Biomechanics of the macaque postorbital septum investigated using finite element analysis: implications for anthropoid evolution

Finite element analysis was used to assess whether the postorbital septum plays a meaningful biomechanical role as a structural support for the circumorbital region in a species of macaque, an anthropoid primate. A finite element model was constructed of a Macaca fascicularis cranium that was subsequently modified to create a second model in which the septum was removed bilaterally. The models were subjected to forces and constraints simulating a molar bite, and resulting strains and displacements were recorded. Strain magnitudes at selected locations on the models were typically lower or unchanged in the model lacking septae, which would seem to be contrary to expectations. However, more broadly, relative to the model containing septae, the model without septae exhibited a mosaic pattern of strain increases and decreases in the circumorbital region. The model lacking septae also exhibited more asymmetric displacements in the orbital region, although not in precisely the manner predicted by prior experimental studies. Overall, the mechanical impact of the postorbital septum is minimal in macaques. These results, when considered along with those of prior experimental studies, suggest that either the postorbital septum in anthropoids did not evolve for mechanical reasons, or, if it did, it no longer plays such a role in extant taxa.

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