Mechanism of action of HI-6 on soman inhibition of acetylcholinesterase in preparations of rat and human skeletal muscle; comparison to SAD-128 and PAM-2

HI-6 is presently considered the most potent oxime antidote against soman poisoning in mice, rats, dogs and monkeys. However, it is still an open question whether efficiency of HI-6, observed in experimental animals, can be extrapolated to soman intoxicated humans. In this paper efficiency of HI-6 and possible mechanisms of action were compared in rat and human fresh muscle preparations. In rat muscle, about 50% of control AChE activity could be recovered by both therapeutic (5 min after soman) and prophylactic (5 min before soman) application of HI-6. On the other hand, in human muscle therapeutic treatment restored only 5%, while prophylactic application of HI-6 again resulted in about 50% recovery of control AChE activity. As revealed by comparison of the prophylactic effects of HI-6 and the non-oxime bispyridinium compound SAD-128, competitive inhibition of AChE plays a minor role as a protective mechanism. Immediate reactivation of rapidly aging human AChE must therefore be instituted for successful protective treatment by HI-6. Retardation of aging, a direct effect of SAD-128, was roughly estimated to improve reactivation by HI-6 for about 10% of control AChE activity of the human muscle. PAM-2 proved completely inefficient as a therapeutic and as a prophylactic agent on both rat and human muscle preparations.     

The effect of pyridostigmine pretreatment on oxime efficacy against intoxication by soman or VX in rats.

This study was done to assess the effects of pyridostigmine (PYR) on a) the accumulation of labelled VX and soman within the brain, b) the therapeutic efficacy of atropine and oxime (2-PAM or HI-6) against intoxication by VX and soman and c) oxime-induced reactivation of inhibited acetylcholinesterase (AChE). In all experiments, rats were given PYR (131 micrograms/kg, im; I70 dose for whole blood AChE) or vehicle 30 min prior to nerve agent. In estimating 3H-agent the accumulation in the brain or estimating blood AChE activity, sufficient soman (47 micrograms/kg, iv) or VX (21.3 micrograms/kg, iv) was given to inhibit 50% of brain AChE activity. In assessing therapeutic efficacy and oxime-induced reactivation of blood AChE, rats were pretreated with PYR, challenged with agent and treated with atropine (16 mg/kg, im) and HI-6 or 2-PAM (100 umoles/kg, im) 30 sec post agent. Whole blood was collected by tail bleeding to monitor peripheral AChE activity at various time points before and after PYR and challenge. Pyridostigmine failed to alter covalent binding of labelled VX or soman in the brain. The 24-hr survival data showed that PYR reduced the therapeutic benefit of atropine and oxime against VX intoxication (but not soman). Protective ratios in VX-challenged rats given vehicle or PYR and treated with atropine + 2-PAM decreased slightly from 2.5 to 2.1 (p > .05), whereas with atropine + HI-6 they decreased significantly from 3.8 to 2.4. Also, AChE reactivation by HI-6 in VX-challenged rats was greater (p < .05) in vehicle- than in PYR-pretreated rats. HI-6 significantly reactivated AChE activity in both pretreatment groups (PYR or vehicle) given soman. The data suggest that PYR decreases the overall recovery of inhibited AChE in VX-challenged rats given HI-6; under the conditions used, this adverse effect decreases atropine+oxime efficacy against VX-induced lethality.     

Effect of HI-6, applied into the cerebral ventricles, on the inhibition of brain acetylcholinesterase by soman in rats

