Release of bioactive volatiles from supramolecular hydrogels: influence of reversible acylhydrazone formation on gel stability and volatile compound evaporation

In the presence of alkali metal cations, guanosine-5'-hydrazide (1) forms stable supramolecular hydrogels by selective self-assembly into a G-quartet structure. Besides being physically trapped inside the gel structure, biologically active aldehydes or ketones can also reversibly react with the...

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Veröffentlicht in:	Organic & biomolecular chemistry 2011-01, Vol.9 (8), p.2906-2919
Hauptverfasser:	Buchs, Barbara, Fieber, Wolfgang, Vigouroux-Elie, Florence, Sreenivasachary, Nampally, Lehn, Jean-Marie, Herrmann, Andreas
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Sprache:	eng
Schlagworte:	Acylation Chemical Sciences Hydrazones - chemistry Hydrogels - chemistry Molecular Structure Thermodynamics Volatilization
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container_title	Organic & biomolecular chemistry
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creator	Buchs, Barbara Fieber, Wolfgang Vigouroux-Elie, Florence Sreenivasachary, Nampally Lehn, Jean-Marie Herrmann, Andreas
description	In the presence of alkali metal cations, guanosine-5'-hydrazide (1) forms stable supramolecular hydrogels by selective self-assembly into a G-quartet structure. Besides being physically trapped inside the gel structure, biologically active aldehydes or ketones can also reversibly react with the free hydrazide functions at the periphery of the G-quartet to form acylhydrazones. This particularity makes the hydrogels interesting as delivery systems for the slow release of bioactive carbonyl derivatives. Hydrogels formed from 1 were found to be significantly more stable than those obtained from guanosine. Both physical inclusion of bioactive volatiles and reversible hydrazone formation could be demonstrated by indirect methods. Gel stabilities were measured by oscillating disk rheology measurements, which showed that thermodynamic equilibration of the gel is slow and requires several cooling and heating cycles. Furthermore, combining the rheology data with dynamic headspace analysis of fragrance evaporation suggested that reversible hydrazone formation of some carbonyl compounds influences the release of volatiles, whereas the absolute stability of the gel seemed to have no influence on the evaporation rates.
doi_str_mv	10.1039/c0ob01139h
format	Article
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source	MEDLINE; Royal Society Of Chemistry Journals 2008-; Alma/SFX Local Collection
subjects	Acylation Chemical Sciences Hydrazones - chemistry Hydrogels - chemistry Molecular Structure Thermodynamics Volatilization
title	Release of bioactive volatiles from supramolecular hydrogels: influence of reversible acylhydrazone formation on gel stability and volatile compound evaporation
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