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Authordc.contributor.authorToro Ibacache, Viviana 
Authordc.contributor.authorFitton, Laura C. 
Authordc.contributor.authorFagan, Michael J. 
Authordc.contributor.authorO'Higgins, Paul 
Admission datedc.date.accessioned2016-05-15T02:07:03Z
Available datedc.date.available2016-05-15T02:07:03Z
Publication datedc.date.issued2016
Cita de ítemdc.identifier.citationJ. Anat. (2016) 228, pp70--84en_US
Identifierdc.identifier.otherDOI: 10.1111/joa.12384
Identifierdc.identifier.urihttps://repositorio.uchile.cl/handle/2250/138318
General notedc.descriptionArtículo de publicación ISIen_US
Abstractdc.description.abstractFinite element analysis (FEA) is a modelling technique increasingly used in anatomical studies investigating skeletal form and function. In the case of the cranium this approach has been applied to both living and fossil taxa to (for example) investigate how form relates to function or infer diet or behaviour. However, FE models of complex musculoskeletal structures always rely on simplified representations because it is impossible completely to image and represent every detail of skeletal morphology, variations in material properties and the complexities of loading at all spatial and temporal scales. The effects of necessary simplifications merit investigation. To this end, this study focuses on one aspect, model geometry, which is particularly pertinent to fossil material where taphonomic processes often destroy the finer details of anatomy or in models built from clinical CTs where the resolution is limited and anatomical details are lost. We manipulated the details of a finite element (FE) model of an adult human male cranium and examined the impact on model performance. First, using digital speckle interferometry, we directly measured strains from the infraorbital region and frontal process of the maxilla of the physical cranium under simplified loading conditions, simulating incisor biting. These measured strains were then compared with predicted values from FE models with simplified geometries that included modifications to model resolution, and how cancellous bone and the thin bones of the circumnasal and maxillary regions were represented. Distributions of regions of relatively high and low principal strains and principal strain vector magnitudes and directions, predicted by the most detailed FE model, are generally similar to those achieved in vitro. Representing cancellous bone as solid cortical bone lowers strain magnitudes substantially but the mode of deformation of the FE model is relatively constant. In contrast, omitting thin plates of bone in the circum-nasal region affects both mode and magnitude of deformation. Our findings provide a useful frame of reference with regard to the effects of simplifications on the performance of FE models of the cranium and call for caution in the interpretation and comparison of FEA results.en_US
Patrocinadordc.description.sponsorshipBecas Chile (Comision Nacional de Investigacion Cientifica y Tecnologica, Chile)en_US
Lenguagedc.language.isoenen_US
Publisherdc.publisherWiley-Blackwellen_US
Type of licensedc.rightsAtribución-NoComercial-SinDerivadas 3.0 Chile*
Link to Licensedc.rights.urihttp://creativecommons.org/licenses/by-nc-nd/3.0/cl/*
Keywordsdc.subjectDigital speckle interferometryen_US
Keywordsdc.subjectFinite element analysisen_US
Keywordsdc.subjectFinite element model validationen_US
Keywordsdc.subjectHuman craniumen_US
Títulodc.titleValidity and sensitivity of a human cranial finite element model: implications for comparative studies of biting performanceen_US
Document typedc.typeArtículo de revista


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Except where otherwise noted, this item's license is described as Atribución-NoComercial-SinDerivadas 3.0 Chile