Organophosphate (OP) compounds are among the most lethal chemical weapons ever developed and are irreversible inhibitors of acetylcholinesterase. Exposure to majority of OP produces status epilepticus (SE) and severe cholinergic symptoms that if left untreated are fatal. Survivors of OP intoxication often suffer from irreversible brain damage and chronic neurological disorders. Although pilocarpine has been used to model SE following OP exposure, there is a need to establish a SE model that uses an OP compound in order to realistically mimic both acute and long-term effects of nerve agent intoxication. Here we describe the development of a rat model of OP-induced SE using diisopropylfluorophosphate (DFP). The mortality, behavioral manifestations, and electroencephalogram (EEG) profile for DFP-induced SE (4 mg/kg, sc) were identical to those reported for nerve agents. However, significantly higher survival rates were achieved with an improved dose regimen of DFP and treatment with pralidoxime chloride (25 mg/kg, im), atropine (2 mg/kg, ip), and diazepam (5 mg/kg, ip) making this model ideal to study chronic effects of OP exposure. Further, DFP treatment produced N-methyl-D-aspartate (NMDA) receptor-mediated significant elevation in hippocampal neuronal [Ca(2+)](i) that lasted for weeks after the initial SE. These results provided direct evidence that DFP-induced SE altered Ca(2+) dynamics that could underlie some of the long-term plasticity changes associated with OP toxicity. This model is ideally suited to test effective countermeasures for OP exposure and study molecular mechanisms underlying neurological disorders following OP intoxication.
Alterations in hippocampal neuronalneuronal plasticity ͉ pilocarpine model ͉ calcium homeostasis ͉ seizure E pilepsy is one of the most common neurological disorders (1), and Ϸ40% of epilepsies are acquired, meaning that the epileptic condition is acquired through an injury to the nervous system (2, 3). Epileptogenesis is the process by which an injury such as status epilepticus (SE), stroke, or traumatic brain injury produces long-term plasticity changes in neurons, resulting in spontaneous recurrent seizures [acquired epilepsy (AE)] in previously normal brain tissue (4-6). AE develops in three phases: injury (brain insult), epileptogenesis (latency), and, finally, chronic epilepsy (spontaneous recurrent seizure) (7). The molecular basis for developing AE is still not completely understood. However, there is growing evidence from the SE and glutamate injury-induced models of AE that elevated intracellular calcium concentration ([Ca 2ϩ ] i ) and altered Ca 2ϩ -homeostatic mechanisms (Ca 2ϩ dynamics) may play a role in the development of AE (6,(8)(9)(10)(11)(12)(13). In addition, altered Ca 2ϩ dynamics have been observed in the hippocampus of chronic epileptic animals as long as 1 year after the induction of seizures in the in vivo pilocarpine model of AE (14). This model of AE shares many of the clinical and pathophysiological characteristics of partial-complex or temporal-lobe epilepsy in humans (14-19). The hippocampus has been shown to be the focus for many of the plasticity, pathophysiological, and epileptogenic alterations in the pilocarpine model of AE (14-19). Thus, if Ca 2ϩ is involved as a second messenger in the inductions and maintenance of AE in the pilocarpine model, it would be expected that Ca 2ϩ dynamics should be altered immediately after SE and in the three phases of the development of AE.This study was undertaken to determine whether hippocampal neuronal Ca 2ϩ dynamics are altered immediately after SE and in the three phases of the development of AE.Ca 2ϩ dynamics were evaluated in acutely isolated CA1 hippocampal, frontal, and occipital neurons at several time points during the injury, epileptogenesis, and chronic-epilepsy phases of AE. The effects of NMDA receptor inhibition by (ϩ)-5-methyl-10,11-dihydro-5H-dibenzo[a,d]cyclohepten-5,10-imine maleate (MK801) on both the development of seizures and Ca 2ϩ dynamics were determined. Comparisons of sham (salinetreated), pilocarpine without SE, and pilocarpine with SE but without AE control animals with SE animals with AE indicated that Ca 2ϩ dynamics were significantly altered during the development of AE and that both changes in Ca 2ϩ dynamics and the development of AE could be blocked by inhibition of the NMDA receptor during SE. The results demonstrate that altered Ca 2ϩ dynamics were associated with the development of AE and that inhibition of these changes in Ca 2ϩ dynamics was associated with the inhibition of the development of AE. The results provide direct evidence that Ca 2ϩ dynamics are significantly altered during epileptogenesis and ...
