Large Deformation Mechanisms, Plasticity, and Failure of an Individual Collagen Fibril With Different Mineral Content

Dépalle, Baptiste; Qin, Zhao; Shefelbine, Sandra J.; Buehler, Markus J.

doi:10.1002/jbmr.2705

Cited by 63 publications

(79 citation statements)

References 53 publications

(84 reference statements)

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“…During the preconditioning phase, the baseline test, and during the holding phase less than 13 % intermolecular bonds failed. This behavior is in line with results of previous studies suggesting that intermolecular bond rupture and molecular failure are prevalent mainly under large deformations . Accordingly, the amount of damaged molecules during the baseline test is negligible (see Figure A).…”

Section: Resultssupporting

confidence: 92%

A generalized inelastic modeling concept for soft fibrous tissues

2019

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This contribution proposes a multiscale modeling approach, ranging from the macromolecular behavior of tropocollagen over collagen fibrils and the interfibrillar matrix up to bundles of collagen fibers. Two damage mechanisms are described: intramolecular damage inside the tropocollagen molecules based on a permanent opening of the triple helical conformation and damage in the interfibrillar matrix restricting the recovery of interfibrillar sliding. Both intramolecular and interfibrillar damage is considered as a probabilistic process based on detachment of adhesive bonds, where the probability of failure depends on the full load history of the bond. The presented modeling concept is based on generalized assumptions valid for most soft fibrous tissues, and can therefore be applied for a variety of tissues and load‐cases. The final constitutive equations are validated against recent experimental data from uniaxial tension tests of rat tail tendon. All utilized material constants have a clear physical interpretation.

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Section: Resultssupporting

confidence: 92%

A generalized inelastic modeling concept for soft fibrous tissues

2019

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“…Incorporation of mineral into the collagen fibril increases its strength up to 10 times and its toughness up to 35 times, and the mineralized fibril reaches its maximum toughness‐to‐density and strength‐to‐density ratios at a mineral density of ∼30%. The addition of crosslinks makes the mineralized fibril stiffer but more brittle . Furthermore, without extreme alterations in the stoichiometry of the mineral phase, high mineral content is not only associated with large increases in stiffness and hardness, but also contributes to a loss of strength and toughness .…”

Section: Introductionmentioning

confidence: 99%

“…The addition of crosslinks makes the mineralized fibril stiffer but more brittle. 4 Furthermore, without extreme alterations in the stoichiometry of the mineral phase, high mineral content is not only associated with large increases in stiffness and hardness, but also contributes to a loss of strength and toughness. 5 Indeed, bone mechanics exhibit different behavior at different length scales.…”

Section: Introductionmentioning

confidence: 99%

Multiscale characterization of cortical bone composition, microstructure, and nanomechanical properties in experimentally induced osteoporosis

Shah

Stoica

Cardemil

et al. 2017

J Biomedical Materials Res

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Cortical bone plays a vital role in determining overall bone strength. We investigate the structural, compositional, and nanomechanical properties of cortical bone following ovariectomy (OVX) of 12-week-old Sprague Dawley rats, since this animal model is frequently employed to evaluate the performance of implantable biomaterials in compromised bone healing conditions. Morphological parameters and material properties of bone in the geometrical center of the femoral cortex were investigated four and eight weeks post-OVX and in unoperated controls (Ctrl), using X-ray micro-computed tomography, backscattered electron scanning electron microscopy, Raman spectroscopy, and nanoindentation. The OVX animals showed increase in body weight, diminished bone mineral density, increased intracortical porosity, but increased bone mass through periosteal apposition (e.g., increases in periosteal perimeter, cortical cross-sectional thickness, and cross-sectional area). However, osteocyte densities, osteocyte lacunar dimensions, and the nanomechanical behavior on the single mineralized collagen fibril level remained unaffected. Our correlative multiscale investigation provides structural, chemical, and nanomechanical evidence substantiating earlier reports suggesting that rats ovariectomized at 12 weeks undergo simultaneous bone loss and growth, resulting in the effects of OVX being less obvious. Periosteal apposition contradicts the conventional view of bone loss in osteoporosis but appears advantageous for the greater functional demand imposed on the skeleton by increased body weight and fragility induced by increased intracortical porosity. Through a variety of morphological changes, it is likely that 12-week-old rats are able to adapt to OVX-related microstructural and compositional alterations. © 2017 Wiley Periodicals, Inc. J Biomed Mater Res Part A: 106A: 997-1007, 2018.

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“…The mechanical properties of bone are determined by the overall phosphate content, that is, the apatite‐to‐collagen ratio. At a mineral density around 30%, the mineralized collagen fibril reaches its maximum toughness‐to‐density and strength‐to‐density ratios . The dimensions of bone apatite crystallites are constrained to the nanometer scale by the high carbonate content, but despite increased carbonate‐to‐phosphate ratios, the mineral crystallinity of bone mineral may remain unaffected .…”

Section: Discussionmentioning

confidence: 53%

Osseointegration of 3D printed microalloyed CoCr implants—Addition of 0.04% Zr to CoCr does not alter bone material properties

Shah

Jergéus

Chiba

et al. 2018

J Biomedical Materials Res

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Electron beam melting (EBM) is a three-dimensional (3D) printing technique for the production of metal structures where complex geometries with interconnected porosities can be built. Incorporation of as little as 0.04% Zr into the CoCr alloy can significantly improve the biomechanical anchorage of constructs fabricated by EBM. Here we investigate bone material properties, including microstructure and composition, adjacent to 3D printed CoCr implants with and without addition of 0.04% Zr, after 8 weeks of healing in the rabbit femur. In low amounts, zirconium addition does not alter the microstructure and extracellular matrix composition of bone formed adjacent to the surface of EBM manufactured implants. Bone ingrowth into surface irregularities of 3D printed CoCr and CoCr + Zr implants is seen. Extensive remodeling is also evident. Osteocytes attach directly on to the implant surface. The interfacial tissue at CoCr and CoCr + Zr has similar mineral crystallinity, apatite-to-collagen ratio, carbonate-to-phosphate ratio, Ca/P ratio, bone-implant contact, percentage porosity, and osteocyte density (N.Ot/B.Ar). Compared to the native bone, the mineral crystallinity of the interfacial tissue was lower while N.Ot/B.Ar was higher for both CoCr and CoCr + Zr. Overall, the results indicate that bone tissue adjacent to CoCr and CoCr + Zr implants is highly mature and exhibits comparable healing kinetics. © 2018 Wiley Periodicals, Inc. J Biomed Mater Res Part A: 106A: 1655-1663, 2018.

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Large Deformation Mechanisms, Plasticity, and Failure of an Individual Collagen Fibril With Different Mineral Content

Cited by 63 publications

References 53 publications

A generalized inelastic modeling concept for soft fibrous tissues

A generalized inelastic modeling concept for soft fibrous tissues

Multiscale characterization of cortical bone composition, microstructure, and nanomechanical properties in experimentally induced osteoporosis

Osseointegration of 3D printed microalloyed CoCr implants—Addition of 0.04% Zr to CoCr does not alter bone material properties

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