Magnetic Lateral Ladder for Unidirectional Transport of Microrobots: Design Principles and Potential Applications of Cells‐on‐Chip

Ali, Abbas; Kim, Hyeonseol; Torati, Sri Ramulu; Kang, Yumin; Reddy, Venu; Kim, Keonmok; Yoon, Jonghwan; Lim, Byeonghwa; Kim, CheolGi

doi:10.1002/smll.202305528

Cited by 2 publications

(1 citation statement)

References 88 publications

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“…Based on the geometry designs of micromagnet ladders or negative patterns and in combination with three-dimensional structures as well, the microrobotic carriers can be controlled simultaneously in a specific direction. [24][25][26][27] Furthermore, the introduction of circuit concepts allows for programmable active transport of the microrobotic carriers under a magnetic in-plane field with a combination of current lines or a pulsed out-of-plane field, which can produce instantaneous potential energy for the microrobotic carriers to cross the energy barrier over the micromagnet. A nonmagnetic gap could also cause an energy barrier to hinder particle transportation.…”

Section: Introductionmentioning

confidence: 99%

Magnetically Selective Versatile Transport of Microrobotic Carriers

Hu,

Kim,

Ali

et al. 2024

Small Methods

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Field‐driven transport systems offer great promise for use as biofunctionalized carriers in microrobotics, biomedicine, and cell delivery applications. Despite the construction of artificial microtubules using several micromagnets, which provide a promising transport pathway for the synchronous delivery of microrobotic carriers to the targeted location inside microvascular networks, the selective transport of different microrobotic carriers remains an unexplored challenge. This study demonstrated the selective manipulation and transport of microrobotics along a patterned micromagnet using applied magnetic fields. Owing to varied field strengths, the magnetic beads used as the microrobotic carriers with different sizes revealed varied locomotion, including all of them moving along the same direction, selective rotation, bidirectional locomotion, and all of them moving in a reversed direction. Furthermore, cells immobilized with magnetic beads and nanoparticles also revealed varied locomotion. It is expected that such steering strategies of microrobotic carriers can be used in microvascular channels for the targeted delivery of drugs or cells in an organized manner.

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Section: Introductionmentioning

confidence: 99%

Magnetically Selective Versatile Transport of Microrobotic Carriers

Hu,

Kim,

Ali

et al. 2024

Small Methods

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Tailored Micromagnet Sorting Gate for Simultaneous Multiple Cell Screening in Portable Magnetophoretic Cell‐On‐Chip Platforms

Yoon,

Kang,

Kim

et al. 2024

Adv Funct Materials

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Conventional magnetophoresis techniques for manipulating biocarriers and cells predominantly rely on large‐scale electromagnetic systems, which is a major obstacle to the development of portable and miniaturized cell‐on‐chip platforms. Herein, a novel magnetic engineering approach by tailoring a nanoscale notch on a disk micromagnet using two‐step optical and thermal lithography is developed. Versatile manipulations are demonstrated, such as separation and trapping, of carriers and cells by mediating changes in the magnetic domain structure and discontinuous movement of magnetic energy wells around the circumferential edge of the micromagnet caused by a locally fabricated nano‐notch in a low magnetic field system. The motion of the magnetic energy well is regulated by the configuration of the nanoscale notch and the strength and frequency of the magnetic field, accompanying the jump motion of the carriers. The proposed concepts demonstrate that multiple carriers and cells can be manipulated and sorted using optimized nanoscale multi‐notch gates for a portable magnetophoretic system. This highlights the potential for developing cost‐effective point‐of‐care testing and lab‐on‐chip systems for various single‐cell‐level diagnoses and analyses.

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Magnetic Lateral Ladder for Unidirectional Transport of Microrobots: Design Principles and Potential Applications of Cells‐on‐Chip

Cited by 2 publications

References 88 publications

Magnetically Selective Versatile Transport of Microrobotic Carriers

Magnetically Selective Versatile Transport of Microrobotic Carriers

Tailored Micromagnet Sorting Gate for Simultaneous Multiple Cell Screening in Portable Magnetophoretic Cell‐On‐Chip Platforms

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