Mesh-morphing algorithms for specimen-specific finite element modeling

Sigal, Ian A.; Hardisty, Michael; Whyne, Cari

doi:10.1016/j.jbiomech.2008.02.019

Cited by 76 publications

(65 citation statements)

References 35 publications

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“…The number of tetrahedral elements was optimized to $ 60,000. This value was based on a mesh refinement study that was previously conducted for subject-specific FE models of rat vertebrae based on the median von Mises stress and the median axial strain values (Sigal et al, 2008). Average element size was further reduced by 30% in our models.…”

Section: Continuum-level Finite Element Analysesmentioning

confidence: 99%

Can micro-imaging based analysis methods quantify structural integrity of rat vertebrae with and without metastatic involvement?

Hojjat

Beek

Akens

et al. 2012

Journal of Biomechanics

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This study compares the ability of μCT image-based registration, 2D structural rigidity analyses and multimodal continuum-level finite element (FE) modeling in evaluating the mechanical stability of healthy, osteolytic, and mixed osteolytic/osteoblastic metastatically involved rat vertebrae. μMR and μCT images (loaded and unloaded) were acquired of lumbar spinal motion segments from 15rnu/rnu rats (five per group). Strains were calculated based on image registration of the loaded and unloaded μCT images and via analysis of FE models created from the μCT and μMR data. Predicted yield load was also calculated through 2D structural rigidity analysis of the axial unloaded μCT slices. Measures from the three techniques were compared to experimental yield loads. The ability of these methods to predict experimental yield loads were evaluated and image registration and FE calculated strains were directly compared. Quantitatively for all samples, only limited weak correlations were found between the image-based measures and experimental yield load. In comparison to the experimental yield load, we observed a trend toward a weak negative correlation with median strain calculated using the image-based strain measurement algorithm (r=-0.405, p=0.067), weak significant correlations (p<0.05) with FE based median and 10th percentile strain values (r=-0.454, -0.637, respectively), and a trend toward a weak significant correlation with FE based mean strain (r=-0.366, p=0.09). Individual group analyses, however, yielded more and stronger correlations with experimental results. Considering the image-based strain measurement algorithm we observed moderate significant correlations with experimental yield load (p<0.05) in the osteolytic group for mean and median strain values (r=-0.840, -0.832, respectively), and in the healthy group for median strain values (r=-0.809). Considering the rigidity-based predicted yield load, we observed a strong significant correlation with the experimental yield load in the mixed osteolytic/osteoblastic group (r=0.946) and trend toward a moderate correlation with the experimental yield load in the osteolytic group (r=0.788). Qualitatively, strain patterns in the vertebral bodies generated using image registration and FEA were well matched, yet quantitatively a significant correlation was found only between mean strains in the healthy group (r=0.934). Large structural differences in metastatic vertebrae and the complexity of motion segment loading may have led to varied modes of failure. Improvements in load characterization, material properties assignments and resolution are necessary to yield a more generalized ability for image-based registration, structural rigidity and FE methods to accurately represent stability in healthy and pathologic scenarios.

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Section: Continuum-level Finite Element Analysesmentioning

confidence: 99%

Can micro-imaging based analysis methods quantify structural integrity of rat vertebrae with and without metastatic involvement?

Hojjat

Beek

Akens

et al. 2012

Journal of Biomechanics

Self Cite

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“…Based on the above reason, even though a finite element model has some limitations, it simulates the biomechanical characteristics of the lumbar preferably [19][20][21].…”

Section: Discussionmentioning

confidence: 99%

An Approach to Lumbar Vertebra Biomechanical Analysis Using the Finite Element Modeling Based on CT Images

Li¹

2011

Theory and Applications of CT Imaging and Analysis

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“…Beyond reconstruction, warping of form has potential in simplifying the building of models that are variants of an exemplar (Sigal et al 2008(Sigal et al , 2010Stayton 2009). Indeed TPS warping is potentially useful both in assessing the mechanical consequences of variations in form such as might be encountered within and between species and in experimenting with form to examine the consequences for function.…”

Section: Using Gmm To Produce Models For Functional Analysesmentioning

confidence: 99%

Virtual Functional Morphology: Novel Approaches to the Study of Craniofacial Form and Function

et al. 2012

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Recent developments in simulating musculoskeletal functioning in the craniofacial complex using multibody dynamic analysis and finite elements analysis enable comprehensive virtual investigations into musculoskeletal form and function. Because the growth of the craniofacial skeleton is strongly influenced by mechanical functioning, these methods have potential in investigating the normal and abnormal development of the skull: loading history during development can be predicted and bony adaptations to these loads simulated. Thus these methods can be used to predict the impact of altered loading or modifications of skull form early in ontogeny on the subsequent development of structures. Combining functional models with geometric morphometric methods (GMM), which are principally concerned with the study of variations of form, offers the opportunity to examine variations in form during development and the covariations between form and factors such as functional performance. Such a combination of functional models and GMM can potentially be applied in many useful ways, for example: to build and modify functional models, to assess the outcomes of remodelling studies by comparing the results with morphological changes during ontogeny, and to compare the outcomes of finite element analyses within a multivariate framework. Studies using these tools can not only investigate the development of the skull but also the mechanical processes and thus to some degree, behaviours underlying the development of variation among extant and fossil skeletal elements. By bringing together these tools from quite different comparative traditions, a novel and potentially powerful framework for simulation and statistical biomechanical analyses of form and function emerges. This paper reviews these recent developments in the context of the evolutionary and functional influences on skull development.

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Mesh-morphing algorithms for specimen-specific finite element modeling

Cited by 76 publications

References 35 publications

Can micro-imaging based analysis methods quantify structural integrity of rat vertebrae with and without metastatic involvement?

Can micro-imaging based analysis methods quantify structural integrity of rat vertebrae with and without metastatic involvement?

An Approach to Lumbar Vertebra Biomechanical Analysis Using the Finite Element Modeling Based on CT Images

Virtual Functional Morphology: Novel Approaches to the Study of Craniofacial Form and Function

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