Pairing computational and scaled physical models to determine permeability as a measure of cellular communication in micro- and nano-scale pericellular spaces

Anderson, Eric J.; Kreuzer, Steven M.; Small, Oliver; Tate, Melissa L. Knothe

doi:10.1007/s10404-007-0156-5

Cited by 47 publications

(28 citation statements)

References 33 publications

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“…As another important material parameter, permeability differs in terms of the bone scale. Several theoretical estimations [6,[19][20][21][22][23] and new measurements [24][25][26][27] of the lacuno-canalicular intrinsic When permeability exceeds 10 −20 m 2 , the velocity amplitude changes little (Fig. 7).…”

Section: Discussionmentioning

confidence: 99%

Poroelastic behaviors of the osteon: A comparison of two theoretical osteon models

Chen

2013

Acta Mech Sin

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In the paper, two theoretical poroelastic osteon models are presented to compare their poroelastic behaviors, one is the hollow osteon model (Haversian fluid is neglected) and the other is the osteon model with Haversian fluid considered. They both have the same two types of impermeable exterior boundary conditions, one is elastic restraint and the other is displacement constrained, which can be used for analyzing other experiments performed on similarly shaped poroelastic specimens. The obtained analytical pressure and velocity solutions demonstrate the effects of the loading factors and the material parameters, which may have a significant stimulus to the mechanotransduction of bone remodeling signals. Model comparisons indicate: (1) The Haversian fluid can enhance the whole osteonal fluid pressure and velocity fields.(2) In the hollow model, the key loading factor governing the poroelastic behavior of the osteon is strain rate, while in the model with Haversian fluid considered, the strain rate governs only the velocity. (3) The pressure amplitude is proportional to the loading frequency in the hollow model, while in the model with Haversian fluid considered, the loading frequency has little effect on the pressure amplitude.

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Section: Discussionmentioning

confidence: 99%

Poroelastic behaviors of the osteon: A comparison of two theoretical osteon models

Chen

2013

Acta Mech Sin

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“…Natural tissues are hierarchically structured materials, 1 exhibiting different structural and mechanical characteristics over a range of length scales. 2 As a consequence of the varied structure, tissues exhibit fluid flow across different length scales 3 and distinct levels of porosity can often be identified. 4 The study of fluid flow in tissues during deformation is fundamental both to understand how natural tissue functions and to develop biomimetic materials for tissue repair and replacement.…”

Section: Introductionmentioning

confidence: 99%

Size effects in indentation of hydrated biological tissues

et al. 2011

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Fluid flow in biological tissues is important in both mechanical and biological contexts. Given the hierarchical nature of tissues, there are varying length scales at which time-dependent mechanical behavior due to fluid flow may be exhibited. Here, spherical nanoindentation and microindentation testings are used for the characterization of length scale effects in the mechanical response of hydrated tissues. Although elastic properties were consistent across length scales, there was a substantial difference between the time-dependent mechanical responses for large and small contact radii in the same tissue specimens. This difference was far more obvious when poroelastic analysis was used instead of viscoelastic analysis. Overall, indentation testing is a fast and robust technique for characterizing the hierarchical structure of biological materials from nanometer to micrometer length scales and is capable of making quantitative material property measurements to do with fluid flow.

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“…The ability to image sub-cellular to tissue-organ scale structures is critical in providing an integrated understanding of physiological mechanisms [2,30,31]. A variety of different imaging modalities are usually required to bridge the gaps amongst various length scales.…”

Section: Discussionmentioning

confidence: 99%

Creating High-Resolution Multiscale Maps of Human Tissue Using Multi-beam SEM

et al. 2016

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Multi-beam scanning electron microscopy (mSEM) enables high-throughput, nano-resolution imaging of macroscopic tissue samples, providing an unprecedented means for structure-function characterization of biological tissues and their cellular inhabitants, seamlessly across multiple length scales. Here we describe computational methods to reconstruct and navigate a multitude of high-resolution mSEM images of the human hip. We calculated cross-correlation shift vectors between overlapping images and used a mass-spring-damper model for optimal global registration. We utilized the Google Maps API to create an interactive map and provide open access to our reconstructed mSEM datasets to both the public and scientific communities via our website www.mechbio.org. The nano- to macro-scale map reveals the tissue’s biological and material constituents. Living inhabitants of the hip bone (e.g. osteocytes) are visible in their local extracellular matrix milieu (comprising collagen and mineral) and embedded in bone’s structural tissue architecture, i.e. the osteonal structures in which layers of mineralized tissue are organized in lamellae around a central blood vessel. Multi-beam SEM and our presented methodology enable an unprecedented, comprehensive understanding of health and disease from the molecular to organ length scale.

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Pairing computational and scaled physical models to determine permeability as a measure of cellular communication in micro- and nano-scale pericellular spaces

Cited by 47 publications

References 33 publications

Poroelastic behaviors of the osteon: A comparison of two theoretical osteon models

Poroelastic behaviors of the osteon: A comparison of two theoretical osteon models

Size effects in indentation of hydrated biological tissues

Creating High-Resolution Multiscale Maps of Human Tissue Using Multi-beam SEM

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