When applied to rats (intraperitoneally) immediately after subcutaneous injection of soman (120 micrograms/kg) HI-6 (100 mg/kg) protected about 40% of the activity of acetylcholinesterase (AChE) in the motor end plate region of the diaphragm but did not protect AChE in the brain. However, a partial protection of AChE in brain against inhibition by soman was obtained in anaesthetized, atropinized rats by the oxime injected into the cerebral ventricle 5 min before parenteral exposure to soman. The AChE activity in brain of rats pretreated with HI-6, analyzed 60 min after the injection of soman was between 10 and 19%, while that in non-protected animals did not exceed 1% of the control. The degree of protection of AChE in brain was dose-dependent. Large doses of HI-6 (greater than or equal to 100 micrograms) were tolerated by animals because of the pentobarbital anaesthesia which counteracted the lethal action of HI-6. The rate of "aging" of AChE in brain inhibited by soman was analyzed by intracerebroventricular injection of 200 micrograms of HI-6 at different time intervals after the subcutaneous injection of soman. A statistically-significant reactivation of inhibited AChE activity in brain was demonstrated when HI-6 was applied up to 20 min after soman. The protection and reactivation by HI-6 of both AChE in brain and AChE in muscle end plates in poisoning with soman appear to be quite similar.     

Two possible orientations of the HI-6 molecule in the reactivation of organophosphate-inhibited acetylcholinesterase

The inhibition of acetylcholinesterase (AChE) by organophosphorus compounds (OPs) causes acute toxicity or death of the intoxicated individual. One group of these compounds, the OP nerve agents, pose an increasing threat in the world due to their possible use in the battlefield or terrorist acts. Antidotes containing oxime compounds to reactivate the inhibited enzyme are highly valued for treatment against OP poisoning. One of these reactivators, HI-6, was shown to be significantly more effective in treating soman toxicity than other oximes, such as 2-PAM, TMB4, and obidoxime. However, HI-6 was less effective in reactivating AChE inhibited by the OP pesticide, paraoxon. In this study, the mechanism for HI-6-induced reactivation of OP-AChE conjugates was investigated using mouse mutant AChEs inhibited with different OPs including organophosphate paraoxon, and several methylphosphonates. Results indicate that the HI-6 molecule may assume two different orientations in the reactivation of AChE inhibited by organophosphate and Sp methylphosphonates. These conclusions were further corroborated by reactivation studies using an analog of HI-6 in which the bispyridinium moieties are linked by a methylene bridge rather than an ether oxygen.     

Aging-resistant organophosphate bioscavenger based on polyethylene glycol-conjugated F338A human acetylcholinesterase

The high reactivity of cholinesterases (ChEs) toward organophosphorus (OP) compounds has led to propose recombinant ChEs as bioscavengers of nerve agents. The bioscavenging potential of recombinant ChEs can be enhanced by conjugation of polyethylene glycol (PEG) moieties, to extend their circulatory residence. However, the ability of exogenously administered ChEs to confer long-term protection against repeated exposures to nerve agents is still limited due to the aging process, whereby organophosphate-ChE adducts undergo irreversible dealkylation, which precludes oxime-mediated reactivation of the enzyme. To generate an optimal acetylcholinesterase (AChE)-based OP bioscavenger, the F338A mutation, known to decelerate the rate of aging of AChE-OP conjugates, was incorporated into polyethylene glycol-conjugated (PEGylated) human AChE. The PEGylated F338A-AChE displayed unaltered rates of hydrolysis, inhibition, phosphylation, and reactivation and could effectively protect mice against exposure to soman (pinacolylmethyl phosphonofluoridate), sarin (O-isopropyl methylphosphonofluoridate), or O-ethyl-S-(2-isopropylaminoethyl) methylphosphonothioate (VX). Unlike PEGylated wild-type (WT)-AChE, the PEGylated F338A-AChE exhibits significantly reduced aging rates after soman inhibition and can be efficiently reactivated by the 1-[[[4(aminocarbonyl)-pyridinio]methoxy]methyl]-2(hydroxyimino)methyl]pyridinium dichloride (HI-6) oxime, both in vitro and in vivo. Accordingly, oxime administration to PEG-F338A-AChE-pretreated mice enabled them to withstand repeated soman exposure (5.4 and 4 LD(50)/dose), whereas same regime treatment of non-PEGylated F338A-AChE- or PEGylated WT-AChE-pretreated mice failed to protect against the second challenge, due to rapid clearance or irreversible aging of the latter enzymes. Thus, judicious incorporation of selected mutations into the AChE mold in conjunction with its chemical modification provides means to engineer an optimal ChE-based OP bioscavenger in terms of circulatory longevity, resistance to aging, and reduced doses required for protection, even against repeated exposures to nerve agents, such as soman.     

