Repetitive stimulation of the vagus nerve inhibits chemically induced seizures in dogs. We report here the results and conclusions from studies designed to answer some of the immediate questions raised by this finding. (1) Maximal stimulation of vagal C fibers at frequencies greater than 4 Hz prevents or reduces chemically and electrically induced seizures in young male rats. (2) Antiepileptic potency is directly related to the fraction of vagal C fibers stimulated. (3) Vagal stimulation shortens but does not shut down a chemical seizure once it has begun. (4) In rats, optimal stimulus frequency is approximately 10-20 Hz; duration of stimulus, 0.5-1 ms; and stimulus strength, 0.2-0.5 mA/mm2 of nerve cross-section. These results, when taken together with similar results obtained from dogs, monkeys, and humans, strongly suggest that periodic stimulation of the vagus nerve using appropriate stimulation parameters is a powerful method for preventing seizures. The data from the literature suggest that the antiepileptic actions of vagal stimulation are largely mediated by widespread release of GABA and glycine in the brainstem and cerebral cortex. The probable pathway is via projections from the nucleus of the solitary tract to the reticular formation and thence by diffuse projections to the cortex and other areas. Intermittent vagal stimulation has the potentiality of reducing the number and/or the intensity of seizures in patients with intractable epilepsy. These results indicate that feasibility studies in humans should be continued and expanded.
To assess the efficacy of PGE2 in inducing in vivo bone formation, graded doses of prostaglandins E2 were administered to 255 g rats. Histomorphometric analyses of selected sequential fluorescent-labeled bones of rats treated with 0, 0.3, 1.0, 3, or 6 mg PGE2/kg/d for 21 days showed that the doses PGE2 depressed longitudinal bone growth, increased growth cartilage thickness slightly, decreased degenerative cartilage cell size and cartilage cell production slightly, and increased proximal tibial metaphyseal hard-tissue mass markedly. Periosteal bone formation was depressed at the higher doses, and an early, slight depression in endosteal bone formation was also observed, along with a striking late increase in endosteal bone formation and in the formation of trabecular bone in the marrow cavity of the tibial shaft. The characteristics and magnitude of these responses were quite similar to those observed in our previous study of the effects of PGE2 on weanling rats except for the delayed increase in cortico-endosteal bone formation.
Nine-month-old female rats were double-labeled with bone markers and subjected to right hindlimb immobilization or served as control for 0, 2, 10, 18, or 26 weeks. The right limb was immobilized against the abdomen, thus unloading it, while the left limb was overloaded during ambulation. Single photon absorptiometry and cancellous bone histomorphometry were performed on dissected intact femur and 20-microns-thick undecalcified specimens of the proximal tibial metaphysis. In the unloaded limb, immobilization-induced muscle and cancellous bone loss occurred rapidly before 10 weeks and stabilized at 50% less bone mass after 18 weeks. Unloading caused a negative bone balance from a combination of elevated bone resorption and depressed bone formation. At 2, 10, and 18 weeks of immobilization, the ratios of bone resorption to bone formation surfaces were 1.6, 1.5, and 1.3, respectively; at 26 weeks, the ratio was 1. The bone loss was accompanied by poorer trabecular architecture (trabecular number decreased and trabecular separation increased), reaching the maximum at 18 weeks and stabilizing thereafter. These observations are in general agreement with Frost's postulate for mechanical effects on lamellar bone remodeling, and the findings on disuse osteoporosis in man. Therefore, the one-legged immobilization model can be useful in studies of the mechanisms of structural adaptation to mechanical usage.
Convulsive dose 50s (CD50s) for various convulsive drugs and minimal and maximal electroshock seizure thresholds were determined in DBA and C57 mice. DBA mice had lower maximal electroshock seizure thresholds (MESTs, 15%) and CD50s for homocysteine thiolactone (HTL, 23%) and bicuculline (69%), and a higher CD50 for pentylenetetrazol (PTZ) at 3 weeks of age, the age of maximal audiogenic seizure (AGS) susceptibility. At 8 weeks, when DBA mice are not susceptible to AGSs, significant differences were a lower minimal electroshock seizure threshold (mEST, 37%) and maximal EST (MEST) (19%), lower CD50s for N-methyl-D-aspartate (NMDA) (39%), kainic acid (KA, 50%), HTL (32%), strychnine (37%), and a higher CD50 for nicotine (55%) in DBA mice. Based on these data it is suggested that pathways involving NMDA and KA receptors are responsible for increased susceptibility to seizure initiation (mEST), and are opposed by glycine pathways, and that opposing GABA and cholinergic systems at higher CNS levels are involved in seizure spread (AGSs and MEST) in these mice. Latency patterns indicate that nicotine, strychnine, PTZ and bicuculline have high blood-brain barrier (BBB) penetrability. Picrotoxin and the excitatory amino acid receptor agonists had longer latencies, suggesting low BBB penetrability. Age-related changes in latency, however, give evidence that difficulty in drug penetration of the BBB is not responsible for differences observed in CD50s between strains.
Effects of various concentrations of CO2 on brain excitability and electrolyte distribution in rats were studied, and also some properties of seizures induced by abrupt withdrawal from high concentrations of CO2. Inhalation of relatively low concentrations of CO2 (5–20%) decreases brain excitability, as measured by an increase in electroshock seizure threshold (EST). In moderately high concentrations (25–40%), CO2 increases brain excitability, as measured by a decrease in EST and the appearance of spontaneous seizures. Inhalation of high concentration of CO2 (40% or higher) markedly decreases brain excitability and causes anesthesia. Thus the effect of CO2 on brain excitability is related to the concentration inhaled. Abrupt removal of rats from high (anesthetic) concentrations of CO2 results in spontaneous clonic seizures within 30 seconds to 1 minute after withdrawal; these seizures last for 1–2 minutes. Inhalation of 50% CO2 decreases brain intracellular Na and K concentrations and produces a marked cellular acidosis. Thirty seconds after abrupt withdrawal of rats from 50% CO2, but prior to the onset of seizures, the concentration of Na in brain cells increases and the concentration of K decreases.
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