Embedded Microbubbles for Acoustic Manipulation of Single Cells and Microfluidic Applications

22 March 2021, Version 1
This content is a preprint and has not undergone peer review at the time of posting.

Abstract

Acoustically excited microstructures have demonstrated significant potential for small scale biomedical applications by overcoming major microfluidic limitations. Recently, the application of oscillating microbubbles has demonstrated their superiority over acoustically excited solid structures due to their enhanced acoustic streaming at low input power. However, their limited temporal stability hinders their direct applicability for industrial or clinical purposes. Here, we introduce the embedded microbubble, a novel acoustofluidic design based on the combination of solid structures (polydimethylsiloxane) and microbubbles (air-filled cavity) to combine benefits of both approaches while minimizing their drawbacks. We investigate the influence of various design parameters and geometrical features through numerical simulations and experimentally evaluate their manipulation capabilities. Finally, we demonstrate the capabilities of our design for microfluidic applications by investigating its mixing performance as well as through the controlled rotational manipulation of individual HeLa cells.

Keywords

Acoustofluidic
Microfluidic
Single-Cell Manipulation
Mixing
Microbubble
lab-on-chip devices

Supplementary materials

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Embedded Microbubble Supporting
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