Twisted fiber microfluidics: a cutting-edge approach to 3D spiral devices
Twisted fiber microfluidics: a cutting-edge approach to 3D spiral devices
The development of 3D spiral microfluidics has opened new avenues for leveraging inertial focusing to analyze small fluid volumes, thereby advancing research across chemical, physical, and biological disciplines. While traditional straight microchannels rely solely on inertial lift forces, the novel spiral geometry generates Dean drag forces, eliminating the necessity for external fields in fluid manipulation. Nevertheless, fabricating 3D spiral microfluidics remains a labor-intensive and costly endeavor, hindering its widespread adoption. Moreover, conventional lithographic methods primarily yield 2D planar devices, thereby limiting the selection of materials and geometrical configurations. To address these challenges, this work introduces a streamlined fabrication method for 3D spiral microfluidic devices, employing rotational force within a miniaturized thermal drawing process, termed as mini-rTDP. This innovation allows for rapid prototyping of twisted fiber-based microfluidics featuring versatility in material selection and heightened geometric intricacy. To validate the performance of these devices, we combined computational modeling with microtomographic particle image velocimetry (μTPIV) to comprehensively characterize the 3D flow dynamics. Our results corroborate the presence of a steady secondary flow, underscoring the effectiveness of our approach. Our 3D spiral microfluidics platform paves the way for exploring intricate microflow dynamics, with promising applications in areas such as drug delivery, diagnostics, and lab-on-a-chip systems.
Shunsuke, Kato
0400993c-d693-474d-a123-2186239feaee
Carlson, Daniel
c0f88797-732c-46ef-8e74-a5186d4733bf
Yuanyuan, Guo
61835fd4-85f0-496c-9201-4b30bfa9fa93
Shen, Amy Q.
f04513a5-fedd-4759-958a-674855da2600
22 January 2024
Shunsuke, Kato
0400993c-d693-474d-a123-2186239feaee
Carlson, Daniel
c0f88797-732c-46ef-8e74-a5186d4733bf
Yuanyuan, Guo
61835fd4-85f0-496c-9201-4b30bfa9fa93
Shen, Amy Q.
f04513a5-fedd-4759-958a-674855da2600
Shunsuke, Kato, Carlson, Daniel, Yuanyuan, Guo and Shen, Amy Q.
(2024)
Twisted fiber microfluidics: a cutting-edge approach to 3D spiral devices.
Microsystems & Nanoengineering, 10.
(doi:10.1038/s41378-023-00642-9).
Abstract
The development of 3D spiral microfluidics has opened new avenues for leveraging inertial focusing to analyze small fluid volumes, thereby advancing research across chemical, physical, and biological disciplines. While traditional straight microchannels rely solely on inertial lift forces, the novel spiral geometry generates Dean drag forces, eliminating the necessity for external fields in fluid manipulation. Nevertheless, fabricating 3D spiral microfluidics remains a labor-intensive and costly endeavor, hindering its widespread adoption. Moreover, conventional lithographic methods primarily yield 2D planar devices, thereby limiting the selection of materials and geometrical configurations. To address these challenges, this work introduces a streamlined fabrication method for 3D spiral microfluidic devices, employing rotational force within a miniaturized thermal drawing process, termed as mini-rTDP. This innovation allows for rapid prototyping of twisted fiber-based microfluidics featuring versatility in material selection and heightened geometric intricacy. To validate the performance of these devices, we combined computational modeling with microtomographic particle image velocimetry (μTPIV) to comprehensively characterize the 3D flow dynamics. Our results corroborate the presence of a steady secondary flow, underscoring the effectiveness of our approach. Our 3D spiral microfluidics platform paves the way for exploring intricate microflow dynamics, with promising applications in areas such as drug delivery, diagnostics, and lab-on-a-chip systems.
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More information
Accepted/In Press date: 14 November 2023
Published date: 22 January 2024
Identifiers
Local EPrints ID: 507354
URI: http://eprints.soton.ac.uk/id/eprint/507354
ISSN: 2055-7434
PURE UUID: 29314441-82d0-43bd-b08d-051ad9352c4a
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Date deposited: 04 Dec 2025 18:01
Last modified: 05 Dec 2025 03:03
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Contributors
Author:
Kato Shunsuke
Author:
Daniel Carlson
Author:
Guo Yuanyuan
Author:
Amy Q. Shen
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