Oxidation organophosphates

Diisopropyl methylphosphonate is an organophosphate compound that was first produced in the United States as a by-product of the manufacture of the nerve gas isopropyl methylphosphonofluoridate (GB, or Sarin) (ATSDR 1996 EPA 1989 Robson 1977, 1981). It is not a nerve gas and is not a metabolite or degradation product (Roberts et al. 1995). Diisopropyl methylphosphonate constitutes approximately 2-3% of the crude GB product, but it is neither a metabolite nor a degradation product of GB (EPA 1989 Rosenblatt et al. 1975b). Diisopropyl methylphosphonate is not normally produced except for its use in research. One method of producing diisopropyl methylphosphonate is to combine triisopropyl phosphite and methyl iodide. The mixture is then boiled, refluxed, and distilled, yielding diisopropyl methylphosphonate and isopropyl iodide (Ford-Moore and Perry 1951). Diisopropyl methylphosphonate may also be prepared from sodium isopropyl methylphosphonate by a reaction at 270° C, but a portion of the resulting diisopropyl methylphosphonate is converted to trimethylphosphine oxide at this temperature (EPA 1989). 

Still another experimental route to introducing otherwise excluded molecules into the brain is to chemically modify them so that they are lipophilic and therefore can passively diffuse. The brain, just as most other organs and tissues of the body, has enzymes to metabolize or biotransform metabolites in order to use and then get rid of them. Many of these pathways are oxidative. A reduced species or derivative which is lipophilic can enter the brain by simple passive diffusion there to be oxidatively transformed into an active state. Compounds which have been tested in animals include derivatives of 2-PAM (an antidote for organophosphate insecticide poisoning) and phenylethylamine (similar to amphetamine type molecules). Figure 5 illustrates the general concept behind this method. 

Organophosphate insecticides are designed for nontoxicity to humans in that the S is relatively nontoxic. Toxicity is achieved by the host s oxidation of the S to 0 as well as the inability to detoxify by hydrolysis of the ester groups. 

Esterase activity is important in both the detoxication of organophosphates and the toxicity caused by them. Thus brain acetylcholinesterase is inhibited by organophosphates such as paraoxon and malaoxon, their oxidized metabolites (see above). This leads to toxic effects. Malathion, a widely used insecticide, is metabolized mostly by carboxylesterase in mammals, and this is a route of detoxication. However, an isomer, isomalathion, formed from malathion when solutions are inappropriately stored, is a potent inhibitor of the carboxylesterase. The consequence is that such contaminated malathion becomes highly toxic to humans because detoxication is inhibited and oxidation becomes important. This led to the poisoning of 2800 workers in Pakistan and the death of 5 (see chap. 5 for metabolism and chap. 7 for more details). 

Organophosphates are far more resistant to hydrolysis than polyphosphates. Thus, the films they form remain intact for longer periods of time in normal water environments. Strong oxidizers in the water such as chlorine, however, rapidly degrade AMP and phosphate esters. HEDP is more resistant to oxidizers. The presence of zinc or calcium cations stabilize organophosphate protective films and prolong their lives (Roti 1985). While phosphates are more environmentally benign in many ways than hexavalent chromium... 

Organophosphates (OPs) 311, 312, 529, 668, 674, 678-680 Organophosphorous 371 Ortho-nitrophenyl octyl ether 58 OTA 537 Overfitting 733 Oxalate 257 Oxidase 107 Oxidative damage 420 stress 418... 

---