Active generation and magnetic actuation of microrobotic swarms in bio-fluids

Yu, Jiangfan; Jin, Dongdong; Chan, Kai Fung; Wang, Qianqian; Yuan, Kangze; Zhang, Li

doi:10.1038/s41467-019-13576-6

Cited by 227 publications

(228 citation statements)

References 43 publications

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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%

Magnetic Actuation Systems for Miniature Robots: A Review

Yang

Zhang

2020

Advanced Intelligent Systems

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194

109

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A magnetic field, which is transparent and relatively safe to biological tissue, is a powerful tool for remote actuation and wireless control of magnetic devices. Furthermore, miniature robots can access complex and narrow regions of the human body as well as manipulate down to subcellular entities; however, integrating onboard components is difficult due to their limited size. Combining these two technologies, magnetic miniature robots have undergone rapid development during the past two decades, mainly because of their high potential in medical and bioengineering applications. To improve the scientific and clinical outcomes of these tiny agents, developing suitable and reliable actuation systems is essential. As a newly emerging field that has progressed in recent years, magnetic actuation systems offer a harmless and effective approach for the remote control of miniature robots via a dynamic magnetic field. Herein, a review on the state‐of‐the‐art magnetic actuation systems for miniature robots is presented with the goal of providing readers with a better understanding of magnetic actuation and guidance for future system design.

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Section: Magnetic End Effectorsmentioning

confidence: 99%

Magnetic Actuation Systems for Miniature Robots: A Review

Yang

Zhang

2020

Advanced Intelligent Systems

Self Cite

194

109

View full text Add to dashboard Cite

show abstract

“…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%

A concise review of microfluidic particle manipulation methods

Zhang

Wang

Onck

et al. 2020

Microfluid Nanofluid

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Particle manipulation is often required in many applications such as bioanalysis, disease diagnostics, drug delivery and selfcleaning surfaces. The fast progress in micro-and nano-engineering has contributed to the rapid development of a variety of technologies to manipulate particles including more established methods based on microfluidics, as well as recently proposed innovative methods that still are in the initial phases of development, based on self-driven microbots and artificial cilia. Here, we review these techniques with respect to their operation principles and main applications. We summarize the shortcomings and give perspectives on the future development of particle manipulation techniques. Rather than offering an in-depth, detailed, and complete account of all the methods, this review aims to provide a broad but concise overview that helps to understand the overall progress and current status of the diverse particle manipulation methods. The two novel developments, self-driven microbots and artificial cilia-based manipulation, are highlighted in more detail.

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“…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%

The Future Application of Organ-on-a-Chip Technologies as Proving Grounds for MicroBioRobots

et al. 2020

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An evolving understanding of disease pathogenesis has compelled the development of new drug delivery approaches. Recently, bioinspired microrobots have gained traction as drug delivery systems. By leveraging the microscale phenomena found in physiological systems, these microrobots can be designed with greater maneuverability, which enables more precise, controlled drug release. Their function could be further improved by testing their efficacy in physiologically relevant model systems as part of their development. In parallel with the emergence of microscale robots, organ-on-a-chip technologies have become important in drug discovery and physiological modeling. These systems reproduce organ-level functions in microfluidic devices, and can also incorporate specific biological, chemical, and physical aspects of a disease. This review highlights recent developments in both microrobotics and organ-on-a-chip technologies and envisions their combined use for developing future drug delivery systems.

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Active generation and magnetic actuation of microrobotic swarms in bio-fluids

Cited by 227 publications

References 43 publications

Magnetic Actuation Systems for Miniature Robots: A Review

Magnetic Actuation Systems for Miniature Robots: A Review

A concise review of microfluidic particle manipulation methods

The Future Application of Organ-on-a-Chip Technologies as Proving Grounds for MicroBioRobots

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