Numerical modelling of cancellous bone damage using an orthotropic failure criterion and tissue elastic properties as a function of the mineral content and microporosity

Megías, Raquel; Vercher-Martínez, Ana; Belda, Ricardo; Peris, José Luis Aguilar; Larraínzar-Garijo, Ricardo; Giner, Eugenio; Fuenmayor, F. J.

doi:10.1016/j.cmpb.2022.106764

Cited by 7 publications

(5 citation statements)

References 50 publications

(81 reference statements)

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“…Different pipelines for the generation of microFE models of trabecular bone were proposed (Cox et al, 2022;Fernández et al, 2022;Megías et al, 2022;Stauber et al, 2004;Verhulp et al, 2008). Nevertheless, the validation and comparison of results across studies is hindered by the use of proprietary or non-open-source software, and by the general absence of reproducible FE pipelines.…”

Section: Statement Of Needmentioning

confidence: 99%

Ciclope: micro Computed Tomography to Finite Elements

Iori¹,

Crimi²,

Schileo³

et al. 2023

JOSS

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Section: Statement Of Needmentioning

confidence: 99%

Ciclope: micro Computed Tomography to Finite Elements

Iori¹,

Crimi²,

Schileo³

et al. 2023

JOSS

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“…Human cancellous bone has a unique porous structure pattern with irregular distribution of trabecular thickness and pore size [ 15 , 16 ]. This morphology provides a comprehensive representation of the fluid and solid mechanics, osteogenic response, and bone marrow function.…”

Section: Introductionmentioning

confidence: 99%

Integrated evaluation of biomechanical and biological properties of the biomimetic structural bone scaffold: Biomechanics, simulation analysis, and osteogenesis

Li,

Yang,

Sun

et al. 2024

Materials Today Bio

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“…Secondly, differences in architectural arrangement lead to difference in bone strength: anisotropy of trabecular structures, trabecular spatial orientation and trabecular thickness are hypothesised to play a crucial role in the determination of mechanical response [4]. Bone mechanical strength at mesoscale is often evaluated experimentally by means of destructive tests, such as reported by Ciarelli et al, Rieger et al and Nikodem [11,17,29,30] and finite element analysis (FEA) [28,31,32]. Ciarelli et al analyse the relation between experimental maximum Young modulus and bone density [29], while Rieger et al investigate the connection between experimental and computational Young modulus values [17].…”

Section: Introductionmentioning

confidence: 99%

“…Nikodem [11] approaches the study of correlation between experimentally mechanical properties and few morphometric parameters, such as bone density and trabecular thickness, but, in spite of the completeness of the research, a comparison of mutual relationships among morphometric parameters is not deepened. Concerning computational analysis, despite the relevant information obtained from FEA, output of computational models are rarely explained in correlation with bone architectural arrangement [28,31,32].…”

Section: Introductionmentioning

confidence: 99%

Effect of trabecular architectures on the mechanical response in osteoporotic and healthy human bone

Bregoli,

Biffi,

Tuissi

et al. 2024

Med Biol Eng Comput

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Research at the mesoscale bone trabeculae arrangement yields intriguing results that, due to their clinical resolution, can be applied in clinical field, contributing significantly to the diagnosis of bone-related diseases. While the literature offers quantitative morphometric parameters for a thorough characterization of the mesoscale bone network, there is a gap in understanding relationships among them, particularly in the context of various bone pathologies. This research aims to bridge these gaps by offering a quantitative evaluation of the interplay among morphometric parameters and mechanical response at mesoscale in osteoporotic and non-osteoporotic bones. Bone mechanical response, dependent on trabecular arrangement, is defined by apparent stiffness, computationally calculated using the Gibson-Ashby model. Key findings indicate that: (i) in addition to bone density, measured using X-ray absorptiometry, trabecular connectivity density, trabecular spacing and degree of anisotropy are crucial parameters for characterize osteoporosis state; (ii) apparent stiffness values exhibit strong correlations with bone density and connectivity density; (iii) connectivity density and degree of anisotropy result the best predictors of mechanical response. Despite the inherent heterogeneity in bone structure, suggesting the potential benefit of a larger sample size in the future, this approach presents a valuable method to enhance discrimination between osteoporotic and non-osteoporotic samples. Graphical Abstract

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Numerical modelling of cancellous bone damage using an orthotropic failure criterion and tissue elastic properties as a function of the mineral content and microporosity

Cited by 7 publications

References 50 publications

Ciclope: micro Computed Tomography to Finite Elements

Ciclope: micro Computed Tomography to Finite Elements

Integrated evaluation of biomechanical and biological properties of the biomimetic structural bone scaffold: Biomechanics, simulation analysis, and osteogenesis

Effect of trabecular architectures on the mechanical response in osteoporotic and healthy human bone

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