Recent advances in evaluation of oxime efficacy in nerve agent poisoning by in vitro analysis

The availability of highly toxic organophosphorus (OP) warfare agents (nerve agents) underlines the necessity for an effective medical treatment. Acute OP toxicity is primarily caused by inhibition of acetylcholinesterase (AChE). 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, e.g. soman and cyclosarin. This led to the synthesis and investigation of numerous oximes in the past decades. Reactivation of OP-inhibited AChE is considered to be the most important reaction of oximes. Clinical data from studies with pesticide-poisoned patients support the assumption that the various reactions between AChE, OP and oxime, i.e. inhibition, reactivation and aging, can be investigated in vitro with human AChE. In contrast to animal experiments such in vitro studies with human tissue enable the evaluation of oxime efficacy without being affected by species differences. In the past few years numerous in vitro studies were performed by different groups with a large number of oximes and methods were developed for extrapolating in vitro data to different scenarios of human nerve agent poisoning. The present status in the evaluation of new oximes as antidotes against nerve agent poisoning will be discussed.     

Simulation of cholinesterase status at different scenarios of nerve agent exposure

The ongoing threat of homicidal use of organophosphorus-type chemical warfare agents ("nerve agents") during military conflicts and by terrorists underlines the necessity for effective medical countermeasures. Standard treatment with atropine and the established acetylcholinesterase (AChE) reactivators, obidoxime and pralidoxime, is considered to be ineffective with certain nerve agents due to low oxime effectiveness. From obvious ethical reasons only animal experiments can be used to evaluate new oximes as nerve agent antidotes. However, the extrapolation of data from animal to humans is hampered by marked species differences. Since reactivation of OP-inhibited AChE is considered to be the main mechanism of action of oximes, human erythrocyte AChE can be exploited to test the efficacy of new oximes. Recently, a dynamic computer model was developed which allows the calculation of AChE activities at different scenarios by combining enzyme kinetics (inhibition, reactivation, aging) with OP toxicokinetics and oxime pharmacokinetics. Now, this computer model was further extended by including the pharmaco- and enzyme kinetics of carbamate pretreatment. Simulations were performed for intravenous and percutaneous nerve agent exposure and intramuscular oxime treatment in the presence and absence of pyridostigmine pretreatment using published data. The model presented may serve as a tool for evaluating the impact of carbamate pretreatment on oxime-induced reactivation of inhibited AChE, for defining effective oxime concentrations and for optimizing oxime treatment. In addition, this model may be useful for the development of meaningful therapeutic strategies in animal experiments.     

Russian VX: inhibition and reactivation of acetylcholinesterase compared with VX agent

Organophosphorus compounds such as nerve agents inhibit, practically irreversibly, cholinesterases by their phosphorylation in the active site of these enzymes. Current antidotal treatment used in the case of acute nerve agent intoxications consists of combined administration of anticholinergic drug (usually atropine) and acetylcholinesterase (AChE, EC 3.1.1.7) reactivator (HI-6, obidoxime, pralidoxime), which from a chemical view is a derivative from the group of pyridinium or bispyridinium aldoximes (commonly called "oxime"). Oximes counteract acetylcholine increase, resulting from AChE inhibition. In the human body environment these compounds are powerful nucleophiles and are able to break down the bond between AChE and nerve agent molecule. This process leads to renewal of enzyme functionality -- to its reactivation. The usefulness of oxime in the reactivation process depends on its chemical structure and on the nerve agent whereby AChE is inhibited. Due to this fact, selection of suitable reactivator in the treatment of intoxications is very important. In our work, we have compared differences in the in vitro inhibition potency of VX and Russian VX on rat, pig and human brain, and subsequently we have tested reactivation of rat brain cholinesterase inhibited by these agents using oxime HI-6, obidoxime, pralidoxime, trimedoxime and methoxime. The results showed that no major differences in the reactivation process of both VX and Russian VX-inhibited cholinesterase. The similarity in reactivation was caused by analogous chemical structure of either nerve agent; and that oxime HI-6 seems to be the most effective reactivator tested, which confirms that HI-6 is currently the most potent reactivator of AChE inhibited by nerve agents. The results obtained in our study should be considered in the future development of new AChE reactivators.     

