Resilience of hierarchical actuators highlighted by a myosin-to-muscle mock-up.

IF 3.1 3区计算机科学 Q1 ENGINEERING, MULTIDISCIPLINARY

Bioinspiration & Biomimetics Pub Date : 2025-02-10 DOI:10.1088/1748-3190/adadd5

Raphaël Perrier, Jean-Marc Linares, Loïc Tadrist

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Abstract

Skeletal muscle is the main actuator of various families of vertebrates (mammals, fish, reptiles). It displays remarkable robustness to micro-damage, that supposedly originates both from its redundant hierarchical structure and its nervous command. A bioinspired mock-up was designed and manufactured mimicking sarcomeres (micro-scale) and its series and parallel structure from fibre to muscle. First, the mechanical performances namely the force-velocity curve of the intact muscle mock-up were measured and modelled. Then, mimicking micro-damage by making some myosin heads inoperative, the mechanical performances were again measured to determine the resilience of the actuator. The mock-up is shown to be resilient: in the event of 10% damage of the mock-up, the mechanical performance of the mock-up was around 80% of the intact one. In this multi degrees of freedom actuator with hierarchical structure, the resilience is shown to be almost linear with the damage level for uniformly distributed damage (both maximal force and velocity decrease). Differently when micro-damage are clustered on a fibre, this decreases the maximal force with little effect on velocity.

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由肌球蛋白到肌肉模型强调的分层致动器的弹性。

骨骼肌是各种脊椎动物（哺乳动物、鱼类、爬行动物）的主要致动器。它对微损伤表现出惊人的稳健性，这可能源于其冗余的等级结构和神经控制。设计和制造了一个仿生模型，模拟了肌节（微尺度）及其从纤维到肌肉的串联和平行结构。首先，对完整肌肉模型的力学性能即力-速度曲线进行了测量和建模。然后，通过使一些肌凝蛋白头部失效来模拟微损伤，再次测量机械性能以确定致动器的弹性。模型显示出弹性：在模型损坏10%的情况下，模型的机械性能约为完整模型的80%。在分层结构的多自由度作动器中，对于均匀分布的损伤（最大力和速度均降低），其回弹性与损伤程度几乎呈线性关系。不同的是，当微损伤聚集在纤维上时，这降低了最大力，对速度几乎没有影响。

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

Bioinspiration & Biomimetics 工程技术-材料科学：生物材料

CiteScore

5.90

自引率

14.70%

发文量

132

审稿时长

3 months

期刊介绍： Bioinspiration & Biomimetics publishes research involving the study and distillation of principles and functions found in biological systems that have been developed through evolution, and application of this knowledge to produce novel and exciting basic technologies and new approaches to solving scientific problems. It provides a forum for interdisciplinary research which acts as a pipeline, facilitating the two-way flow of ideas and understanding between the extensive bodies of knowledge of the different disciplines. It has two principal aims: to draw on biology to enrich engineering and to draw from engineering to enrich biology. The journal aims to include input from across all intersecting areas of both fields. In biology, this would include work in all fields from physiology to ecology, with either zoological or botanical focus. In engineering, this would include both design and practical application of biomimetic or bioinspired devices and systems. Typical areas of interest include: Systems, designs and structure Communication and navigation Cooperative behaviour Self-organizing biological systems Self-healing and self-assembly Aerial locomotion and aerospace applications of biomimetics Biomorphic surface and subsurface systems Marine dynamics: swimming and underwater dynamics Applications of novel materials Biomechanics; including movement, locomotion, fluidics Cellular behaviour Sensors and senses Biomimetic or bioinformed approaches to geological exploration.