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Vesicular perylene dye nanocapsules as supramolecular fluorescent pH sensor systems
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Vesicular perylene dye nanocapsules as supramolecular fluorescent pH sensor systems
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Vesicular perylene dye nanocapsules as supramolecular fluorescent pH sensor systems
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Journal Article
Vesicular perylene dye nanocapsules as supramolecular fluorescent pH sensor systems
2009
Overview
Water-soluble, self-assembled nanocapsules composed of a functional bilayer membrane and enclosed guest molecules can provide smart (that is, condition responsive) sensors for a variety of purposes. Owing to their outstanding optical and redox properties, perylene bisimide chromophores are interesting building blocks for a functional bilayer membrane in a water environment. Here, we report water-soluble perylene bisimide vesicles loaded with bispyrene-based energy donors in their aqueous interior. These loaded vesicles are stabilized by
in situ
photopolymerization to give nanocapsules that are stable over the entire aqueous pH range. On the basis of pH-tunable spectral overlap of donors and acceptors, the donor-loaded polymerized vesicles display pH-dependent fluorescence resonance energy transfer from the encapsulated donors to the bilayer dye membrane, providing ultrasensitive pH information on their aqueous environment with fluorescence colour changes covering the whole visible light range. At pH 9.0, quite exceptional white fluorescence could be observed for such water-soluble donor-loaded perylene vesicles.
Artificial vesicles consisting of encapsulated fluorescence resonance energy transfer (FRET)-donor molecules and a FRET-acceptor bilayer dye-membrane provide ultrasensitive pH information in aqueous media by displaying pH-dependent fluorescence colour covering the entire visible light range. An exceptional white fluorescence was observed at pH 9.
Publisher
Nature Publishing Group UK,Nature Publishing Group
