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Your search keyword '"Laura C. Fitton"' showing total 5 results
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5 results on '"Laura C. Fitton"'

1. The Impact of Simplifications on the Performance of a Finite Element Model of aMacaca fascicularisCranium

Author

Paul O'Higgins, Laura C. Fitton, Charlie Rowland, Viviana Toro-Ibacache, and Miguel Prôa

Subjects
Histology, Scale (ratio), business.industry, Computer science, Structural engineering, Anatomy, Finite element method, Matrix (mathematics), Point (geometry), Segmentation, Deformation (engineering), business, Material properties, Model building, Ecology, Evolution, Behavior and Systematics, Biotechnology
Abstract

In recent years finite element analysis (FEA) has emerged as a useful tool for the analysis of skeletal form-function relationships. While this approach has obvious appeal for the study of fossil specimens, such material is often fragmentary with disrupted internal architecture and can contain matrix that leads to errors in accurate segmentation. Here we examine the effects of varying the detail of segmentation and material properties of teeth on the performance of a finite element model of a Macaca fascicularis cranium within a comparative functional framework. Cranial deformations were compared using strain maps to assess differences in strain contours and Procrustes size and shape analyses, from geometric morphometrics, were employed to compare large scale deformations. We show that a macaque model subjected to biting can be made solid, and teeth altered in material properties, with minimal impact on large scale modes of deformation. The models clustered tightly by bite point rather than by modeling simplification approach, and fell out as being distinct from another species. However localized fluctuations in predicted strain magnitudes were recorded with different modeling approaches, particularly over the alveolar region. This study indicates that, while any model simplification should be undertaken with care and attention to its effects, future applications of FEA to fossils with unknown internal architecture may produce reliable results with regard to general modes of deformation, even when detail of internal bone architecture cannot be reliably modeled.

Published
2014

2. Masticatory loadings and cranial deformation in Macaca fascicularis: a finite element analysis sensitivity study

Author

M.J. Fagan, Junfen Shi, Laura C. Fitton, and Paul O'Higgins

Subjects
Molar, Histology, Strain (injury), Cell Biology, Anatomy, Biology, medicine.disease, Masticatory force, Bite force quotient, Skull, medicine.anatomical_structure, Biting, Cranial vault, medicine, Zygomatic arch, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Developmental Biology
Abstract

Biomechanical analyses are commonly conducted to investigate how craniofacial form relates to function, particularly in relation to dietary adaptations. However, in the absence of corresponding muscle activation patterns, incomplete muscle data recorded experimentally for different individuals during different feeding tasks are frequently substituted. This study uses finite element analysis (FEA) to examine the sensitivity of the mechanical response of a Macaca fascicularis cranium to varying muscle activation patterns predicted via multibody dynamic analysis. Relative to the effects of varying bite location, the consequences of simulated variations in muscle activation patterns and of the inclusion/exclusion of whole muscle groups were investigated. The resulting cranial deformations were compared using two approaches; strain maps and geometric morphometric analyses. The results indicate that, with bite force magnitude controlled, the variations among the mechanical responses of the cranium to bite location far outweigh those observed as a consequence of varying muscle activations. However, zygomatic deformation was an exception, with the activation levels of superficial masseter being most influential in this regard. The anterior portion of temporalis deforms the cranial vault, but the remaining muscles have less profound effects. This study for the first time systematically quantifies the sensitivity of an FEA model of a primate skull to widely varying masticatory muscle activations and finds that, with the exception of the zygomatic arch, reasonable variants of muscle loading for a second molar bite have considerably less effect on cranial deformation and the resulting strain map than does varying molar bite point. The implication is that FEA models of biting crania will generally produce acceptable estimates of deformation under load as long as muscle activations and forces are reasonably approximated. In any one FEA study, the biological significance of the error in applied muscle forces is best judged against the magnitude of the effect that is being investigated.

Published
2012

3. Combining geometric morphometrics and functional simulation: an emerging toolkit for virtual functional analyses

Author

Jia Liu, Laura C. Fitton, Roger W. Phillips, M.J. Fagan, Samuel N. Cobb, Flora Gröning, and Paul O'Higgins

Subjects
Morphometrics, Histology, business.industry, Skeletal structures, Cell Biology, Multibody system, Machine learning, computer.software_genre, Functional simulation, Finite element method, Visualization, Biomechanical Phenomena, Form and function, Artificial intelligence, Anatomy, business, Molecular Biology, computer, Ecology, Evolution, Behavior and Systematics, Simulation, Developmental Biology
Abstract

The development of virtual methods for anatomical reconstruction and functional simulation of skeletal structures offers great promise in evolutionary and ontogenetic investigations of form–function relationships. Key developments reviewed here include geometric morphometric methods for the analysis and visualization of variations in form (size and shape), finite element methods for the prediction of mechanical performance of skeletal structures under load and multibody dynamics methods for the simulation and prediction of musculoskeletal function. These techniques are all used in studies of form and function in biology, but only recently have they been combined in novel ways to facilitate biomechanical modelling that takes account of variations in form, can statistically compare performance, and relate performance to form and its covariates. Here we provide several examples that illustrate how these approaches can be combined and we highlight areas that require further investigation and development before we can claim a mature theory and toolkit for a statistical biomechanical framework that unites these methods.

Published
2010

4. Functional Integration During Development Within The Masticatory Apparatus

Author

Edwin Dickinson, S. N. Cobb, Karen Swan, and Laura C. Fitton

Subjects
Orthodontics, Lever, business.product_category, Muscle size, Functional integration (neurobiology), Food item, Biology, Body size, Biochemistry, Masticatory force, Genetics, business, Molecular Biology, Biotechnology, Muscle force
Abstract

During development the masticatory apparatus undergoes significant changes; including changes in muscle size and orientation, and in dental form due to replacement and wear. As body size increases during development, absolute masticatory forces are predicted to increase. However the effect of simultaneous changes to muscle lever mechanics and dental topography upon masticatory performance is currently unknown. Cercocebus atys (the sooty mangabey) provides an ideal opportunity to examine this. Over 50% of the diet among all post-weaning individuals centres upon exploiting a mechanically stress resistant seed. Given this dietary consistency, it may be expected that the masticatory system will be integrated across development; such that individuals of all ages are capable of processing this food item. Using virtual modelling techniques, changes in bite pressure along the postcanine dental row were predicted at various stages of development. Results indicate that while maximum muscle force production increase...

Published
2015

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