Electrical stimulation using conductive polymer polypyrrole promotes differentiation of human neural stem cells: A biocompatible platform for translational neural tissue engineering

Tissue Engineering - Part C: Methods

Volumn 21, Issue 4, 2015, Pages 385-393

  Stewart, Elise ^a   Kobayashi, Nao R ^a   Higgins, Michael J ^a   Quigley, Anita F ^a   Jamali, Sina ^a   Moulton, Simon E ^a   Kapsa, Robert M I ^a,b   Wallace, Gordon G ^a   Crook, Jeremy M ^a,b  

^a UNIVERSITY OF WOLLONGONG   (Australia)

^b UNIVERSITY OF MELBOURNE   (Australia)

Author keywords

[No Author keywords available]

Indexed keywords

BIOCOMPATIBILITY; CELL ENGINEERING; CONDUCTIVE MATERIALS; NEURONS; ORGANIC POLYMERS; POLYMERS; POLYPYRROLES; STEM CELLS; TISSUE; TISSUE ENGINEERING; TRANSLATION (LANGUAGES);

CONDUCTIVE POLYMER; DODECYLBENZENESULFONATE; ELECTRICAL STIMULATIONS; GLIAL FIBRILLARY ACIDIC PROTEINS; IMPLANTABLE ELECTRODES; NEURAL TISSUE ENGINEERING; ORGANIC MATERIALS; REGENERATIVE MEDICINE;

SCAFFOLDS (BIOLOGY);

BETA TUBULIN; CONDUCTIVE POLYMER; DODECYLBENZENESULFONIC ACID; GLIAL FIBRILLARY ACIDIC PROTEIN; POLYMER; POLYPYRROLE; UNCLASSIFIED DRUG; DIFFERENTIATION ANTIGEN; PYRROLE DERIVATIVE;

ARTICLE; BRAIN TISSUE; CELL DIFFERENTIATION; CONDUCTANCE; DRUG DEVELOPMENT; ELECTROSTIMULATION; GLIA CELL; HUMAN; HUMAN CELL; NERVE CELL; NERVOUS TISSUE; NEURAL STEM CELL; NEURITE; PRIORITY JOURNAL; REGENERATIVE MEDICINE; SCANNING ELECTRON MICROSCOPY; TISSUE ENGINEERING; CHEMISTRY; CYTOLOGY; METABOLISM; PLURIPOTENT STEM CELL; TRANSLATIONAL RESEARCH;

ANTIGENS, DIFFERENTIATION; CELL DIFFERENTIATION; ELECTRIC STIMULATION; HUMANS; INDUCED PLURIPOTENT STEM CELLS; NEURAL STEM CELLS; NEURONS; POLYMERS; PYRROLES; TISSUE ENGINEERING; TRANSLATIONAL MEDICAL RESEARCH;

EID: 84926459284     PISSN: 19373384     EISSN: 19373392     Source Type: Journal    
DOI: 10.1089/ten.tec.2014.0338     Document Type: Article

References (31)

