Fracture, aging, and disease in bone

Ager, Joel W.; Balooch, Guive; Ritchie, Robert O.

doi:10.1557/jmr.2006.0242

Cited by 60 publications

(35 citation statements)

References 77 publications

(108 reference statements)

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“…In human cortical bone, cross-links occur in two forms: (i) enzymatic crosslinks-as immature intrafibrillar (dehydrodihydroxynorleucine and dehydrohydroxylysinonorleucine) and mature interfibrillar (pyridinoline and pyrrole), and (ii) nonenzymatic advanced glycation end products (AGEs), such as pentosidine, that form both intra-and interfibrillar links along the collagen backbone (16). Although the level of enzymatic cross-links stabilizes around 10-15 y of age (17,18), AGEs can increase up to fivefold with age (15,18,19), which has been correlated to reduced bone toughness and fracture resistance (20)(21)(22)(23). Similarly, excessive remodeling with age increases the osteonal density in human cortical bone; this governs the degree of microcracking and in turn affects the development of crack bridges, which provide a major source of toughening at micrometer-scale levels and above (12).…”

mentioning

confidence: 99%

Age-related changes in the plasticity and toughness of human cortical bone at multiple length scales

Zimmermann

Schaible

Bale

et al. 2011

Proc. Natl. Acad. Sci. U.S.A.

330

315

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The structure of human cortical bone evolves over multiple length scales from its basic constituents of collagen and hydroxyapatite at the nanoscale to osteonal structures at near-millimeter dimensions, which all provide the basis for its mechanical properties. To resist fracture, bone’s toughness is derived intrinsically through plasticity (e.g., fibrillar sliding) at structural scales typically below a micrometer and extrinsically (i.e., during crack growth) through mechanisms (e.g., crack deflection/bridging) generated at larger structural scales. Biological factors such as aging lead to a markedly increased fracture risk, which is often associated with an age-related loss in bone mass ( bone quantity ). However, we find that age-related structural changes can significantly degrade the fracture resistance ( bone quality ) over multiple length scales. Using in situ small-angle X-ray scattering and wide-angle X-ray diffraction to characterize submicrometer structural changes and synchrotron X-ray computed tomography and in situ fracture-toughness measurements in the scanning electron microscope to characterize effects at micrometer scales, we show how these age-related structural changes at differing size scales degrade both the intrinsic and extrinsic toughness of bone. Specifically, we attribute the loss in toughness to increased nonenzymatic collagen cross-linking, which suppresses plasticity at nanoscale dimensions, and to an increased osteonal density, which limits the potency of crack-bridging mechanisms at micrometer scales. The link between these processes is that the increased stiffness of the cross-linked collagen requires energy to be absorbed by “plastic” deformation at higher structural levels, which occurs by the process of microcracking.

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mentioning

confidence: 99%

Age-related changes in the plasticity and toughness of human cortical bone at multiple length scales

Zimmermann

Schaible

Bale

et al. 2011

Proc. Natl. Acad. Sci. U.S.A.

330

315

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“…The length between 30 to 60 μm, about 40 microns, the average length of about 2 to 4 microns wide, length to diameter ratio between 10 to 20. [15] Figure 3 is the infrared spectrum of sample f. Seen from the image, there are several characteristic peaks. The absorption peaks at 561 cm -1, 960 cm-1 , 603 cm -1 are the PO43 -characteristics vibration peak; at 871 cm -1 is the HPO42-characteristics vibration peak; at 1450 cm -1 belongs to the characteristics infrared spectrum(type B replace) of CO32- [14]; OH -is shown by the characteristic of vibration peak at 1310 cm -1 without 3570 cm -1.…”

Section: Experiments Methodsmentioning

confidence: 99%

Temperature Effect on Hydroxyapatite Preparation by Co-precipitation Method under Carbamide Influence

Luo

Chen

et al. 2015

MATEC Web of Conferences

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Abstract. Hydroxyapatite crystal was prepared by homogeneous co-precipitation method using a mixture of Calcium nitrate and diammonium phosphate as raw materials and carbamide as the buffering agent. To analyzed the influence of temperature on hydroxyapatite crystal morphology, the phase composition, crystal morphology and growth orientation were characterized by X-ray diffraction , scanning electron microscope and infrared spectrum respectively. The results show that when the reaction temperature increase from 70 to 95 the phases composition of crystal transform from the two phases of tricalcium phosphate and eight calcium phosphate to hydroxyapatite single crystal; the morphology of the hydroxyapatite crystals transforms from nodular whisker to perfectly and compactly acicular whisker.

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“…315 While a great deal of the work to date has been focussed on metals and alloys, CT analyses of crack propagation are becoming more widespread in other areas, particularly with respect to more complex structured materials including 2D and 3D composite systems, 103,291,316 self-healing systems 111,317 and crack propagation in natural materials, e.g. bone, [318][319][320] teeth, 321 wood, 268 as well as graphite, 322 which is an important structural material for the nuclear industry. Mostafavi et al 323 found from surface DIC that unstable fracture is preceded by the sub-critical propagation of surface cracks having a scale similar to the microstructure.…”

Section: Quantitative 3d Fracture Mechanicsmentioning

confidence: 99%

Quantitative X-ray tomography

Maire¹,

Withers²

2013

International Materials Reviews

1,036

601

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X-ray computer tomography (CT) is fast becoming an accepted tool within the materials science community for the acquisition of 3D images. Here the authors review the current state of the art as CT transforms from a qualitative diagnostic tool to a quantitative one. Our review considers first the image acquisition process, including the use of iterative reconstruction strategies suited to specific segmentation tasks and emerging methods that provide more insight (e.g. fast and high resolution imaging, crystallite (grain) imaging) than conventional attenuation based tomography. Methods and shortcomings of CT are examined for the quantification of 3D volumetric data to extract key topological parameters such as phase fractions, phase contiguity, and damage levels as well as density variations. As a non-destructive technique, CT is an ideal means of following structural development over time via time lapse sequences of 3D images (sometimes called 3D movies or 4D imaging). This includes information needed to optimise manufacturing processes, for example sintering or solidification, or to highlight the proclivity of specific degradation processes under service conditions, such as intergranular corrosion or fatigue crack growth. Besides the repeated application of static 3D image quantification to track such changes, digital volume correlation (DVC) and particle tracking (PT) methods are enabling the mapping of deformation in 3D over time. Finally the use of CT images is considered as the starting point for numerical modelling based on realistic microstructures, for example to predict flow through porous materials, the crystalline deformation of polycrystalline aggregates or the mechanical properties of composite materials.

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Fracture, aging, and disease in bone

Cited by 60 publications

References 77 publications

Age-related changes in the plasticity and toughness of human cortical bone at multiple length scales

Age-related changes in the plasticity and toughness of human cortical bone at multiple length scales

Temperature Effect on Hydroxyapatite Preparation by Co-precipitation Method under Carbamide Influence

Quantitative X-ray tomography

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