Data from: Model sensitivity and use of the comparative finite element method in mammalian jaw mechanics: mandible performance in the Gray Wolf

Finite Element Analysis (FEA) is a powerful tool gaining use in studies of biological form and function. This method is particularly conducive to studies of extinct and fossilized organisms, as models can be assigned properties that approximate living tissues. In disciplines where model validation i...

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Main Authors: Tseng, Zhijie Jack, McNitt-Gray, Jill L., Flashner, Henryk, Wang, Xiaoming, Enciso, Reyes
Format: Dataset
Language:unknown
Published: 2011
Subjects:
Life sciences
medicine and health care
Functional morphology
Carnivora
mastication
Mammalia
Sensitivity Analysis
mandible
Canidae
bite force
biomechanics
finite element analysis
vertebrate paleontology
Canis lupus
manag
geo
gray wolf
Online Access:https://doi.org/10.5061/dryad.8961
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spelling fttriple:oai:gotriple.eu:50|dedup_wf_001::1a6c841661b82f2df298556473b6f89c 2023-05-15T15:50:12+02:00 Data from: Model sensitivity and use of the comparative finite element method in mammalian jaw mechanics: mandible performance in the Gray Wolf Tseng, Zhijie Jack McNitt-Gray, Jill L. Flashner, Henryk Wang, Xiaoming Enciso, Reyes 2011-01-01 https://doi.org/10.5061/dryad.8961 undefined unknown http://dx.doi.org/10.5061/dryad.8961 https://dx.doi.org/10.5061/dryad.8961 lic_creative-commons oai:services.nod.dans.knaw.nl:Products/dans:oai:easy.dans.knaw.nl:easy-dataset:80863 10.5061/dryad.8961 oai:easy.dans.knaw.nl:easy-dataset:80863 10|eurocrisdris::fe4903425d9040f680d8610d9079ea14 10|openaire____::081b82f96300b6a6e3d282bad31cb6e2 re3data_____::r3d100000044 10|openaire____::9e3be59865b2c1c335d32dae2fe7b254 10|re3data_____::94816e6421eeb072e7742ce6a9decc5f 10|re3data_____::84e123776089ce3c7a33db98d9cd15a8 10|opendoar____::8b6dd7db9af49e67306feb59a8bdc52c Life sciences medicine and health care Functional morphology Carnivora mastication Mammalia Sensitivity Analysis mandible Canidae bite force biomechanics finite element analysis vertebrate paleontology Canis lupus manag geo Dataset https://vocabularies.coar-repositories.org/resource_types/c_ddb1/ 2011 fttriple https://doi.org/10.5061/dryad.8961 2023-01-22T16:51:09Z Finite Element Analysis (FEA) is a powerful tool gaining use in studies of biological form and function. This method is particularly conducive to studies of extinct and fossilized organisms, as models can be assigned properties that approximate living tissues. In disciplines where model validation is difficult or impossible, the choice of model parameters and their effects on the results become increasingly important, especially in comparing outputs to infer function. To evaluate the extent to which performance measures are affected by initial model input, we tested the sensitivity of bite force, strain energy, and stress to changes in seven parameters that are required in testing craniodental function with FEA. Simulations were performed on FE models of a Gray Wolf (Canis lupus) mandible. Results showed that unilateral bite force outputs are least affected by the relative ratios of the balancing and working muscles, but only ratios above 0.5 provided balancing-working side joint reaction force relationships that are consistent with experimental data. The constraints modeled at the bite point had the greatest effect on bite force output, but the most appropriate constraint may depend on the study question. Strain energy is least affected by variation in bite point constraint, but larger variations in strain energy values are observed in models with different number of tetrahedral elements, masticatory muscle ratios and muscle subgroups present, and number of material properties. These findings indicate that performance measures are differentially affected by variation in initial model parameters. In the absence of validated input values, FE models can nevertheless provide robust comparisons if these parameters are standardized within a given study to minimize variation that arise during the model-building process. Sensitivity tests incorporated into the study design not only aid in the interpretation of simulation results, but can also provide additional insights on form and function. FE sensitivity models and ... Dataset Canis lupus gray wolf Unknown
institution Open Polar
collection Unknown
op_collection_id fttriple
language unknown
topic Life sciences
medicine and health care
Functional morphology
Carnivora
mastication
Mammalia
Sensitivity Analysis
mandible
Canidae
bite force
biomechanics
finite element analysis
vertebrate paleontology
Canis lupus
manag
geo
spellingShingle Life sciences
medicine and health care
Functional morphology
Carnivora
mastication
Mammalia
Sensitivity Analysis
mandible
Canidae
bite force
biomechanics
finite element analysis
vertebrate paleontology
Canis lupus
manag
geo
Tseng, Zhijie Jack
McNitt-Gray, Jill L.
