蜥蜴头骨的刚体分析：对硬尾蜥的头骨进行建模

Rigid-body analysis of a lizard skull: modelling the skull of Uromastyx hardwickii.

作者信息

Moazen M, Curtis N, Evans S E, O'Higgins P, Fagan M J

机构信息

Centre for Medical Engineering and Technology, University of Hull, Hull, East Yorkshire HU6 7RX, UK.

出版信息

J Biomech. 2008;41(6):1274-80. doi: 10.1016/j.jbiomech.2008.01.012. Epub 2008 Mar 4.

DOI:10.1016/j.jbiomech.2008.01.012

PMID:18308322

Abstract

Lizard skulls vary greatly in their detailed morphology. Theoretical models and practical studies have posited a definite relationship between skull morphology and bite performance, but this can be difficult to demonstrate in vivo. Computer modelling provides an alternative approach, as long as hard and soft tissue components can be integrated and the model can be validated. An anatomically accurate three-dimensional computer model of an Uromastyx hardwickii skull was developed for rigid-body dynamic analysis. The Uromastyx jaw was first opened under motion control, and then muscle forces were applied to produce biting simulations where bite forces and joint forces were calculated. Bite forces comparable to those reported in the literature were predicted, and detailed muscular force information was produced along with additional information on the stabilizing role of temporal ligaments in late jaw closing.

摘要

蜥蜴的头骨在详细形态上差异很大。理论模型和实际研究推测头骨形态与咬合力之间存在明确关系，但这在活体中很难得到证实。只要能整合硬组织和软组织成分并验证模型，计算机建模就能提供一种替代方法。为进行刚体动力学分析，构建了一个解剖学精确的硬尾蜥头骨三维计算机模型。首先在运动控制下张开硬尾蜥的颌骨，然后施加肌肉力量进行咬合力模拟，计算咬合力和关节力。预测出与文献报道相当的咬合力，并生成了详细的肌肉力量信息以及关于颞韧带在颌骨闭合后期稳定作用的额外信息。

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蜥蜴头骨的刚体分析：对硬尾蜥的头骨进行建模

Rigid-body analysis of a lizard skull: modelling the skull of Uromastyx hardwickii.

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