Advances in assessment of bone porosity, permeability and interstitial fluid flow

Cardoso, Luís; Fritton, Susannah P.; Gailani, Gaffar; Benalla, Mohammed; Cowin, Stephen C.

doi:10.1016/j.jbiomech.2012.10.025

Cited by 161 publications

(113 citation statements)

References 103 publications

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“…This porosity contains the osteocytes' stellar network of bone (typical pore size of 100 nm) and the smallest porosity level in bone corresponds to the spaces inside the collagen-apatite structure (typical pore size of 5 nm). At this nanoconfined environment, water strongly interacts with the ionic crystal [25,26] and plays a key role in structuring the apatite mineral [27,28] and during mineralization [29] by acting as a prominent charge carrier, maintaining the pH of the medium, and transporting ions [26].…”

Section: Introductionmentioning

confidence: 99%

Molecular Dynamics Simulations of Hydroxyapatite Nanopores in Contact with Electrolyte Solutions: The Effect of Nanoconfinement and Solvated Ions on the Surface Reactivity and the Structural, Dynamical, and Vibrational Properties of Water

et al. 2017

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Hydroxyapatite, the main mineral phase of mammalian tooth enamel and bone, grows within nanoconfined environments and in contact with aqueous solutions that are rich in ions. Hydroxyapatite nanopores of different pore sizes (20 Å ≤ H ≤ 110 Å, where H is the size of the nanopore) in contact with liquid water and aqueous electrolyte solutions (CaCl 2 (aq) and CaF 2 (aq)) were investigated using molecular dynamics simulations to quantify the effect of nanoconfinement and solvated ions on the surface reactivity and the structural and dynamical properties of water. The combined effect of solution composition and nanoconfinement significantly slows the self-diffusion coefficient of water molecules compared with bulk liquid. Analysis of the pair and angular distribution functions, distribution of hydrogen bonds, velocity autocorrelation functions, and power spectra of water shows that solution composition and nanoconfinement in particular enhance the rigidity of the water hydrogen bonding network. Calculation of the water exchange events in the coordination of calcium ions reveals that the dynamics of water molecules at the HAP-solution interface decreases substantially with the degree of confinement. Ions in solution also reduce the water dynamics at the surface calcium sites. Together, these changes in the properties of water impart an overall rigidifying effect on the solvent network and reduce the reactivity at the hydroxyapatite-solution interface. Since the process of surface-cation-dehydration governs the kinetics of the reactions occurring at mineral surfaces, such as adsorption and crystal growth, this work shows how nanoconfinement and solvation environment influence the molecular-level events surrounding the crystallization of hydroxyapatite.

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Section: Introductionmentioning

confidence: 99%

Molecular Dynamics Simulations of Hydroxyapatite Nanopores in Contact with Electrolyte Solutions: The Effect of Nanoconfinement and Solvated Ions on the Surface Reactivity and the Structural, Dynamical, and Vibrational Properties of Water

et al. 2017

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“…Although the LCN is raising increasing interest, it is a structure difficult to assess since it is deeply embedded in calcified bone matrix and it is composed of a huge number of nanometric structures. Lacunae are flat ellipsoidal voids housing the osteocyte bodies and with a density between 26000 to 90000/mm 3 (Cardoso et al, 2013). Canaliculi are narrow tunnels, enclosing the cell processes of the osteocytes with a reported diameter around 100-700 nm (You et al, 2004).…”

Section: Introductionmentioning

confidence: 99%

Quantification of the 3d Morphology of the Bone Cell Network From Synchrotron Micro-Ct Images

Dong

Pacureanu

Zuluaga³

et al. 2014

Image Anal Stereol

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In the context of bone diseases research, recent works have highlighted the crucial role of the osteocyte system. This system, hosted in the lacuno-canalicular network (LCN), plays a key role in the bone remodeling process. However, few data are available on the LCN due to the limitations of current microscopy techniques, and have mainly only been obtained from 2D histology sections. Here we present, for the first time, an automatic method to quantify the LCN in 3D from synchrotron radiation microtomography images. After segmentation of the LCN, two binary images are generated, one of lacunae (hosting the cell body) and one of canaliculi (small channels linking the lacunae). The binary image of lacunae is labeled, and for each object, lacunar descriptors are extracted after calculating the second order moments and the intrinsic volumes. Furthermore, we propose a specific method to quantify the ramification of canaliculi around each lacuna. To this aim, a signature of the numbers of canaliculi at different distances from the lacunar surface is estimated through the calculation of topological parameters. The proposed method was applied to the 3D SR micro-CT image of a human femoral mid-diaphysis bone sample. Statistical results are reported on 399 lacunae and their surrounding canaliculi.

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“…The correct order of magnitude of bone permeability is still a matter of debate (Cardoso et al, 2013). Previous computational studies (Pereira and Shefelbine, 2014) showed that poroelastic models with bone permeability k = 10 −22 m 2 simulate relaxation times similar to in vivo measures in mice and consistent with recent experimental estimations (Benalla et al, 2014).…”

Section: Constitutive Assumptions For Permeability Of Bone and Membranessupporting

confidence: 67%

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Supplemental Information 1: Figure S1 and Figure S2

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The development of predictive mathematical models can contribute to a deeper understanding of the specific stages of bone mechanobiology and the process by which bone adapts to mechanical forces. The objective of this work was to predict, with spatial accuracy, cortical bone adaptation to mechanical load, in order to better understand the mechanical cues that might be driving adaptation.The axial tibial loading model was used to trigger cortical bone adaptation in C57BL/6 mice and provide relevant biological and biomechanical information.A method for mapping cortical thickness in the mouse tibia diaphysis was developed, allowing for a thorough spatial description of where bone adaptation occurs.Poroelastic finite-element (FE) models were used to determine the structural response of the tibia upon axial loading and interstitial fluid velocity as the mechanical stimulus. FE models were coupled with mechanobiological governing equations, which accounted for non-static loads and assumed that bone responds instantly to local mechanical cues in an on-off manner. PrePrintsThe presented formulation was able to simulate the areas of adaptation and accurately reproduce the distributions of cortical thickening observed in the experimental data with a statistically significant positive correlation (Kendall's tau rank coefficient τ = 0.51, p < 0.001).This work demonstrates that computational models can spatially predict cortical bone mechanoadaptation to time variant stimulus. Such models could be used in the design of more efficient loading protocols and drugs therapies that target the relevant physiological mechanisms.

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Advances in assessment of bone porosity, permeability and interstitial fluid flow

Cited by 161 publications

References 103 publications

Molecular Dynamics Simulations of Hydroxyapatite Nanopores in Contact with Electrolyte Solutions: The Effect of Nanoconfinement and Solvated Ions on the Surface Reactivity and the Structural, Dynamical, and Vibrational Properties of Water

Molecular Dynamics Simulations of Hydroxyapatite Nanopores in Contact with Electrolyte Solutions: The Effect of Nanoconfinement and Solvated Ions on the Surface Reactivity and the Structural, Dynamical, and Vibrational Properties of Water

Quantification of the 3d Morphology of the Bone Cell Network From Synchrotron Micro-Ct Images

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