Issue 1, 2011

Absorption into fluorescence. A method to sense biologically relevant gas molecules

Abstract

In this work we present an innovative optical sensing methodology based on the use of biomolecules as molecular gating nano-systems. Here, as an example, we report on the detection of analytes related to climate change. In particular, we focused our attention on the detection of nitric oxide (NO) and oxygen (O2). Our methodology builds on the possibility of modulating the excitation intensity of a fluorescent probe used as a transducer and a sensor molecule whose absorption is strongly affected by the binding of an analyte of interest used as a filter. The two simple conditions that have to be fulfilled for the method to work are: (a) the absorption spectrum of the sensor placed inside the cuvette, and acting as the recognition element for the analyte of interest, should strongly change upon the binding of the analyte and (b) the fluorescence dye transducer should exhibit an excitation band which overlaps with one or more absorption bands of the sensor. The absorption band of the sensor affected by the binding of the specific analyte should overlap with the excitation band of the transducer. The high sensitivity of fluorescence detection combined with the use of proteins as highly selective sensors makes this method a powerful basis for the development of a new generation of analytical assays. Proof-of-principle results showing that cytochrome c peroxidase (CcP) for NO detection and myoglobin (Mb) for O2 detection can be successfully used by exploiting our new methodology are reported. The proposed technology can be easily expanded to the determination of different target analytes.

Graphical abstract: Absorption into fluorescence. A method to sense biologically relevant gas molecules

Article information

Article type
Paper
Submitted
09 Sep 2010
Accepted
06 Oct 2010
First published
09 Nov 2010

Nanoscale, 2011,3, 298-302

Absorption into fluorescence. A method to sense biologically relevant gas molecules

M. Strianese, A. Varriale, M. Staiano, C. Pellecchia and S. D'Auria, Nanoscale, 2011, 3, 298 DOI: 10.1039/C0NR00661K

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