Comparison of inhibition kinetics of several organophosphates, including some nerve agent surrogates, using human erythrocyte and rat and mouse brain acetylcholinesterase.

Because testing of nerve agents is limited to only authorized facilities, our laboratory developed several surrogates that resemble nerve agents because they phosphylate the acetylcholinesterase (AChE) with the same moiety as the actual nerve agents. The inhibition kinetic parameters were determined for AChE by surrogates of cyclosarin (NCMP), sarin (NIMP, PIMP and TIMP) and VX (NEMP and TEMP) and other organophosphorus compounds derived from insecticides. All compounds were tested with rat brain and a subset was tested with mouse brain and purified human erythrocyte AChE. Within the compounds tested on all AChE sources, chlorpyrifos-oxon had the highest molecular rate constant followed by NCMP and NEMP. This was followed by NIMP then paraoxon and DFP with rat and mouse brain AChE but DFP was a more potent inhibitor than NIMP and paraoxon with human AChE. With the additional compounds tested only in rat brain, TEMP was slightly less potent than NEMP but more potent than PIMP which was more potent than NIMP. Methyl paraoxon was slightly less potent than paraoxon but more potent than TIMP which was more potent than DFP. Overall, this study validates that the pattern of inhibitory potencies of our surrogates is comparable to the pattern of inhibitory potencies of actual nerve agents (i.e., cyclosarin>VX>sarin), and that these are more potent than insecticidal organophosphates.

Synthesis and in vitro and in vivo inhibition potencies of highly relevant nerve agent surrogates.

Four nonvolatile nerve agent surrogates, 4-nitrophenyl ethyl dimethylphosphoramidate (NEDPA, a tabun surrogate), 4-nitrophenyl ethyl methylphosphonate (NEMP, a VX surrogate), and two sarin surrogates, phthalimidyl isopropyl methylphosphonate (PIMP) and 4-nitrophenyl isopropyl methylphosphonate (NIMP), were synthesized and tested as acetylcholinesterase (AChE) and butyrylcholinesterase (BuChE) inhibitors. These surrogates were designed to phosphorylate cholinesterases with the same moiety as their respective nerve agents, making them highly relevant for the study of cholinesterase reactivators. Surrogates were characterized by liquid chromatography-mass spectrometry and nuclear magnetic resonance. NEMP, PIMP, and NIMP were potent inhibitors of rat brain, skeletal muscle, diaphragm, and serum AChE as well as human erythrocyte AChE and serum BuChE in vitro. PIMP was determined to degrade quickly in aqueous solution, making it useful for in vitro assays only, and NEDPA was not a potent inhibitor of AChE or BuChE in vitro; therefore, these two surrogates were not tested in subsequent in vivo studies. Sublethal dosages (yielding about 80% brain AChE inhibition) were determined for both the stable sarin surrogate, NIMP (0.325 mg/kg ip), and the VX surrogate, NEMP (0.4 mg/kg ip), in adult male rats. Time course studies indicated the time to peak brain AChE inhibition for both NIMP and NEMP to be 1 h postexposure. Both surrogates yielded severe cholinergic signs. These dosages did not require the addition of atropine to prevent lethality, and the rate of AChE aging was slow, making these surrogates useful for reactivation studies both in vitro and in vivo. The surrogates synthesized in this study are potent yet safer to test than nerve agents and are useful tools for initial screening of nerve agent oxime therapeutics.