University of Illinois at Chicago
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Drastic sensing enhancement using acoustic bubbles for surface-based microfluidic sensors

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posted on 2018-06-19, 00:00 authored by A. De Vellis, D. Gritsenko, Y. Lin, Z. Wu, X. Zhang, Y. Pan, W. Xue, J. Xu
There is a high demand for ultrafast biosensors for industrial and public health applications. However, the performance of existing sensors is often limited by the slow mass transport process in traditional pressure-driven microfluidic devices. In this paper we show for the first time, that acoustic microbubbles trapped in prefabricated cavities in a micro-chamber are capable of enhancing fluid sample mixing that results in faster delivery of target species to the sensor surface. We demonstrate a drastic reduction of sensor response time (up to 21.3 fold) for surface-based nanosenors in presence of resonantly actuated microbubbles. The obtained results are valid in a wide pH (4-10) range and agree well with previous studies.

Funding

This research was supported by J. Xu’s start up fund at UIC.

History

Citation

De Vellis, A., Gritsenko, D., Lin, Y., Wu, Z. P., Zhang, X., Pan, Y. Y., Xue, W. and Xu, J. Drastic sensing enhancement using acoustic bubbles for surface-based microfluidic sensors. Sensors and Actuators B-Chemical. 2017. 243: 298-302. 10.1016/j.snb.2016.11.098.

Publisher

Elsevier

Language

  • en_US

issn

0925-4005

Issue date

2016-11-01

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