Ontogenetic changes of geometrical and mechanical characteristics of the avian femur: a comparison between precocial and altricial birds

The mechanical performance of limb bones is closely associated with an animal's locomotor capability and is thus important to our understanding of animal behaviour. This study combined a geometrical analysis and three‐point bending tests to address the question of how the mechanical performance of the femurs of Japanese quail (Coturnix coturnix japonica) and pigeon (Columba livia domestica) respond to changing functional demands during ontogeny. Results showed that hatchling quails had stiff bone tissues, and the femoral ultimate loads scaled negatively with body mass, corresponding to high functional demands during early growth. The hatchling pigeon femora had weak material properties but they showed a dramatic increase in Young's modulus during growth. Consequently, although femoral cross‐sectional geometry showed negative allometry, the ultimate loads scaled positively with body mass. Older pigeons had more circular bone cross‐sections than younger pigeons, probably due to load stimulation changes occurred shortly after the onset of locomotion. Negative allometry and isometry of the cross‐sectional geometry of hind limb bones were observed in flying birds and ground‐dwelling birds, respectively. The correspondence between geometrical change and locomotor pattern suggests that ontogenetic changes in cross‐sectional geometry may be an effective indicator of avian locomotor behaviour. This study analysed the ontogenetic changes of femoral mechanical performance of Japanese quail and pigeons, and the results were compared with published data of three other birds. Results showed precocial and altricial birds are different from each other in ontogenetic patterns of both femoral material properties and structural properties. Birds with similar locomotor behaviour may share uniform cross‐sectional ontogenetic pattern.