Limb Loss and Specialized Leg Dynamics in Tiny Water-Walking Insects.

IF 2.2 3区 生物学 Q1 ZOOLOGY
Johnathan N O'Neil, Kai Lauren Yung, Gaetano Difini, Pankaj Rohilla, Saad Bhamla
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引用次数: 0

Abstract

The air-water interface of the planet's water bodies, such as ponds, lakes, and streams, presents an uncertain ecological niche with predatory threats from above and below. As Microvelia americana move across the water surface in small ponds, they face potential injury from attacks by birds, fish, and underwater invertebrates. Thus, our study investigates the effects of losing individual or pairs of tarsi on M. americana's ability to walk on water. Removal of both hind tarsi causes M. americana to rock their bodies (yaw) while running across the water surface at $\pm 19^{\circ }$, compared to $\pm 7^{\circ }$ in nonablated specimens. This increase in yaw, resulting from the removal of hind tarsi, indicates that M. americana use their hind legs as "rudders" to regulate yaw, originating from the contralateral middle legs' strokes on the water's surface through an alternating tripod gait. Ablation of the ipsilateral middle and hind tarsi disrupts directionality, making M. americana turn in the direction of their intact limbs. This loss of directionality does not occur with the removal of contralateral middle and hind tarsi. However, M. americana lose their ability to use the alternating tripod gait to walk on water on the day of contralateral ablation. Remarkably, by the next day, M. americana adapt and regain the ability to walk on water using the alternating tripod gait. Our findings elucidate the specialized leg dynamics within the alternating tripod gait of M. americana, and their adaptability to tarsal loss. This research could guide the development and design strategies of small, adaptive, and resilient micro-robots that can adapt to controller malfunction or actuator damage for walking on water and terrestrial surfaces.

在水中行走的小昆虫的肢体损失和特化腿的动态变化。
地球上池塘、湖泊和溪流等水体的空气-水界面是一个不确定的生态位,受到来自上方和下方的捕食威胁。当美洲小锹形虫在小池塘的水面上移动时,它们面临着鸟类、鱼类和水下无脊椎动物攻击的潜在伤害。因此,我们的研究调查了失去单个或成对跗节对美洲小锹形虫水上行走能力的影响。去掉两只后跗节会导致美洲金蛙在水面上奔跑时身体摇晃(偏航),幅度为±19○,而未去掉跗节的标本则为±7○。这种因切除后跗关节而导致的偏航增加表明,美洲金蛙将其后腿用作调节偏航的 "舵",通过交替的三脚架步态,由对侧中腿在水面上的划动产生偏航。同侧中跗关节和后跗关节的切除会破坏方向性,使美洲金蛙转向其完整肢体的方向。切除对侧中跗关节和后跗关节不会导致这种方向性丧失。然而,在对侧肢体被切除的当天,美洲金蛙就失去了使用交替三脚架步态在水面上行走的能力。值得注意的是,到了第二天,美洲金丝猴就能适应并恢复使用交替三脚架步态在水面上行走的能力。我们的研究结果阐明了水陆两栖动物交替三脚架步态中专门的腿部动力学,以及它们对跗关节缺失的适应能力。这项研究可以指导小型、自适应和弹性微型机器人的开发和设计策略,这些机器人可以适应控制器故障或致动器损坏,在水上和陆地表面行走。
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
4.70
自引率
7.70%
发文量
150
审稿时长
6-12 weeks
期刊介绍: Integrative and Comparative Biology ( ICB ), formerly American Zoologist , is one of the most highly respected and cited journals in the field of biology. The journal''s primary focus is to integrate the varying disciplines in this broad field, while maintaining the highest scientific quality. ICB''s peer-reviewed symposia provide first class syntheses of the top research in a field. ICB also publishes book reviews, reports, and special bulletins.
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