15658-59-0Relevant academic research and scientific papers
Pyridine-2,6-dihydroxamic acid, a powerful dihydroxamate ligand for Ni2+ and Cu2+ ions
Swiatek-Kozlowska, Jolanta,Gumienna-Kontecka, Elzbieta,Dobosz, Agnieszka,Golenya, Irina A.,Fritsky, Igor O.
, p. 4639 - 4643 (2002)
Pyridine-2,6-dihydroxamic acid was found to be the most effective ligand for Ni2+ and Cu2+ ions among the known dihydroxamates. The stability constants of the title complexes are many orders of magnitude higher than those obtained for the other dihydroxamates. Only equimolar species are formed with Cu2+ ions, while NiL and bis-complexes are formed in the case of Ni2+. The [NIL2]2- complex anion contains compressed octahedral hexanitrogen surroundings of two meridionally coordinated ligands. The equatorial Ni-N(Py) bonds are significantly shorter than the axial Ni-N(hydroxamate) distances although the latter are formed by the deprotonated groups.
A HTS assay for the detection of organophosphorus nerve agent scavengers
Louise-Leriche, Ludivine,Paunescu, Emilia,Saint-Andre, Geraldine,Baati, Rachid,Romieu, Anthony,Wagner, Alain,Renard, Pierre-Yves
experimental part, p. 3510 - 3523 (2010/07/06)
A new pro-fluorescent probe aimed at a HTS assay of scavengers is able to selectively and efficiently cleave the P-S bond of organophosphorus nerve agents and by this provides non-toxic phosphonic acid has been designed and synthesised. The previously described pro-fluorescent probes were based on a conventional activated P-Oaryl bond cleavage, whereas our approach uses a self-immolative linker strategy that allows the detection of phosphonothioase activity with respect to a non-activated P-Salkyl bond. Further, we have also developed and optimised a high-throughput screening assay for the selection of decontaminants (chemical or biochemical scavengers) that could efficiently hydrolyse highly toxic V-type nerve agents. A preliminary screening, realised on a small α-nucleophile library, allowed us to identify some preliminary "hits", among which pyridinealdoximes, α-oxo oximes, hydroxamic acids and, less active but more original, amidoximes were the most promising. Their selective phosphonothioase activity has been further confirmed by using PhX as the substrate, and thus they offer new perspectives for the synthesis of more potent V nerve agent scavengers.
Monohydroxamic acids and bridging dihydroxamic acids as chelators to ruthenium(iii) and as nitric oxide donors: Syntheses, speciation studies and nitric oxide releasing investigation
Griffith, Darren,Krot, Krystyna,Comiskey, Jedd,Nolan, Kevin B.,Marmion, Celine J.
, p. 137 - 147 (2008/04/13)
The synthesis and spectroscopic characterisation of novel mononuclear RuIII(edta)(hydroxamato) complexes of general formula [Ru(H 2edta)(monoha)] (where monoha = 3- or 4-NH2, 2-, 3- or 4-Cl and 3-Me-phenylhydroxamato), as well as the first example of a Ru III-N-aryl aromatic hydroxamate, [Ru(H2edta)(N-Me-bha)] ·H2O (N-Me-bha = N-methylbenzohydroxamato) are reported. Three dinuclear RuIII complexes with bridging dihydroxamato ligands of general formula [{Ru(H2edta)}2(μ-diha)] where diha = 2,6-pyridinedihydroxamato and 1,3- or 1,4-benzodihydroxamato, the first of their kind with RuIII, are also described. The speciation of all of these systems (with the exception of the Ru-1,4-benzodihydroxamic acid and Ru-N-methylbenzohydroxamic systems) in aqueous solution was investigated. We previously proposed that nitrosyl abstraction from hydroxamic acids by Ru III involves initial formation of RuIII-hydroxamates. Yet, until now, no data on the rate of nitric oxide (NO) release from hydroxamic acids has been published. We now describe a UV-VIS spectroscopic study, where we monitored the decrease in the ligand-to-metal charge-transfer band of a series of RuIII-monohydroxamates with time, with a view to gaining an insight into the NO-releasing properties of hydroxamic acids. The Royal Society of Chemistry.
