Bioelectric activity and metabolism of individual brain structures at different times after administration of synthetic tetrapeptidamide

Complex study of the opioid tetrapeptide amid (TPA) effect on metabolism and neurophysiological processes of different cortical areas, caudate nucleus n. accumbens allowed to detect prolonged (several days) specific action on these structures. The influence was manifested in certain changes of transmitter metabolism, background bioelectric activity, as well as in changes of EEG reactions to adequate afferent signals. The duration of the detected changes significantly exceeded the duration of anti-pain TPA effect.     

Neuropharmacological activity of cerucal and haloperidol by intraperitoneal and intrastriatal administration in rats]

The effects of three-week administration of cerucal and haloperidol were compared in two ways of injections--intraperitoneal 10 mg/kg and intrastriatal 5 micrograms/l microliter. Both of the ways produce the inhibition of rats locomotor activity, but only after the intraperitoneal haloperidol injection the cataleptic status was observed. The inhibition of avoidance conditioning in shuttle box was registered in each haloperidol microinjections, but in case of cerucal intrastriatal microinjection this effect in first 4-5 days of experiment was limited. No any muscular deviation after cerucal injection (systemic and intrabrain) were observed. The antihyperkinetic activity and striatal mechanisms of cerucal and their application in neurology were discussed.     

The significance of multiple neuromediator activity in supporting integrative brain functions

Properties were studied of reactions of neural cells of the sensorimotor cortical area to locally microionophoretically administered l-glutamate, acetylcholine, norepinephrine and gamma-aminobutyric acid. It is shown that neuronal reactions to the action of the above-mentioned transmitters differ both in direction of change in the impulse activity frequency and in temporal offracteristics (latency and duration of after-effect). It is substantiated that due to the specificity of temporal ranges of action of the transmitter on neural cells, the possibility of effective interaction and temporal coding of heterofunctional information is provided.     

Monoaminoxidase activity and serotonin metabolism in the brain of rats during latent inhibition]

The monoamine oxidase (MAO) activities and the concentrations of 5-HT and 5-hydroxyindoleacetic acid were investigated in four brain regions in rats during the acquisition of latent inhibition in one-trial passive avoidance task. 5-HT metabolism was not altered in the hippocampus. Changes of 5-HT metabolism were found in the frontal cortex during testing of latent inhibition and were accompanied by lowering of MAO activity. No change of 5-HT metabolism was observed in this structure at the stage of pre-exposition to conditioned stimulus. 5-HT metabolism was activated at the stage of pre-exposition to conditioned stimulus in the amygdala and striatum and was maintained on high level, in these structures during testing of latent inhibition. The data presented here indicate that serotoninergic system in various brains regions is specifically involved in the formation of different stages of latent inhibition.     

Corticosterone administration and lipid metabolism in brain regions during development.

Effect of corticosterone on lipid contents of different brain regions and the effect of age on the sensitivity of these regions to corticosterone have been studied. Corticosterone administration (40 mg/kg body wt, sc) to 17-day-old rat for 3 days led to significant decrease in phospholipid content of cerebellum and increase in cholesterol contents of hippocampus and striatum. However, there was no effect on cerebral cortex and brain stem lipids. This alteration in lipids was associated with decrease in [U-14C] glucose incorporation into cholesterol and phospholipids, decrease in plasma beta-hydroxy butyrate levels and increase in beta-hydroxy butyrate dehydrogenase activity in hippocampus and striatum, thereby suggesting that suppression of glucose utilization by corticosterone was compensated by higher utilization of ketone bodies for lipid synthesis in these regions. The sensitivity to corticosterone appears to be age-specific as, at 20-day, cerebellum, hippocampus and striatum were susceptible, at 10-day only hippocampus and at 40- and 90-day none of these regions responded to the treatment.     

Change in monoamine content and monoamine oxidase activity in brain structures during experimental allergic encephalomyelitis]

The serotonin, noradrenaline, adrenaline concentration in the blood, cerebrospinal fluid and some brain structures, and tissue monoaminoxidase activity (MAO) were investigated in dogs during experimental allergic encephalomyelitis. During the perparalytic period there was a tendency to reduction of the serotonin concentration and to the elevation of the catecholamine content. The stage of clinical manifestation of encephalomyelitis was accompanied by reduction of the serotonin level in the white matter of the cerebral hemispheres, and by genralized inhibition of the adrenergic structures. In this case the MAO activity displayed no significant change; this permitted to consider the disturbance of the monoamine synthesis as a result of immune aggression, as a possible cause of inhibition of the monoaminergic system.     

