Hyeonseol Kim scite author profile

Hyeonseol Kim

5Publications

30Citation Statements Received

248Citation Statements Given

How they've been cited

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187

248

Affiliations

Daegu Gyeongbuk Institute of Science and Technology

Publications

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Mattertronics for programmable manipulation and multiplex storage of pseudo-diamagnetic holes and label-free cells

Goudu

Kim

et al. 2021

Nat Commun

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Manipulating and separating single label-free cells without biomarker conjugation have attracted significant interest in the field of single-cell research, but digital circuitry control and multiplexed individual storage of single label-free cells remain a challenge. Herein, by analogy with the electrical circuitry elements and electronical holes, we develop a pseudo-diamagnetophoresis (PsD) mattertronic approach in the presence of biocompatible ferrofluids for programmable manipulation and local storage of single PsD holes and label-free cells. The PsD holes conduct along linear negative micro-magnetic patterns. Further, eclipse diode patterns similar to the electrical diode can implement directional and selective switching of different PsD holes and label-free cells based on the diode geometry. Different eclipse heights and junction gaps influence the switching efficiency of PsD holes for mattertronic circuitry manipulation and separation. Moreover, single PsD holes are stored at each potential well as in an electrical storage capacitor, preventing multiple occupancies of PsD holes in the array of individual compartments due to magnetic Coulomb-like interaction. This approach may enable the development of large programmable arrays of label-free matters with high throughput, efficiency, and reliability as multiplex cell research platforms.

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Multifarious Transit Gates for Programmable Delivery of Bio‐functionalized Matters

Torati

Kim

et al. 2019

Small

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Programmable delivery of biological matter is indispensable for the massive arrays of individual objects in biochemical and biomedical applications. Although a digital manipulation of single cells has been implemented by the integrated circuits of micromagnetophoretic patterns with current wires, the complex fabrication process and multiple current operation steps restrict its practical application for biomolecule arrays. Here, a convenient approach using multifarious transit gates is proposed, for digital manipulation of biofunctionalized microrobotic particles that can pass through the local energy barriers by a time‐dependent pulsed magnetic field instead of multiple current wires. The multifarious transit gates including return, delay, and resistance linear gates, as well as dividing, reversed, and rectifying T‐junction gates, are investigated theoretically and experimentally for the programmable manipulation of microrobotic particles. The results demonstrate that, a suitable angle of the gating field at a suitable time zone is crucial to implement digital operations at integrated multifarious transit gates along bifurcation paths to trap microrobotic particles in specific apartments, paving the way for flexible on‐chip arrays of biomolecules and cells.

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Magnetophoretic Micro‐Distributor for Controlled Clustering of Cells

et al. 2021

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Cell clustering techniques are important to produce artificial cell clusters for in vitro models of intercellular mechanisms at the single‐cell level. The analyses considering physical variables such as the shape and size of cells have been very limited. In addition, the precise manipulation of cells and control of the physical variables are still challenging. In this paper, a magnetophoretic device consisting of a trampoline micromagnet and active elements that enable the control of individual selective jumping motion and positioning of a micro‐object is proposed. Based on a numerical simulation under various conditions, automatic separation or selective clustering of micro‐objects according to their sizes is performed by parallel control and programmable manipulation. This method provides efficient control of the physical variables of cells and grouping of cells with the desired size and number, which can be a milestone for a better understanding of the intercellular dynamics between clustered cells at the single‐cell level for future cell‐on‐chip applications.

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Magnetophoretic Decoupler for Disaggregation and Interparticle Distance Control

et al. 2021

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The manipulation of superparamagnetic beads has attracted various lab on a chip and magnetic tweezer platforms for separating, sorting, and labeling cells and bioentities, but the irreversible aggregation of beads owing to magnetic interactions has limited its actual functionality. Here, an efficient solution is developed for the disaggregation of magnetic beads and interparticle distance control with a magnetophoretic decoupler using an external rotating magnetic field. A unique magnetic potential energy distribution in the form of an asymmetric magnetic thin film around the gap is created and tuned in a controlled manner, regulated by the size ratio of the bead with a magnetic pattern. Hence, the aggregated beads are detached into single beads and transported in one direction in an array pattern. Furthermore, the simultaneous and accurate spacing control of multiple magnetic bead pairs is performed by adjusting the angle of the rotating magnetic field, which continuously changes the energy well associated with a specific shape of the magnetic patterns. This technique offers an advanced solution for the disaggregation and controlled manipulation of beads, can allow new possibilities for the enhanced functioning of lab on a chip and magnetic tweezers platforms for biological assays, intercellular interactions, and magnetic biochip systems.

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Magnetophoretic Decoupler: Magnetophoretic Decoupler for Disaggregation and Interparticle Distance Control (Adv. Sci. 12/2021)

Kim¹,

Lim²,

Yoon³

et al. 2021

Advanced Science

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In article number 2100532, Sri Ramulu Torati, CheolGi Kim, and co-workers develop the magnetophoretic decoupler for the disaggregation and inter-particle distance control of magnetic bead cluster for higher efficiency of bio-carrier role. This magnetophoretic decoupler can split the multiple bead pairs in different directions using single driving force, and linearly control the inter-particle distance between them through the angle of the external field.

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Hyeonseol Kim

Mattertronics for programmable manipulation and multiplex storage of pseudo-diamagnetic holes and label-free cells

Multifarious Transit Gates for Programmable Delivery of Bio‐functionalized Matters

Magnetophoretic Micro‐Distributor for Controlled Clustering of Cells

Magnetophoretic Decoupler for Disaggregation and Interparticle Distance Control

Magnetophoretic Decoupler: Magnetophoretic Decoupler for Disaggregation and Interparticle Distance Control (Adv. Sci. 12/2021)

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