Literature DB >> 24738014

Modulating chemotaxis of lung cancer cells by using electric fields in a microfluidic device.

Yu-Chiu Kao1, Meng-Hua Hsieh2, Chung-Chun Liu3, Huei-Jyuan Pan3, Wei-Yu Liao4, Ji-Yen Cheng5, Po-Ling Kuo6, Chau-Hwang Lee5.   

Abstract

We employed direct-current electric fields (dcEFs) to modulate the chemotaxis of lung cancer cells in a microfluidic cell culture device that incorporates both stable concentration gradients and dcEFs. We found that the chemotaxis induced by a 0.5 μM/mm concentration gradient of epidermal growth factor can be nearly compensated by a 360 mV/mm dcEF. When the effect of chemical stimulation was balanced by the electrical drive, the cells migrated randomly, and the path lengths were largely reduced. We also demonstrated electrically modulated chemotaxis of two types of lung cancer cells with opposite directions of electrotaxis in this device.

Entities:  

Year:  2014        PMID: 24738014      PMCID: PMC3976467          DOI: 10.1063/1.4870401

Source DB:  PubMed          Journal:  Biomicrofluidics        ISSN: 1932-1058            Impact factor:   2.800


  30 in total

1.  Microfluidic device for studying cell migration in single or co-existing chemical gradients and electric fields.

Authors:  Jing Li; Ling Zhu; Michael Zhang; Francis Lin
Journal:  Biomicrofluidics       Date:  2012-05-16       Impact factor: 2.800

2.  Asymmetric cancer-cell filopodium growth induced by electric-fields in a microfluidic culture chip.

Authors:  Chun-Chieh Wang; Yu-Chiu Kao; Pei-Yin Chi; Ching-Wen Huang; Jiunn-Yuan Lin; Chia-Fu Chou; Ji-Yen Cheng; Chau-Hwang Lee
Journal:  Lab Chip       Date:  2010-12-09       Impact factor: 6.799

3.  Generation of stable concentration gradients in 2D and 3D environments using a microfluidic ladder chamber.

Authors:  Wajeeh Saadi; Seog Woo Rhee; Francis Lin; Behrad Vahidi; Bong Geun Chung; Noo Li Jeon
Journal:  Biomed Microdevices       Date:  2007-10       Impact factor: 2.838

4.  Lung cancer A549 cells migrate directionally in DC electric fields with polarized and activated EGFRs.

Authors:  Xiaolong Yan; Jing Han; Zhipei Zhang; Jian Wang; Qingshu Cheng; Kunxiang Gao; Yunfeng Ni; Yunjie Wang
Journal:  Bioelectromagnetics       Date:  2009-01       Impact factor: 2.010

5.  Label-free quantification of asymmetric cancer-cell filopodium activities in a multi-gradient chip.

Authors:  Tsi-Hsuan Hsu; Meng-Hua Yen; Wei-Yu Liao; Ji-Yen Cheng; Chau-Hwang Lee
Journal:  Lab Chip       Date:  2009-01-15       Impact factor: 6.799

6.  Activated T lymphocytes migrate toward the cathode of DC electric fields in microfluidic devices.

Authors:  Jing Li; Saravanan Nandagopal; Dan Wu; Sean F Romanuik; Kausik Paul; Douglas J Thomson; Francis Lin
Journal:  Lab Chip       Date:  2011-02-16       Impact factor: 6.799

Review 7.  The physics of cancer: the role of physical interactions and mechanical forces in metastasis.

Authors:  Denis Wirtz; Konstantinos Konstantopoulos; Peter C Searson
Journal:  Nat Rev Cancer       Date:  2011-06-24       Impact factor: 60.716

Review 8.  Microenvironmental regulation of metastasis.

Authors:  Johanna A Joyce; Jeffrey W Pollard
Journal:  Nat Rev Cancer       Date:  2008-03-12       Impact factor: 60.716

9.  A transparent cell-culture microchamber with a variably controlled concentration gradient generator and flow field rectifier.

Authors:  Ji-Yen Cheng; Meng-Hua Yen; Ching-Te Kuo; Tai-Horng Young
Journal:  Biomicrofluidics       Date:  2008-06-17       Impact factor: 2.800

10.  Electrophoresis of cellular membrane components creates the directional cue guiding keratocyte galvanotaxis.

Authors:  Greg M Allen; Alex Mogilner; Julie A Theriot
Journal:  Curr Biol       Date:  2013-03-28       Impact factor: 10.834
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  8 in total

1.  Effects of hydraulic pressure on cardiomyoblasts in a microfluidic device.

Authors:  Yu-Fang Hsiao; Huei-Jyuan Pan; Yi-Chung Tung; Chien-Chang Chen; Chau-Hwang Lee
Journal:  Biomicrofluidics       Date:  2015-04-07       Impact factor: 2.800

2.  Designing Microfluidic Devices for Studying Cellular Responses Under Single or Coexisting Chemical/Electrical/Shear Stress Stimuli.

Authors:  Tzu-Yuan Chou; Yung-Shin Sun; Hsien-San Hou; Shang-Ying Wu; Yun Zhu; Ji-Yen Cheng; Kai-Yin Lo
Journal:  J Vis Exp       Date:  2016-08-13       Impact factor: 1.355

Review 3.  Microfluidic Organ/Body-on-a-Chip Devices at the Convergence of Biology and Microengineering.

Authors:  Ana Rubina Perestrelo; Ana C P Águas; Alberto Rainer; Giancarlo Forte
Journal:  Sensors (Basel)       Date:  2015-12-10       Impact factor: 3.576

4.  A Gal-MµS Device to Evaluate Cell Migratory Response to Combined Galvano-Chemotactic Fields.

Authors:  Shawn Mishra; Maribel Vazquez
Journal:  Biosensors (Basel)       Date:  2017-11-21

5.  Uniform electric field generation in circular multi-well culture plates using polymeric inserts.

Authors:  Hsieh-Fu Tsai; Ji-Yen Cheng; Hui-Fang Chang; Tadashi Yamamoto; Amy Q Shen
Journal:  Sci Rep       Date:  2016-05-19       Impact factor: 4.379

Review 6.  Studying Electrotaxis in Microfluidic Devices.

Authors:  Yung-Shin Sun
Journal:  Sensors (Basel)       Date:  2017-09-07       Impact factor: 3.576

7.  Comparison of Chip Inlet Geometry in Microfluidic Devices for Cell Studies.

Authors:  Yung-Shin Sun
Journal:  Molecules       Date:  2016-06-15       Impact factor: 4.411

8.  Use Microfluidic Chips to Study the Phototaxis of Lung Cancer Cells.

Authors:  Fong-Yi Lin; Jin-Young Lin; Kai-Yin Lo; Yung-Shin Sun
Journal:  Int J Mol Sci       Date:  2019-09-12       Impact factor: 5.923
  8 in total

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