Tiny Amphibious Insects Use Tripod Gait for Traversal on Land, Water, and Duckweed.

IF 2.2 3区 生物学 Q1 ZOOLOGY Integrative and Comparative Biology Pub Date : 2024-09-27 DOI:10.1093/icb/icae078
Johnathan N O'Neil, Kai Lauren Yung, Gaetano Difini, Holden Walker, Saad Bhamla
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Abstract

Insects exhibit remarkable adaptability in their locomotive strategies in diverse environments, a crucial trait for foraging, survival, and predator avoidance. Microvelia americana, tiny 2-3 mm insects that adeptly walk on water surfaces, exemplify this adaptability by using the alternating tripod gait in both aquatic and terrestrial terrains. These insects commonly inhabit low-flow ponds and streams cluttered with natural debris like leaves, twigs, and duckweed. Using high-speed imaging and pose-estimation software, we analyze M. americana movement on water, sandpaper (simulating land), and varying duckweed densities (10%, 25%, and 50% coverage). Our results reveal M. americana maintain consistent joint angles and strides of their upper and hind legs across all duckweed coverages, mirroring those seen on sandpaper. Microvelia americana adjust the stride length of their middle legs based on the amount of duckweed present, decreasing with increased duckweed coverage and at 50% duckweed coverage, their middle legs' strides closely mimic their strides on sandpaper. Notably, M. americana achieve speeds up to 56 body lengths per second on the deformable surface of water, nearly double those observed on sandpaper and duckweed, which are rough, heterogeneous surfaces. This study highlights M. americana's ecological adaptability, setting the stage for advancements in amphibious robotics that emulate their unique tripod gait for navigating complex terrains.

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微小的两栖昆虫利用三脚架步态在陆地、水面和浮萍上穿行。
昆虫在不同环境中的运动策略表现出惊人的适应性,这是昆虫觅食、生存和躲避捕食者的重要特征。美国微小昆虫(Microvelia americana)是一种 2-3 毫米的小昆虫,善于在水面上行走,在水生和陆生地形中均采用交替三脚架步态,是这种适应性的典范。这些昆虫通常栖息在水流较小的池塘和溪流中,池塘和溪流中布满了树叶、树枝和浮萍等自然碎屑。利用高速成像和姿态估计软件,我们分析了美洲蓟马在水面、砂纸(模拟陆地)和不同浮萍密度(10%、25% 和 50%)上的运动情况。我们的研究结果表明,在所有浮萍覆盖率下,美洲金蛙的上肢和后肢的关节角度和步幅都保持一致,这与在沙纸上看到的情况一致。美洲斑鸠会根据浮萍的数量调整中腿的步长,随着浮萍覆盖率的增加而减少,当浮萍覆盖率为 50%时,中腿的步长与它们在砂纸上的步长非常接近。值得注意的是,美洲蝠在可变形的水面上的速度高达每秒 56 个体长,几乎是在砂纸和浮萍这些粗糙的异质表面上观察到的速度的两倍。这项研究凸显了美洲蛙的生态适应能力,为两栖机器人技术的发展奠定了基础,这种机器人可以模仿美洲蛙独特的三脚架步态在复杂地形上航行。
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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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