Micromechanics modeling of Haversian cortical bone properties

In this study, the fracture micromechanics of Haversian cortical bone has been considered. To this effect, a two-dimensional micromechanical fibre-ceramic matrix composite tissue materials model has been presented. The interstitial tissue was modeled as a matrix and the osteon was modeled as a fibre

We investigated the micromechanical behavior of porcine femoral cortical bone using a novel, nondestructive, noncontacting, laser-based strain measurement technique. The technique is based upon the well-known concept of tracking translating laser speckle with a linear array CCD camera, but employs a

## Abstract The micromechanical elastic properties of potential bone‐graft materials were compared with that of the human mandible. Six different potential bone‐replacement materials were used: Bio‐Oss (Osteohealth), OsteoGraf/N‐700 (Ceramed), Pepgen P15 (Ceramed), Interpore200 (Interpore Cross Int

## Abstract Analytical models that predict modulus degradation in cortical bone subjected to uniaxial fatigue loading in tension and compression are presented. On the basis of experimental observations, damage was modeled as self‐limiting for tension but not for compression. These mechanistic uniax

## Abstract The ability to assess the risk of fracture, evaluate new therapies, predict implant success and assess the influence of bone remodeling disorders requires specific measurement of local bone micromechanical properties. Nanoindentation is an established tool for assessing the micromechani