Please use this identifier to cite or link to this item: https://hdl.handle.net/1959.11/14830
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dc.contributor.authorChamoli, Upharen
dc.contributor.authorWroe, Stephenen
dc.date.accessioned2014-04-28T14:10:00Z-
dc.date.issued2011-
dc.identifier.citationJournal of Theoretical Biology, 283(1), p. 217-226en
dc.identifier.issn1095-8541en
dc.identifier.issn0022-5193en
dc.identifier.urihttps://hdl.handle.net/1959.11/14830-
dc.description.abstractExtant members of the cat family (Felidae) have been considered behaviourally and morphologically conservative, i.e., despite great differences in size, there is relatively little variation in either the shape of the felid skull and dentition across species, or in the way in which these structures are used to kill and dismember prey. Consequently felids have been considered an appropriate focus for a number of investigations into the influence of allometry on craniomandibular mechanics and morphology. However, although previous treatments have considered the role of shape, they have not investigated the influence of differences in the distribution of relatively stiff cortical and more compliant cancellous bone on performance. Here, using models that incorporate material properties for both cortical and cancellous bone, we apply three-dimensional (3D) finite element analysis (FEA) to models representing the skulls of seven extant felid species. Our objectives being to determine allometric trends regarding both overall geometry and the relative distributions of cortical and cancellous bone tissue. We also more comprehensively assess variation in the efficiency with which muscular force is converted to bite force and the capacity to resist associated stresses. Our results show that the cheetah ('Acinonyx jubatus') may be exceptional regarding both the efficiency with which muscular force is converted to bite force and the distribution of stress. We found a negative allometric trend between cortical bone volume and total skull bone volume, and positive allometry between the total skull bone volume and skull surface area. Results gained from mathematical modelling of beam analogies suggest that these trends reflect a need for larger species to respond to physical challenges associated with increased size, and, that changes in skull shape, bone composition, or a combination of both may be required to accommodate these challenges. With geometrical scaling stress increases by the same factor, and displacement by the same factor squared, but the ultimate failure stress of the material is invariant. We find that as species become larger, overall skull bone volume relative to surface area increases by adding a higher proportion of less dense and more compliant cancellous bone. This results in an increased cross-sectional area and second moment of inertia, which acts to reduce the overall stresses. An overall saving in mass is a likely additional consequence. Although we do find evidence that skull stiffness does diminish with size, we also argue that this is at least in part mitigated through the influence of these allometric trends. We further suggest that these trends and the explanations for them may be universal for vertebrates.en
dc.languageenen
dc.publisherAcademic Pressen
dc.relation.ispartofJournal of Theoretical Biologyen
dc.titleAllometry in the distribution of material properties and geometry of the felid skull: Why larger species may need to change and how they may achieve iten
dc.typeJournal Articleen
dc.identifier.doi10.1016/j.jtbi.2011.05.020en
dc.subject.keywordsAnimal Structure and Functionen
local.contributor.firstnameUpharen
local.contributor.firstnameStephenen
local.subject.for2008060807 Animal Structure and Functionen
local.subject.seo2008970106 Expanding Knowledge in the Biological Sciencesen
local.profile.schoolSchool of Environmental and Rural Scienceen
local.profile.emailswroe@une.edu.auen
local.output.categoryC1en
local.record.placeauen
local.record.institutionUniversity of New Englanden
local.identifier.epublicationsrecordune-20140415-095047en
local.publisher.placeUnited Kingdomen
local.format.startpage217en
local.format.endpage226en
local.identifier.scopusid79959351136en
local.peerreviewedYesen
local.identifier.volume283en
local.identifier.issue1en
local.title.subtitleWhy larger species may need to change and how they may achieve iten
local.contributor.lastnameChamolien
local.contributor.lastnameWroeen
dc.identifier.staffune-id:swroeen
local.profile.orcid0000-0002-6365-5915en
local.profile.roleauthoren
local.profile.roleauthoren
local.identifier.unepublicationidune:15045en
local.identifier.handlehttps://hdl.handle.net/1959.11/14830en
dc.identifier.academiclevelAcademicen
local.title.maintitleAllometry in the distribution of material properties and geometry of the felid skullen
local.output.categorydescriptionC1 Refereed Article in a Scholarly Journalen
local.search.authorChamoli, Upharen
local.search.authorWroe, Stephenen
local.uneassociationUnknownen
local.year.published2011en
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