SUMMARY1. The effects of the N-methyl-D-aspartate (NMDA) receptor antagonist, D-2-amino-5-phosphonovaleric acid (D-APV), and other excitatory amino acid antagonists, were studied on CAI pyramidal neurones treated with picrotoxin or bicuculline to reduce synaptic inhibition mediated by y-aminobutyric acid (GABA). Under these conditions epileptiform burst firing is readily produced by orthodromic stimulation of the pyramidal cell population.2. D-APV reduced the plateau amplitude and duration of the depolarization underlying evoked and spontaneous bursts without affecting membrane potential, input resistance or the ability of the cell to fire a Ca2+ spike or a short train of Na+ spikes.3. A late component of the subthreshold excitatory post-synaptic potential (e.p.s.p.) was voltage dependent, being reduced in amplitude on membrane hyperpolarization. D-APV selectively removed this component of the e.p.s.p. in disinhibited slices. In contrast, in the absence of GABA antagonists, D-APV had no noticeable effect on the e.p.s.p. as studied with field potential recordings.4. The concentration-response relationship of the inhibitory effect of D-APV and L-APV on population spike bursts was studied. The action of APV was highly stereoselective; the EC50 of D-APV was approximately 700 nm, whereas a similar inhibition required 540 /iM-L-APV. A number of other excitatory amino acid antagonists were tested at a fixed concentration (100 ,M). Among them, the quisqualate antagonist y-D-glutamylaminomethyl sulphonic acid was ineffective against epileptiform bursts.5. In the low nanomolar concentration range both D-and L-APV potentiated bursting.6. These results suggest that in the absence of GABAergic inhibition, a significant component of the slow depolarization underlying burst firing is voltage dependent, synaptic in origin and mediated by NMDA receptors. We propose that, under normal (non-epileptic) physiological conditions, the balance between synaptic inhibition mediated by GABA receptors and synaptic excitation mediated by NMDA receptors may modulate the excitability of pyramidal cell dendrites.
The emetic responses to various pharmacological agents, cytotoxins, and radiation are compared among animal species. The species included for comparison are the human, nonhuman primate, dog, cat, and ferret. The categories of pharmacologic compounds include both those compounds that act on identified membrane receptors (e.g., cholinergic agonists, catecholamines, and neuroactive peptides) and those that act on unidentified receptors (e.g., cardiac glycosides and Veratrum alkaloids, among others). Emphasis is placed on emetic dose-response relations and threshold ED50 and ED100 values calculated from these relations, as indices of species sensitivity to emetic stimuli. For the more noxious emetics, the cytotoxins and radiation, the latency to the first emetic episode and duration of emesis are also compared across species. The effect that peripheral and central nerve lesions have on species differences in emetic responses to stimuli is also discussed.
To determine if electrophysiological properties of hippocampal pathways are altered in kindled rats, extracellular recordings were made from hippocampal slices of rats kindled in the lateral entorhinal cortex and compared with those from implanted but unstimulated controls. Studies were made either 24 h or 28 days after the last kindled seizure and done in normal (3.5 mM) or elevated (7 mM) K+. The preparation of slices, data accumulation, and data analyses were done blind. One day or 28 days after the last kindled seizure, the proportion of slices with spontaneous epileptiform bursts recorded from the CA2/3 region in elevated K+ was significantly (P less than 0.001) increased in the kindled animals. The frequency of spontaneous burst firing was also increased and reached significance (P less than 0.02) at 28 days following the last kindling stimulus. One day after the last kindling stimulus, paired-pulse (GABAergic) inhibition in the CA1 region was decreased (P less than 0.001). Several measures suggested an increased synaptic inhibition in the dentate gyrus of slices from the kindled groups 1 day after kindling. Paired-pulse inhibition was increased (P less than 0.01), the current required to evoke a near-threshold population spike was increased (P less than 0.05), and the population spike amplitude was reduced for a given field excitatory postsynaptic potential (EPSP) (P less than 0.01). Twenty-eight days after the last kindling