n-n--monomethylenebis(pyridiniumaldoxime) and Organophosphate-Poisoning

The oximes pralidoxime (2-PAM), its dimethanesulphonate salt derivative P2S, and obidoxime (toxogonin) are currently licensed and fielded for the treatment of chemical warfare (CW) organophosphorous (OP) nerve agent poisoning. While they are effective against several of the identified threat CW OP agents, they have little efficacy against others such as soman (GD) and cyclosarin (CF). In addition, they are also significantly less effective than other investigational oximes against the nerve agent known as Russian VX (RVX). Among the oximes currently being investigated, two in particular, HI-6 (asoxime) and MMB-4 (ICD-039, methoxime) have been proposed as replacement therapies for the currently licensed oximes. HI-6 has been safely used in individuals to treat OP insecticide poisoning, as well as in human volunteers, although its efficacy against OP nerve agent poisoning in humans cannot be demonstrated due to ethical considerations. It is currently available for use in defined military settings in Canada, Sweden and the Czech Republic, and is also under development in a number of other countries. The oxime MMB-4 has not yet been studied clinically, but is fielded by the Czech Republic, and is being developed by the United States armed services as a replacement for the currently fielded 2-PAM. This review compares the effectiveness of HI-6 and MMB-4 against nerve agent threats where comparisons can be made. HI-6 has been demonstrated to be generally a superior reactivator of nerve agent inhibited enzyme, particularly with human and non-human primate derived enzyme, and has also shown better protective effects against the lethality of most OP agents in a variety of species. Both compounds appear to be clearly superior to the available oximes, obidoxime and 2-PAM.

Topics: Antidotes; Chemical Warfare Agents; Humans; Organophosphate Poisoning; Organophosphates; Organophosphorus Compounds; Oximes; Pyridinium Compounds; Sarin; Soman

Organophosphorus (OP) compounds inhibit central and peripheral acetylcholinesterase (AChE) activity, overstimulating cholinergic receptors and causing autonomic dysfunction (e.g., bronchoconstriction, excess secretions), respiratory impairment, seizure and death at high doses. Current treatment for OP poisoning in the United States includes reactivation of OP-inhibited AChE by the pyridinium oxime 2-pyridine aldoxime (2-PAM). However, 2-PAM has a narrow therapeutic index and its efficacy is confined to a limited number of OP agents. The bis-pyridinium oxime MMB4, which is a more potent reactivator than 2-PAM with improved pharmaceutical properties and therapeutic range, is under consideration as a potential replacement for 2-PAM. Similar to other pyridinium oximes, high doses of MMB4 lead to off-target effects culminating in respiratory depression and death. To understand the toxic mechanisms contributing to respiratory depression, we evaluated the effects of MMB4 (0.25-16 mM) on functional and neurophysiological parameters of diaphragm and limb muscle function in rabbits and rats. In both species, MMB4 depressed nerve-elicited muscle contraction by blocking muscle endplate nicotinic receptor currents while simultaneously prolonging endplate potentials by inhibiting AChE. MMB4 increased quantal content, endplate potential rundown and tetanic fade during high frequency stimulation in rat but not rabbit muscles, suggesting species-specific effects on feedback mechanisms involved in sustaining neurotransmission. These data reveal multifactorial effects of MMB4 on cholinergic neurotransmission, with the primary toxic modality being reduced muscle nicotinic endplate currents. Evidence of species-specific effects on neuromuscular function illustrates the importance of comparative toxicology when studying pyridinium oximes and, by inference, other quaternary ammonium compounds.

