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Notes: Abstract HI 6 (Pyridinium, 1-[[[4-(aminocarbonyl)pyridinio]methoxy]methyl]-2-[(hydroxyimino)methyl]-dichloride is an effective antidote against poisoning with extremely toxic organophosphates. Because of conflicting reports on the stability of HI 6 in aqueous solutions, we studied the factors influencing its stability. HI 6 has been shown to be most stable in acidic solution between pH 2 and 3. At that pH, HI 6 decomposes probably by attack of nucleophiles on the methylene carbon atom of the aminal-acetal bond of the “ether bridge”. HI 6 decomposition follows first order kinetics. From Arrhenius plots of the decay of HI 6 at various concentrations it became obvious that the rate of decomposition increased with increasing HI 6 concentration with simultaneous decrease in the energy of activation. To decide whether the pyridinium compound itself or its anions are responsible for the enhanced decomposition, we studied the influence of chloride, phosphate and iodide. These anions stimulated the decay of HI 6 at increasing strength; their effect, however, was small as compared to that brought about by the pyridinium oxime itself. Since 1-methylisonicotinamide chloride had virtually no effect in contrast to 1-methylpyridinium-2-aldoxime chloride, we conclude that the oximate anion is responsible for the intermolecular attack on HI 6. At present, we recommend storage of HI 6 at concentrations not exceeding 0.1 M in aqueous solution at pH 2.5 and low temperatures. Under these conditions an apparent shelf-life of 20 years is calculated when HI 6 is stored at 8° C.

Notes: Abstract Certain recently developed antidotes of the bispyridinium type, commonly called “H-oximes” (HGG 12, 21, 42, 52, 65, 70, 89, and HGG 90) have been investigated as to their effects on muscarinic and nicotinic acetylcholine receptors. These compounds clearly discriminate between these two types of receptors being more potent inhibitors of the muscarinic receptor with inhibitory constants in the micromole range. (The corresponding values for the nicotinic receptor are in the range of 0.1 mM.) However, the inhibitory potency in the binding assay does not correlate with the ED50 values obtained against soman in mice. The site of antidotal action therefore appears not to be the nicotinic acetylcholine receptor. Binding to the muscarinic receptors may partially contribute to the effects against soman in vivo.

Notes: Abstract HLö 7 dimethanesulfonate (1-[[[4-(aminocarbonyl)pyridinio] methoxy] methyl] -2,4-bis [(hydroxyimino) methyl]pyridinium dimethanesulfonate) is a broad-spectrum reactivator against highly toxic organophosphorus compounds. The compound was synthesized by a new route with the carcinogenic bis(chloromethyl)ether being substituted by the non-mutagenic bis(methylsulfonoxymethyl)ether. The very soluble dimethanesulfonate of obidoxime was also prepared by this way. HLö 7 dimethanesulfonate is the first water-soluble salt of HLö 7 that should be suitable for the wet/dry autoinjector technology, because aqueous solutions of HLö 7 are not very stable (calculated shelf-life 0.2 years when stored at 8°C, 1 M solution, pH 2.5). The crystalline preparation contains 96% of thesyn/syn-isomer, less than 2% of thesyn/anti-isomer and some minor identified by-products. HLö 7 was very efficient in reactivating acetylcholinesterase (AChE) blocked by organophosphates as long as ageing did not prevent dephosphylation. HLö 7 was superior to HI 6 (1-[[[4-(aminocarbonyl)pyridinio]methoxy]methyl]-2-[(hydroxyimino)methyl]pyridinium dichloride) in reactivating soman and sarin-inhibited AChE from erythrocytes, and literature data indicate that HLö 7 exceeds HI 6 by far in reactivating tabun-inhibited AChE. In atropine-protected, soman-poisoned mice HLö 7 was three times more potent than HI 6 (protective ratio 5 versus 2.5), and in sarin-poisoned mice HLö 7 was 10 times more potent than HI 6 (protective ratio 8 for both oximes). In atropine-protected guinea-pigs HLö 7 was less effective than HI 6 (protective ratio: 2.3 versus 5.2 for soman; 5.2 versus 6.8 for sarin; 4.3 versus 3.8 for tabun). The mean survival time of anaesthetized guinea-pigs exposed to 5 LD50 soman (6.3 min) was increased by atropine (27 min) and atropine + HLö 7 (57 min). HLö 7 alone did not prolong the survival. The most impressive effect of HLö 7 was on respiration: 3 min after i.v. injection of HLö 7 and atropine, the depressed respiration increased rapidly to 60% of control and remained at that level during the observation period (60 min). With atropine alone, respiration recovered only slowly. Behavioural and physiologic parameters were determined in atropine-protected mice exposed to a sublethal soman dose. The running performance was significantly improved by HLö 7. Even central symptoms, e.g. hypothermia and convulsions, were decreased markedly by HLö 7 (evaluation 60 min after poisoning). The pharmacokinetic data for HLö 7 in male beagle dogs are similar to those of HI 6. After i.v. injection: t1/2α = 5 min; t1/2ß = 46 min; VD = 0.24 1/kg; Clp1 = 3.7 ml x min−1 x kg−1; Clren= 3.2 ml x min−1 x kg−1; renal excretion of unchanged HLö 7 = 86%. After i. m. injection: t1/2abs = 14 min; t1/2ß = 48 min; Vd = 0.27 1/kg; Clp1= 3.9 ml x min−1 x kg−1; Clren= 2.7 ml x min−1 x kg−1; renal excretion of unchanged HLö 7 = 76%; bioavailability 〉95%. Plasma protein binding was 〈5%; HLö 7 did not permeate into red cells. A dose of 20 μmol/kg was well tolerated both after i.v. and i.m. administration. In anaesthetized dogs (chloralose) HLö 7 i.v. (20 (imol/kg) showed marginal hypotensive effects, whereas 50 μmol/kg resulted in decreased mean blood pressure (−15%) and blood flow (−30%) without reflex tachycardia. One out of four dogs developed a circulatory shock syndrome with anuria. Respiration varied only transiently. Blood gases and pH were not influenced. Similar cardiovascular effects were observed in anaesthetized (urethane) guinea-pigs. In isolated guinea-pig hearts (Langendorff) sinus and ventricular heart rate were not influenced by HLö 7 〈500 μM. HLö 7 antagonized both carbachol and nicotine effects. Red cell AChE was inhibited by HLö 7 by up to 50%; C50 about 100 μM. Previously, HLö 7 was shown to block ganglionic transmission (IC50= 500 μM), probably due to ion-channel blockade. These data indicate that HLö 7 combines ganglion blocking, anticholinergic and indirect cholinergic properties like other bispyridinium compounds. The results suggest that HLö 7 may be tolerated by man at a dose of 10 μmol/kg. Vital functions are not expected to be impaired. At such a dose (250–500 mg), which can be injected by an autoinjector, HLö 7 is expected to be superior to HI 6.