Functionalized cyclodextrins bearing an alpha nucleophile--a promising way to degrade nerve agents.

Organophosphorus nerve agents are irreversible inhibitors of acetylcholinesterase. Current treatment of nerve agent poisoning has limited efficacy and more efficient medical countermeasures need to be developed. A promising approach is to design chemical scavengers more stable during storage and less immunogenic than bioscavengers. Furthermore, they could be produced at lowest production costs. Cyclodextrins are attractive cyclic oligosaccharides that can be used to develop chemical scavengers of organophosphorus nerve agents. Their abilities to form inclusion and non-inclusion complexes with organic substrates are useful to trap chemical warfare agents. Selective introduction of an α-nucleophile residue on the secondary face of ß-cyclodextrin allowed to obtain supramolecular derivatives active against organophosphorus compounds. The degradation activity of these monosubstituted cyclodextrins was determined against paraoxon and chemical warfare agents. These tests showed that the structure of the scavengers mainly influences the interaction between the organophosphorus substrate, or its reaction products, and the cyclodextrin moiety. All the tested G-type agents were efficiently degraded. According to the binding modes of cyclosarin, some oligosaccharidic scavengers led to an enantioselective degradation of this nerve agent. These promising derivatives open the way to further investigations of new structural modifications to reach more sophisticated and efficient scavengers for prophylactic and curative medical applications.

Detoxification of nerve agents by a substituted beta-cyclodextrin: application of a modified biological assay.

Chemical warfare agents (nerve agents) are still available and present a real threat to the population. Numerous in vitro and in vivo studies showed that various nerve agents, e.g. tabun and cyclosarin, are resistant towards standard therapy with atropine and oxime. Based on these facts we applied a modified biological assay for the easy, semi-quantitative testing of the detoxifying properties of the beta-cyclodextrin derivative CD-IBA. Cyclosarin, sarin, tabun and VX were incubated with CD-IBA for 1-50 min at 37 degrees C, then an aliquot was added to erythrocyte acetylcholinesterase (AChE) and the percentage of AChE inhibition was determined. The validity of the assay was confirmed by concomitant quantification of tabun by GC-MS. Different concentrations of cyclosarin were detoxified by CD-IBA in a concentration-dependent velocity. The ability to detoxify various nerve agents decreased in the order cyclosarin>sarin>tabun>>VX. Hereby, no detoxification of VX could be detected. Sarin was detoxified in a biphasic reaction with a fast reduction of inhibitory potential in the first phase and a slower detoxification in the second phase. CD-IBA detoxified tabun in a one phase decay and, compared to cyclosarin and sarin, a longer half-life was determined with tabun. The modified biological assay is appropriate for the initial semi-quantitative screening of candidate compounds for the detoxification of nerve agents. The beta-cyclodextrin derivative CD-IBA demonstrated its ability to detoxify different nerve agents.