Rail configuration for lateral particle transport across intact co-flows: effect of wall and rail geometry on liquid and particle transport

Iwona Ziemecka; Amaury de Hemptinne; Vyacheslav R. Misko; Matthieu Briet; Pierre Gelin; Dominique Maes; Wim De Malsche

doi:10.1039/D2SM01346K

Rail configuration for lateral particle transport across intact co-flows: effect of wall and rail geometry on liquid and particle transport

Iwona Ziemecka, Amaury de Hemptinne, Vyacheslav R. Misko, Matthieu Briet, Pierre Gelin, Dominique Maes, Wim De Malsche

Research output: Contribution to journal › Article › peer-review

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Abstract

Layer-by-Layer coating technology is of great importance for many applications of microparticles whereby exposure of the particles to various reagents is needed. Mutual contamination of the reagents during this process is a key challenge, and this undesired effect should be avoided. Here we introduce a device that provides subsequent exposure of particles to various liquids and minimizes mixing of the liquids at the same time. The key element of the device is a rail (groove) at the bottom of a microfluidic channel. The rail forms an angle (between 0 and 90 degrees) and thus enables passive transport of particles through the intact co-flows of the different fluids. To avoid the undesirable effect of reagent stream mixing, internal walls are introduced to separate the different flows. Various designs of the proposed device are considered, and their performance is experimentally analyzed.

Original language	English
Pages (from-to)	1231-1240
Number of pages	10
Journal	Soft Matter
Volume	19
Issue number	6
Early online date	16 Jan 2023
DOIs	https://doi.org/10.1039/D2SM01346K
Publication status	Published - 8 Feb 2023

Bibliographical note

Funding Information:
We thank Prof. Ruslan Efremov for giving access to his profilometer instrument. This work was partially supported by Research Foundation-Flanders (FWO-Vl), Grant no. G029322N, Grant no. 1512018N, and by Innoviris (‘Colores’ Bridge type project).

Publisher Copyright:
© 2023 The Royal Society of Chemistry.

Copyright:
Copyright 2023 Elsevier B.V., All rights reserved.

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10.1039/D2SM01346K

Rail_2_MS_20230109_SoftMatter_Resubmission_pre-printAccepted author manuscript, 647 KBLicence: Unspecified

Cite this

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title = "Rail configuration for lateral particle transport across intact co-flows: effect of wall and rail geometry on liquid and particle transport",

abstract = "Layer-by-Layer coating technology is of great importance for many applications of microparticles whereby exposure of the particles to various reagents is needed. Mutual contamination of the reagents during this process is a key challenge, and this undesired effect should be avoided. Here we introduce a device that provides subsequent exposure of particles to various liquids and minimizes mixing of the liquids at the same time. The key element of the device is a rail (groove) at the bottom of a microfluidic channel. The rail forms an angle (between 0 and 90 degrees) and thus enables passive transport of particles through the intact co-flows of the different fluids. To avoid the undesirable effect of reagent stream mixing, internal walls are introduced to separate the different flows. Various designs of the proposed device are considered, and their performance is experimentally analyzed.",

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Rail configuration for lateral particle transport across intact co-flows: effect of wall and rail geometry on liquid and particle transport. / Ziemecka, Iwona; Hemptinne, Amaury de ; Misko, Vyacheslav R.; Briet, Matthieu; Gelin, Pierre; Maes, Dominique ; Malsche, Wim De.

In: Soft Matter, Vol. 19, No. 6, 08.02.2023, p. 1231-1240.

Research output: Contribution to journal › Article › peer-review

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AU - Ziemecka, Iwona

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AU - Briet, Matthieu

AU - Gelin, Pierre

AU - Maes, Dominique

AU - Malsche, Wim De

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PY - 2023/2/8

Y1 - 2023/2/8

N2 - Layer-by-Layer coating technology is of great importance for many applications of microparticles whereby exposure of the particles to various reagents is needed. Mutual contamination of the reagents during this process is a key challenge, and this undesired effect should be avoided. Here we introduce a device that provides subsequent exposure of particles to various liquids and minimizes mixing of the liquids at the same time. The key element of the device is a rail (groove) at the bottom of a microfluidic channel. The rail forms an angle (between 0 and 90 degrees) and thus enables passive transport of particles through the intact co-flows of the different fluids. To avoid the undesirable effect of reagent stream mixing, internal walls are introduced to separate the different flows. Various designs of the proposed device are considered, and their performance is experimentally analyzed.

AB - Layer-by-Layer coating technology is of great importance for many applications of microparticles whereby exposure of the particles to various reagents is needed. Mutual contamination of the reagents during this process is a key challenge, and this undesired effect should be avoided. Here we introduce a device that provides subsequent exposure of particles to various liquids and minimizes mixing of the liquids at the same time. The key element of the device is a rail (groove) at the bottom of a microfluidic channel. The rail forms an angle (between 0 and 90 degrees) and thus enables passive transport of particles through the intact co-flows of the different fluids. To avoid the undesirable effect of reagent stream mixing, internal walls are introduced to separate the different flows. Various designs of the proposed device are considered, and their performance is experimentally analyzed.

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Rail configuration for lateral particle transport across intact co-flows: effect of wall and rail geometry on liquid and particle transport

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SRP51: SRP-Onderzoekszwaartepunt: Optical and microfluidic tools to unravel the dynamics of bio-condensates

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Rail configuration for lateral particle transport across intact co-flows: effect of wall and rail geometry on liquid and particle transport

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Bibliographical note

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SRP51: SRP-Onderzoekszwaartepunt: Optical and microfluidic tools to unravel the dynamics of bio-condensates

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