2019
DOI: 10.1038/s41467-019-13576-6
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Active generation and magnetic actuation of microrobotic swarms in bio-fluids

Abstract: In nature, various types of animals will form self-organised large-scale structures. Through designing wireless actuation methods, microrobots can emulate natural swarm behaviours, which have drawn extensive attention due to their great potential in biomedical applications. However, as the prerequisite for their in-vivo applications, whether microrobotic swarms can take effect in bio-fluids with complex components has yet to be fully investigated. In this work, we first categorise magnetic active swarms into t… Show more

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Cited by 263 publications
(247 citation statements)
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“…Governed by the magnetic field, agent–agent effect, fluidic force, and other interactions, a group of micro/nanorobots can be dynamically assembled into snake‐like, vortex‐like, ribbon‐like, and other patterns, and can move as a relatively stable unit. Some swarming robots are reconfigurable to adapt to various situations and have the potential to enhance medical imaging …”
Section: Magnetic End Effectorsmentioning
confidence: 99%
“…Governed by the magnetic field, agent–agent effect, fluidic force, and other interactions, a group of micro/nanorobots can be dynamically assembled into snake‐like, vortex‐like, ribbon‐like, and other patterns, and can move as a relatively stable unit. Some swarming robots are reconfigurable to adapt to various situations and have the potential to enhance medical imaging …”
Section: Magnetic End Effectorsmentioning
confidence: 99%
“…For example, helical magnetic microstructures have been developed with controllable transportation direction induced by a rotating magnetic field (Tottori et al 2012). Also, collective behavior of magnetic microparticles can be exploited to induce swarm-like behavior with control over transportation and navigation in fluids (Yu et al 2019). ing-coupled surface Plasmon resonance (SPR) for detecting β human chorionic gonadotropin (βhCG).…”
Section: Figmentioning
confidence: 99%
“…In another study, Yu et al investigated magnetic MBR swarm formation and swimming behavior in biologically inspired fluids of various ionic strength and viscosity. After their surfaces were functionalized to achieve hydrophobicity, the nanoparticle swarms maintained their swim pattern and trajectories in an ex vivo bovine eye tissue sample [ 38 ]. Other researchers have reported 3D models of tissue-fluids with potential for integration of organ-on-a-chip techniques and microrobotic interactions.…”
Section: Microbiorobots: Motility In Fluid Environments and Penetrmentioning
confidence: 99%