Topics: Acetylcholinesterase; Animals; Cholinesterase Reactivators; Dose-Response Relationship, Drug; Female; Male; Muscles; Organophosphate Poisoning; Oximes; Pralidoxime Compounds; Rabbits; Rats; Rats, Sprague-Dawley; Respiratory Insufficiency; Species Specificity; Synaptic Transmission

Anticholinesterases, such as organophosphorus pesticides and warfare nerve agents, present a significant health threat. Onset of symptoms after exposure can be rapid, requiring quick-acting, efficacious therapy to mitigate the effects. The goal of the current study was to identify the safest antidote with the highest therapeutic index (TI = oxime 24-hr LD50/oxime ED50) from a panel of four oximes deemed most efficacious in a previous study. The oximes tested were pralidoxime chloride (2-PAM Cl), MMB4 DMS, HLö-7 DMS, and obidoxime Cl2. The 24-hr median lethal dose (LD50) for the four by intramuscular (IM) injection and the median effective dose (ED50) were determined. In the ED50 study, male guinea pigs clipped of hair received 2x LD50 topical challenges of undiluted Russian VX (VR), VX, or phorate oxon (PHO) and, at the onset of cholinergic signs, IM therapy of atropine (0.4 mg/kg) and varying levels of oxime. Survival was assessed at 3 hr after onset clinical signs. The 3-hr 90th percentile dose (ED90) for each oxime was compared to the guinea pig pre-hospital human-equivalent dose of 2-PAM Cl, 149 µmol/kg. The TI was calculated for each OP/oxime combination. Against VR, MMB4 DMS had a higher TI than HLö-7 DMS, whereas 2-PAM Cl and obidoxime Cl2 were ineffective. Against VX, MMB4 DMS > HLö-7 DMS > 2-PAM Cl > obidoxime Cl2. Against PHO, all performed better than 2-PAM Cl. MMB4 DMS was the most effective oxime as it was the only oxime with ED90 < 149 µmol/kg against all three topical OPs tested.

Topics: Animals; Antidotes; Atropine; Chemical Warfare Agents; Cholinesterase Inhibitors; Cholinesterase Reactivators; Dose-Response Relationship, Drug; Guinea Pigs; Lethal Dose 50; Male; Muscarinic Antagonists; Obidoxime Chloride; Organophosphate Poisoning; Organothiophosphorus Compounds; Oximes; Pesticides; Pralidoxime Compounds; Pyridinium Compounds; Time Factors

The currently fielded pre-hospital therapeutic regimen for the treatment of organophosphorus (OP) poisoning in the United States (U.S.) is the administration of atropine in combination with an oxime antidote (2-PAM Cl) to reactivate inhibited acetylcholinesterase (AChE). Depending on clinical symptoms, an anticonvulsant, e.g., diazepam, may also be administered. Unfortunately, 2-PAM Cl does not offer sufficient protection across the range of OP threat agents, and there is some question as to whether it is the most effective oxime compound available. The objective of the present study is to identify an oxime antidote, under standardized and comparable conditions, that offers protection at the FDA approved human equivalent dose (HED) of 2-PAM Cl against tabun (GA), sarin (GB), soman (GD), cyclosarin (GF), and VX, and the pesticides paraoxon, chlorpyrifos oxon, and phorate oxon. Male Hartley guinea pigs were subcutaneously challenged with a lethal level of OP and treated at approximately 1 min post challenge with atropine followed by equimolar oxime therapy (2-PAM Cl, HI-6 DMS, obidoxime Cl₂, TMB-4, MMB4-DMS, HLö-7 DMS, MINA, and RS194B) or therapeutic-index (TI) level therapy (HI-6 DMS, MMB4-DMS, MINA, and RS194B). Clinical signs of toxicity were observed for 24 h post challenge and blood cholinesterase [AChE and butyrylcholinesterase (BChE)] activity was analyzed utilizing a modified Ellman's method. When the oxime is standardized against the HED of 2-PAM Cl for guinea pigs, the evidence from clinical observations, lethality, quality of life (QOL) scores, and cholinesterase reactivation rates across all OPs indicated that MMB4 DMS and HLö-7 DMS were the two most consistently efficacious oximes.

