Size Sorting of Exosomes by Tuning the Thicknesses of the Electric Double Layers on a Micro-Nanofluidic Device

Fujiwara, Satoko; Morikawa, Kyojiro; Endo, Tatsuro; Hisamoto, Hideaki; Sueyoshi, Kenji

doi:10.3390/mi11050458

Cited by 14 publications

(14 citation statements)

References 44 publications

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“…developed a method to sort exosomes in the nanochannels by controlling the thickness of the electric double layers. [ 91 ] Under optimized conditions, different cutoffs of the exosomes are separated. In addition, a nanopipette tip based on DEP was used to trap exosomes with high yield.…”

Section: Microfluidics‐based Isolation Strategiesmentioning

confidence: 99%

Microfluidic‐Based Exosome Analysis for Liquid Biopsy

et al. 2021

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Liquid biopsy offers non‐invasive and real‐time molecular profiling of individual patients, and is thus considered a revolutionary technology in precision medicine. Exosomes have been acknowledged as significant biomarkers in liquid biopsy, as they play a central role in cell–cell communication and are closely related to the pathogenesis of most human malignancies. Nevertheless, in biofluids exosomes always co‐exist with other particles, and the cargo components of exosomes are highly heterogeneous. Thus, the isolation and molecular characterization of exosomes are still technically challenging. Microfluidics technology effectively addresses this challenge by virtue of its inherent advantages, such as precise manipulation of fluids, low consumption of samples and reagents, and a high level of integration. Recent advances in microfluidics allow in situ exosome capture and molecular detection with unprecedented selectivity and sensitivity. In this review, the state‐of‐the‐art developments in microfluidics‐based exosome research, including exosome isolation approaches and molecular detection strategies, with highlights of the characterization of exosomal biomarkers in cancer liquid biopsy is summarized. The major challenges are also discussed and some perspectives for the future directions of exosome‐based liquid biopsy in microfluidic systems are presented.

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Section: Microfluidics‐based Isolation Strategiesmentioning

confidence: 99%

Microfluidic‐Based Exosome Analysis for Liquid Biopsy

et al. 2021

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“…The length of the nanochannel is set as L ¼ 11σ 1 and width W ranges from 5σ 1 to 7σ 1 . The choice of this dimension in our calculation is comparative with that in the practical case 55 where the nanochannel can be reasonably modeled as a slit channel 51 as the width of the nanochannel is four times larger than the depth. Effects of channel length on permeability are not considered here, because this effect has been studied by other researchers.…”

Section: Computational Detailsmentioning

confidence: 99%

Permeability and selectivity analysis for affinity‐based nanoparticle separation through nanochannels

Wang

Long

et al. 2022

AIChE Journal

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Whereas the separation by surface affinity represents an advanced technique for the separation of nanoparticles with distinct surface properties, how the interaction of particles with nanochannel impacts the separation performance is less understood. Herein, the dynamical density functional theory is employed to study the separation of two types of similar-sized particles with different surface affinities within nanochannels.We show that a proper design of the channel inner-surface, which attracts one type of particles while repelling the other, can promote the permeability and selectivity of particles. Meanwhile, the trade-off relations between permeability and selectivity are found and analyzed in nanochannels of different sizes. Based on dynamical density functional theory calculations, an extended model relating permeability to the equilibrium partition coefficient is proposed to analyze the permeability and selectivity, which displays good predictions of the transport of charged particles in comparison with experimental results. This work provides helpful insights for designing an efficient affinity-based separation of nanoparticles process through nanochannels.

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“…129 electric double layers of fused silica surfaces of nanochannels to sort exosomes derived from the HEK293 human embryonic kidney cell line. 130 In this study, size-selective separation of exosomes was performed by nanogates, which had a height restriction determined by the depth of the nanochannels as well as thickness of the electric double layers controlled by electrolyte concentration of a running buffer. Quantitation of subcellular vesicles is also possible with nanostructures.…”

Section: ■ Applications For Biological Particlesmentioning

confidence: 99%

“…This nanofluidic device sorted electroosmotic flow (EOF)-driven vesicles by nanopillars that induced displacement of vesicles in the direction perpendicular to the EOF based on vesicle size. Another example used electric double layers of fused silica surfaces of nanochannels to sort exosomes derived from the HEK293 human embryonic kidney cell line . In this study, size-selective separation of exosomes was performed by nanogates, which had a height restriction determined by the depth of the nanochannels as well as thickness of the electric double layers controlled by electrolyte concentration of a running buffer.…”

Section: Applications For Biological Particlesmentioning

confidence: 99%