Refractory and Super-Refractory Status Epilepticus in Nerve Agent-Poisoned Rats Following Application of Standard Clinical Treatment Guidelines.

Nerve agents (NAs) induce a severe cholinergic crisis that can lead to status epilepticus (SE). Current guidelines for treatment of NA-induced SE only include prehospital benzodiazepines, which may not fully resolve this life-threatening condition. This study examined the efficacy of general clinical protocols for treatment of SE in the specific context of NA poisoning in adult male rats. Treatment with both intramuscular and intravenous benzodiazepines was entirely insufficient to control SE. Second line intervention with valproate (VPA) initially terminated SE in 35% of rats, but seizures always returned. Phenobarbital (PHB) was more effective, with SE terminating in 56% of rats and 19% of rats remaining seizure-free for at least 24 h. The majority of rats demonstrated refractory SE (RSE) and required treatment with a continuous third-line anesthetic. Both ketamine (KET) and propofol (PRO) led to high levels of mortality, and nearly all rats on these therapies had breakthrough seizure activity, demonstrating super-refractory SE (SRSE). For the small subset of rats in which SE was fully resolved, significant improvements over controls were observed in recovery metrics, behavioral assays, and brain pathology. Together these data suggest that NA-induced SE is particularly severe, but aggressive treatment in the intensive care setting can lead to positive functional outcomes for casualties.

Functional basis for dose-dependent antagonism of rat and rabbit neuromuscular transmission by the bis-pyridinium oxime MMB4.

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.