Topics: Animals; Antidotes; Atropine; Chemical Warfare Agents; Cholinesterase Inhibitors; Cholinesterase Reactivators; Cholinesterases; Drug Administration Schedule; Drug Monitoring; Drug Therapy, Combination; Guinea Pigs; Injections, Intramuscular; Injections, Subcutaneous; Male; Muscarinic Antagonists; Organophosphate Poisoning; Oximes; Pesticides; Pyridinium Compounds; Random Allocation

The widespread use of organophosphorus compounds (OPs) as pesticides and the frequent misuse of OP nerve agents in military conflicts or terrorist attacks emphasize the high clinical relevance of OP poisoning. The toxic symptomatology is caused by inhibition of acetylcholinesterase (AChE). A mainstay of standard antidotal treatment is atropine for antagonizing effects mediated by over stimulation of muscarinic ACh-receptors and oxime to reactivate OP-inhibited AChE. For therapeutic monitoring of oxime treatment in OP poisoning, measurement of erythrocyte AChE is suitable because erythrocyte AChE is an easily accessible surrogate for synaptic AChE. However, measurement of erythrocyte AChE is not standard practice. In contrast, determination of plasma butyrylcholinesterase (BChE) activity is in routine use for monitoring the benefit of oxime therapy. As oxime efficacy is limited with certain OPs (e.g. dimethoate, tabun, soman) alternative therapeutic approaches, e.g. the application of scavengers (BChE) which may sequester OPs before they reach their physiological target, are under investigation. To assess the eligibility of BChE as laboratory parameter and (pseudo catalytic or stoichiometric) scavenger in OP poisoning we initiated an in vitro study under standardized experimental conditions with the objective of determination of kinetic constants for inhibition, reactivation and aging of plasma BChE. It could be shown that, due to limited efficacy of obidoxime, pralidoxime, HI 6 and MMB4 with OP-inhibited BChE, plasma BChE activity is an inappropriate parameter for therapeutic monitoring of oxime treatment in OP poisoning. Furthermore, oxime-induced reactivation is too slow to accomplish a pseudo catalytic function, so that administered BChE may be merely effective as a stoichiometric scavenger.

Topics: Acetylcholinesterase; Biomarkers; Butyrylcholinesterase; Chemical Warfare Agents; Cholinesterase Inhibitors; Cholinesterase Reactivators; Erythrocyte Membrane; Humans; Kinetics; Obidoxime Chloride; Organophosphate Poisoning; Organophosphorus Compounds; Oximes; Pesticides; Pralidoxime Compounds; Pyridinium Compounds

The effect of methoxime combined with a) atropine, b) benactyzine, c) atropine and natrium thiosulphate, d) atropine and diazepam on antidotal treatment effectiveness was studied in tabun-poisoned mice. In addition, the influence of pretreatment consisiting of pyridostigmine, benactyzine and trihexyphenidyle (PANPAL) administered 2 hours before tabun intoxication on the treatment effectivity of methoxime combined with e) atropine or f) benactyzine was tested. The most efficacious therapeutic mixture in non-pretreated mice was methoxime, atropine and diazepam. Natrium thiosulphate did not significantly increase neither decrease the antidotal treatment efficacy in comparison with methoxime and atropine alone. Pretreatment with PANPAL significantly decreased tabun toxicity (nearly 4 times in methoxime and benactyzine combination and more than 4 times in atropine and methoxime mixture). The present study demonstrates that the tabun toxicity in mice is more effectively reduced when PANPAL prophylactically is administered than in case of treatment with methoxime and cholinergic drug alone. We established that anticholinergic drug option in the therapeutic mixture of methoxime and anticholinergic drug did not cause the difference in the antidotal treatment effectivities.

Topics: Animals; Anticonvulsants; Antidotes; Benactyzine; Chemical Warfare Agents; Cholinesterase Inhibitors; Drug Combinations; Drug Therapy, Combination; Female; Mice; Organophosphate Poisoning; Organophosphates; Oximes; Premedication; Pyridostigmine Bromide; Thiosulfates; Trihexyphenidyl

Topics: Animals; Atropine; Cholinesterase Reactivators; Dogs; Dose-Response Relationship, Drug; Drug Evaluation, Preclinical; Drug Therapy, Combination; Heart Rate; Male; Organophosphate Poisoning; Organothiophosphates; Oximes; Respiration; Time Factors