Probing Cell Deformability Via Acoustically Actuated Bubbles

Overview

Journal Small

Date 2015 Dec 31

PMID 26715211

Citations 15

Authors

Yuliang Xie

Nitesh Nama

Peng Li

Zhangming Mao

Po-Hsun Huang

Chenglong Zhao

Francesco Costanzo

Tony Jun Huang

Affiliations

Soon will be listed here.

Abstract

An acoustically actuated, bubble-based technique is developed to investigate the deformability of cells suspended in microfluidic devices. A microsized bubble is generated by an optothermal effect near the targeted cells, which are suspended in a microfluidic chamber. Subsequently, acoustic actuation is employed to create localized acoustic streaming. In turn, the streaming flow results in hydrodynamic forces that deform the cells in situ. The deformability of the cells is indicative of their mechanical properties. The method in this study measures mechanical biomarkers from multiple cells in a single experiment, and it can be conveniently integrated with other bioanalysis and drug-screening platforms. Using this technique, the mean deformability of tens of HeLa, HEK, and HUVEC cells is measured to distinguish their mechanical properties. HeLa cells are deformed upon treatment with Cytochalasin. The technique also reveals the deformability of each subpopulation in a mixed, heterogeneous cell sample by the use of both fluorescent markers and mechanical biomarkers. The technique in this study, apart from being relevant to cell biology, will also enable biophysical cellular diagnosis.

Citing Articles

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