1. Srivastava, N., Venugopalan, V., Divya, M.S., Rasheed, V.A., James, J., and Narayan, K.S. Neuronal differentiation of embryonic stem cell derived neuronal progenitors can be regulated by stretchable conducting polymers. Tissue Eng Part A 19, 1984, 2013.
2. Yamada, M., Tanemura, K., Okada, S., Iwanami, A., Nakamura, M., Mizuno, H., Ozawa, M., Ohyama-Goto, R., Kitamura, N., Kawano, M., Tan-Takeuchi, K., Ohtsuka, C., Miyawaki, A., Takashima, A., Ogawa, M., Toyama, Y., Okano, H., and Kondo, T. Electrical stimulation modulates fate determination of differentiating embryonic stem cells. Stem Cells 25, 562, 2007.
3. Mycielska, M.E., and Djamgoz, M.B. Cellular mechanisms of direct-current electric field effects: galvanotaxis and metastatic disease. J Cell Sci 117, 1631, 2004.
4. Zhao, M. Electrical fields in wound healing-An overriding signal that directs cell migration. Semin Cell Dev Biol 20, 674, 2009.
5. Cameron, I.L., Hardman, W.E., Winters, W.D., Zimmerman, S., and Zimmerman, A.M. Environmental magnetic fields: influences on early embryogenesis. J Cell Biochem 51, 417, 1993.
6. Robinson, K.R. The responses of cells to electrical fields: a review. J Cell Biol 101, 2023, 1985.
7. Herland, A., Persson, K.M., Lundin, V., Fahlman, M., Berggren, M., Jager, E.W., and Teixeira, A.I. Electrochemical control of growth factor presentation to steer neural stem cell differentiation. Angew Chem 50, 12529, 2011.
8. Lundin, V., Herland, A., Berggren, M., Jager, E.W., and Teixeira, A.I. Control of neural stem cell survival by electroactive polymer substrates. PLoS One 6, e18624, 2011.
9. Zhang, L., Stauffer, W.R., Jane, E.P., Sammak, P.J., and Cui, X.T. Enhanced differentiation of embryonic and neural stem cells to neuronal fates on laminin peptides doped polypyrrole. Macromol Biosci 10, 1456, 2010.
10. Collier, J.H., Camp, J.P., Hudson, T.W., and Schmidt, C.E. Synthesis and characterization of polypyrrole-hyaluronic acid composite biomaterials for tissue engineering applications. J Biomed Mater Res 50, 574, 2000.
11. Garner, B., Georgevich, A., Hodgson, A.J., Liu, L., and Wallace, G.G. Polypyrrole-heparin composites as stimulusresponsive substrates for endothelial cell growth. J Biomed Mater Res 44, 121, 1999.
12. Richardson, R.T., Thompson, B., Moulton, S., Newbold, C., Lum, M.G., Cameron, A., Wallace, G., Kapsa, R., Clark, G., and O'Leary, S. The effect of polypyrrole with incorporated neurotrophin-3 on the promotion of neurite outgrowth from auditory neurons. Biomaterials 28, 513, 2007.
13. Arca, M., Mirkin, M.V., and Bard, A.J. Polymer films on electrodes. 26. Study of ion transport and electron transfer at polypyrrole films by scanning electrochemical microscopy. J Phys Chem 99, 5040, 1995.
14. Kranz, C., Wittstock, G., Wohlschläger, H., and Schuhmann, W. Imaging of microstructured biochemically active surfaces by means of scanning electrochemical microscopy. Electrochim Acta 42, 3105, 1997.
15. Engler, A.J., Sen, S., Sweeney, H.L., and Discher, D.E. Matrix elasticity directs stem cell lineage specification. Cell 126, 677, 2006.
16. Discher, D.E., Janmey, P., and Wang, Y.L. Tissue cells feel and respond to the stiffness of their substrate. Science 310, 1139, 2005.
17. Spatz, J.P., and Geiger, B. Molecular engineering of cellular environments: cell adhesion to nano-digital surfaces. Methods Cell Biol 83, 89, 2007.
18. Vogel, V., and Sheetz, M. Local force and geometry sensing regulate cell functions. Nat Rev Mol Cell Biol 7, 265, 2006.
19. Ohgaki, M., Kizuki, T., Katsura, M., and Yamashita, K. Manipulation of selective cell adhesion and growth by surface charges of electrically polarized hydroxyapatite. J Biomed Mater Res 57, 366, 2001.
20. Xu, Y., Takai, M., and Ishihara, K. Protein adsorption and cell adhesion on cationic, neutral, and anionic 2-methacryloyloxyethyl phosphorylcholine copolymer surfaces. Biomaterials 30, 4930, 2009.
21. Velzenberger, E., El Kirat, K., Legeay, G., Nagel, M.D., and Pezron, I. Characterization of biomaterials polar interactions in physiological conditions using liquidliquid contact angle measurements: relation to fibronectin adsorption. Colloids Surf B Biointerfaces 68, 238, 2009.
22. Wei, J., Igarashi, T., Okumori, N., Maetani, T., Liu, B., and Yoshinari, M. Influence of surface wettability on competitive protein adsorption and initial attachment of osteoblasts. Biomed Mater 4, 045002, 2009.
23. Thompson, B.C., Moulton, S.E., Ding, J., Richardson, R., Cameron, A., O'Leary, S., Wallace, G.G., and Clark, G.M. Optimising the incorporation and release of a neurotrophic factor using conducting polypyrrole. J Control Release 116, 285, 2006.
24. Forch, R., Schonherr, H., and Jenkins, A.T.A. Contact angle ganiometry. In: Forch, R., Schonherr, H., and Jenkins, A.T.A., eds. Surface Design: Applications in Bioscience and Nanotechnology. Weinheim, Germany: Wiley-VCH, 2009, p. 471.
25. Kobayashi, N.R., Sui, L., Tan, P.S., Lim, E.K., Chan, J., Choolani, M., and Crook, J.M. Modelling disruptedin-schizophrenia 1 loss of function in human neural progenitor cells: tools for molecular studies of human neurodevelopment and neuropsychiatric disorders. Mol Psychiatry 15, 672, 2010.
26. Barisci, J.N., Stella, R., Spinks, G.M., and Wallace, G.G. Characterisation of the topography and surface potential of electrodeposited conducting polymer films using atomic force and electric force microscopies. Electrochim Acta 46, 519, 2000.
27. Fonner, J.M., Forciniti, L., Nguyen, H., Byrne, J.D., Kou, Y.F., Syeda-Nawaz, J., and Schmidt, C.E. Biocompatibility implications of polypyrrole synthesis techniques. Biomed Mater 3, 034124, 2008.
28. Azevedo, F.A., Carvalho, L.R., Grinberg, L.T., Farfel, J.M., Ferretti, R.E., Leite, R.E., Jacob Filho, W., Lent, R., and Herculano-Houzel, S. Equal numbers of neuronal and nonneuronal cells make the human brain an isometrically scaled-up primate brain. J Comp Neurol 513, 532, 2009.
29. Jun, S.B., Hynd, M.R., Smith, K.L., Song, J.K., Turner, J.N., Shain, W., and Kim, S.J. Electrical stimulationinduced cell clustering in cultured neural networks. Med Biol Eng Comput 45, 1015, 2007.
30. Gelmi, A., Higgins, M.J., and Wallace, G.G. Quantifying fibronectin adhesion with nanoscale spatial resolution on glycosaminoglycan doped polypyrrole using Atomic Force Microscopy. Biochim Biophys Acta 1830, 4305, 2013.
31. Donato, R., Miljan, E.A., Hines, S.J., Aouabdi, S., Pollock, K., Patel, S., Edwards, F.A., and Sinden, J.D. Differential development of neuronal physiological responsiveness in two human neural stem cell lines. BMC Neurosci 8, 36, 2007.