Legreneur Pierre, Bels Vincent, Monteil Karine, Laurin Michel
CRIS EA 647 (P3M), Université de Lyon, Villeurbanne, France.
Eur Phys J E Soft Matter. 2013 May;36(5):49. doi: 10.1140/epje/i2013-13049-4. Epub 2013 May 17.
In this paper, we demonstrated that interarticular coordination of terrestrial tetrapods emerges from an environment highly constrained by friction and the gravitational field. We briefly review recent works on the jumping behavior in squamates, lemurs and amphibians. We then explore previously published work as well as some unpublished experimental data on human jumping. Finally, we end by inferring locomotion in some of the first limbed vertebrates using a simulation procedure. All these data show that despite changes in shape, structure, and motor controls of taxa, the same spatio-temporal sequence of joint displacements always occurs when the movement is executed in a terrestrial environment. Comparison with aquatic locomotion argues for the hypothesis that this pattern emerged in early terrestrial tetrapods as a response to the gravitational constraint and the terrestrial frictional environment.
在本文中,我们证明了陆生四足动物的关节间协调源自一个受摩擦力和重力场高度限制的环境。我们简要回顾了近期关于有鳞目动物、狐猴和两栖动物跳跃行为的研究。然后,我们探讨了先前发表的关于人类跳跃的研究以及一些未发表的实验数据。最后,我们通过模拟程序推断最早的有肢脊椎动物的运动方式来结束本文。所有这些数据表明,尽管不同分类群的形状、结构和运动控制有所变化,但当在陆地环境中执行运动时,关节位移的时空序列总是相同的。与水生运动的比较支持了这样一种假说,即这种模式在早期陆生四足动物中出现是对重力约束和陆地摩擦环境的一种反应。
