Monitoring cellular activities of cancer cells using impedance sensing devices

Sensors and Actuators, B: Chemical

Volumn 193, Issue , 2014, Pages 478-483

  Pradhan, Rangadhar ^a   Mandal, Mahitosh ^a   Mitra, Analava ^a   Das, Soumen ^a  

^a INDIAN INSTITUTE OF TECHNOLOGY   (India)

Author keywords

Bioimpedance; Cytotoxicity; Microfabrication; T47D; ZD6474

Indexed keywords

BIO-IMPEDANCE; FREQUENCY RESPONSE CHARACTERISTIC; IMPEDANCE MONITORING; MICROMACHINING TECHNOLOGIES; QUANTITATIVE RELATIONS; SENSITIVITY VARIATION; T47D; ZD6474;

CELL DEATH; CYTOTOXICITY; FREQUENCY RESPONSE; MICROFABRICATION; SENSITIVITY ANALYSIS; SENSORS;

DRUG DOSAGE;

EID: 84891317950     PISSN: 09254005     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.snb.2013.12.003     Document Type: Article

References (42)

1. X. Jiang, L. Tan, B. Zhang, Y. Zhang, H. Tang, and Q. Xie et al. Detection of adherent cells using electrochemical impedance spectroscopy based on molecular recognition of integrin β1 Sensors and Actuators B: Chemical 149 2010 87 93
2. N. Hu, T. Wang, J. Cao, K. Su, J. Zhou, and J. Wu et al. Comparison between ECIS and LAPS for establishing a cardiomyocyte-based biosensor Sensors and Actuators B: Chemical 185 2013 238 244
3. L. Ceriotti, J. Ponti, F. Broggi, A. Kob, S. Drechsler, and E. Thedinga et al. Real-time assessment of cytotoxicity by impedance measurement on a 96-well plate Sensors and Actuators B: Chemical 123 2007 769 778
4. P. Daza, A. Olmo, D. Cañete, and A. Yúfera Monitoring living cell assays with bio-impedance sensors Sensors and Actuators B: Chemical 176 2013 605 610
5. J. Hong, K. Kandasamy, M. Marimuthu, C.S. Choi, and S. Kim Electrical cell-substrate impedance sensing as a non-invasive tool for cancer cell study The Analyst 136 2011 237 245
6. H.E. Park, D. Kim, H.S. Koh, S. Cho, J.S. Sung, and J.Y. Kim Real-time monitoring of neural differentiation of human mesenchymal stem cells by electric cell-substrate impedance sensing Journal of Biomedicine and Biotechnology 2011
7. J. Wegener, C.R. Keese, and I. Giaever Electric cell-substrate impedance sensing (ECIS) as a noninvasive means to monitor the kinetics of cell spreading to artificial surfaces Experimental Cell Research 259 2000 158 166
8. C. Xiao, and J.H.T. Luong On-line monitoring of cell growth and cytotoxicity using electric cell-substrate impedance sensing (ECIS) Biotechnology Progress 19 2003 1000 1005
9. A. Janshoff, A. Kunze, S. Michaelis, V. Heitmann, B. Reiss, and J. Wegener Cell adhesion monitoring using substrate-integrated sensors Journal of Adhesion Science and Technology 24 2010 2079 2104
10. J. Wang, C. Wu, N. Hu, J. Zhou, L. Du, and P. Wang Microfabricated electrochemical cell-based biosensors for analysis of living cells in vitro Biosensors 2 2012 127 170
11. S. Michaelis, J. Wegener, and R. Robelek Label-free monitoring of cell-based assays: combining impedance analysis with SPR for multiparametric cell profiling Biosensors and Bioelectronics 49 2013 63 70
12. K. Heileman, J. Daoud, and M. Tabrizian Dielectric spectroscopy as a viable biosensing tool for cell and tissue characterization and analysis Biosensors and Bioelectronics 49 2013 348 359
