Three dimensional microelectrode array device integrating multi-channel microfluidics to realize manipulation and characterization of enzyme-immobilized polystyrene beads

Sensors and Actuators, B: Chemical

Volumn 141, Issue 1, 2009, Pages 256-262

  Kunikata, Ryouta ^a   Takahashi, Yasufumi ^a   Koide, Masahiro ^a,b   Itayama, Tomoaki ^b   Yasukawa, Tomoyuki ^c   Shiku, Hitoshi ^a   Matsue, Tomokazu ^a  

^a TOHOKU UNIVERSITY   (Japan)

^b NATIONAL INSTITUTE FOR ENVIRONMENTAL STUDIES   (Japan)

^c UNIVERSITY OF HYOGO   (Japan)

Author keywords

Chronoamperometry; Dielectrophoresis; Enzyme immobilized beads; Microelectrode array; Microfluidics

Indexed keywords

AC VOLTAGE; AG/AGCL; COLLECTION MEASUREMENTS; DEP FORCE; DIELECTROPHORESIS; DIELECTROPHORETIC; ELECTROCHEMICAL GENERATION; ENZYMATIC ACTIVITIES; FERROCENEMETHANOL; MICRO WELLS; MICRO-CHAMBER; MICROBAND ELECTRODE; MICROBEADS; MICROELECTRODE ARRAY; MICROFABRICATED; MULTI-CHANNEL; NOVEL DEVICES; POLYSTYRENE BEADS; REDUCTION CURRENT; SIMULATION-BASED;

CHRONOAMPEROMETRY; DIELECTRIC DEVICES; ELECTRIC POTENTIAL; ELECTROPHORESIS; ENZYMES; GLUCOSE; GLUCOSE OXIDASE; GLUCOSE SENSORS; MICROELECTRODES; MICROFLUIDICS; POLYMER BLENDS; POLYSTYRENES; SURFACE DEFECTS;

MICROCHANNELS;

EID: 67949120306     PISSN: 09254005     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.snb.2009.05.028     Document Type: Article

References (30)