Paraoxon (POX) is an active metabolite of organophosphate (OP) pesticide parathion that has been weaponized and used against civilian populations. Exposure to POX produces high mortality. OP poisoning is often associated with chronic neurological disorders. In this study, we optimize a rat survival model of lethal POX exposures in order to mimic both acute and long-term effects of POX intoxication. Male Sprague-Dawley rats injected with POX (4 mg/kg, ice-cold PBS, s.c.) produced a rapid cholinergic crisis that evolved into status epilepticus (SE) and death within 6–8 min. The EEG profile for POX induced SE was characterized and showed clinical and electrographic seizures with 7–10 Hz spike activity. Treatment of 100% lethal POX intoxication with an optimized three drug regimen (atropine, 2 mg/kg, i.p., 2-PAM, 25 mg/kg, i.m. and diazepam, 5 mg/kg, i.p.) promptly stopped SE and reduced acute mortality to 12% and chronic mortality to 18%. This model is ideally suited to test effective countermeasures against lethal POX exposure. Animals that survived the POX SE manifested prolonged elevations in hippocampal [Ca2+]i (Ca2+ plateau) and significant multifocal neuronal injury. POX SE induced Ca2+ plateau had its origin in Ca2+ release from intracellular Ca2+ stores since inhibition of ryanodine/ IP3 receptor lowered elevated Ca2+ levels post SE. POX SE induced neuronal injury and alterations in Ca2+ dynamics may underlie some of the long term morbidity associated with OP toxicity.
Status epilepticus is a major medical emergency associated with a significant morbidity and mortality. Little is known about the mechanisms that terminate seizure activity and prevent the development of status epilepticus. Cannabinoids possess anticonvulsant properties and the endocannabinoid system has been implicated in regulating seizure duration and frequency. Endocannabinoids regulate synaptic transmission and dampen seizure activity via activation of the presynaptic cannabinoid receptor 1 (CB1). This study was initiated to evaluate the role of CB1 receptor-dependent endocannabinoid synaptic transmission towards preventing the development of status epilepticuslike activity in the well-characterized hippocampal neuronal culture model of acquired epilepsy using patch clamp electrophysiology. Application of the CB1 receptor antagonists SR141716A (1 μM) or AM251 (1 μM) to "epileptic" neurons caused the development of continuous epileptiform activity, resembling electrographic status epilepticus. The induction of status epilepticus-like activity by CB1 receptor antagonists was reversible and could be overcome by maximal concentrations of CB1 agonists. Similar treatment of control neurons with CB1 receptor antagonists did not produce status epilepticus or hyperexcitability. These findings suggest that CB1 receptor-dependent endocannabinoid endogenous tone plays an important role in modulating seizure frequency and duration and preventing the development of status epilepticus-like activity in populations of epileptic neurons. The regulation of seizure activity and prevention of status epilepticus by the endocannabinoid system offers an important insight into understanding the basic mechanisms that control the development of continuous epileptiform discharges. KeywordsCB1 receptor; status epilepticus; cannabinoid; epilepsy; endocannabinoid tone Epilepsy is one of the most common neurological disorders affecting approximately 1-2% of the world population [5]. It is characterized by the occurrence of spontaneous recurrent epileptiform discharges (SREDs) or seizures [9,16]. Status epilepticus (SE) is a majorTo whom correspondence should be addressed: Robert J. DeLorenzo, M.D., Ph.D., M.P.H., Virginia Commonwealth University, School of Medicine, PO Box 980599, Richmond, VA 23298, Phone: 804-828-8969, Fax: 804-828-6432, E-mail: rdeloren@hsc.vcu.edu. Publisher's Disclaimer: This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final citable form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. [2,12,18,19]. The CB1 receptor has been shown to mediate many of the anticonvulsant effects of cannabinoids [20] and to play an important role in regulating synaptic transmissio...
Aging is associated with increased vulnerability to neurodegenerative conditions such as Parkinson's and Alzheimer's disease and greater neuronal deficits after stroke and epilepsy. Emerging studies have implicated increased levels of intracellular calcium ([Ca 2+ ] i ) for the neuronal loss associated with aging related disorders. Recent evidence demonstrates increased expression of voltage gated Ca 2+ channel proteins and associated Ca 2+ currents with aging. However, a direct comparison of [Ca 2+ ] i levels and Ca 2+ homeostatic mechanisms in hippocampal neurons acutely isolated from young and mid-age adult animals has not been performed. In this study, Fura-2 was used to determine [Ca 2+ ] i levels in CA1 hippocampal neurons acutely isolated from young (4-5 months) and mid-age (12-16 months) Sprague-Dawley rats. Our data provide the first direct demonstration that mid-age neurons in comparison to young neurons manifest significant elevations in basal [Ca 2+ ] i levels. Upon glutamate stimulation and a subsequent [Ca 2+ ] i load, mid-age neurons took longer to remove the excess [Ca 2+ ] i in comparison to young neurons, providing direct evidence that altered Ca 2+ homeostasis may be present in animals at significantly younger ages than those that are commonly considered aged (≥ 24 months). These alterations in Ca 2+ dynamics may render aging neurons more vulnerable to neuronal death following stroke, seizures or head trauma. Elucidating the functionality of Ca 2+ homeostatic mechanisms may offer an understanding of the increased neuronal loss that
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