13. S. Reitinger, J. Wissenwasser, W. Kapferer, R. Heer, and G. Lepperdinger Electric impedance sensing in cell-substrates for rapid and selective multipotential differentiation capacity monitoring of human mesenchymal stem cells Biosensors and Bioelectronics 34 2012 63 69
14. A.R. Burns, D.C. Walker, E.S. Brown, L.T. Thurmon, R.A. Bowden, and C.R. Keese et al. Neutrophil transendothelial migration is independent of tight junctions and occurs preferentially at tricellular corners Journal of Immunology 159 1997 2893 2903
15. C.M. Chan, J.H. Huang, H.S. Chiang, W.B. Wu, H.H. Lin, and J.Y. Hong et al. Effects of (-)-epigallocatechin gallate on RPE cell migration and adhesion Molecular Vision 16 2010 586 595
16. C.C. Hsu, W.C. Tsai, C.P.C. Chen, Y.M. Lu, and J.S. Wang Effects of negative pressures on epithelial tight junctions and migration in wound healing American Journal of Physiology-Cell Physiology 299 2010 C528 C534
17. C.C. Lee, A.J. Putnam, C.K. Miranti, M. Gustafson, L.M. Wang, and G.F.V. Woude et al. Overexpression of sprouty 2 inhibits HGF/SF-mediated cell growth, invasion, migration, and cytokinesis Oncogene 23 2004 5193 5202
18. S. Arndt, J. Seebach, K. Psathaki, H.J. Galla, and J. Wegener Bioelectrical impedance assay to monitor changes in cell shape during apoptosis Biosensors and Bioelectronics 19 2004 583 594
19. H.Y. Yin, F.L. Wang, A.L. Wang, J. Cheng, and Y.X. Zhou Bioelectrical impedance assay to monitor changes in aspirin-treated human colon cancer HT-29 cell shape during apoptosis Analytical Letters 40 2007 85 94
20. K.B. Male, S.M. Crowley, S.G. Collins, Y.M. Tzeng, and J.H.T. Luong Cell-based impedance spectroscopy for probing inhibitory effects of steroids and ergostane/lanosta-related compounds Analytical Methods 2 2010 870 877
21. J. Muller, C. Thirion, and M.W. Pfaffl Electric cell-substrate impedance sensing (ECIS) based real-time measurement of titer dependent cytotoxicity induced by adenoviral vectors in an IPI-2I cell culture model Biosensors and Bioelectronics 26 2011 2000 2005
22. Y.C. Xu, Y. Lv, L. Wang, W.L. Xing, and J. Cheng A microfluidic device with passive air-bubble valves for real-time measurement of dose-dependent drug cytotoxicity through impedance sensing Biosensors and Bioelectronics 32 2012 300 304
23. D. Opp, B. Wafula, J. Lim, E. Huang, J.C. Lo, and C.M. Lo Use of electric cell-substrate impedance sensing to assess in vitro cytotoxicity Biosensors and Bioelectronics 24 2009 2625 2629
24. C. Xiao, and J.H.T. Luong Assessment of cytotoxicity by emerging impedance spectroscopy Toxicology and Applied Pharmacology 206 2005 102 112
25. T.B. Tran, S. Cho, and J. Min Hydrogel-based diffusion chip with electric cell-substrate impedance sensing (ECIS) integration for cell viability assay and drug toxicity screening Biosensors and Bioelectronics 50 2013 453 459
26. X. Sun, J. Ji, D. Jiang, X. Li, Y. Zhang, and Z. Li et al. Development of a novel electrochemical sensor using pheochromocytoma cells and its assessment of acrylamide cytotoxicity Biosensors and Bioelectronics 44 2013 122 126
27. H. Alborzinia, S. Can, P. Holenya, C. Scholl, E. Lederer, and I. Kitanovic et al. Real-time monitoring of cisplatin-induced cell death PLoS ONE 6 2011 e19714
