Gerhard J. Mohr scite author profile

A new class of dyes has been investigated that reversibly interacts with aliphatic amines, resulting in changes in absorbance or fluorescence. These dyes, which combine the properties of both a chemical reagent and a ligand, are termed "reactands". When embedded in plasticized PVC membranes, the reactand 4-(N,N-dioctylamino)-4′trifluoroacetylazobenzene (ETH T 4001) shows a significant signal change on exposure to aqueous amine solutions, with a decrease in absorbance around 490 nm and an increase in absorbance around 420 nm wavelength. This change in absorbance is caused by a conversion of the trifluoroacetyl group of the reactand into a hemiaminal or a zwitterion. Upon interaction with 1-butylamine, the sensor layer exhibits a dynamic range from 1 to 100 mM 1-butylamine, with maximum relative signal changes of 90%. The limit of detection with this approach is 0.3 mM. The forward response time (t 95 ) for a decade change in activity is 10 min, and the reverse response time is 5 min. The selectivity of ETH T 4001 toward amines correlates with the lipophilicity of the amines in plasticized PVC. Sterical factors additionally affect selectivity in that the reactions of secondary, tertiary, and bulky primary amines with the trifluoroacetyl group are hindered. A similar response is observed for the fluorescent reactand 4-(N,Ndioctylamino)-4′-trifluoroacetylstilbene (ETH T 4004). When this reactand is exposed to 1-butylamine, a decrease in fluorescence around 580 nm is observed, which can be as high as 90% of the total fluorescence intensity. To prevent interferences from ions and ambient light, the sensor layer is coated with a protective layer of microporous white PTFE.

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Biocompatible fluorescent nanoparticles for pH-sensoring

Hornig

Biskup

Gräfe

et al. 2008

Soft Matter

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On the Design of Fluorescent Ratiometric Nanosensors

Doussineau¹,

Schulz²,

Lapresta-Fernández³

et al. 2010

Chemistry A European J

107

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Advances in nanoparticle technology have recently offered new tools to the bioanalytical field of research. In particular, new nanoparticle‐based sensors have appeared able to give quantitative information about different species (ions, metabolites, biomolecules) in biosamples through ratiometric measurements. This article describes the methodologies developed so far in the design of such nanosensors. In particular, the different approaches to immobilize fluorescent chemosensor dyes to nanoparticles are presented. Concept designs of ratiometric nanosensors in terms of composition and architecture are also described and illustrated with examples taken from the literature.

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An ATP fluorescent chemosensor based on a Zn(ii)-complexed dipicolylaminereceptor coupled with a naphthalimidechromophore

et al. 2010

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Gerhard J. Mohr

Application of Chromogenic and Fluorogenic Reactands in the Optical Sensing of Dissolved Aliphatic Amines

Biocompatible fluorescent nanoparticles for pH-sensoring

On the Design of Fluorescent Ratiometric Nanosensors

An ATP fluorescent chemosensor based on a Zn(ii)-complexed dipicolylaminereceptor coupled with a naphthalimidechromophore

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