Bioelectrodes modified with chitosan for long-term energy supply from the body

A 3D nanofibrous network of compressed chitosan in the presence of genipin as the cross-linker, carbon nanotubes and laccase constitutes a new design to enhance the stability and the biocompatibility of biocathodes. The in vitro delivered current was around −0.3 mA mL −1 for 20 days under continuous...

Full description

Saved in:
Bibliographic Details
Published in:Energy & environmental science 2015-03, Vol.8 (3), p.117-126
Main Authors: El Ichi, S, Zebda, A, Alcaraz, J.-P, Laaroussi, A, Boucher, F, Boutonnat, J, Reverdy-Bruas, N, Chaussy, D, Belgacem, M. N, Cinquin, P, Martin, D. K
Format: Article
Language:English
Subjects:
Biocompatibility
Biotechnology
Chitosan
Crosslinking
Enzymes
Genipin
Implantation
Life Sciences
Nanostructure
Networks
Three dimensional
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:A 3D nanofibrous network of compressed chitosan in the presence of genipin as the cross-linker, carbon nanotubes and laccase constitutes a new design to enhance the stability and the biocompatibility of biocathodes. The in vitro delivered current was around −0.3 mA mL −1 for 20 days under continuous discharge. A thin film made of chitosan cross-linked with genipin was synthesized and optimized for oxygen and glucose diffusion. This film was used as a biocompatible barrier on the surface of biocathodes implanted in rats. The biocathodes remained operational after 167 days in vivo . This biocathode design minimised the inflammatory response in the first two weeks after implantation. After several months, the growth of macrophages was observed. The electrical connection and the catalytic activity of the enzyme entrapped into the biocathode were demonstrated after almost 6 months of implantation by the ex vivo measurement of the OCP (0.45 V to 0.48 V) and the delivered current (−0.6 mA mL −1 ) under optimal conditions. We demonstrate that the use of a Chit-MWCNT matrix, fabricated by mechanical compression, allows construction of a biocompatible enzymatic biocathode which remains operational after more than five months in vivo (retaining 50% of its initial electrocatalytic activity).
ISSN:1754-5692
1754-5706
DOI:10.1039/c4ee03430a