Using MRI for the assessment of paraoxon-induced brain damage and efficacy of antidotal treatment.

Organophosphate intoxication induces neural toxicity as demonstrated in histological analysis of poisoned animals. Diffusion-weighted magnetic resonance imaging (DWMRI) enables early noninvasive characterization of biological tissues based on their water diffusion characteristics. Our objectives were to study the application of MRI for assessment of paraoxon-induced brain damage and the efficacy of antidotal treatments. Seventy-six rats were poisoned with paraoxon followed by treatment with atropine and obidoxime. The rats were then divided into five treatment groups consisting of midazolam after 1 or 30 min, scopolamine after 1 or 30 min and a no anticonvulsant treatment group. Five untreated rats served as controls. Animals underwent MRI on days 1, 8, 15, 29 and 50 post poisoning. Histological evaluation was performed on representative rat brains. Acute DWMRI effects, such as enhancement of temporal brain regions, and chronic effects such as ventricular enlargement and brain atrophy, depicted on T2-weighted MRI, were significantly more prominent in late anticonvulsant treatment groups. There was no significant difference between the neuroprotective effects of midazolam and scopolamine as shown by DWMRI. Early MRI abnormalities were found to correlate significantly with histological analysis of samples obtained 15 days post treatment. In conclusion, our results demonstrate the feasibility of using DWMRI for depiction of early cytotoxic response to paraoxon and T2-weighted MRI for later changes, thus enabling assessment of early/late brain damage as well as treatment efficacy in rats. The ability to depict these changes early and noninvasively may be applied clinically in the acute phase of organophosphate poisoning.

Efficacy of antidotal treatment against sarin poisoning: the superiority of benactyzine and caramiphen.

Sarin, a potent cholinesterase inhibitor, induces an array of toxic effects including convulsions and behavioral impairments. We report here on the protection provided by post-exposure antidotal treatments against a lethal dose of sarin (1.2xLD50) by scopolamine, benactyzine, trihexyphenidyl or caramiphen, administered 5, 10 or 20 min after the initiation of convulsions. A mixture of the oxime TMB4 and atropine (TA) was injected 1 min following poisoning a paradigm that may represent a scenario reminiscent of a terror incident. Surviving TA-treated rats exhibited marked tonic-clonic convulsions, weight loss, poor clinical status and abnormal cognitive performance as assessed by the Morris water maze. Additionally, a dramatic increase in the density of peripheral benzodiazepine receptors (PBRs), a faithful marker for neuronal damage, was noted. Animals treated 5 min after the development of toxic signs with benactyzine, trihexyphenidyl or caramiphen demonstrated control levels of PBR values, whereas scopolamine produced binding densities significantly above basal levels. Examined at the 10-min time point, scopolamine and trihexyphenidyl afforded no protection against brain damage and did not differ from TA-injected rats. All four drugs failed to significantly prevent the alterations when applied 20 min after onset of convulsions. Assessment of learning processes yielded similar results, where caramiphen exibited some protection at the 20-min time point. Our results show that caramiphen and benactyzine, agents with combined anticholinergic and antiglutamatergic pharmacological profiles, offer considerable shielding against sarin, even when their administration is delayed.

Extrapolating from animal studies to the efficacy in humans of a pretreatment combination against organophosphate poisoning.

The extrapolation from animal data to therapeutic effects in humans, a basic pharmacological issue, is especially critical in studies aimed to estimate the protective efficacy of drugs against nerve agent poisoning. Such efficacy can only be predicted by extrapolation of data from animal studies to humans. In pretreatment therapy against nerve agents, careful dose determination is even more crucial than in antidotal therapy, since excessive doses may lead to adverse effects or performance decrements. The common method of comparing dose per body weight, still used in some studies, may lead to erroneous extrapolation. A different approach is based on the comparison of plasma concentrations at steady state required to obtain a given pharmacodynamic endpoint. In the present study, this approach was applied to predict the prophylactic efficacy of the anticholinergic drug caramiphen in combination with pyridostigmine in man based on animal data. In two species of large animals, dogs and monkeys, similar plasma concentrations of caramiphen (in the range of 60-100 ng/ml) conferred adequate protection against exposure to a lethal-dose of sarin (1.6-1.8 LD(50)). Pharmacokinetic studies at steady state were required to achieve the correlation between caramiphen plasma concentrations and therapeutic effects. Evaluation of total plasma clearance values was instrumental in establishing desirable plasma concentrations and minimizing the number of animals used in the study. Previous data in the literature for plasma levels of caramiphen that do not lead to overt side effects in humans (70-100 ng/ml) enabled extrapolation to expected human protection. The method can be applied to other drugs and other clinical situations, in which human studies are impossible due to ethical considerations. When similar dose response curves are obtained in at least two animal models, the extrapolation to expected therapeutic effects in humans might be considered more reliable.