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Acoustically-driven thread-based tuneable gradient generators

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posted on 2024-07-11, 11:13 authored by Shwathy Ramesan, Amgad R. Rezk, Kai Wei Cheng, Peggy ChanPeggy Chan, Leslie Y. Yeo
Thread-based microfluidics offer a simple, easy to use, low-cost, disposable and biodegradable alternative to conventional microfluidic systems. While it has recently been shown that such thread networks facilitate manipulation of fluid samples including mixing, flow splitting and the formation of concentration gradients, the passive capillary transport of fluid through the thread does not allow for precise control due to the random orientation of cellulose fibres that make up the thread, nor does it permit dynamic manipulation of the flow. Here, we demonstrate the use of high frequency sound waves driven from a chip-scale device that drives rapid, precise and uniform convective transport through the thread network. In particular, we show that it is not only possible to generate a stable and continuous concentration gradient in a serial dilution and recombination network, but also one that can be dynamically tuned, which cannot be achieved solely with passive capillary transport. Additionally, we show a proof-of-concept in which such spatiotemporal gradient generation can be achieved with the entire thread network embedded in a three-dimensional hydrogel construct to more closely mimic the in vivo tissue microenvironment in microfluidic chemotaxis studies and cell culture systems, which is then employed to demonstrate the effect of such gradients on the proliferation of cells within the hydrogel.

Funding

Microscale microRNA Detection and Delivery for Effective Point-of-Care Cancer Screening and Therapeutics

Australian Research Council

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Acoustowetting: Microscale and Nanoscale Liquid Manipulation for Microfluidic Applications

Australian Research Council

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History

Available versions

PDF (Accepted manuscript)

ISSN

1473-0189

Journal title

Lab on a Chip

Volume

16

Issue

15

Pagination

8 pp

Publisher

Royal Society of Chemistry

Copyright statement

This journal is © The Royal Society of Chemistry 2016.

Language

eng

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