28. C.K. Goldman, J. Kim, W.L. Wong, V. King, T. Brock, and G.Y. Gillespie Epidermal growth factor stimulates vascular endothelial growth factor production by human malignant glioma cells: a model of glioblastoma multiforme pathophysiology Molecular Biology of the Cell 4 1993 121 133
29. D.S. Salomon, R. Brandt, F. Ciardiello, and N. Normanno Epidermal growth factor-related peptides and their receptors in human malignancies Critical Reviews in Oncology/Hematology 19 1995 183 232
30. J. Gille, R.A. Swerlick, and S.W. Caughman Transforming growth factor-alpha-induced transcriptional activation of the vascular permeability factor (VPF/VEGF) gene requires AP-2-dependent DNA binding and transactivation EMBO Journal 16 1997 750 759
31. P. Perrotte, T. Matsumoto, K. Inoue, H. Kuniyasu, B.Y. Eve, and D.J. Hicklin et al. Anti-epidermal growth factor receptor antibody C225 inhibits angiogenesis in human transitional cell carcinoma growing orthotopically in nude mice Clinical Cancer Research 5 1999 257 265
32. K.L. Weber, M. Doucet, J.E. Price, C. Baker, S.J. Kim, and I.J. Fidler Blockade of epidermal growth factor receptor signaling leads to inhibition of renal cell carcinoma growth in the bone of nude mice Cancer Research 63 2003 2940 2947
33. R. Pradhan, L. Das, J. Chatterjee, M.M.A. Mitra, and S. Das Monopolar impedance sensing microdevices for characterization of cells and tissue culture Sensor Letters 11 2013 466 475
34. L. Wang, H. Wang, K. Mitchelson, Z. Yu, and J. Cheng Analysis of the sensitivity and frequency characteristics of coplanar electrical cell-substrate impedance sensors Biosensors and Bioelectronics 24 2008 14 21
35. N.N. Mishra, S. Retterer, T.J. Zieziulewicz, M. Isaacson, D. Szarowski, and D.E. Mousseau et al. On-chip micro-biosensor for the detection of human CD4+ cells based on AC impedance and optical analysis Biosensors and Bioelectronics 21 2005 696 704
36. C.M.A. Brett, and A.M.O. Brett Electrochemistry: Principles, Methods, and Applications 1993 Oxford University Press London, UK 185 186
37. R. Lind, P. Connolly, C.D.W. Wilkinson, and R.D. Thomson Finite-element analysis applied to extracellular microelectrode design Sensors and Actuators B: Chemical 3 1991 23 30
38. L.J. Breckenridge, R.J.A. Wilson, P. Connolly, A.S.G. Curtis, J.A.T. Dow, and S.E. Blackshaw et al. Advantages of using microfabricated extracellular electrodes for in vitro neuronal recording Journal of Neuroscience Research 42 1995 266 276
39. R. Pradhan, A. Mitra, and S. Das Characterization of electrode/ electrolyte interface of ECIS devices Electroanalysis 24 2012 2405 2414
40. X. Huang, D.W. Greve, D.D. Nguyen, and M.M. Domach Impedance based biosensor array for monitoring mammalian cell behavior Proceedings of IEEE Sensors, 2003, vol. 1 2003 304 309
41. R. Pradhan, S. Rajput, M. Mandal, A. Mitra, S. Das, Electric cell-substrate impedance sensing technique to monitor cellular behaviours of cancer cells, RSC Advances, (2013). http://dx.doi.org/10.1039/C3RA45090B.
42. R. Pradhan, S. Rajput, M. Mandal, A. Mitra, S. Das, Frequency Dependant Impedimetric Cytotoxic Evaluation of Anticancer Drug on Breast Cancer Cell, Biosensors and Bioelectronics, (2013). http://dx.doi.org/10.1016/j.bios.2013.11. 060.