Issue 10, 2022

Generation of dynamic vortices in a microfluidic system incorporating stenosis barrier by tube oscillation

Abstract

Microfluidic systems incorporating sudden expansions are widely used for generation of vortex flow patterns. However, the formation of vortices requires high flow rates to induce inertial effects. Here, we introduce a new method for generating dynamic vortices in microfluidics at low static flow rates. Human blood is driven through a microfluidic channel incorporating a semi-circular stenosis barrier. The inlet tube of the channel is axially oscillated using a computer-controlled audio-speaker. The tube oscillation induces high transient flow rates in the channel, which generates dynamic vortices across the stenosis barrier. The size of the vortices can be modulated by varying the frequency and amplitude of tube oscillation. Various vortex flow patterns can be generated by varying the flow rate. The formation and size of the vortices can be predicted using the Reynolds number of the oscillating tube. We demonstrate the potential application of the system for investigating the adhesion and phagocytosis of circulating immune cells under pathologically high shear rates induced at the stenosis. This approach facilitates the development of versatile and controllable inertial microfluidic systems for performing various cellular assays while operating at low static flow rates and low sample volumes.

Graphical abstract: Generation of dynamic vortices in a microfluidic system incorporating stenosis barrier by tube oscillation

Supplementary files

Article information

Article type
Paper
Submitted
11 Feb 2022
Accepted
01 Apr 2022
First published
02 Apr 2022

Lab Chip, 2022,22, 1917-1928

Generation of dynamic vortices in a microfluidic system incorporating stenosis barrier by tube oscillation

P. Thurgood, C. Chheang, S. Needham, E. Pirogova, K. Peter, S. Baratchi and K. Khoshmanesh, Lab Chip, 2022, 22, 1917 DOI: 10.1039/D2LC00135G

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