A. D. Lagorio, F. R. McGechie, M. G. Fields, J. Fortner, E. Mackereth, C Perez, A. T. Wilken, M. Leal, C. V. Ward, K. M. Middleton, C. M. Holliday
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引用次数: 0
Abstract
High-resolution imaging, 3D modeling, and quantitative analyses are equipping evolutionary biologists with new approaches to understanding the variation and evolution of the musculoskeletal system. However, challenges with interpreting DiceCT data and higher order use of modeled muscles have not yet been fully explored, and the error in and accuracy of some digital methods remain unclear. West Indian Anolis lizards are a model clade for exploring patterns in functional adaptation, ecomorphology, and sexual size dimorphism in vertebrates. These lizards possess numerous jaw muscles with potentially different anatomies that sculpt the adductor chamber of the skull. Here we test approaches to quantifying the musculoskeletal shape of the heads of two species of Anolis: A. pulchellus and A. sagrei. We employ comparative approaches such as DiceCT segmentation of jaw muscles, 3D surface-attachment mapping, and 3D landmarking with the aim of exploring muscle volumes, 3D muscle fiber architecture, and sexual dimorphism of the skull. We then compare sources of measurement error in these 3D analyses while also presenting new 3D musculoskeletal data from the Anolis feeding apparatus. These findings demonstrate the accessibility and repeatability of these emerging techniques as well as provide details regarding the musculoskeletal anatomy of the heads of A. pulchellus and A. sagrei which show potential for further research of comparative biomechanics and evolution in the clade.
高分辨率成像、三维建模和定量分析为进化生物学家提供了了解肌肉骨骼系统变异和进化的新方法。然而,解读 DiceCT 数据和高阶使用建模肌肉所面临的挑战尚未得到充分探讨,一些数字方法的误差和准确性仍不清楚。西印度阿诺利斯蜥蜴是探索脊椎动物功能适应、异形和性别大小二态模式的一个模式支系。这些蜥蜴拥有许多下颌肌肉,其解剖结构可能各不相同,这些肌肉雕刻着头骨的内收腔。在这里,我们测试了量化两种巨蜥头部肌肉骨骼形状的方法:pulchellus 和 A. sagrei。我们采用了 DiceCT 下颚肌肉分割、三维表面附着映射和三维标记等比较方法,旨在探索头骨的肌肉体积、三维肌肉纤维结构和性双态性。然后,我们比较了这些三维分析中测量误差的来源,同时还展示了来自食蚁兽进食装置的新三维肌肉骨骼数据。这些发现证明了这些新兴技术的易用性和可重复性,并提供了有关 A. pulchellus 和 A. sagrei 头部肌肉骨骼解剖学的详细信息,为进一步研究该支系的比较生物力学和进化提供了可能。