Modular off-chip emulsion generator enabled by a revolving needle
Modular off-chip emulsion generator enabled by a revolving needle
Microfluidic chips have demonstrated unparalleled abilities in droplet generation, including precise control over droplet size and monodispersity. And yet, their rather complicated microfabrication process and operation can be a barrier for inexperienced researchers, which hinders microdroplets from unleashing their potential in broader fields of research. Here, we attempt to remove this barrier by developing an integrated and modular revolving needle emulsion generator (RNEG) to achieve high-throughput production of uniformly sized droplets in an off-chip manner. The RNEG works by driving a revolving needle to pinch the dispersed phase in a minicentrifuge tube. The system is constructed using modular components without involving any microfabrication, thereby enabling user-friendly operation. The RNEG is capable of producing microdroplets of various liquids with diameters ranging from tens to hundreds of micrometres. We further examine the principle of operation using numerical simulations and establish a simple model to predict the droplet size. Moreover, by integrating curing and centrifugation processes, the RNEG can produce hydrogel microparticles and transfer them from an oil phase into a water phase. Using this ability, we demonstrate the encapsulation and culture of single yeast cells within hydrogel microparticles. We envisage that the RNEG can become a versatile and powerful tool for high-throughput production of emulsions to facilitate diverse biological and chemical research.
4592-4599
Zhang, Yuxin
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Zhao, Qianbin
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Yuan, Dan
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Liu, Hangrui
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Yun, Guolin
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Lu, Hongda
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Li, Ming
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Guo, Jinhong
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Li, Weihua
e2555036-0e48-425a-afeb-db6ffba5238e
Tang, Shi Yang
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Zhang, Yuxin
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Zhao, Qianbin
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Yuan, Dan
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Liu, Hangrui
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Yun, Guolin
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Lu, Hongda
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Li, Ming
734c0e4b-d284-491f-9cdc-ac394181bdf9
Guo, Jinhong
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Li, Weihua
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Tang, Shi Yang
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Zhang, Yuxin, Zhao, Qianbin, Yuan, Dan, Liu, Hangrui, Yun, Guolin, Lu, Hongda, Li, Ming, Guo, Jinhong, Li, Weihua and Tang, Shi Yang
(2020)
Modular off-chip emulsion generator enabled by a revolving needle.
Lab on a Chip, 20 (24), .
(doi:10.1039/d0lc00939c).
Abstract
Microfluidic chips have demonstrated unparalleled abilities in droplet generation, including precise control over droplet size and monodispersity. And yet, their rather complicated microfabrication process and operation can be a barrier for inexperienced researchers, which hinders microdroplets from unleashing their potential in broader fields of research. Here, we attempt to remove this barrier by developing an integrated and modular revolving needle emulsion generator (RNEG) to achieve high-throughput production of uniformly sized droplets in an off-chip manner. The RNEG works by driving a revolving needle to pinch the dispersed phase in a minicentrifuge tube. The system is constructed using modular components without involving any microfabrication, thereby enabling user-friendly operation. The RNEG is capable of producing microdroplets of various liquids with diameters ranging from tens to hundreds of micrometres. We further examine the principle of operation using numerical simulations and establish a simple model to predict the droplet size. Moreover, by integrating curing and centrifugation processes, the RNEG can produce hydrogel microparticles and transfer them from an oil phase into a water phase. Using this ability, we demonstrate the encapsulation and culture of single yeast cells within hydrogel microparticles. We envisage that the RNEG can become a versatile and powerful tool for high-throughput production of emulsions to facilitate diverse biological and chemical research.
Text
d0lc00939c
- Version of Record
More information
Accepted/In Press date: 27 October 2020
e-pub ahead of print date: 28 December 2020
Additional Information:
Correction notice:
A correction has been attached to this output located at: https://doi.org/10.1039/D1LC90011K
Funding Information:
This work is supported by the Australian Research Council (ARC) Discovery Project (Grant no. DP200102269).
Identifiers
Local EPrints ID: 481673
URI: http://eprints.soton.ac.uk/id/eprint/481673
ISSN: 1473-0197
PURE UUID: 71056f67-fc1e-4e0b-88cd-14d1df98e772
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Date deposited: 06 Sep 2023 16:30
Last modified: 18 Mar 2024 04:13
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Contributors
Author:
Yuxin Zhang
Author:
Qianbin Zhao
Author:
Dan Yuan
Author:
Hangrui Liu
Author:
Guolin Yun
Author:
Hongda Lu
Author:
Ming Li
Author:
Jinhong Guo
Author:
Weihua Li
Author:
Shi Yang Tang
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