Universal anchored-droplet device for cellular bioassays

Gabriel Amselem; Sébastien Sart; Charles N. Baroud

doi:10.1016/bs.mcb.2018.05.004

Universal anchored-droplet device for cellular bioassays

Institut Pasteur, Paris

Research output: Chapter in Book/Report/Conference proceeding › Chapter › peer-review

Abstract

The ability to encapsulate cells individually in droplets has many potential applications, for example for observing the heterogeneity of behaviors within a population. However, implementing operations on moving droplets require feedback control and instruments that provide precise timing. These technical difficulties impede the adoption of droplet microfluidic protocols in nonspecialist labs. In this chapter we describe an approach to produce and manipulate droplets that remain stationary within a microfluidic chamber, by fabricating a microfluidic device having three-dimensional topography. The method uses microchannels that confine the fluids everywhere except in predefined regions where the channels have a large height, a technique known as “rails and anchors.” By relying on the natural tendency of droplets to minimize their surface area, the approach provides a wide range of droplet manipulation tools. This chapter shows how this can be used to produce droplets, and several biological applications are demonstrated.

Original language	English
Title of host publication	Microfluidics in Cell Biology Part C
Subtitle of host publication	Microfluidics for Cellular and Subcellular Analysis
Editors	Daniel A. Fletcher, Junsang Doh, Matthieu Piel
Publisher	Academic Press Inc.
Pages	177-199
Number of pages	23
ISBN (Print)	9780128142844
DOIs	https://doi.org/10.1016/bs.mcb.2018.05.004
Publication status	Published - 1 Jan 2018

Publication series

Name	Methods in Cell Biology
Volume	148
ISSN (Print)	0091-679X

Keywords

Anchors
Antibiogram
Droplet microfluidics
Heterogeneity
Rails
Single cell
Transfection

Access to Document

10.1016/bs.mcb.2018.05.004

Cite this

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title = "Universal anchored-droplet device for cellular bioassays",

abstract = "The ability to encapsulate cells individually in droplets has many potential applications, for example for observing the heterogeneity of behaviors within a population. However, implementing operations on moving droplets require feedback control and instruments that provide precise timing. These technical difficulties impede the adoption of droplet microfluidic protocols in nonspecialist labs. In this chapter we describe an approach to produce and manipulate droplets that remain stationary within a microfluidic chamber, by fabricating a microfluidic device having three-dimensional topography. The method uses microchannels that confine the fluids everywhere except in predefined regions where the channels have a large height, a technique known as “rails and anchors.” By relying on the natural tendency of droplets to minimize their surface area, the approach provides a wide range of droplet manipulation tools. This chapter shows how this can be used to produce droplets, and several biological applications are demonstrated.",

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author = "Gabriel Amselem and S{\'e}bastien Sart and Baroud, \{Charles N.\}",

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Universal anchored-droplet device for cellular bioassays. / Amselem, Gabriel; Sart, Sébastien; Baroud, Charles N.
Microfluidics in Cell Biology Part C: Microfluidics for Cellular and Subcellular Analysis. ed. / Daniel A. Fletcher; Junsang Doh; Matthieu Piel. Academic Press Inc., 2018. p. 177-199 (Methods in Cell Biology; Vol. 148).

Research output: Chapter in Book/Report/Conference proceeding › Chapter › peer-review

TY - CHAP

T1 - Universal anchored-droplet device for cellular bioassays

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AU - Sart, Sébastien

AU - Baroud, Charles N.

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AB - The ability to encapsulate cells individually in droplets has many potential applications, for example for observing the heterogeneity of behaviors within a population. However, implementing operations on moving droplets require feedback control and instruments that provide precise timing. These technical difficulties impede the adoption of droplet microfluidic protocols in nonspecialist labs. In this chapter we describe an approach to produce and manipulate droplets that remain stationary within a microfluidic chamber, by fabricating a microfluidic device having three-dimensional topography. The method uses microchannels that confine the fluids everywhere except in predefined regions where the channels have a large height, a technique known as “rails and anchors.” By relying on the natural tendency of droplets to minimize their surface area, the approach provides a wide range of droplet manipulation tools. This chapter shows how this can be used to produce droplets, and several biological applications are demonstrated.

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KW - Antibiogram

KW - Droplet microfluidics

KW - Heterogeneity

KW - Rails

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KW - Transfection

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PB - Academic Press Inc.

ER -

Universal anchored-droplet device for cellular bioassays

Abstract

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Keywords

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