Hominoid Hallucal Metatarsal Divergence and Tarsometatarsal Joint Morphology

IF 2 2区生物学 Q1 ANTHROPOLOGY

American Journal of Biological Anthropology Pub Date : 2025-09-29 DOI:10.1002/ajpa.70129

Thomas C. Prang

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Abstract

Objectives

The objective of this study is to test the hypothesis that variation in hallucal metatarsal divergence and tarsometatarsal joint morphology reflects mobility and stability across hominoids using a comparative morphological approach.

Methods

The comparative sample includes 896 3D models of extant hominoid first metatarsals, second metatarsals, intermediate cuneiforms, and medial cuneiforms representing 224 individuals across 10 taxa. The variables include the hallucal metatarsal divergence angle, articular surface areas, curvatures, and joint congruence indices. Linear modeling and information criteria were used to evaluate taxon, locomotor frequency, and ecology and locomotion effects.

Results

Extant hominoids vary in a predictable manner based on their ecological and locomotor differences. Humans and eastern gorillas have morphologies suggestive of a less divergent, less mobile hallux, whereas orangutans and hylobatids fall on the opposite end of the morphological spectrum. The models using a graded ecology and locomotion predictor variable substantially outperform those using binary locomotor predictors based on frequencies of arboreality and terrestriality.

Conclusions

The morphology of the hominoid hallucal tarsometatarsal joint reflects variation in ecology and locomotion. A large-bodied, forest-living ecological niche may select for hallucal grasping features in taxa that spend a large proportion of their locomotor budget on the ground because foraging for preferred foods and avoiding predators relies on vertical climbing, which is a relatively infrequent but potentially selectively advantageous locomotor behavior of African apes.

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类人猿幻觉跖骨分化与跗跖骨关节形态。

目的：本研究的目的是通过比较形态学方法检验幻觉跖骨分化和跗跖骨关节形态的变化反映人科动物的移动性和稳定性的假设。方法：比较样本包括10个类群224个个体的896个现存古人类第一跖骨、第二跖骨、中间楔形骨和中间楔形骨的三维模型。变量包括幻觉跖骨发散角、关节表面积、曲率和关节同余指数。采用线性建模和信息准则对分类群、运动频率、生态和运动效应进行评价。结果：现存的类人猿以可预测的方式根据其生态和运动的差异而变化。人类和东部大猩猩的足趾形态分化程度较低，活动能力较弱，而猩猩和足跖动物的足趾形态则处于相反的一端。使用分级生态和运动预测变量的模型大大优于基于树栖和陆地频率的二元运动预测模型。结论：类人猿幻觉跗跖关节的形态反映了生态和运动的变化。一个体型庞大、生活在森林中的生态位可能会选择那些将大部分运动预算花在地面上的类群的幻觉抓取特征，因为觅食喜欢的食物和躲避捕食者依赖于垂直攀登，这是一种相对少见的、但可能具有选择性优势的非洲猿运动行为。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

American Journal of Biological Anthropology

CiteScore

4.80

自引率

0.00%

发文量