Reactivation of VX-inhibited AChE by novel oximes having two oxygen atoms in the linker

Two newly developed AChE reactivators possessing two oxime groups in 4-position of the pyridinium rings with linkers CH(2)O(CH(2))(2)OCH(2) and CH(2)O(CH(2))(4)OCH(2) were tested for their potency to reactivate VX-inhibited AChE. Their reactivation potency was compared with currently available oximes such as pralidoxime, obidoxime and HI-6. Appropriate constants (affinity towards the intact and inhibited enzyme, reactivation rate) characterizing the reactivation process were determined. According to the data obtained, a new oxime with CH(2)O(CH(2))(2)OCH(2) linker reached as high reactivation potency as HI-6. The percentage of reactivation of the oxime with CH(2)O(CH(2))(2)OCH(2) linker was comparable to that of obidoxime at a concentration 10(-3)M. Hence, these oximes may be worthy of future development for the treatment of nerve agent intoxications, especially, with lipophilic agents such as soman and cyclosarin.     

Reactivation of organophosphate-inhibited human, Cynomolgus monkey, swine and guinea pig acetylcholinesterase by MMB-4: a modified kinetic approach

Treatment of poisoning by highly toxic organophosphorus compounds (OP, nerve agents) is a continuous challenge. Standard treatment with atropine and a clinically used oxime, obidoxime or pralidoxime is inadequate against various nerve agents. For ethical reasons testing of oxime efficacy has to be performed in animals. Now, it was tempting to investigate the reactivation kinetics of MMB-4, a candidate oxime to replace pralidoxime, with nerve agent-inhibited acetylcholinesterase (AChE) from human and animal origin in order to provide a kinetic basis for the proper assessment of in vivo data. By applying a modified kinetic approach, allowing the use of necessary high MMB-4 concentrations, it was possible to determine the reactivation constants with sarin-, cyclosarin-, VX-, VR- and tabun-inhibited AChE. MMB-4 exhibited a high reactivity and low affinity towards OP-inhibited AChE, except of tabun-inhibited enzyme where MMB-4 had an extremely low reactivity. Species differences between human and animal AChE were low (Cynomolgus) to moderate (swine, guinea pig). Due to the high reactivity of MMB-4 a rapid reactivation of inhibited AChE can be anticipated at adequate oxime concentrations which are substantially higher compared to HI-6. Additional studies are necessary to determine the in vivo toxicity, tolerability and pharmacokinetics of MMB-4 in humans in order to enable a proper assessment of the value of this oxime as an antidote against nerve agent poisoning.     

Pre- and post-treatment effect of physostigmine on soman-inhibited human erythrocyte and muscle acetylcholinesterase in vitro

Standard treatment of organophosphorus (OP) poisoning includes administration of an antimuscarinic (e.g., atropine) and of an oxime-based reactivator. However, successful oxime treatment in soman poisoning is limited due to rapid aging of phosphylated acetylcholinesterase (AChE). Hence, the inability of standard treatment procedures to counteract the effects of soman poisoning resulted in the search for alternative strategies. Recently, results of an in vivo guinea pig study indicated a therapeutic effect of physostigmine given after soman. The present study was performed to investigate a possible pre- and post-treatment effect of physostigmine on soman-inhibited human AChE given at different time intervals before or after perfusion with soman by using a well-established dynamically working in vitro model for real-time analysis of erythrocyte and muscle AChE. The major findings were that prophylactic physostigmine prevented complete inhibition of AChE by soman and resulted in partial spontaneous recovery of the enzyme by decarbamylation. Physostigmine given as post-treatment resulted in a time-dependent reduction of the protection from soman inhibition and recovery of AChE. Hence, these date indicate that physostigmine given after soman does not protect AChE from irreversible inhibition by the OP and that the observed therapeutic effect of physostigmine in nerve agent poisoning in vivo is probably due to other factors.     

