Study of the Elasto-Plastic Properties of Mineralized Biomaterials Via Synchrotron High-Energy X-Ray Diffraction

Synchrotron high-energy X-ray diffraction was employed to investigate the strains in the hydroxyapatite (HAP) platelets and mineralized collagen fibrils in bovine dentin and cortical bone. The HAP and the fibrillar apparent moduli, defined as the applied stress divided by the phase strain, in dentin were measured as 27±7.2 and 16±4.9 GPa. The HAP apparent modulus (E^HAP_app) is less than the lower bound calculated for E^HAP_app from the Voigt model. This discrepancy is probably due to stress concentrators or decreases in the HAP Young’s modulus due to size or composition effects. E^HAP_app and E^fib_app in dentin vary significantly within a single tooth in both the apical-cervical direction and the buccal-lingual direction. However, the variation between teeth is minimal. The HAP and fibrillar apparent moduli are not affected by freezing in dentin or by X-ray irradiation in bone and dentin.

X-ray irradiation causes a decrease in HAP residual strain in bone. This decrease suggests the presence of HAP-collagen interfacial damage. It was determined from the HAP 00.2 peak broadening that irradiation damage mostly affects the HAP unit cells which are under the highest strain. From this it was theorized that irradiation may damage highly-strained bonds at stress concentrators and/or calcium-mediated electrostatic bonds. The fact that the apparent modulus does not change with irradiation suggests that the interfacial damage must be reversible.

Bone and dentin both undergo creep when loaded to high stresses. At low irradiation doses, both the fibrillar and HAP strains increase with creep time indicating that load is being transferred from the matrix to the HAP. However, at high doses, the strain on the HAP decreases with creep time. This supports the interfacial damage theory which would allow the HAP to release its elastic load upon interfacial debonding. At -80 MPa, beyond a dose of 50 kGy, the rate of change in HAP strain with time begins to increase, becoming positive at ~115 kGy. After 300 kGy the HAP strain rate decreases and plateaus probably due to stiffening of the matrix through cross-linking. The HAP and fibrillar strain rate in irradiated bone and dentin samples increase with increased temperature and applied load.

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Year

Entry

2005

Akkus O. Elastic deformation of mineralized collagen fibrils: an equivalent inclusion based composite model. J Biomech Eng. June 2005;127(3):383-390.

1977

Ascenzi A, Benvenuti A. Evidence of a state of initial stress in osteonic lamellae. J Biomech. 1977;10(8):447-453.

1985

Bonar LC, Lees S, Mook HA. Neutron diffraction studies of collagen in fully mineralized bone. J Mol Biol. 1985;181(2):265-270.

1982

Gilmore RS, Katz JL. Elastic properties of apatites. J Mater Sci. 1982;17:1131-1141.

2002

Currey JD. Bones: Structure and Mechanics. Princeton, NJ: Princeton University Press; 2002.