Life sciences
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Hypertonic (1M) sodium bicarbonate can partially reverse the cardiac toxicity of some Class IA antiarrhythmic agents, presumably by antagonizing sodium channel inhibition. We studied the effects of 1M sodium bicarbonate on toxicity due to the Class IC drug flecainide. Anesthetized rats received i.v. loading and maintenance doses of flecainide to produce QRS prolongation of 76% that was stable over the 60 min study period. 20 min after the start of the maintenance infusion, groups of 8 rats received an i.v. infusion of 1M sodium bicarbonate (6 meq/kg) or an equal volume of 0.9% saline. ⋯ Serum flecainide concentrations were similar. These data suggest that 1M sodium bicarbonate can partially reverse flecainide-induced conduction delay in rats. This effect may be due to changes in the extracellular pH and sodium concentration. 1M sodium bicarbonate may be useful in assessing the role of sodium channel inhibition in mediating the toxicity of flecainide or other Class IC drugs.
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Review Comparative Study
Cocaine and central monoaminergic neurotransmission: a review of electrophysiological studies and comparison to amphetamine and antidepressants.
Psychomotor stimulants (e.g. cocaine and amphetamine) and many antidepressants are believed to elicit their psychotropic actions by interacting primarily with central monoaminergic neurons. The acute central neuronal effects of amphetamine and antidepressants have been extensively investigated in rats utilizing extracellular single unit electrophysiological and microiontophoretic techniques in vivo. In recent years the chronic effects of these compounds on the above neuronal systems have also been reported. ⋯ In terms of effects on single monoaminergic neurons, this assumption had gone by untested until two years ago, when the first report of the electrophysiological effects of cocaine on central monoaminergic (locus ceruleus) neurons appeared in the literature (61). This review discusses recent electrophysiological studies with cocaine at the level of single identified monoaminergic neurons and compares such data with that previously reported for amphetamine and antidepressants. In addition to identifying some of the similarities and differences between these compounds, this review also highlights some of the gaps in our knowledge regarding the effects of these drugs on central monoaminergic neurotransmission.
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We believe that two findings are interconnected and help to comprehend a major mechanism behind the regulation of renal ammonia production during acidosis. First, slices from acidotic compared to control and alkalotic rats produce more ammonia from glutamine. Second, inhibition of renal oxidative metabolism at various points by metabolic inhibitors augments slice ammoniagenesis. ⋯ Lactate decarboxylation decreases in the face of increased glucose production during acidosis, and lactate inhibition of glutamine decarboxylation decreases in slices from acidotic rats. Also, we found lesser oxygen consumption in the presence of lactate by kidney slices from acidotic rats compared to control and alkalotic rats. We postulate that relatively less incorporation of lactate into the TCA cycle, causing decreased citrate formation and citrate oxidation during acidosis, contributes, at least in part, to acidotic adaptation of ammoniagenesis.
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A specific RIA for beta-endorphin (B-END) was developed to measure horse plasma levels of B-END-like material (B-END-LI) during exercises and shipping. Three exercise speeds and durations were: trot at 260-300 m/min for 10 min; slow gallop at 390-420 m/min for 5 min and fast gallop at 700-800 m/min for 2 min. Blood samples were taken from 4 horses before, immediately after, 30 and 60 min after exercise. ⋯ Transportation in horse trailer also significantly increased plasma levels of B-END-LI from a basal level of 138 +/- 12 to 196 +/- 24 pg/ml within 30 min and this levels were maintained at 45 min (177 +/- 3 pg/ml). Plasma levels of B-END-LI began to decline at 60 min of shipping. These results showed that plasma B-END-LI was increased in all speeds of exercise and by shipping and returned to pre-exercise and pre-shipping level in 30 min except fast gallop which returned to pre-exercise level in 1 hr.
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The genetically epilepsy-prone rat (GEPR) is abnormally susceptible to induction of seizures by acoustic stimulation. The inferior colliculus (IC) is critically important to audiogenic seizure susceptibility. The GEPR is more susceptible to induction of audiogenic seizures at 12 kHz than at other pure tone frequencies. ⋯ Iontophoresis of the GABAA antagonist, bicuculline, often converts normal response patterns in the IC to onset-offset responses seen with high incidence in GEPR IC neurons, suggesting that the decreased effectiveness of GABA may lead to the onset-offset prevalence. This reduced effectiveness of inhibition may be unable to compensate for the rise in the putative excitatory transmitter, aspartate, in IC during high intensity acoustic stimulation in the GEPR. These altered transmitter actions may be important mechanisms subserving initiation of audiogenic seizures in the genetically epilepsy-prone rat.