directions across the model surface. In addition, we perform a geometric morphometric analysis of the deformation resulting from the loading of each model. The results show that the effects of altering the different model properties can be significant and that most effects are potentially large enough to cause problems for the biological interpretation of FEA results. We therefore recommend that researchers conduct more sensitivity analyses than at present to assess the robusticity of their FEA results and their biological conclusions. Anat Rec, 2012. © 2012 Wiley Periodicals, Inc.</div></front></TEI><affiliations><list><country><li>Royaume-Uni</li></country></list><tree><country name="Royaume-Uni"><noRegion><name sortKey="Groning, Flora" sort="Groning, Flora" uniqKey="Groning F" first="Flora" last="Gröning">Flora Gröning</name></noRegion><name sortKey="Fagan, Michael" sort="Fagan, Michael" uniqKey="Fagan M" first="Michael" last="Fagan">Michael Fagan</name><name sortKey="Groning, Flora" sort="Groning, Flora" uniqKey="Groning F" first="Flora" last="Gröning">Flora Gröning</name><name sortKey="Groning, Flora" sort="Groning, Flora" uniqKey="Groning F" first="Flora" last="Gröning">Flora Gröning</name><name sortKey="Groning, Flora" sort="Groning, Flora" uniqKey="Groning F" first="Flora" last="Gröning">Flora Gröning</name><name sortKey="O Higgins, Paul" sort="O Higgins, Paul" uniqKey="O Higgins P" first="Paul" last="O'Higgins">Paul O'Higgins</name></country></tree></affiliations></record>Pour manipuler ce document sous Unix (Dilib)
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