Aberrations of cortical and subcortical integration during chronic administration of haloperidol to the dog

The character of evoked potentials (EPs) dynamics to signal light stimulus during elaboration of avoidance reaction, allows to assert that during formation of adaptive activity functional balance is established of sensory and integrative-triggering brain parts or functional balance of "motor" and "sensory" integration regimes. Each of the studied subcortical structures is characterized by simultaneous but specific functioning both in the motor and sensory regimes; such conclusion is based on different dynamics of their EPs parameters: the changes of ones correspond to EPs dynamics in the visual cortical area, of the others--in the motor area. During chronic haloperidol administration, the reorganizations of intercentral relations are observed in 10--12 days after the beginning of drug administration. They may be considered as a succession of disturbances of functional balance between "sensory" and "motor" integration regimes: at first the sensory regime domination appears in which subcortical structures are chiefly and uniformly involved (ncd, pall and n. acc.); "motor" regime is weakened; then, as a result, a distortion of the "motor" regime of integration takes place. In this case a bradykinesia is developed.     

Increased tolerance of the dopamine- and serotoninergic systems during chronic administration of haloperidol and levomepromazine

In experiments on male albino rats single administration of haloperidol produced catalepsy, increase in dopamine turnover, enhancement of main dopamine metabolite homovanilinic acid in the forebrain. After single administration of the levomepromazine the cataleptogenic effect was accompanied by an enhanced 5-hydroxyindole acetic acid level, and no influence on the dopamine metabolism was observed. During chronic administration of haloperidol and levomepromazine their ability to induce catalepsy and to increase homovanilinic acid or 5-hydroxyindoleacetic acid concentration diminished. Thus, it appears that chronic administration of haloperidol reduces the sensitivity of dopamine receptors, and chronic administration of levomepromazine--reduces the sensitivity of dopamine and serotonin receptors in the brain.     

Biogenic amines in brain structures of rats of different zoo-social rank during immobilization stress]

The content of monoamines and their metabolites in different parts of the brain: mesencephalic reticular formation, locus coeruleus, sensomotor cortex was studied by high-performance liquid chromatography in rats with different zoo-social position. Content of dopamine and serotonin in the brain structures studied was found to be different in dominants and subdominants. Maximal changes of monoamines under immobilization stress were observed in dominants.     

Hippocampal electrical activity and gamma-aminobutyrate metabolism in brain tissue following administration of homocysteine

Abstract: The concentration of γ-aminobutyrate (GABA) and the activity of glutamate decarboxylase and GABA-transaminase were measured in extracts of mouse brain before the onset and during the course of generalized seizures induced by systemic administration of homocysteine thiolactone. The results indicate that whole brain GABA metabolism is unaffected by subconvulsive and convulsive doses of homocysteine at all stages of the generalized seizure. Electroencephalographic monitoring of rat brain electrical activity via hippocampal electrode implantation allowed the course of homocysteine-induced seizures to be followed and afforded a means of quantifying such seizures.     

Glutathione defense system in various brain structures during starvation]

Distribution of glutathione reductase (GR) and selenium-dependent glutathione peroxidase (GP) activity and the content of selenium in the cytosolic fraction of the brain stem, hypothalamus and different cortical areas of the rat cerebrum in norm and under starvation was investigated. It was shown that GR activity in all investigated structures was approximately identical, but GP activity in various cortical areas was 1.5-2.0 times higher, than that in the mesencephalon and myeloencepalon. During 2-3 days of starvation GR activity changed insignificantly, whereas GP activity varied within wide limits. Under prolonged starvation a significant decrease in the content of selenium and GP activity was observed. The correlation of these changes was more expressed in the hypothalamus. It was assumed that glutathione and enzymes of its metabolism were involved in the regulatory system of redox processes in the nervous tissues in the primary period of starvation.     

Interrelationships between plasma homovanillic acid and indices of dopamine turnover in multiple brain areas during haloperidol and saline administration

Haloperidol or saline was administered to rats daily for 1, 8, 15 or 22 days. During haloperidol, but not saline administration, changes in plasma homovanillic acid (HVA) concentrations were correlated with changes in nucleus accumbens HVA. Haloperidol administration also had a significant effect on the intercorrelation of dopamine (DA) concentrations and indices of DA turnover across multiple brain areas. In particular, intercorrelations of HVA concentrations among DA terminal brain areas (i.e. striatum, nucleus accumbens, and olfactory tubercle) occurred only during haloperidol treatment.     

