A self‐locking mechanism of the frog‐legged beetle Sagra femorata

Author:

Zong Le123ORCID,Sun Zonghui12,Zhao Jieliang4,Huang Zhengzhong1,Liu Xiaokun12,Jiang Lei12,Li Congqiao1,Muinde Jacob Mulwa12,Wu Jianing5,Wang Xiaolong1,Liang Hongbin1,Liu Haoyu3,Yang Yuxia3ORCID,Ge Siqin12ORCID

Affiliation:

1. Key Laboratory of Zoological Systematics and Evolution Institute of Zoology Chinese Academy of Sciences Beijing China

2. University of Chinese Academy of Sciences Beijing China

3. The Key Laboratory of Zoological Systematics and Application School of Life Science Institute of Life Science and Green Development Hebei University Baoding Hebei Province China

4. Department of Mechanical Engineering Beijing Institute of Technology Beijing China

5. School of Aeronautics and Astronautics Sun Yat‐sen University Shenzhen Guangdong Province China

Abstract

AbstractInsect legs play a crucial role in various modes of locomotion, including walking, jumping, swimming, and other forms of movement. The flexibility of their leg joints is critical in enabling various modes of locomotion. The frog‐legged leaf beetle Sagra femorata possesses remarkably enlarged hind legs, which are considered to be a critical adaptation that enables the species to withstand external pressures. When confronted with external threats, S. femorata initiates a stress response by rapidly rotating its hind legs backward and upward to a specific angle, thereby potentially intimidating potential assailants. Based on video analysis, we identified 4 distinct phases of the hind leg rotation process in S. femorata, which were determined by the range of rotation angles (0°−168.77°). Utilizing micro‐computed tomography (micro‐CT) technology, we performed a 3‐dimensional (3D) reconstruction and conducted relative positioning and volumetric analysis of the metacoxa and metatrochanter of S. femorata. Our analysis revealed that the metacoxa–trochanter joint is a “screw‐nut” structure connected by 4 muscles, which regulate the rotation of the legs. Further testing using a 3D‐printed model of the metacoxa–trochanter joint demonstrated its possession of a self‐locking mechanism capable of securing the legs in specific positions to prevent excessive rotation and dislocation. It can be envisioned that this self‐locking mechanism holds potential for application in bio‐inspired robotics.

Funder

National Natural Science Foundation of China

Publisher

Wiley

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