Single cell and neural process experimentation using laterally applied electrical fields between pairs of closely apposed microelectrodes with vertical sidewalls

Biosensors and Bioelectronics

Volumn 24, Issue 12, 2009, Pages 3600-3607

  Chang, Wesley C ^a   Sretavan, David W ^a  

^a UNIVERSITY OF CALIFORNIA   (United States)

Author keywords

Axon; Electrodes with vertical sidewalls; Electroporation; Field stimulation; Microelectrode array; Neurons

Indexed keywords

ACTION POTENTIALS; AXON; BIOMEDICAL RESEARCH; CALCIUM INDICATOR; ELECTRICAL FIELD; ELECTRODE CONFIGURATIONS; ELECTROPORATION; FIELD STIMULATION; FINITE ELEMENT MODELING; GOLD ELECTROPLATING; GREEN FLUORESCENT PROTEIN; HIGH-CONTENT; HIGH-THROUGHPUT; IN-BETWEEN; INDIVIDUAL CELLS; MICROELECTRODE ARRAY; MICROSCALE DEVICES; NEURAL PROCESS; NEW TOOLS; SINGLE CELLS; SMALL SCALE; SU-8 PHOTORESIST; SUBCELLULAR STRUCTURE; TRANSGENE;

CALCIUM; CALCIUM ALLOYS; EXPERIMENTS; FLUORESCENCE; NEURONS; NUCLEIC ACIDS; PHOTORESISTS; QUENCHING; SURFACE DEFECTS;

MICROELECTRODES;

CALCIUM; EGTAZIC ACID; GREEN FLUORESCENT PROTEIN;

ACCURACY; ANIMAL CELL; ANIMAL TISSUE; ARTICLE; CONTROLLED STUDY; CYTOPLASM; ELECTRIC FIELD; ELECTROPORATION; EMBRYO; FINITE ELEMENT ANALYSIS; FLUORESCENCE ANALYSIS; GENE EXPRESSION; INTERMETHOD COMPARISON; MICROELECTRODE; MOUSE; NERVE CELL MEMBRANE POTENTIAL; NONHUMAN; SIMULATION; TRANSGENE; VERTICAL SIDEWALL;

ANIMALS; CELL SEPARATION; CELLS, CULTURED; ELECTRIC STIMULATION; ELECTROMAGNETIC FIELDS; ELECTROPORATION; EQUIPMENT DESIGN; EQUIPMENT FAILURE ANALYSIS; MICE; MICROELECTRODES; MICROMANIPULATION; NEURONS;

EID: 67650034492     PISSN: 09565663     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.bios.2009.05.024     Document Type: Article

References (37)

