Sequential Cell-Processing System by Integrating Hydrodynamic Purification and Dielectrophoretic Trapping for Analyses of Suspended Cancer Cells

Park, Jong-Ho; Komori, Takayuki; Uda, Toru; Miyajima, Keiichi; Fujii, Teruo; Kim, Soo Hyeon

doi:10.3390/mi11010047

Cited by 4 publications

(7 citation statements)

References 32 publications

(34 reference statements)

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“…Cell are separated by slanted electrodes Possible continuous separation Samples need to be preadjusted to constant conductivity. Separation by size cannot be performed Park et al. (2019) Not required Yes (DEP-DLD) Not required Microwell array No by batch Separation with DEP array after adjusting the conductivity in the chip Not requiring buffer exchange and size separation Continuous separation cannot be performed This study (2021) Not required Yes (DEP-HDF) Not required Slanted (pDEP) Yes Continuous separation with slanted electrodes after adjusting the conductivity in the chip Not requiring buffer exchange and continuous size separation Sample throughput need to be improved.…”

Section: Discussionmentioning

confidence: 99%

“…Because the device is a label-free and one-step operation, cell damage during the operation is minimized. Our device is similar to what Park et al. (2019) introduced, a microfluidic DEP capable of replacing buffer by an integrated DLD (deterministic lateral displacement) module.…”

Section: Introductionmentioning

confidence: 98%

“…The two devices differ in cell sorting systems, “batch” or “continuous” separation ( Hughes, 2016 ). The device by Park et al. (2019) uses the former, where positive DEP traps one cell type while the other is repelled and collected, requiring a second step to recover the trapped cells ( Hughes, 2016 ).…”

Section: Introductionmentioning

confidence: 99%

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Fabrication of a new all-in-one microfluidic dielectrophoresis integrated chip and living cell separation

et al. 2022

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Summary Microfluidic dielectrophoresis (DEP) technology has been applied to many devices to perform label-free target cell separation. Cells separated by these devices are used in laboratories, mainly for medical research. The present study designed a microfluidic DEP device to fabricate a rapid and semiautomated cell separation system in conjunction with microscopy to enumerate the separated cells. With this device, we efficiently segregated bacterial cells from liquid products and enriched one cell type from two mixed eukaryotic cell types. The device eliminated sample pretreatment and established cell separation by all-in-one operation in a lab-on-chip, requiring only a small sample volume (0.5–1 mL) to enumerate the target cells and completing the entire separation process within 30 min. Such a rapid cell separation technique is in high demand by many researchers to promptly characterize the target cells.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 98%

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Fabrication of a new all-in-one microfluidic dielectrophoresis integrated chip and living cell separation

et al. 2022

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“…The separation target is not limited to cells, but can also be applied to purifying nano-scale virus, nanoparticles, DNA, and so on [88]. Park et al utilized dielectrophoresis to manufacture single-cell traps in a microfluidic chip for the analysis of suspended cancer cells [89]. Sun et al pre-created patterned dielectrophoretic force in a microfluidic device to direct cells into a capture zone.…”

Section: Biomedical Sorting and Diagnosticsmentioning

confidence: 99%

The Fabrication and Application Mechanism of Microfluidic Systems for High Throughput Biomedical Screening: A Review

Song

et al. 2020

Micromachines

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Microfluidic systems have been widely explored based on microfluidic technology, and it has been widely used for biomedical screening. The key parts are the fabrication of the base scaffold, the construction of the matrix environment in the 3D system, and the application mechanism. In recent years, a variety of new materials have emerged, meanwhile, some new technologies have been developed. In this review, we highlight the properties of high throughput and the biomedical application of the microfluidic chip and focus on the recent progress of the fabrication and application mechanism. The emergence of various biocompatible materials has provided more available raw materials for microfluidic chips. The material is not confined to polydimethylsiloxane (PDMS) and the extracellular microenvironment is not limited by a natural matrix. The mechanism is also developed in diverse ways, including its special physical structure and external field effects, such as dielectrophoresis, magnetophoresis, and acoustophoresis. Furthermore, the cell/organ-based microfluidic system provides a new platform for drug screening due to imitating the anatomic and physiologic properties in vivo. Although microfluidic technology is currently mostly in the laboratory stage, it has great potential for commercial applications in the future.

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“…Dielectrophoresis (DEP) utilizes the dielectric properties of cells to trap them. Electrodes are placed on one or both sides of a flow channel; cells are passed through the nonuniform electric field, which manipulates the charged cells and separates and traps them at the designated position (s) [ 18 , 19 , 20 ]. DEP also has high-resolution cell manipulation performance; however, specialized knowledge and complex equipment are required for a well-balanced set up, considering the fluid, electrical, and gravitational forces.…”

Section: Introductionmentioning

confidence: 99%

Single-Cell Microarray Chip with Inverse-Tapered Wells to Maintain High Ratio of Cell Trapping

et al. 2023

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A single-cell microarray (SCM) influenced by gravitational force is expected to be one of the simple methods in various fields such as DNA analysis and antibody production. After trapping the cells in the SCM chip, it is necessary to remove the liquid from the SCM to wash away the un-trapped cells on the chip and treat the reagents for analysis. The flow generated during this liquid exchange causes the trapped cells to drop out of conventional vertical wells. In this study, we propose an inverse-tapered well to keep trapped cells from escaping from the SCM. The wells with tapered side walls have a reduced force of flow toward the opening, which prevents trapped cells from escaping. The proposed SCM chip was fabricated using 3D photolithography and polydimethylsiloxane molding techniques. In the trapping experiment using HeLa cells, the cell residual rate increased more than two-fold for the SCM chip with the inverse-tapered well with a taper angle of 30° compared to that for the conventional vertical SCM chip after multiple rounds of liquid exchanges. The proposed well structure increases the number of trapped cells and decreases the cell dropout rate to improve the efficiency of cellular analysis.

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Sequential Cell-Processing System by Integrating Hydrodynamic Purification and Dielectrophoretic Trapping for Analyses of Suspended Cancer Cells

Cited by 4 publications

References 32 publications

Fabrication of a new all-in-one microfluidic dielectrophoresis integrated chip and living cell separation

Fabrication of a new all-in-one microfluidic dielectrophoresis integrated chip and living cell separation

The Fabrication and Application Mechanism of Microfluidic Systems for High Throughput Biomedical Screening: A Review

Single-Cell Microarray Chip with Inverse-Tapered Wells to Maintain High Ratio of Cell Trapping

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