A structure-activity analysis of the variation in oxime efficacy against nerve agents

A structure-activity analysis was used to evaluate the variation in oxime efficacy of 2-PAM, obidoxime, HI-6 and ICD585 against nerve agents. In vivo oxime protection and in vitro oxime reactivation were used as indicators of oxime efficacy against VX, sarin, VR and cyclosarin. Analysis of in vivo oxime protection was conducted with oxime protective ratios (PR) from guinea pigs receiving oxime and atropine therapy after sc administration of nerve agent. Analysis of in vitro reactivation was conducted with second-order rate contants (k(r2)) for oxime reactivation of agent-inhibited acetylcholinesterase (AChE) from guinea pig erythrocytes. In vivo oxime PR and in vitro k(r2) decreased as the volume of the alkylmethylphosphonate moiety of nerve agents increased from VX to cyclosarin. This effect was greater with 2-PAM and obidoxime (>14-fold decrease in PR) than with HI-6 and ICD585 (<3.7-fold decrease in PR). The decrease in oxime PR and k(r2) as the volume of the agent moiety conjugated to AChE increased was consistent with a steric hindrance mechanism. Linear regression of log (PR-1) against log (k(r2)[oxime dose]) produced two offset parallel regression lines that delineated a significant difference between the coupling of oxime reactivation and oxime protection for HI-6 and ICD585 compared to 2-PAM and obidoxime. HI-6 and ICD585 appeared to be 6.8-fold more effective than 2-PAM and obidoxime at coupling oxime reactivation to oxime protection, which suggested that the isonicotinamide group that is common to both of these oximes, but absent from 2-PAM and obidoxime, is important for oxime efficacy.     

Currently used cholinesterase reactivators against nerve agent intoxication: comparison of their effectivity in vitro

In vitro comparison of reactivation efficacy of five currently used oximes - pralidoxime, obidoxime, trimedoxime, methoxime, and HI-6 (at two concentrations: 10-5 and 10-3 M) - against acetylcholinesterase (AChE; E.C. 3.1.1.7) inhibited by six different nerve agents (VX, Russian VX, sarin, cyclosarin, tabun, soman) and organophosphorus insecticide chlorpyrifos was the aim of this study. As a source of AChE in the experiments, rat brain homogenate was used. According to the results obtained, no AChE reactivator was able to reach sufficient potency for AChE inhibited by all nerve agents used. Moreover, oxime HI-6 (the most effective one) was not able to reactivate tabun- and soman-inhibited AChE. Due to this fact, it could be designated as a partially broad-spectrum reactivator.     

Evaluation of HI 6 treatment after percutaneous VR exposure by use of a kinetic-based dynamic computer model

The availability of highly toxic OP-type chemical warfare agents (nerve agents) and the exertion of organophosphorus compounds during military conflicts and terrorist attacks against civilians in the past underlines the necessity of an effective treatment regimen of OP-poisoning. Presently, standard treatment includes administration of an antimuscarinic agent (e.g. atropine) and a reactivator of inhibited AChE (oxime), but is considered to be rather ineffective with certain nerve agents due to low oxime effectiveness of the currently available oximes, obidoxime and pralidoxime. The evaluation of new oximes as antidotes relies on the implementation of animal experiments for ethical reasons and is complicated by a limited extrapolation of animal data to humans. The development of a reliable animal model might accelerate the evaluation of new substances and their approval as antidotes, whereas, the pig as higher mammalian species seems to be promising as model animal. A dynamic in vitro model, which allows the calculation of AChE activities at different scenarios was developed to facilitate the definition of effective oxime concentrations and the optimization of oxime treatment of OP poisoning of humans and may furthermore be helpful by designing animal experiments. The model is based on a combination of enzyme kinetics (inhibition, reactivation, aging) of AChE with OP, toxicokinetics and oxime pharmacokinetics. By considering species-specific kinetic data this dynamic model was used for the calculation of AChE activities in humans and pigs after percutaneous exposure with 5x LD(50) VR (Russian VX) and treatment with HI 6, a promising new reactivator of OP-inhibited AChE. Due to a low affinity of HI 6 with VR-inhibited pig AChE the oxime dose that causes maximal reactivation of VR-inhibited pig AChE is conspicuously higher compared to humans. Therefore, the design of animal experiments in consideration of calculated data based on species-specific kinetic values may lead to a more reliable extrapolation of animal data to humans and may reduce the number of necessary animal experiments.     

