X. Wang scite author profile

The objective of this study was to investigate how molecular level changes in the collagen network affect its mechanical integrity. Our hypothesis is that the cleavage and unwinding of triple helices of collagen molecules significantly reduce the mechanical integrity of the collagen network in bone, whereas collagen crosslinks play a major role in sustaining the structural integrity of the collagen network. To test this hypothesis, the collagen molecular structure was altered in demineralized human cadaveric bone samples in the following two ways: heat induced unwinding and pancreas elastase induced cleavage of collagen molecules. Along with control specimens, the treated specimens were mechanically tested in tension to determine their strength, elastic modulus, toughness, and strain to failure. Also, the percentage of denatured collagen molecules and amounts of two major collagen crosslinks (hydroxylysylpyridinoline and lysylpyridinoline) were determined using high-performance liquid chromatography techniques. It was found that unwinding of collagen molecules may cause more reduction in stiffness (E) but less strain to failure (ef) than cleavage. Both collagen denaturation types cause similar changes in the strength (ss) and work to fracture (Wf) of the collagen network with no significant changes in hydroxylysylpyridinoline and lysylpyridinoline crosslinks. The results of this study indicate that the integrity of collagen molecules significantly affect the mechanical properties of the collagen network in bone, and that collagen crosslinks may play an important role in maintaining the mechanical integrity of the collagen network after collagen denaturation occurs.

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A novel scratching approach for measuring age-related changes in the in situ toughness of bone

Wang

Yoon

2007

Journal of Biomechanics

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A scratch test using a nanoindentation system was proposed in this study to assess the age-related changes in the in situ toughness of bone matrix at ultrastructural levels. A tissue removal energy density (u r ) was defined and estimated as the work done by the scratch (U T ) divided by the total volume of the scratch groove (u s ). The value of u s was used as a relative measure of the in situ toughness of the tissue. Human cortical bone specimens obtained from middle-aged (between 49 and 59 years old) and elderly groups (over 69 years old) were tested using this technique. A significant difference in the estimated removal energy density (u s ) in the secondary osteons was found between the middle-aged and elderly groups (5.49±0.696 vs. 4.09±1.30 N/mm 2 , respectively).

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Mechanical properties and interface toughness of FeCo thin films on Ti–6Al–4V

Chan

Wang

et al. 2006

Materials Science and Engineering: A

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X. Wang

Fundamentals of Biomechanics in Tissue Engineering of Bone

Fundamental Biomechanics in Bone Tissue Engineering

Effects of Collagen Unwinding and Cleavage on the Mechanical Integrity of the Collagen Network in Bone

A novel scratching approach for measuring age-related changes in the in situ toughness of bone

Mechanical properties and interface toughness of FeCo thin films on Ti–6Al–4V

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