The evolution of femoral morphology in giant non-avian theropod dinosaurs

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2024-05-02 DOI:10.1017/pab.2024.6
Romain Pintore, John R. Hutchinson, Peter J. Bishop, Henry P. Tsai, Alexandra Houssaye
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Abstract

Theropods are obligate bipedal dinosaurs that appeared 230 Ma and are still extant as birds. Their history is characterized by extreme variations in body mass, with gigantism evolving convergently between many lineages. However, no quantification of hindlimb functional morphology has shown whether these body mass increases led to similar specializations between distinct lineages. Here we studied femoral shape variation across 41 species of theropods (n = 68 specimens) using a high-density 3D geometric morphometric approach. We demonstrated that the heaviest theropods evolved wider epiphyses and a more distally located fourth trochanter, as previously demonstrated in early archosaurs, along with an upturned femoral head and a mediodistal crest that extended proximally along the shaft. Phylogenetically informed analyses highlighted that these traits evolved convergently within six major theropod lineages, regardless of their maximum body mass. Conversely, the most gracile femora were distinct from the rest of the dataset, which we interpret as a femoral specialization to “miniaturization” evolving close to Avialae (bird lineage). Our results support a gradual evolution of known “avian” features, such as the fusion between lesser and greater trochanters and a reduction of the epiphyseal offset, independent from body mass variations, which may relate to a more “avian” type of locomotion (more knee than hip driven). The distinction between body mass variations and a more “avian” locomotion is represented by a decoupling in the mediodistal crest morphology, whose biomechanical nature should be studied to better understand the importance of its functional role in gigantism, miniaturization, and higher parasagittal abilities.
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巨型非鸟类兽脚类恐龙股骨形态的演变
兽脚类恐龙是一种两足恐龙,出现于距今230万年前,现在仍以鸟类的形式存在。它们的历史以体重的极端变化为特征,许多类群之间的巨型化演化趋同。然而,对后肢功能形态的量化研究还没有显示这些体重的增加是否导致了不同类群之间类似的特化。在这里,我们使用高密度三维几何形态计量学方法研究了 41 种兽脚类动物(n = 68 个标本)的股骨形状变化。我们证明,最重的兽脚类恐龙进化出了更宽的骨骺和位于更远处的第四转子,这与之前在早期古龙身上所证明的一样,同时还进化出了上翘的股骨头和沿轴向近端延伸的中嵴。系统发育分析突出表明,这些特征是在六大兽脚类中趋同进化的,与它们的最大体重无关。相反,最纤细的股骨与其他数据集截然不同,我们将其解释为股骨特化向 "小型化 "演化的过程接近于鸟类(Avialae)。我们的研究结果支持已知的 "鸟类 "特征的逐步进化,例如小转子和大转子之间的融合以及骺偏移的减少,这与体重的变化无关,这可能与更 "鸟类 "的运动类型有关(膝关节驱动多于髋关节驱动)。体重变化与更 "禽类 "运动之间的区别体现在中嵴形态的脱钩,应研究其生物力学性质,以更好地了解其在巨型化、小型化和更高的副躯干能力中的重要功能作用。
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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