posted on 2014-12-24, 00:00authored byF. Lamberti, L. Brigo, M. Favaro, C. Luni, A. Zoso, M. Cattelan, S. Agnoli, G. Brusatin, G. Granozzi, M. Giomo, N. Elvassore
Both
optical and electrochemical graphene-based sensors have gone through
rapid development, reaching high sensitivity at low cost and with
fast response time. However, the complex validating biochemical operations,
needed for their consistent use, currently limits their effective
application. We propose an integration strategy for optoelectrochemical
detection that overcomes previous limitations of these sensors used
separately. We develop an optoelectrochemical sensor for aptamer-mediated
protein detection based on few-layer graphene immobilization on selectively
modified fluorine-doped tin oxide (FTO) substrates. Our results show
that the electrochemical properties of graphene-modified FTO samples
are suitable for complex biological detection due to the stability
and inertness of the engineered electrodic interface. In addition,
few-layer immobilization of graphene sheets through electrostatic
linkage with an electrochemically grafted FTO surface allows obtaining
an optically accessible and highly conductive platform. As a proof
of concept, we used insulin as the target molecule to reveal in solution.
Because of its transparency and low sampling volume (a few microliters),
our sensing unit can be easily integrated in lab-on-a-chip cell culture
systems for effectively monitoring subnanomolar concentrations of
proteins relevant for biomedical applications.