Review of oximes in the antidotal treatment of poisoning by organophosphorus nerve agents

The cholinesterase-inhibiting organophosphorus compounds referred to as nerve agents (soman, sarin, tabun, GF agent, and VX) are particularly toxic and are considered to be among the most dangerous chemical warfare agents. Included in antidotal medical countermeasures are oximes to reactivate the inhibited cholinesterase. Much experimental work has been done to better understand the properties of the oxime antidotal candidates including the currently available pralidoxime and obidoxime, the H oximes HI-6 and Hl?-7, and methoxime. There is no single, broad-spectrum oxime suitablefor the antidotal treatment of poisoning with all organophosphorus agents. If more than one oxime is available, the choice depends primarily on the identity of the responsible organophosphorus compound. The H oximes appear to be very promising antidotes against nerve agents because they are able to protect experimental animals from toxic effects and improve survival of animals poisoned with supralethal doses. They appear more effective against nerve agent poisoning than the currently used oximes pralidoxime and obidoxime, especially in the case of soman poisoning. On the other hand, pralidoxime and especially obidoxime seem sufficiently effective to treat poisonings with organophosphorus insecticides that have relatively less toxicity than nerve agents.     

Restoration of nerve agent inhibited muscle force production in human intercostal muscle strips with HI 6

An important factor for successful therapy of poisoning with organophosphorus compounds (OP) is the rapid restoration of blocked respiratory muscle function. To achieve this goal, oximes are administered for reactivation of inhibited acetylcholinesterase (AChE). Unfortunately, clinically used oximes, e.g. obidoxime and pralidoxime, are of limited effectiveness in poisoning with different OP nerve agents requiring the search for alternative oximes, e.g. HI 6. In view of substantial species differences regarding reactivation properties of oximes, the effect of HI 6 was investigated with sarin, tabun and soman exposed human intercostal muscle. Muscle force production by indirect field stimulation and the activity of the human muscle AChE was assessed. 30 μM HI 6 resulted in an almost complete recovery of sarin blocked muscle force and in an increase of completely inhibited muscle AChE activity to approx. 30% of control. In soman or tabun exposed human intercostal muscle HI 6 (50 and 100 μM) had no effect on blocked muscle force or on inhibited human muscle AChE activity. In addition, HI 6 up to 1000 μM had no effect on soman blocked muscle force indicating that this oxime has no direct, pharmacological effect in human tissue. These results emphasize that sufficient reactivation of AChE is necessary for a beneficial therapeutic effect on nerve agent blocked neuromuscular transmission.     

Currently Used Cholinesterase Reactivators Against Nerve Agent Intoxication: Comparison of Their Effectivity in Vitro

In vitro comparison of reactivation efficacy of five currently used oximes—pralidoxime, obidoxime, trimedoxime, methoxime, and HI-6 (at two concentrations: 10^?5 and 10^?3 M)—against acetylcholinesterase (AChE; E.C. 3.1.1.7) inhibited by six different nerve agents (VX, Russian VX, sarin, cyclosarin, tabun, soman) and organophosphorus insecticide chlorpyrifos was the aim of this study. As a source of AChE in the experiments, rat brain homogenate was used. According to the results obtained, no AChE reactivator was able to reach sufficient potency for AChE inhibited by all nerve agents used. Moreover, oxime HI-6 (the most effective one) was not able to reactivate tabun- and soman-inhibited AChE. Due to this fact, it could be designated as a partially broad-spectrum reactivator.     

