Simultaneous Characterization of Instantaneous Young’s Modulus and Specific Membrane Capacitance of Single Cells Using a Microfluidic System

Simultaneous Characterization of Instantaneous Young’s Modulus and Specific Membrane Capacitance of Single Cells Using a Microfluidic System

This paper presents a microfluidics-based approach capable of continuously characterizing instantaneous Young’s modulus (Einstantaneous) and specific membrane capacitance (Cspecific membrane) of suspended single cells. In this method, cells were aspirated through a constriction channel while the cel...

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Bibliographic Details
Main Authors: Yang Zhao, Deyong Chen, Yana Luo, Feng Chen, Xiaoting Zhao, Mei Jiang, Wentao Yue, Rong Long, Junbo Wang, Jian Chen
Format: Article
Language:English
Published: MDPI AG 2015-01-01
Series:Sensors
Subjects:
microfluidics
single-cell analysis
cellular biophysics
instantaneous Young’s modulus
specific membrane capacitance
Online Access:http://www.mdpi.com/1424-8220/15/2/2763
Description
Summary:This paper presents a microfluidics-based approach capable of continuously characterizing instantaneous Young’s modulus (Einstantaneous) and specific membrane capacitance (Cspecific membrane) of suspended single cells. In this method, cells were aspirated through a constriction channel while the cellular entry process into the constriction channel was recorded using a high speed camera and the impedance profiles at two frequencies (1 kHz and 100 kHz) were simultaneously measured by a lock-in amplifier. Numerical simulations were conducted to model cellular entry process into the constriction channel, focusing on two key parameters: instantaneous aspiration length (Linstantaneous) and transitional aspiration length (Ltransitional), which was further translated to Einstantaneous. An equivalent distribution circuit model for a cell travelling in the constriction channel was used to determine Cspecific membrane. A non-small-cell lung cancer cell line 95C (n = 354) was used to evaluate this technique, producing Einstantaneous of 2.96 ± 0.40 kPa and Cspecific membrane of 1.59 ± 0.28 μF/cm2. As a platform for continuous and simultaneous characterization of cellular Einstantaneous and Cspecific membrane, this approach can facilitate a more comprehensive understanding of cellular biophysical properties.
ISSN:1424-8220

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