Development of limb bone laminarity in the homing pigeon (Columba livia)
Background. Birds show adaptations in limb bone shape that are associated with resisting locomotor loads. Whether comparable adaptations occur in the microstructure of avian cortical bone is less clear. One proposed microstructural adaptation is laminar bone in which the proportion of circumferentia...
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Zusammenfassung: | Background. Birds show adaptations in limb bone shape that are associated
with resisting locomotor loads. Whether comparable adaptations occur in
the microstructure of avian cortical bone is less clear. One proposed
microstructural adaptation is laminar bone in which the proportion of
circumferentially-oriented vascular canals (i.e., laminarity) is large.
Previous work on adult birds shows elevated laminarity in specific limb
elements of some taxa, presumably to resist torsion-induced shear strain
during locomotion. However, more recent analyses using improved
measurements in adult birds and bats reveal lower laminarity than expected
in bones associated with torsional loading. Even so, there may still be
support for the resistance hypothesis if laminarity increases with growth
and locomotor maturation. Methods. Here, we tested that hypothesis using a
growth series of 17 homing pigeons (15–563 g). Torsional rigidity and
laminarity of limb bones were measured from histological sections sampled
from midshaft. Ontogenetic trends in laminarity were assessed using
principal component analysis to reduce dimensionality followed by beta
regression with a logit link function. Results. We found that torsional
rigidity of limb bones increases disproportionately with growth,
consistent with rapid structural compensation associated with locomotor
maturation. However, laminarity decreases with maturity, weakening the
hypothesis that high laminarity is a flight adaptation at least in the
pigeon. Instead, the histological results suggest that low laminarity,
specifically the relative proportion of longitudinal canals aligned with
peak principal strains, may better reflect the loading history of a bone. |
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DOI: | 10.5061/dryad.4b8gtht9c |