Application of kinetic-based computer modelling to evaluate the efficacy of HI 6 in percutaneous VX poisoning

The rife use of organophosphorus compounds (OP) as pesticides and the exertion of highly toxic OP-type chemical warfare agents (nerve agents) during military conflicts and terrorist attacks in the past emphasize the necessity of the development of effective therapeutic countermeasures. Presently, standard treatment of poisoning by OP includes administration of atropine as an antimuscarinic agent and of oximes, e.g. obidoxime or pralidoxime, as reactivators of OP-inhibited acetylcholinesterase (AChE), but is considered to be rather ineffective with certain nerve agents. The evaluation of new oximes as antidotes is only possible by implementation of animal experiments for ethical reasons and therefore complicated by a limited extrapolation of animal data to humans due to marked species differences. A computer simulation based on combination of AChE kinetic data (inhibition, reactivation, aging) with OP toxicokinetics and oxime pharmacokinetics allows the calculation of AChE activities at different scenarios and may facilitate to define effective oxime concentrations and to optimize oxime dosage in OP poisoning. On the base of species-specific kinetic data this model was used to calculate AChE activities in humans and pigs after percutaneous exposure to 5 x LD50 VX and treatment with HI 6. Due to marked species differences between human and pig AChE the HI 6 dose that is necessary to cause a comparable reactivation of VX-inhibited pig AChE is conspicuously higher. Hence, designing animal experiments with the aid of computer modeling may reduce the number of animal experiments and allow a more reliable extrapolation of animal data to humans.     

Therapeutic efficacy of HI-6 in soman-poisoned marmoset monkeys.

The therapeutic efficacy of the oxime HI-6 against intoxication with the irreversible cholinesterase (ChE) inhibitor soman was tested in marmoset monkeys. Five out of six marmosets, intoxicated with 5 x LD50 soman and treated immediately with diazepam (0.2 mg.kg-1 iv) and 15 sec later with atropine (0.5 mg.kg-1 im) and HI-6 (50 mg.kg-1 im), survived for more than 24 hr. One of these animals died after 4 days. In the HI-6-treated marmosets blood ChE activity was inhibited at a rate slower than that in three animals treated similarly but with saline instead of HI-6. The latter marmosets died within 8 min after soman. HI-6 achieved its plasma peak 5 min after injection and was eliminated with a t1/2 of about 40 min. In a second experiment similarly treated marmosets were euthanized at 5 min (three saline-treated animals) or at 10 min (three HI-6-treated animals) after the soman intoxication to enable the determination of acetylcholinesterase (AChE) activities in diaphragm and brain tissue. In addition, in these animals blood AChE and butyrylcholine esterase (BuChE) activities were determined. Low AChE activities were encountered in diaphragms and brains. These levels were not significantly different between saline- and HI-6-treated marmosets. In vitro treatment with HI-6 at 40 min after soman still led to an increase of the AChE activity, which was significant in diaphragm, suggesting that postmortem AChE inhibition had occurred. The ratio of AChE to BuChE in blood was significantly enhanced in HI-6-treated animals, indicating that HI-6 preferentially reactivated AChE. It is concluded that (i) HI-6 is an effective treatment against soman poisoning in marmosets and (ii) AChE reactivation or protection by HI-6 contributed to the survival of the animals.     

HI-6 therapy of soman and tabun poisoning in primates and rodents

The bis-pyridinium oxime HI-6, in conjunction with atropine, was found to offer significant protection against multiple LD₅₀ challenges with the organophosphorus compounds soman and tabun. In adult rhesus macaques, the therapeutic administration of HI-6 with atropine and diazepam protected three of four animals from the lethal effects of 5 × LD₅₀ of soman and three of three animals from 5 × LD₅₀ of tabun. However, when toxogonin was substituted for HI-6 in the therapeutic mixture, all three animals poisoned with 5 × LD₅₀ of soman died. In rats, the 24 h protective ratios against tabun and soman with HI-6 were 2 and 3.5, respectively, whereas in guinea pigs these values were between 4 and 6 for both agents. No evidence was obtained for acetylcholinesterase (AChE) reactivation by HI-6 in tissue from tabun-poisoned rodents or following soman or tabun in primate plasma. The results underscore the significant therapeutic benefit of HI-6 in primates, a species specific efficacy against tabun, and argue for some mechanism of action of HI-6 at least partly unrelated to AChE reactivation.