1. Manz A., Graber N., and Widmer H.M. Miniaturized total chemical systems: a novel concept for chemical sensing. Sens. Actuators B 1 (1990) 244-248
2. Shoji S., Nakagawa S., and Esashi M. Micropump and sample-injector for integrated chemical analyzing systems. Sens. Actuators A 21-23 (1990) 189-192
3. West J., Becker M., Tombrik S., and Manz A. Micro total analysis systems; latest achievements. Anal. Chem. 80 (2008) 4403-4419
4. Anderson H., and van der Berg A. Microfluidic devices for cellomics: a review. Sens. Actuators B 92 (2003) 315-325
5. Pumara M., Merkoci A., and Alegret S. New materials for electrochemical eensing VII. Microfluidic chip platforms. Trends Anal. Chem. 25 (2006) 219-235
6. Muller T., Gradl G., Howitz S., Shirley S., Schnelle Th., and Fuhr G. A 3-D microelectrode system for handling and caging single cells and particles. Biosens. Bioelectron. 14 (1999) 247-256
7. Becker F.F., Wang X.B., Huang Y., Pethig R., Vykoukal J., and Gascoyne P.R.C. Separation of human breast cancer cells from blood by differential dielectric affinity. Proc. Natl. Acad. Sci. U.S.A. 92 (1995) 860-864
8. Ozkan M., Pisanic T., Scheel J., Barlow C., Esener S., and Bhatia S.N. Electro-optical platform for manipulation of live cells. Langmuir 19 (2003) 1532-1538
9. Flanagan L.A., Lu J., Wang L., Marchenko S.A., Jeon N.L., Lee A.P., and Monuki E.S. Unique dielectric properties distinguish stem cells and their differentiated progeny. Stem Cells 26 (2008) 656-665
10. Matsumoto N., Matsue T., and Uchida I. Paired cell alignment using a jagged microarray electrode. Bioelectrochem. Bioenergetics 34 (1994) 199-202
11. Matsue T., Matsumoto N., and Uchida I. Rapid micropatterning of living cells by repulsive dielectrophoretic force. Electrochim. Acta 42 (1997) 3251-3256
12. Suzuki M., Yasukawa T., Mase Y., Oyamatsu D., Shiku H., and Matsue T. Dielectrophoretic micropatterning with microparticle monolayers covalently linked to glass surfaces. Langmuir 20 (2004) 11005-11011
13. Suzuki M., Yasukawa T., Shiku H., and Matsue T. Negative dielectrophoretic patterning with colloidal particles and encapsulation into a hydrogel. Langmuir 23 (2007) 4088-4094
14. Yasukawa T., Suzuki M., Sekiya T., Shiku H., and Matsue T. Flow sandwich-type immunoassay in microfluidic devices based on negative dielectrophoresis. Biosens. Bioelectron. 22 (2007) 2730-2736
15. Lee H.J., Yasukawa T., Suzuki M., Taki Y., Tanaka A., Kameyama M., Shiku H., and Matsue T. Rapid fabrication of nanoparticles array on polycarbonate membrane based on positive dielectrophoresis. Sens. Actuators B 131 (2008) 424-431
16. Lee H.J., Yasukawa T., Suzuki M., Lee S.H., Yao T., Taki Y., Tanaka A., Kameyama M., Shiku H., and Matsue T. Simple and rapid preparation of vertically aligned gold nanoparticle arrays and fused nanorods in pores of alumina membrane based on positive dielectrophoresis. Sens. Actuators B 136 (2009) 320-325 10.1016/j.snb.2008.12.054
17. Lee H.J., Yasukawa T., Shiku H., and Matsue T. Rapid and separation-free sandwich immunosensing based on accumulation of microbeads by negative-dielectrophoresis. Biosens. Bioelectron. 24 (2008) 1000-1005 10.1016/j.bios.2008.08.002
18. Suzuki M., Yasukawa T., Shiku H., and Matsue T. Nagative dielectrophoretic patterning with different cell types. Biosens. Bioelectron. 24 (2008) 1043-1047 10.1016/j.bios.2008.06.051
19. Ramón-Azcón J., Kunikata R., Sanchez F.-J., Marco M.-P., Shiku H., Yasukawa T., and Matsue T. Detection of pesticide residues using an immunodevice based on negative dielectrophoresis. Biosens. Bioelectron. 24 (2009) 1592-1597 10.1016/j.bios.2008.08.035
20. Taff B.M., and Voldman J. A scalable addressable positive-dielectrophoretic cell-sorting array. Anal. Chem. 77 (2005) 7976-7983
21. Mittal N., Rosenthal A., and Voldman J. nDEP microwells for single-cell patterning in physiological media. Lab Chip 7 (2007) 1146-1153
22. Fuchs B., Romani A., Freida D., Medoro G., Abonnec M., Altomare L., Chartier I., Guergour D., Villiers C., Marche P.N., Tartagni M., Guerrieri R., Chatelain F., and Manaresi N. Electronic sorting and recovery of single live sells from microlitre sized samples. Lab Chip 6 (2006) 121-126
23. Hunt T.P., Issadore D., and Westervelt R.M. Integrated circuit/microfluidic chip to programmably trap and move cells and droplets with dielectrophoresis. Lab Chip 8 (2008) 81-87
24. Hermes T., Buhner M., Bucher S., Sundermeier S., Dumschat C., Borchardt M., Cammann K., and Knoll M. An amperometric microsensor array 1024 individually addressable elements for two-dimensional concentration mapping. Sens. Actuators B 21 (1994) 33-37
25. Kakerow R., Manoli Y., Mokwa W., Rospert M., Meyer H., Drewer H., Krause J., and Cammann K. A monolithic sensor array of individually addressable microelectrodes. Sens. Actuators A 43 (1994) 296-301
26. Lin Z.Y., Takahashi Y., Kitagawa Y., Umemura T., Shiku H., and Matsue T. An addressable microelectrode array for electrochemical detection. Anal. Chem. 80 (2008) 6830-6833
27. Lin Z.Y., Takahashi Y., Murata T., Takeda M., Ino K., Shiku H., and Matsue T. Electrochemical gene-function analysis for single cells with addressable microelectrode/microwell arrays. Angew. Chem. Int. Ed. 48 (2009) 2044-2046
28. Yasukawa T., Nagamine K., Horiguchi Y., Shiku H., Koide M., Itayama T., Shiraishi F., and Matsue T. Electrophoretic cell manipulation and electrochemical gene-function analysis based on a yeast two-hybrid system in a microfluidic device. Anal. Chem. 80 (2008) 3722-3727
29. Chang C.-Y., Murata T., Takahashi Y., Shiku H., Chang H.-C., and Matsue T. Entrapment and measurement of a biologically functionalized microbead with a microwell electrode. Lab Chip 9 (2009) 1185-1192
30. Rees N.V., Matthews S.M., Yunus K., Fisher A.C., and Compton R.G. A method for the positioning and tracking of small moving particles. Angew. Chem. Int. Ed. 48 (2009) 2376-2378