Flashner, Henryk
Wang, Xiaoming
Enciso, Reyes
Data from: Model sensitivity and use of the comparative finite element method in mammalian jaw mechanics: mandible performance in the Gray Wolf
topic_facet Life sciences
medicine and health care
Functional morphology
Carnivora
mastication
Mammalia
Sensitivity Analysis
mandible
Canidae
bite force
biomechanics
finite element analysis
vertebrate paleontology
Canis lupus
manag
geo
description Finite Element Analysis (FEA) is a powerful tool gaining use in studies of biological form and function. This method is particularly conducive to studies of extinct and fossilized organisms, as models can be assigned properties that approximate living tissues. In disciplines where model validation is difficult or impossible, the choice of model parameters and their effects on the results become increasingly important, especially in comparing outputs to infer function. To evaluate the extent to which performance measures are affected by initial model input, we tested the sensitivity of bite force, strain energy, and stress to changes in seven parameters that are required in testing craniodental function with FEA. Simulations were performed on FE models of a Gray Wolf (Canis lupus) mandible. Results showed that unilateral bite force outputs are least affected by the relative ratios of the balancing and working muscles, but only ratios above 0.5 provided balancing-working side joint reaction force relationships that are consistent with experimental data. The constraints modeled at the bite point had the greatest effect on bite force output, but the most appropriate constraint may depend on the study question. Strain energy is least affected by variation in bite point constraint, but larger variations in strain energy values are observed in models with different number of tetrahedral elements, masticatory muscle ratios and muscle subgroups present, and number of material properties. These findings indicate that performance measures are differentially affected by variation in initial model parameters. In the absence of validated input values, FE models can nevertheless provide robust comparisons if these parameters are standardized within a given study to minimize variation that arise during the model-building process. Sensitivity tests incorporated into the study design not only aid in the interpretation of simulation results, but can also provide additional insights on form and function. FE sensitivity models and ...
format Dataset
author Tseng, Zhijie Jack
McNitt-Gray, Jill L.
Flashner, Henryk
Wang, Xiaoming
Enciso, Reyes
author_facet Tseng, Zhijie Jack
McNitt-Gray, Jill L.
Flashner, Henryk
Wang, Xiaoming
Enciso, Reyes
author_sort Tseng, Zhijie Jack
title Data from: Model sensitivity and use of the comparative finite element method in mammalian jaw mechanics: mandible performance in the Gray Wolf
title_short Data from: Model sensitivity and use of the comparative finite element method in mammalian jaw mechanics: mandible performance in the Gray Wolf
title_full Data from: Model sensitivity and use of the comparative finite element method in mammalian jaw mechanics: mandible performance in the Gray Wolf
title_fullStr Data from: Model sensitivity and use of the comparative finite element method in mammalian jaw mechanics: mandible performance in the Gray Wolf
title_full_unstemmed Data from: Model sensitivity and use of the comparative finite element method in mammalian jaw mechanics: mandible performance in the Gray Wolf
title_sort data from: model sensitivity and use of the comparative finite element method in mammalian jaw mechanics: mandible performance in the gray wolf
publishDate 2011
url https://doi.org/10.5061/dryad.8961
genre Canis lupus
gray wolf
genre_facet Canis lupus
gray wolf
op_source oai:services.nod.dans.knaw.nl:Products/dans:oai:easy.dans.knaw.nl:easy-dataset:80863
10.5061/dryad.8961
oai:easy.dans.knaw.nl:easy-dataset:80863
10|eurocrisdris::fe4903425d9040f680d8610d9079ea14
10|openaire____::081b82f96300b6a6e3d282bad31cb6e2
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10|openaire____::9e3be59865b2c1c335d32dae2fe7b254
10|re3data_____::94816e6421eeb072e7742ce6a9decc5f
10|re3data_____::84e123776089ce3c7a33db98d9cd15a8
10|opendoar____::8b6dd7db9af49e67306feb59a8bdc52c
op_relation http://dx.doi.org/10.5061/dryad.8961
https://dx.doi.org/10.5061/dryad.8961
op_rights lic_creative-commons
op_doi https://doi.org/10.5061/dryad.8961
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