Volumetric versus Element-scaling Mass Estimation and Its Application to Permo-Triassic Tetrapods.

IF 2.2 4区 生物学 Q2 BIOLOGY
Integrative Organismal Biology Pub Date : 2024-09-13 eCollection Date: 2024-01-01 DOI:10.1093/iob/obae034
M A Wright, T J Cavanaugh, S E Pierce
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Abstract

Size has an impact on various aspects of an animal's biology, including physiology, biomechanics, and ecology. Accurately and precisely estimating size, in particular body mass, is therefore a core objective of paleobiologists. Two approaches for estimating body mass are common: whole-body volumetric models and individual element-scaling (e.g., bones, teeth). The latter has been argued to be more accurate, while the former more precise. Here, we use minimum convex hulls (MCHs) to generate a predictive volumetric model for estimating body mass across a broad taxonomic and size range (127 g - 2735 kg). We compare our MCH model to stylopodial-scaling, incorporating data from the literature, and find that MCH body mass estimation is both more accurate and more precise than stylopodial estimation. An explanation for the difference between methods is that reptile and mammal stylopod circumference and length dimensions scale differentially (slope 1.179 ± 0.102 vs. 1.038 ± 0.031, respectively), such that reptiles have more robust bones for a given size. Consequently, a mammalian-weighted stylopodial-scaling sample overestimates the body mass of larger reptiles, and this error increases with size. We apply both estimation equations to a sample of 12 Permo-Triassic tetrapods and find that stylopodial-scaling consistently estimates a higher body mass than MCH estimation, due to even more robust bones in extinct species (slope = 1.319 ± 0.213). Finally, we take advantage of our MCH models to explore constraints regarding the position of the center of mass (CoM) and find that relative body proportions (i.e., skull:tail ratio) influence CoM position differently in mammals, crocodylians, and Permo-Triassic tetrapods. Further, we find that clade-specific body segment expansion factors do not affect group comparisons but may be important for individual specimens with rather disproportionate bodies (e.g., the small-headed and large-tailed Edaphosaurus). Our findings suggest that the whole-body volumetric approach is better suited for estimating body mass than element-scaling when anatomies are beyond the scope of the sample used to generate the scaling equations and provides added benefits such as the ability to measure inertial properties.

体积与元素比例质量估算及其在二叠纪四足动物中的应用
体型对动物生物学的各个方面都有影响,包括生理学、生物力学和生态学。因此,准确和精确地估计体型,尤其是体重,是古生物学家的核心目标。估算体重通常有两种方法:全身体积模型和单个元素比例(如骨骼、牙齿)。有人认为后者更准确,而前者更精确。在这里,我们使用最小凸壳(MCH)生成一个预测性的体积模型,用于估算在广泛的分类和体型范围(127 克 - 2735 千克)内的体重。我们结合文献中的数据,比较了我们的 MCH 模型和stylopodial-scaling,发现 MCH 体重估计比stylopodial 估计更准确、更精确。造成两种方法之间差异的原因之一是爬行动物和哺乳动物的花柱周长和长度的比例不同(斜率分别为 1.179 ± 0.102 与 1.038 ± 0.031),因此爬行动物在一定体型下的骨骼更为粗壮。因此,哺乳动物加权的骨骼尺度样本会高估较大爬行动物的体重,而且这种误差会随着爬行动物体型的增大而增大。我们将这两种估算方程应用于 12 个二叠三叠纪四足类动物样本,结果发现,由于已灭绝物种的骨骼更为粗壮,因此造型尺度估算的体重始终高于 MCH 估算的体重(斜率 = 1.319 ± 0.213)。最后,我们利用 MCH 模型探讨了质量中心(CoM)位置的制约因素,发现相对身体比例(即头骨与尾部的比例)对哺乳动物、鳄类和二叠三叠纪四足动物的质量中心位置的影响是不同的。此外,我们还发现,类群特有的体节扩张因素并不影响类群的比较,但对于身体比例失调的个体标本(如小头和大尾的埃达弗龙)来说可能很重要。我们的研究结果表明,当解剖结构超出了用于生成比例方程的样本范围时,全身体积测量法比元素比例法更适合估算身体质量,而且还能提供额外的好处,例如测量惯性特性的能力。
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
CiteScore
3.70
自引率
6.70%
发文量
48
审稿时长
20 weeks
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