Reconfigurable Microfluidic Device with Discretized Sidewall

Overview

Journal Biomicrofluidics

Publisher American Institute of Physics

Specialty Biomedical Engineering

Date 2017 May 16

PMID 28503247

Citations 1

Authors

Masahiro Oono

Keisuke Yamaguchi

Amirul Rasyid

Atsushi Takano

Masato Tanaka

Nobuyuki Futai

Affiliations

Soon will be listed here.

Abstract

Various microfluidic features, such as traps, have been used to manipulate flows, cells, and other particles within microfluidic systems. However, these features often become undesirable in subsequent steps requiring different fluidic configurations. To meet the changing needs of various microfluidic configurations, we developed a reconfigurable microfluidic channel with movable sidewalls using mechanically discretized sidewalls of laterally aligned rectangular pins. The user can deform the channel sidewall at any time after fabrication by sliding the pins. We confirmed that the flow resistance of the straight microchannel could be reversibly adjusted in the range of 10-10Pa s/l by manually displacing one of the pins comprising the microchannel sidewall. The reconfigurable microchannel also made it possible to manipulate flows and cells by creating a segmented patterned culture of COS-7 cells and a coculture of human umbilical vein endothelial cells (HUVECs) and human lung fibroblasts (hLFs) inside the microchannel. The reconfigurable microfluidic device successfully maintained a culture of COS-7 cells in a log phase throughout the entire period of 216 h. Furthermore, we performed a migration assay of cocultured HUVEC and hLF spheroids within one microchannel and observed their migration toward each other.

Citing Articles

Reconfigurable Microfluidic Channel with Pin-discretized Sidewalls.

Futai N, Fujita K, Ikuta W J Vis Exp. 2018; (134).

PMID: 29708554 PMC: 5933500. DOI: 10.3791/57230.

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