Inhibitor Report for: Diethyltabun

The history of the synthesis of organophosphate inhibitors of cholinesterase starting with the synthesis of tetraethyl-pyrophosphate by Moschnin(e) and de Clermont and leading to the recognition about half a century later of the toxicity of the phosphor ester by Lange and von Krueger has been told in great detail previously. An almost parallel history -described originally by Bo Holmstedt--exists for organophosphonate inhibitors of cholinesterase starting with the synthesis (1898) in Rostock of diethylamido-ethoxy-phosphoryl-cyanide by the pharmacist Adolph Schall (1870-1957), a graduate student of August Michaelis (1847-1916), the re-examination of the chemical structure of the Schall compound (1903) by Michaelis, recognition (1937) of the toxicity of class by Gerhard Schrader (1903-1990) and confirmation (1951) of the structure by Bo Holmstedt (1919-2002). This short report attempts to shed some light on the life of the pharmacists and chemists involved in the synthesis of the first P-CN organophosphonate inhibitor of cholinesterase, focusing on the two less known pharmacists, the graduate students of Professor Michaelis Adolph Schall and Ernst Ratzlaff (1870-1948).

The high number of fatalities due to poisoning by organophosphorus compound-based (OP) pesticides and the availability of highly toxic OP-type chemical warfare agents (nerve agents) emphasize the necessity for an effective medical treatment. Acute OP toxicity is mainly caused by inhibition of acetylcholinesterase (AChE, EC 3.1.1.7). Reactivators (oximes) of inhibited AChE are a mainstay of treatment. However, human AChE inhibited by certain OP, e.g. the phosphoramidates tabun and fenamiphos, is rather resistant towards reactivation by oximes while AChE inhibited by others, e.g. the phosphoramidate methamidophos is easily reactivated by oximes. To get more insight into a potential structure-activity relationship human AChE was inhibited by 16 different tabun analogues and the time-dependent reactivation by 1mM obidoxime, TMB-4, MMB-4, HI 6 or HLo 7, the reactivation kinetics of obidoxime and the kinetics of aging and spontaneous reactivation were investigated. A clear structure-activity relationship of aging, spontaneous and oxime-induced reactivation kinetics could be determined with AChE inhibited by N-monoalkyl tabun analogues depending on the chain length of the N-alkyl residue. N,N-dialkyl analogues bearing ethyl and n-propyl residues were completely resistant towards reactivation while N,N-di-i-propyl tabun was highly susceptible towards reactivation by oximes. AChE inhibited by phosphonoamidate analogues of tabun, bearing a N,N-dimethyl and N,N-diethyl group, could be reactivated and had comparable reactivation kinetics with obidoxime. These results in conjunction with previous data with organophosphates and organophosphonates emphasizes the necessity for kinetic studies as basis for future work on structural analysis with human AChE and for the development of effective broad-spectrum oximes.

The wide-spread use of organophosphorus compounds (OP) as pesticides and the availability of highly toxic OP-type chemical warfare agents (nerve agents) underlines the necessity for an effective medical treatment. Acute OP toxicity is primarily caused by inhibition of acetylcholinesterase (AChE, EC 3.1.1.7). Reactivators (oximes) of inhibited AChE are a mainstay of treatment, however, the commercially available compounds, obidoxime and pralidoxime, are considered to be rather ineffective against various nerve agents. The antidotal efficacy of new oximes is primarily tested in animals for ethical reasons. However, the various interactions between AChE, OP and oximes can be investigated with human AChE which enables the direct assessment of oxime potency, thus excluding species differences. The kinetics of inhibition, reactivation and aging were investigated with human erythrocyte AChE, various structurally different OP (organophosphates, -phosphonates and phosphoramidates) and oximes (obidoxime, pralidoxime, HI 6, HLo 7). The inhibitory potency of OPs, reactivating potency of oximes and spontaneous reactivation and aging were strongly affected by the structural characteristics of the OPs and of the phosphyl-AChE-complex. The kinetic data emphasize the superior inhibitory potency of organophosphonates. AChE inhibited by various phosphoramidates was mostly resistant towards reactivation by oximes while phosphonylated AChE was easily reactivated. HLo 7 was most potent with phosphonylated AChE and obidoxime with AChE inhibited by organophosphates and phosphoramidates. With the exception of soman, OP-inhibited AChE aged rather slowly (t(1/2) 3-231 h) and reactivated spontaneously with some compounds. These results indicate that there is obviously no direct structure-activity relationship for the various interactions of human AChE, OPs and oximes.