Ma. Harrington et al., GEOMETRIC-PROPERTIES AND THE PREDICTED MECHANICAL-BEHAVIOR OF ADULT HUMAN CLAVICLES, Journal of biomechanics, 26(4-5), 1993, pp. 417-426
An image processing system was used to examine histomorphometric prope
rties of 15 adult male and female human clavicles. Variations in poros
ity, cross-sectional area, anatomic and principal moments of inertia w
ere assessed at 2.5-5.0% increments along the length of the clavicles.
The clavicle's biomechanical behavior (axial, flexural, and torsional
rigidities and the critical force for buckling) was modeled from thes
e data using beam theory. Over threefold variations in porosity and mo
ments of inertia were found along the length of the s-shaped clavicle-
the greatest porosity and moments of inertia were located in the varia
bly shaped sternal and acromial thirds of the bone in contrast to the
denser and smaller, more circularly shaped central third of the bone.
Clavicle orientation, as indicated by the direction of greatest resist
ance to bending (maximum principal moment of inertia), was found to ro
tate from a primarily cranio-caudal orientation at the sternum to a pr
imarily anterior posterior orientation at the acromion. Based on cross
-sectional geometry, section moduli, and estimates of flexural and tor
sional rigidity, the clavicle was found to be weakest in the central t
hird of its length. These data concur with the fracture location most
commonly reported clinically. Analysis of Euler buckling predicted a m
inimum critical force for buckling during axial loading of approximate
ly two to three body weights for an average adult. Thus, buckling, or
a combination of axial loading and bending or torsional loading, must
be considered as possible failure mechanisms for this commonly injured
bone.