A continuous-flow acoustofluidic cytometer for single-cell mechanotyping

Han Wang; Zhongzheng Liu; Dong M. Shin; Zhuo G. Chen; Younghak Cho; Yong Joe Kim; Arum Han

doi:10.1039/c8lc00711j

A continuous-flow acoustofluidic cytometer for single-cell mechanotyping

Han Wang, Zhongzheng Liu, Dong M. Shin, Zhuo G. Chen, Younghak Cho, Yong Joe Kim, Arum Han

Dept. of Mechanical System and Design Engineering

Research output: Contribution to journal › Article › peer-review

31 Scopus citations

Abstract

The biophysical properties of cells such as their compressibility have been found to be closely related to disease progression such as cancer development and metastasis. As cancer cells are heterogeneous, rapid and high-throughput evaluation of cell biophysical properties at single-cell resolution is needed to assess their potential as biomarkers for cancer staging and prognosis. Acoustofluidics has shown promise as a contactless method for accurately measuring cell biophysical properties; however, previously reported methods had relatively low throughput due to their requirement of no-flow conditions. This work presents a high-throughput continuous flow-based acoustofluidic cell mechanotyping method at single-cell resolution that retains the advantage of simplicity and low-cost.

Original language	English
Pages (from-to)	387-393
Number of pages	7
Journal	Lab on a Chip
Volume	19
Issue number	3
DOIs	https://doi.org/10.1039/c8lc00711j
State	Published - 7 Feb 2019

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10.1039/c8lc00711j

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abstract = "The biophysical properties of cells such as their compressibility have been found to be closely related to disease progression such as cancer development and metastasis. As cancer cells are heterogeneous, rapid and high-throughput evaluation of cell biophysical properties at single-cell resolution is needed to assess their potential as biomarkers for cancer staging and prognosis. Acoustofluidics has shown promise as a contactless method for accurately measuring cell biophysical properties; however, previously reported methods had relatively low throughput due to their requirement of no-flow conditions. This work presents a high-throughput continuous flow-based acoustofluidic cell mechanotyping method at single-cell resolution that retains the advantage of simplicity and low-cost.",

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AU - Liu, Zhongzheng

AU - Shin, Dong M.

AU - Chen, Zhuo G.

AU - Cho, Younghak

AU - Kim, Yong Joe

AU - Han, Arum

PY - 2019/2/7

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AB - The biophysical properties of cells such as their compressibility have been found to be closely related to disease progression such as cancer development and metastasis. As cancer cells are heterogeneous, rapid and high-throughput evaluation of cell biophysical properties at single-cell resolution is needed to assess their potential as biomarkers for cancer staging and prognosis. Acoustofluidics has shown promise as a contactless method for accurately measuring cell biophysical properties; however, previously reported methods had relatively low throughput due to their requirement of no-flow conditions. This work presents a high-throughput continuous flow-based acoustofluidic cell mechanotyping method at single-cell resolution that retains the advantage of simplicity and low-cost.

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A continuous-flow acoustofluidic cytometer for single-cell mechanotyping

Abstract

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