44 research outputs found
Evidence for an elementary process in bone plasticity with an activation enthalpy of 1 eV
The molecular mechanisms for plastic deformation of bone tissue are not well understood. We analysed temperature and strain-rate dependence of the tensile deformation behaviour in fibrolamellar bone, using a technique originally developed for studying plastic deformation in metals. We show that, beyond the elastic regime, bone is highly strain-rate sensitive, with an activation volume of ca 0.6 nm3. We find an activation energy of 1.1 eV associated with the basic step involved in the plastic deformation of bone at the molecular level. This is much higher than the energy of hydrogen bonds, but it is lower than the energy required for breaking covalent bonds inside the collagen fibrils. Based on the magnitude of these quantities, we speculate that disruption of electrostatic bonds between polyelectrolyte molecules in the extrafibrillar matrix of bone, perhaps mediated by polyvalent ions such as calcium, may be the rate-limiting elementary step in bone plasticity
Accelerated Growth Plate Mineralization and Foreshortened Proximal Limb Bones in Fetuin-A Knockout Mice
PMCID: PMC3473050This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited
The Secret Life of Collagen: Temporal Changes in Nanoscale Fibrillar Pre-Strain and Molecular Organization during Physiological Loading of Cartilage
Articular
cartilage is a natural biomaterial whose structure at
the micro- and nanoscale is critical for healthy joint function and
where degeneration is associated with widespread disorders such as
osteoarthritis. At the nanoscale, cartilage mechanical functionality
is dependent on the collagen fibrils and hydrated proteoglycans that
form the extracellular matrix. The dynamic response of these ultrastructural
building blocks at the nanoscale, however, remains unclear. Here we
measure time-resolved changes in collagen fibril strain, using small-angle
X-ray diffraction during compression of bovine and human cartilage
explants. We demonstrate the existence of a collagen fibril tensile
pre-strain, estimated from the D-period at approximately 1–2%,
due to osmotic swelling pressure from the proteoglycan. We reveal
a rapid reduction and recovery of this pre-strain which occurs during
stress relaxation, approximately 60 s after the onset of peak load.
Furthermore, we show that this reduction in pre-strain is linked to
disordering in the intrafibrillar molecular packing, alongside changes
in the axial overlapping of tropocollagen molecules within the fibril.
Tissue degradation in the form of selective proteoglycan removal disrupts
both the collagen fibril pre-strain and the transient response during
stress relaxation. This study bridges a fundamental gap in the knowledge
describing time-dependent changes in collagen pre-strain and molecular
organization that occur during physiological loading of articular
cartilage. The ultrastructural details of this transient response
are likely to transform our understanding of the role of collagen
fibril nanomechanics in the biomechanics of cartilage and other hydrated
soft tissues
Interfibrillar stiffening of echinoderm mutable collagenous tissue demonstrated at the nanoscale
The mutable collagenous tissue (MCT) of echinoderms (e.g., sea cucumbers and starfish) is a remarkable example of a biological material that has the unique attribute, among collagenous tissues, of being able to rapidly change its stiffness and extensibility under neural control. However, the mechanisms of MCT have not been characterized at the nanoscale. Using synchrotron small-angle X-ray diffraction to probe time-dependent changes in fibrillar structure during in situ tensile testing of sea cucumber dermis, we investigate the ultrastructural mechanics of MCT by measuring fibril strain at different chemically induced mechanical states. By measuring a variable interfibrillar stiffness (E(IF)), the mechanism of mutability at the nanoscale can be demonstrated directly. A model of stiffness modulation via enhanced fibrillar recruitment is developed to explain the biophysical mechanisms of MCT. Understanding the mechanisms of MCT quantitatively may have applications in development of new types of mechanically tunable biomaterials
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Collagen pre-strain discontinuity at the bone—Cartilage interface
The bone-cartilage unit (BCU) is a universal feature in diarthrodial joints, which is mechanically-graded and subjected to shear and compressive strains. Changes in the BCU have been linked to osteoarthritis (OA) progression. Here we report existence of a physiological internal strain gradient (pre-strain) across the BCU at the ultrastructural scale of the extracellular matrix (ECM) constituents, specifically the collagen fibril. We use X-ray scattering that probes changes in the axial periodicity of fibril-level D-stagger of tropocollagen molecules in the matrix fibrils, as a measure of microscopic pre-strain. We find that mineralized collagen nanofibrils in the calcified plate are in tensile pre-strain relative to the underlying trabecular bone. This behaviour contrasts with the previously accepted notion that fibrillar pre-strain (or D-stagger) in collagenous tissues always reduces with mineralization, via reduced hydration and associated swelling pressure. Within the calcified part of the BCU, a finer-scale gradient in pre-strain (0.6% increase over ~50μm) is observed. The increased fibrillar pre-strain is linked to prior research reporting large tissue-level residual strains under compression. The findings may have biomechanical adaptative significance: higher in-built molecular level resilience/damage resistance to physiological compression, and disruption of the molecular-level pre-strains during remodelling of the bone-cartilage interface may be potential factors in osteoarthritis-based degeneration
collagen fibrils in antler bone Nanointerfacial strength between non-collagenous protein and References Nanointerfacial strength between non-collagenous protein and collagen fibrils in antler bone
Antler bone displays considerable toughness through the use of a complex nanofibrous structure of mineralized collagen fibrils (MCFs) bound together by non-collagenous proteins (NCPs). While the NCP regions represent a small volume fraction relative to the MCFs, significant surface area is evolved upon failure of the nanointerfaces formed at NCP-collagen fibril boundaries. The mechanical properties of nanointerfaces between the MCFs are investigated directly in this work using an in situ atomic force microscopy technique to pull out individual fibrils from the NCP. Results show that the NCP-fibril interfaces in antler bone are weak, which highlights the propensity for interface failure at the nanoscale in antler bone and extensive fibril pullout observed at antler fracture surfaces. The adhesion between fibrils and NCP is additionally suggested as being rate dependent, with increasing interfacial strength and fracture energy observed when pullout velocity decreases