Infiltration of Cell-Inspired Ultra-Deformable Magnetic Microrobots in Restrictive Environments

IF 3.8 Q2 ENGINEERING, BIOMEDICAL IEEE transactions on medical robotics and bionics Pub Date : 2024-11-26 DOI:10.1109/TMRB.2024.3503898

Eugenia De Remigis;Fehmi M. Dikbaş;Michele Ibrahimi;Francesco Bianciardi;Elisa L. Petrocelli;Elisa Roberti;Veronica Iacovacci;Stefano Palagi

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Abstract

Microscale robotics represents a promising future for minimally invasive medicine. However, one of the biggest challenges of microrobots moving through the human body is represented by the complex 3D structure of biological lumina and tissues, which obstructs the navigation of micron-sized devices. Here, we fabricate ultra-deformable magnetic microrobots, consisting of ferrofluid-loaded lipid vesicles, and we magnetically pull them through chambers that exert upon them a gradually more forceful confinement. We thus analyze their capability to face interstices comparable to or smaller than their characteristic size and their consequent behavior in terms of stability, velocity, and deformation. The results show that the inherent compliance of these vesicle-based magnetic microrobots allows them to infiltrate successfully in interstices slightly smaller than their size. Further enhancement of their compliance and the development of specific control strategies may lead to microrobots able to move through interstices and traverse complex biological environments.

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细胞启发的超变形磁性微型机器人在限制性环境中的渗透

微型机器人代表了微创医学的一个有希望的未来。然而，微型机器人在人体中移动的最大挑战之一是生物腔和组织的复杂3D结构，这阻碍了微米级设备的导航。在这里，我们制造了超可变形的磁性微型机器人，由装载铁磁流体的脂质囊泡组成，我们用磁力把它们拉过一个逐渐对它们施加更强限制的腔室。因此，我们分析了它们面对与其特征尺寸相当或小于其特征尺寸的间隙的能力，以及它们在稳定性、速度和变形方面的后续行为。结果表明，这些基于囊泡的磁性微机器人的固有顺应性使它们能够成功地渗透到比其尺寸略小的间隙中。进一步提高它们的顺应性和特定控制策略的发展可能会导致微型机器人能够通过间隙和穿越复杂的生物环境。

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