Yin, LingVenkatesan, SudharshanWebb, DarylKalyanasundaram, ShankarQin, Qing Hua2015-12-071044-5803http://hdl.handle.net/1885/28342Microcracks accumulate in cortical bone tissue as a consequence of everyday cyclic loading. However, it remains unclear to what extent microdamage accumulation contributes to an increase in fracture risk. A cryo-preparation technique was applied to induce microcracks in cortical bone tissue. Microcracks with lengths up to approximately 20 μm, which were initiated mainly on the boundaries of haversian canals, were observed with cryo-scanning electron microscopy. A microindentation technique was applied to study the mechanical loading effect on the microcracked hydrated bone tissue. The microindentation patterns were section-scanned using confocal laser scanning microscopy to understand the deformation and bone damage mechanisms made by mechanical loading. The results show that there was no significant difference with respect to microhardness between the original and microcracked hydrated cortical bone tissues (ANOVA, p > 0.05). The cryo-induced microcracks in the bone tissue were not propagated further under the mechanical loads applied. The deformation mechanism of the microcracked cortical bone tissue was plastic deformation, not brittle fracture.Keywords: Bone tissue; Confocal laser scanning microscopy; Cortical bone; Cryo-preparation; Cryo-scanning electron microscopy; Cyclic loadings; Damage mechanism; Deformation mechanism; Fracture risks; Hydrated cortical bone; Mechanical loading; Mechanical loads; Mi Confocal laser scanning microscopy; Cryo-preparation; Hydrated cortical bone; Microcracks; Microindentation200910.1016/j.matchar.2009.01.0042016-02-24