Regional brain glucose utilization during and following chronic naltrexone administration: preliminary observations in rat brain

Experiments were conducted to determine some of the metabolic correlates of tonic opioid activity in the central nervous system under conditions previously examined for changes in monoamine levels. The glucose metabolic rates in seven brain regions were determined by autoradiographic visualization of 14C-deoxyglucose incorporation in female rats after 8 days of chronic exposure to naltrexone pellets and 10 days after pellet removal. Autoradiographs were analyzed on a region-by-region basis to correspond to areas previously dissected and analyzed for changes in monoamine content under similar experimental conditions. Chronic administration of naltrexone resulted in a significant decrease in the metabolic activity of neurons in the striatum. Other brain areas examined under this condition were not significantly affected. Ten days following pellet removal, 14C-deoxy-glucose incorporation was indistinguishable from that determined in placebo treated rats in all brain regions examined. These results indicate that tonic opioid input is an important determinant of metabolic activity in the striatum. In addition, these results indicate that conditions previously shown to alter regional content of monoamines do not necessarily produce concomitant changes in regional glucose utilization.     

Enhancement of rat brain tryptophan metabolism by chronic ethanol administration and possible involvement of decreased liver tryptophan pyrrolase activity.

1. Chronic ethanol administration enhances rat brain 5-hydroxytryptamine synthesis by increasing the availability of circulating tryptophan to the brain. This increased availability is not insulin-mediated or lipolysis-dependent. 2. Under these conditions, tryptophan accumulates in the liver and apo-(tryptophan pyrrolase) activity is completely abolished, but could be restored by administration of regenerators of liver NAD+ and/or NADP+. 3. All four regenerators used (fructose, Methylene Blue, phenazine methosulphate and sodium pyruvate) prevented the ethanol-induced increase in liver tryptophan concentration and the increased availability of tryptophan to the brain. 4. It is suggested that the enhancement of brain tryptophan metabolism by chronic ethanol administration is caused by the decreased hepatic tryptophan pyrrolase activity. The results are briefly discussed in relation to previous work with ethanol. 5. Fructose enhances the conversion of tryptophan into 5-hydroxyindol-3-ylacetic acid in brains of ethanol-treated rats, whereas Methylene Blue inhibits this conversion in both control and ethanol-treated animals.     

Impact of chronic fructose infusion on hepatic metabolism during TPN administration

During chronic total parenteral nutrition (TPN), net hepatic glucose uptake (NHGU) is markedly elevated. However, NHGU is reduced by the presence of an infection. We recently demonstrated that a small, acute (3-h) intraportal fructose infusion can correct the infection-induced impairment in NHGU. The aim of this study was to determine whether the addition of fructose to the TPN persistently enhances NHGU in the presence of an infection. TPN was infused continuously into the inferior vena cava of chronically catheterized dogs for 5 days. On day 3, a bacterial clot was implanted in the peritoneal cavity, and either saline (CON, n = 5) or fructose (+FRUC, 1.0 mg. kg(-1). min(-1), n = 6) infusion was included with the TPN. Forty-two hours after the infection was induced, hepatic glucose metabolism was assessed in conscious dogs with arteriovenous and tracer methods. Arterial plasma glucose concentration was lower with chronic fructose infusion (120 +/- 4 vs. 131 +/- 3 mg/dl, +FRUC vs. CON, P < 0.05); however, NHGU was not enhanced (2.2 +/- 0.5 vs. 2.8 +/- 0.4 mg. kg(-1). min(-1)). Acute removal of the fructose infusion dramatically decreased NHGU (2.2 +/- 0.5 to -0.2 +/- 0.5 mg. kg(-1). min(-1)), and net hepatic lactate release also fell (1.6 +/- 0.3 to 0.5 +/- 0.3 mg. kg(-1). min(-1)). This led to an increase in the arterial plasma glucose (Delta13 +/- 3 mg/dl, P < 0.05) and insulin (Delta5 +/- 2 micro U/ml) concentrations and to a decrease in glucagon (Delta-11 +/- 3 pg/ml) concentration. In conclusion, the addition of chronic fructose infusion to TPN during infection does not lead to a persistent augmentation of NHGU.     

Disturbances in catecholamine metabolism during formation and development of chronic alcoholism]

There has been carried out an investigation dealing with catecholamines metabolism in the patients suffering from alcoholism in the first, second and third stage at the short-term remission. The first developed alcoholism stage was determined as a typical one for increasing the excretion with urine of DOPA, dopamine (DA), noradrenaline (NA) and adrenaline (A), as well as the blood levels of DA, NA and A. DA/NA rate evidences about an increased synthesis of NA with DA. The marked second alcoholism stage is characterized by an acute decrease of excreting with urine and blood levels of NA. Alongside with the latter. DA excretion with urine and its blood levels remained high. DA/NA rate indicates to the considerably low relative activity of NA with DA synthesis, both in relation to the control and to the developed first alcoholism stage. In the third alcoholism stage NA excretion with urine and its blood levels become lower relatively to the marked second stage. Simultaneously DA excretion with urine and its blood levels are lower than in the developed second stage, hower exceed the control values. DA/NA rate testifies the slight activation of NA and DA synthesis. The results obtained in the work indicate to the significant role of CA metabolism disturbances in the alcoholic dependence formation.