Living electrodes: Tissue engineering the neural interface

Author

Green, Rylie A. ; Lim, Ka Sing ; Henderson, William C. ; Hassarati, Rachelle T. ; Martens, Penny J. ; Lovell, Nigel H. ; Poole-Warren, Laura A.

Author_Institution

Grad. Sch. of Biomed. Eng., Univ. of New South Wales, Sydney, NSW, Australia

fYear

2013

fDate

3-7 July 2013

Firstpage

6957

Lastpage

6960

Abstract

Soft, cell integrated electrode coatings are proposed to address the problem of scar tissue encapsulation of stimulating neuroprosthetics. The aim of these studies was to prove the concept and feasibility of integrating a cell loaded hydrogel with existing electrode coating technologies. Layered conductive hydrogel constructs are embedded with neural cells and shown to both support cell growth and maintain electro activity. The safe charge injection limit of these electrodes was 8 times higher than conventional platinum (Pt) electrodes and the stiffness was four orders of magnitude lower than Pt. Future studies will determine the biological cues required to support stem cell differentiation from the electrode surface.

Keywords

bioelectric phenomena; biological tissues; biomedical electrodes; biomedical materials; cellular biophysics; coating techniques; elasticity; hydrogels; tissue engineering; cell growth; charge injection limit; conductive hydrogel construct; electroactivity; electrode coating technology; neural cell interface; neuroprosthetic stimulation; scar tissue encapsulation; stem cell differentiation; stiffness; tissue engineering; Biology; Charge transfer; Coatings; Electrodes; Impedance; Polymers;

fLanguage

English

Publisher

ieee

Conference_Titel

Engineering in Medicine and Biology Society (EMBC), 2013 35th Annual International Conference of the IEEE

Conference_Location

Osaka

ISSN

1557-170X

Type

conf

DOI

10.1109/EMBC.2013.6611158

Filename

6611158