Focusing of sub-micrometer particles in microfluidic devices
Focusing of sub-micrometer particles in microfluidic devices
Sub-micrometer particles (0.10-1.0 μm) are of great significance to study, e.g., microvesicles and protein aggregates are targets for therapeutic intervention, and sub-micrometer fluorescent polystyrene (PS) particles are used as probes for diagnostic imaging. Focusing of sub-micrometer particles-precisely control over the position of sub-micrometer particles in a tightly focused stream-has a wide range of applications in the field of biology, chemistry and environment, by acting as a prerequisite step for downstream detection, manipulation and quantification. Microfluidic devices have been attracting great attention as desirable tools for sub-micrometer particle focusing, due to their small size, low reagent consumption, fast analysis and low cost. Recent advancements in fundamental knowledge and fabrication technologies have enabled microfluidic focusing of particles at sub-micrometer scale in a continuous, label-free and high-throughput manner. Microfluidic methods for the focusing of sub-micrometer particles can be classified into two main groups depending on whether an external field is applied: 1) passive methods, which utilize intrinsic fluidic properties without the need of external actuation, such as inertial, deterministic lateral displacement (DLD), viscoelastic and hydrophoretic focusing; and 2) active methods, where external fields are used, such as dielectrophoretic, thermophoretic, acoustophoretic and optical focusing. This article mainly reviews the studies on the focusing of sub-micrometer particles in microfluidic devices over the past 10 years. It aims to bridge the gap between the focusing of micrometer and nanometer scale (1.0-100 nm) particles and to improve the understanding of development progress, current advances and future prospects in microfluidic focusing techniques.
35-53
Zhang, Tianlong
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Hong, Zhen Yi
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Tang, Shi Yang
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Li, Weihua
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Inglis, David W.
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Hosokawa, Yoichiroh
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Yalikun, Yaxiaer
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Li, Ming
734c0e4b-d284-491f-9cdc-ac394181bdf9
7 January 2020
Zhang, Tianlong
9fcc7c27-5e97-400a-990d-93a6dfb89ea3
Hong, Zhen Yi
f2e57b48-ad0a-4b55-a146-9316a8d64eae
Tang, Shi Yang
1d0f15c6-2a3e-4bad-a3d8-fc267db93ed4
Li, Weihua
e2555036-0e48-425a-afeb-db6ffba5238e
Inglis, David W.
980dc731-9677-416f-aa5d-b84ba8aca952
Hosokawa, Yoichiroh
95f6de03-53dd-4e04-b4fc-3e85ecf46e9f
Yalikun, Yaxiaer
8b1b3e72-0b0c-40d9-b307-1bcdb87a4d38
Li, Ming
734c0e4b-d284-491f-9cdc-ac394181bdf9
Zhang, Tianlong, Hong, Zhen Yi, Tang, Shi Yang, Li, Weihua, Inglis, David W., Hosokawa, Yoichiroh, Yalikun, Yaxiaer and Li, Ming
(2020)
Focusing of sub-micrometer particles in microfluidic devices.
Lab on a Chip, 20 (1), .
(doi:10.1039/c9lc00785g).
Abstract
Sub-micrometer particles (0.10-1.0 μm) are of great significance to study, e.g., microvesicles and protein aggregates are targets for therapeutic intervention, and sub-micrometer fluorescent polystyrene (PS) particles are used as probes for diagnostic imaging. Focusing of sub-micrometer particles-precisely control over the position of sub-micrometer particles in a tightly focused stream-has a wide range of applications in the field of biology, chemistry and environment, by acting as a prerequisite step for downstream detection, manipulation and quantification. Microfluidic devices have been attracting great attention as desirable tools for sub-micrometer particle focusing, due to their small size, low reagent consumption, fast analysis and low cost. Recent advancements in fundamental knowledge and fabrication technologies have enabled microfluidic focusing of particles at sub-micrometer scale in a continuous, label-free and high-throughput manner. Microfluidic methods for the focusing of sub-micrometer particles can be classified into two main groups depending on whether an external field is applied: 1) passive methods, which utilize intrinsic fluidic properties without the need of external actuation, such as inertial, deterministic lateral displacement (DLD), viscoelastic and hydrophoretic focusing; and 2) active methods, where external fields are used, such as dielectrophoretic, thermophoretic, acoustophoretic and optical focusing. This article mainly reviews the studies on the focusing of sub-micrometer particles in microfluidic devices over the past 10 years. It aims to bridge the gap between the focusing of micrometer and nanometer scale (1.0-100 nm) particles and to improve the understanding of development progress, current advances and future prospects in microfluidic focusing techniques.
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Accepted/In Press date: 6 November 2019
Published date: 7 January 2020
Additional Information:
Funding Information:
This work is supported by Amada Foundation and NSG Foundation of Japan and MQ-NAIST Cotutelle Program. We also acknowledge the support of JSPS Core-to-Core program and Macquarie University New Staff Grant.
Identifiers
Local EPrints ID: 481674
URI: http://eprints.soton.ac.uk/id/eprint/481674
ISSN: 1473-0197
PURE UUID: c66662a7-bb4c-4b4c-ade7-2bb0631298ce
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Date deposited: 06 Sep 2023 16:30
Last modified: 06 Jun 2024 02:18
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Contributors
Author:
Tianlong Zhang
Author:
Zhen Yi Hong
Author:
Shi Yang Tang
Author:
Weihua Li
Author:
David W. Inglis
Author:
Yoichiroh Hosokawa
Author:
Yaxiaer Yalikun
Author:
Ming Li
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