A Simple and Reusable Bilayer Membrane-based Microfluidic Device for the Study of Gradient-mediated Bacterial Behaviors

Overview

Journal Biomicrofluidics

Publisher American Institute of Physics

Specialty Biomedical Engineering

Date 2017 Sep 5

PMID 28868107

Citations 6

Authors

Wu Shang

Chen-Yu Tsao

Xiaolong Luo

Mairan Teodoro

Ryan McKay

David N Quan

Hsuan-Chen Wu

Gregory F Payne

William E Bentley

Affiliations

Soon will be listed here.

Abstract

We have developed a user-friendly microfluidic device for the study of gradient-mediated bacterial behaviors, including chemotaxis. This device rapidly establishes linear concentration gradients by exploiting solute diffusion through porous membranes in the absence of convective flows. As such, the gradients are created rapidly and can be sustained for long time periods (e.g., hours), sufficient to evaluate cell phenotype. The device exploits a unique simple bilayer configuration that enables rapid setup and quick reproducible introduction of cells. Its reusability represents an additional advantage in that it need not be limited to settings with microfluidics expertise. We have successfully demonstrated the applicability of this tool in studying the chemotactic response of to glucose. When coupled with our recent Python program, quantified metrics such as speed, ratio of tumble to run, and effective diffusivity can be obtained from slow frame rate videos. Moreover, we introduce a chemotaxis partition coefficient that conveniently scores swimming behavior on the single-cell level.

Citing Articles

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Virgile C, Hauk P, Wu H, Bentley W Biotechnol Prog. 2019; 35(3):e2778.

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