stimulus, however, paired-pulse inhibition in the dentate was slightly less in slices from kindled rats (P less than 0.005). In other respects the CA1 and dentate regions did not differ between kindled and control groups within 24 h of the last stage V seizure. Thus the maximum amplitudes of presynaptic fiber volley, population spike, and field-excitatory postsynaptic potential (EPSP) slope, and the number of population spikes evoked by a near-maximally effective afferent stimulus, were unchanged. In the CA1 region the input-output curve of field EPSP versus population spike, and the current intensity required to evoke a near-threshold population spike were also unchanged. In addition, no spontaneous bursts were recorded from CA1 in 3.5 mM K+. We conclude that either synapses or neurons intrinsic to the hippocampus are altered by kindling stimuli applied outside this brain area. The transient increase in inhibition in the dentate gyrus suggests that it may reflect a compensatory reaction to kindled seizures. In contrast, the long-lasting (at least 28 days) increase in burst firing in CA2/3 may represent a mechanism for the initiation or propagation of kindled seizures.(ABSTRACT TRUNCATED AT 400 WORDS)
Acute radiation sickness (ARS) following exposure to ionizing irradiation is characterized by radiation-induced multiorgan dysfunction/failure that refers to progressive dysfunction of two or more organ systems, the etiological agent being radiation damage to cells and tissues over time. Radiation sensitivity data on humans and animals has made it possible to describe the signs associated with ARS. A mouse model of total-body irradiation (TBI) has previously been developed that represents the likely scenario of exposure in the human population. Herein, we present the Mouse Intervention Scoring System (MISS) developed at the Veterinary Sciences Department (VSD) of the Armed Forces Radiobiology Research Institute (AFRRI) to identify moribund mice and decrease the numbers of mice found dead, which is therefore a more humane refinement to death as the endpoint. Survival rates were compared to changes in body weights and temperatures in the mouse (CD2F1 male) TBI model (6–14 Gy, 60Co γ-rays at 0.6 Gy min-1), which informed improvements to the Scoring System. Individual tracking of animals via implanted microchips allowed for assessment of criteria based on individuals rather than by group averages. From a total of 132 mice (92 irradiated), 51 mice were euthanized versus only four mice that were found dead (7% of non-survivors). In this case, all four mice were found dead after overnight periods between observations. Weight loss alone was indicative of imminent succumbing to radiation injury, however mice did not always become moribund within 24 hours while having weight loss >30%. Only one survivor had a weight loss of greater than 30%. Temperature significantly dropped only 2–4 days before death/euthanasia in 10 and 14 Gy animals. The score system demonstrates a significant refinement as compared to using subjective assessment of morbidity or death as the endpoint for these survival studies.
Forty-eight ferrets (Mustela putorius furo) were individually head-shielded and radiated with bilateral 60Co gamma radiation at 100 cGy min-1 at doses ranging between 49 and 601 cGy. The emetic threshold was observed at 69 cGy, the ED50 was calculated at 77 cGy, and 100% incidence of emesis occurred at 201 cGy. With increasing doses of radiation, the latency to first emesis after radiation decreased dramatically, whereas the duration of the prodromal period increased. Two other sets of experiments suggest that dopaminergic mechanisms play a minor role in radiation-induced emesis in the ferret. Twenty-two animals were injected either intravenously or subcutaneously with 30 to 300 micrograms/kg of apomorphine. Fewer than 50% of the animals vomited to 300 micrograms/kg apomorphine; central dopaminergic receptor activation was apparent at all doses. Another eight animals received 1 mg/kg domperidone prior to either 201 (n = 4) or 401 (n = 4) cGy radiation and their emetic responses were compared with NaCl-injected-irradiated controls (n = 8). At 201 cGy, domperidone significantly reduced only the total time in emetic behavior. At 401 cGy, domperidone had no salutary effect on radiation-induced emesis. The emetic responses of the ferret to radiation and apomorphine are compared with these responses in other vomiting species.
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