Undecalcified samples extracted from human femoral shafts are fractured by bending and the fracture surfaces are examined with a scanning electron microscope (SEM). The investigation is performed on both dry and wet (hydrated with a saline solution) specimens. SEM micrographs show patterns in many respects similar to those observed in fractography studies of laminated fiber reinforced synthetic composites. In particular, dry and wet samples behave like brittle and ductile matrix laminates, respec¬tively. An analysis carried out on the basis of the mechanisms that dominate the frac¬ture process of laminates shows that a reasonable cortical bone model is that of a lami¬nated composite material whose matrix is composed of extracellular noncollage¬nous calcified proteins, and the reinforcement is constituted by the calcified collagen fiber system.

Braidotti, P., Branca, F.p., Stagni, L. (1997). Scanning electron microscopy of human cortical bone failure surfaces. JOURNAL OF BIOMECHANICS, 30(2), 155-162.

Scanning electron microscopy of human cortical bone failure surfaces

STAGNI, Luigi
1997-01-01

Abstract

Undecalcified samples extracted from human femoral shafts are fractured by bending and the fracture surfaces are examined with a scanning electron microscope (SEM). The investigation is performed on both dry and wet (hydrated with a saline solution) specimens. SEM micrographs show patterns in many respects similar to those observed in fractography studies of laminated fiber reinforced synthetic composites. In particular, dry and wet samples behave like brittle and ductile matrix laminates, respec¬tively. An analysis carried out on the basis of the mechanisms that dominate the frac¬ture process of laminates shows that a reasonable cortical bone model is that of a lami¬nated composite material whose matrix is composed of extracellular noncollage¬nous calcified proteins, and the reinforcement is constituted by the calcified collagen fiber system.
1997
Braidotti, P., Branca, F.p., Stagni, L. (1997). Scanning electron microscopy of human cortical bone failure surfaces. JOURNAL OF BIOMECHANICS, 30(2), 155-162.
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11590/131480
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