Functional Morphology and Evolutionary Anatomy Working Group, Department of Biological Sciences, Western Illinois University, Macomb, Illinois, USA.
Anat Rec (Hoboken). 2010 Dec;293(12):2044-55. doi: 10.1002/ar.21266.
In nonavian dinosaur long bones, the once-living chondroepiphysis (joint surface) overlay a now-fossilized calcified cartilage zone. Although the shape of this zone is used to infer nonavian dinosaur locomotion, it remains unclear how much it reflects chondroepiphysis shape. We tested the hypothesis that calcified cartilage shape reflects the overlying chondroepiphysis in extant archosaurs. Long bones with intact epiphyses from American alligators (Alligator mississippiensis), helmeted guinea fowl (Numida meleagris), and juvenile ostriches (Struthio camelus) were measured and digitized for geometric morphometric (GM) analyses before and after chondroepiphysis removal. Removal of the chondroepiphysis resulted in significant element truncation in all examined taxa, but the amount of truncation decreased with increasing size. GM analyses revealed that Alligator show significant differences between chondroepiphysis shape and the calcified cartilage zone in the humerus, but display nonsignificant differences in femora of large individuals. In Numida, GM analysis shows significant shape differences in juvenile humeri, but humeri of adults and the femora of all guinea fowl show no significant shape difference. The juvenile Struthio sample showed significant differences in both long bones, which diminish with increasing size, a pattern confirmed with magnetic resonance imaging scans in an adult. Our data suggest that differences in extant archosaur long bone shape are greater in elements not utilized in locomotion and related stress-inducing activities. Based on our data, we propose tentative ranges of error for nonavian dinosaur long bone dimensional measurements. We also predict that calcified cartilage shape in adult, stress-bearing nonavian dinosaur long bones grossly reflects chondroepiphysis shape.
在非鸟兽脚类恐龙的长骨中,曾经有生命的骺软骨(关节面)覆盖在现在已石化的钙化软骨区上。虽然这个区域的形状被用来推断非鸟兽脚类恐龙的运动方式,但它仍然不清楚它反映了骺软骨的形状有多少。我们检验了这样一个假设,即钙化软骨的形状反映了现存的主龙类动物的骺软骨。我们对来自美洲短吻鳄(Alligator mississippiensis)、盔鸡(Numida meleagris)和幼年鸵鸟(Struthio camelus)的带有完整骺的长骨进行了测量和数字化,以便进行几何形态测量(GM)分析,然后再去除骺软骨。在所有检查的分类群中,去除骺软骨都会导致元素的明显截断,但随着尺寸的增加,截断的量会减少。GM 分析显示,短吻鳄的肱骨骺软骨形状和钙化软骨区之间存在显著差异,但大型个体的股骨则没有显著差异。在盔鸡中,GM 分析显示幼年肱骨存在显著的形状差异,但成年个体的肱骨和所有盔鸡的股骨则没有显著的形状差异。幼年鸵鸟样本的两种长骨都显示出显著的形状差异,而且随着尺寸的增加,这种差异会减小,这一模式在成年鸵鸟的磁共振成像扫描中得到了证实。我们的数据表明,现生主龙类动物长骨的形状差异在不用于运动和相关的应激诱导活动的元素中更大。基于我们的数据,我们提出了非鸟兽脚类恐龙长骨尺寸测量的暂定误差范围。我们还预测,成年、承受压力的非鸟兽脚类恐龙长骨的钙化软骨形状大致反映了骺软骨的形状。
