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Abstract
The indentation-derived elastic modulus, E, of bovine compact bone was obtained by nanoindentation. The indentation modulus of the dry condition (i.e. under atmospheric conditions) is 40% higher than when measured wet (i.e. immersed in buffer solution). Although this difference is independent of orientation, there is a 20% difference in the indentation modulus within the same tested environment between longitudinal and transversal directions. In addition, the estimated indentation modulus of the same samples when tested wet in buffer solution after deep freezing (−15°C) was not affected. The discrepancy between wet and dry results was attributed to the non-mineralized phase contribution and rationalized by a simple mechanical model [I. Jäger and P. Fratzl, Biophys. J. 79 (2000) p.1737]. Anisotropy effects could be explained in terms of deformation mechanisms with orientation. The effect of frozen storage temperatures may be clarified considering the biomechanics of the helicoidal arrangement of lamellar bone. Viscoelastic effects were also considered and incorporated into analysis of the force–displacement data.
Acknowledgements
Financial aid through EC Contract No. MEST-CT-2004-504465 'Marie Curie Host Fellowships for Early Stage Research Training’ is gratefully acknowledged. GG thanks Dr. Himadri Gupta and Professor Peter Fratzl from the Max Planck Institute of Colloids and Interfaces in Golm, Germany, for discussions and guidance, and Dr. Markus Lengauer for mechanical simulations.
