具有多模式运动的磁驱动四足软机器人，用于靶向给药。

IF 3.4 3区医学 Q1 ENGINEERING, MULTIDISCIPLINARY Biomimetics Pub Date : 2024-09-16 DOI:10.3390/biomimetics9090559

Huibin Liu, Xiangyu Teng, Zezheng Qiao, Wenguang Yang, Bentao Zou

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引用次数: 0

摘要

无系绳磁性软机器人具有高度灵活性和最小损伤能力，因此在生物医学和小规模微操作应用方面显示出巨大潜力。然而，目前对这些机器人的研究大多集中在海洋和爬行动物的生物仿生上，这限制了它们在非结构化环境中的移动能力。在这项工作中，我们从自然界四足动物的常见运动模式中汲取灵感，并结合我们独特的致动原理，设计了一种带有磁性顶盖和特定磁化角的四足软体机器人。它可以爬行和翻滚，并通过调整磁场参数，使其运动适应环境条件，从而使其能够跨越障碍并执行远程运输和释放货物。

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Magnetically Driven Quadruped Soft Robot with Multimodal Motion for Targeted Drug Delivery.

Untethered magnetic soft robots show great potential for biomedical and small-scale micromanipulation applications due to their high flexibility and ability to cause minimal damage. However, most current research on these robots focuses on marine and reptilian biomimicry, which limits their ability to move in unstructured environments. In this work, we design a quadruped soft robot with a magnetic top cover and a specific magnetization angle, drawing inspiration from the common locomotion patterns of quadrupeds in nature and integrating our unique actuation principle. It can crawl and tumble and, by adjusting the magnetic field parameters, it adapts its locomotion to environmental conditions, enabling it to cross obstacles and perform remote transportation and release of cargo.

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