Propulsion of Magnetic Beads Asymmetrically Covered with DNA Origami Appendages

Advanced Materials & Technologies Pub Date : 2022-07-24 DOI:10.1002/admt.202200450

Christoph Pauer, Aron Venczel, Mihir Dass, T. Liedl, J. Tavacoli

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引用次数: 2

Abstract

Eukaryotic cells that swim by the beating of nanoscale elastic filaments (flagella) present a promising locomotion paradigm for man‐made analogues essential for next‐generation in‐vivo treatments and for the study of collective phenomena at the low Reynolds number limit. However, artificial analogues have been limited to many microns in size due to the engineering challenges of fabricating actable flexible filaments at the nanoscale—thereby narrowing the application scope. Here, made‐to‐order nanoscale filaments designed on the molecular level are fabricated using the DNA‐origami technique. It is found that magnetic beads anisotropically covered with such bundles move in a ballistic fashion when wagged back and forth under an external magnetic field. Furthermore, by comparing bead dynamics at a range of bundle coverages and driving frequencies, compelling evidence is amassed to suggest that this ballistic motion is imparted by the beating of the DNA origami filaments as synthetic flagella. This proof‐of‐concept work opens up avenues for further made‐for‐purpose appendages designed using DNA self‐assembly and with it ever more complex locomotion on the nano and microscale.

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磁珠不对称覆盖DNA折纸附属物的推进

真核细胞通过纳米级弹性细丝(鞭毛)的跳动游动，为下一代体内治疗和低雷诺数极限下集体现象的研究所必需的人造类似物提供了一种有前途的运动范式。然而，由于在纳米尺度上制造可操作的柔性细丝的工程挑战，人工类似物的尺寸被限制在许多微米，从而缩小了应用范围。在这里，使用DNA折纸技术在分子水平上设计了按顺序制造的纳米级细丝。研究发现，在外加磁场作用下，被磁束覆盖的磁珠各向异性以弹道方式运动。此外，通过比较在束覆盖和驱动频率范围内的头部动力学，积累了令人信服的证据，表明这种弹道运动是由作为合成鞭毛的DNA折纸丝的跳动传递的。这一概念验证工作为进一步使用DNA自组装设计的专用附件以及在纳米和微观尺度上更复杂的运动开辟了道路。

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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Advanced Materials & Technologies

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