Chemical warfare soman

Organophosphorsus inhibitors have been developed as insecticides (paraoxon, parathion) and for chemical warfare (soman, tabun, sarin). They are extremely toxic and lethal either by cardiac arrest of general paralysis and subsequent suffocation. 

Discovered in the late 1930s in Germany as improved poisonous insecticides, organophosphorus ChEIs were developed as chemical warfare agents (e.g. sarin, soman, and tabun) and were more recently employed in the 1995 terrorist attack in the Tokyo subway system [5]. 

Chemical warfare agents, such as soman and sarin, sometimes termed nerve gases, are powerful anticholinesterases, which bear some resemblance in structure and properties, to the OP insecticides. A major difference from most insecticides is their high volatility. These agents were possessed by the major powers during World War II, althongh they were never employed in warfare. 

Nerve Agent Substances that interfere with the central nervous system. Organic esters of phosphoric acid used as a chemical warfare agent because of their extreme toxicity (tabun-GA, sarin-GB, soman-GD, GF, and VX). All are potent inhibitors of the enzyme, acetylcholinesterase, which is responsible for the degradation of the neurotransmitter, acetylcholine in neuronal synapses or myoneural junctions. Nerve agents are readily absorbed by inhalation and/or through intact skin. 

German Trilons. Extremely toxic Chemical Warfare Agents developed before WWII but never employed. They included Sarin, Soman, Tabun and probably others. See PATR 2510(1958), p Ger 204-L and GA and GB in Vol 2 of Encycl, p C167-R... 

Figure 1 Structures of chemical warfare agents (sarin and soman), simulants (dimethyl methylphosphonate and diisoproyl fluorophosphate), and pesticides (paratliion and diazinon).

Methylphosphonic acid (MPA), a degradation product of gas chemical warfare agents, such as sarin (isopropyl methylphosphonofluoridate), soman or VX (0-ethy I -.S -2-di isopropyl am i noethvl methyl phosphonoth ioate), has been recognized selectively by an MIP chemosensor using potentiometric transduction (Table 6) [181]. The MIP preparation involved co-adsorption, in ethanol, of the methylphosphonic acid (MPA) template and octadecyltrichlorosilane, followed by silanization on the indium-tin oxide (ITO) electrode surface in the chloroform-carbon tetrachloride solution at 0 °C. Subsequently, the electrode was rinsed with chloroform to remove the template. A potential shift due to the presence of MPA was significant as compared to that due to interferants like methyl parathion, dimethoate, phosdrin, malathion, etc. The linear concentration range varied from 50 pM to 0.62 M MPA at LOD as low as 50 pM and an appreciably short response time of 50 s. 

As with chemical weapons ingredients, the chemical equipment needed to make chemical warfare agents is commercially available just about anywhere. Certainly, to set up a full-scale poison gas production line, terrorists would need reactors and agitators, chemical storage tanks, containers, receivers, condensers for temperature control, distillation columns to separate chemical compounds, valves and pumps to move chemicals between reactors and other containers. Additionally, ideally the equipment would be corrosion-resistant. For a full-scale mustard gas production plant the price tag would be between 2.5 and 5 million. Approximately 10 million would be required to set up a plant to manufacture tabun, sarin or soman.47 Terrorists, however, can be assumed to forego the scale and the safety precautions that most governments would consider essential for a weapons programme. In fact, standard process equipment or a laboratory set-up of beakers and... 

The foundation of the CWC s inspection activities was based around the declaration by member states of their chemical weapons capabilities and activities. Nations with chemical warfare programmes were required to declare their production, storage and destruction facilities, which would then receive top monitoring priority. Nevertheless, the CWC did allow states to maintain research programmes to ensure the integrity of defensive equipment such as gas masks and gas detectors, but these activities were also to be closely monitored since they involved work with the chemical agents listed on Schedule l.9 Otherwise, all other warfare agents, mustard gas, Lewisite, soman, sarin, tabun, VX and the capability to produce them were to be eliminated under the watchful eyes of international inspectors (Table 8.1).10 The convention thus defined chemical weapons as any toxic chemical, or its precursors, intended for purposes other than those not prohibited under this convention for... 

Soman (= Methyl-phosphonofluoridic acid 1,2,2-trimethylpropyl ester)] (organophosphate) Synthetic AChE (forms phosphoryl ester with active site Serine) [chemical warfare agent]... 

The chemical warfare (CW) nerve agents primarily addressed in this chapter include the anticholinesterase nerve agents tabun (GA), sarin (GB), soman (GD), cyclosarin (GF), and VX, all of which are, or have been, part of the US domestic munitions inventories (Carnes, 1989 NRC, 1999 Opresko et al, 1998). Russian VX (often represented as VR) will be evaluated in the following chapter by Radilov et al. (2009). Other, less well-characterized nerve agents such as compound GE, VG (Amiton ) or Vx will be evaluated as data allow. 

Fleming, C.D., Edwards, C.E., Kirby, S.D., Maxwell, D.M., Potter, P.M., Cerasoli, D.M., Redindo, M.R. (2007). Crystal structure of human carhoxylesterase 1 in covalent complexes with the chemical warfare agents soman and tahun. Biochemistry 46 5063-71. 

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