1. Albrecht D.R., Sah R.L., and Bhatia S.N. Biophys. J. 87 4 (2004) 2131-2147
2. Andersson H., and van den Berg A. Curr. Opin. Biotechnol. 15 1 (2004) 44-49
3. Barbier V., Tatoulian M., Li H., Arefi-Khonsari F., Ajdari A., and Tabeling P. Langmuir 22 12 (2006) 5230-5232
4. Brewer G.J., Torricelli J.R., Evege E.K., and Price P.J. J. Neurosci. Res. 35 5 (1993) 567-576
5. Chang D.C., Chassy B.M., Saunders J.A., and Sowers A. Guide to Electroporation and Electrofusion (1992), Academic Press, Inc.
6. Chang J.C., and Wheeler B.C. Pattern Technologies for Structuring Neuronal Networks on MEAs. Advances in Network Electrophysiology (2006), Springer, US pp. 153-192
7. Chang W.C., and Sretavan D.W. Langmuir 24 22 (2008) 13048-13057
8. Coleman M.P., and Perry V.H. Trends Neurosci. 25 10 (2002) 532-537
9. Djurisic M., Zochowski M., Wachowiak M., Falk C.X., Cohen L.B., and Zecevic D. Methods Enzymol. 361 (2003) 423-451
10. Fox M.B., Esveld D.C., Valero A., Luttge R., Mastwijk H.C., Bartels P.V., van den Berg A., and Boom R.M. Anal. Bioanal. Chem. 385 3 (2006) 474-485
11. Gascoyne P.R., and Vykoukal J. Electrophoresis 23 13 (2002) 1973-1983
12. Gross M., Altpeter D., Steiglitz T., Schuettler M., and Meyer J.-U. Sens. Actuators A 96 (2002) 105-110
13. Heuschkel M.O., Wirth C., Steidl E., and Buissson B. In: Taketani M., and Baudry M. (Eds). Advances in Network Electrophysiology (2006), Springer, US 69-111
14. Huang K.S., Lin Y.C., Su C.C., and Fang C.S. Lab Chip 7 1 (2007) 86-92
15. Jain T., and Muthuswamy J. Biosens. Bioelectron. 22 6 (2007) 863-870
16. Kaech S., and Banker G. Nat. Protoc. 1 5 (2006) 2406-2415
17. Kamiguchi H., and Lemmon V. J. Neurosci. Res. 49 1 (1997) 1-8
18. Lee E.S., Robinson D., Rognlien J.L., Harnett C.K., Simmons B.A., Bowe Ellis C.R., and Davalos R.V. Bioelectrochemistry 69 1 (2006) 117-125
19. Lin Y.C., Li M., and Wu C.C. Lab Chip 4 2 (2004) 104-108
20. Loew L.M., Cohen L.B., Dix J., Fluhler E.N., Montana V., Salama G., and Wu J.Y. J. Membr. Biol. 130 1 (1992) 1-10
21. Lundqvist J.A., Sahlin F., Aberg M.A., Stromberg A., Eriksson P.S., and Orwar O. Proc. Natl. Acad. Sci. U.S.A. 95 18 (1998) 10356-10360
22. Olofsson J., Nolkrantz K., Ryttsen F., Lambie B.A., Weber S.G., and Orwar O. Curr. Opin. Biotechnol. 14 1 (2003) 29-34
23. Pearce T.M., and Williams J.C. Lab Chip 7 1 (2007) 30-40
24. Pine J. In: Taketani M., and Baudry M. (Eds). Advances in Network Electrophysiology (2006), Springer, US 3-23
25. Rajaraman S., Choi S.-O., Shafer R.H., Ross J.D., Vukasinovic J., Choi Y., DeWeerth S.P., Glezer A., and Allen M.G. J. Micromech. Microeng. 17 (2007) 163-171
26. Ravula S.K., McClain M.A., Wang M.S., Glass J.D., and Frazier A.B. Lab Chip 6 12 (2006) 1530-1536
27. Song I., and Ajmera P.K. J. Micromech. Microeng. 13 (2003) 816-821
28. Stett A., Egert U., Guenther E., Hofmann F., Meyer T., Nisch W., and Haemmerle H. Anal. Bioanal. Chem. 377 3 (2003) 486-495
29. Suh L.H., Oster S.F., Soehrman S.S., Grenningloh G., and Sretavan D.W. J. Neurosci. 24 8 (2004) 1976-1986
30. Taketani M., and Baudry M. Advances in Network Electrophysiology (2006), Springer, US
31. Teruel M.N., Blanpied T.A., Shen K., Augustine G.J., and Meyer T. J. Neurosci. Methods 93 1 (1999) 37-48
32. Teruel M.N., and Meyer T. Biophys. J. 73 4 (1997) 1785-1796
33. Thiebaud P., de Rooij N.F., Koudelka-Hep M., and Stoppini L. IEEE Trans. Biomed. Eng. 44 11 (1997) 1159-1163
34. Voldman, J., 2001. A Microfabricated Dielectrophoretic Trapping Array for Cell-based Biological Assays (Ph.D. thesis). Electrical Engineering and Computer Science. Massachusetts Institute of Technology, Cambridge, MA, p. 86.
35. Voldman J., Gray M.L., Toner M., and Schmidt M.A. Anal. Chem. 74 16 (2002) 3984-3990
36. Wang L., Flanagan L.A., Jeon N.L., Monuki E., and Lee A.P. J. Microelectromech. Syst. 16 2 (2007) 454-461
37. Yuan T.F. Cytotechnology 54 2 (2007) 71-76