Effect of lithium oxybutyrate on excitability of the cortex and some subcortical structures in rabbit brain

Lithium oxybutyrate microinjections (10 mg/ml) produce a depressant action on spontaneous bioelectrical activity of the cortex and subcortical structure. The drug brings down excitability of the motor cortex, hippocampus, caudate nucleus, thalamus, posterior hypothalamus and mesencephalic reticular formation; it also raises excitability of the tonsils. The depressant effect of lithium oxybutyrate is superior to that of lithium chloride.     

Function of the superior colliculi of the corpora quadrigemina during creation of a local focus of increased excitability in the mesencephalic reticular formation and sensomotor cortex

In chronic experiments on waking rabbits, the foci of heightened excitability in the sensorimotor cortex and mesencephalic reticular formation affected in a similar way the background neuronal activity in the superior colliculi and that evoked by light stimuli. The effect was manifested in elimination of inhibitory pauses in the neuronal response to light stimulus and in a general increase of discharge frequency. Similarity of the cortical and reticular influences is due to their possible mediation by the same collicular interneurones participating in inhibitory pauses formation in the process of backward inhibition. Increased neuronal activity in the superior colliculi under the action of local foci in the sensorimotor cortex and mesencephalic reticular formation correlated with appearance of forelimb motor reaction to isolated light stimulus testifying to a formation of a functional connection between the visual and motor analyzers. Possible role of the superior colliculi in this process and their participation in the formation of a visually controlled reaction is discussed.     

Mechanism of the effect of the midbrain reticular formation on the hypothalamus-hypophysis-thyroid gland system]

The role of the posterior hypothalamic nuclei in the transmission of the influences of the mesencephalic reticular formation upon the thyroid hormone secretion was studied. Stimulation of the mesencephalic reticular formation in anesthetized cats was followed by the excitation of the thyroid hormoone secretion: the content of the blood protein-bound iodine was increased. This effect was eliminated after the bilateral coagulation of the posterior hypothalamic nuclei. These findings confirmed the hypothesis on the leading role of the posterior hypothalamic nuclpeus in the stimulation of the hormone secretion.     

Participation of the posterior hypothalamus in the activity of the ascending activating system]

In chronic experiments on cats with premezencaphalic section of the brain stem electrica stimulation of the posterior hypothalamus caused desynchronization of the electrical activity of the neocortex. After the isolated injury of the posterior hypothalamus a moderate electrical stimulation of the medical part of the midbrain reticular formation failed to cause any pronounced activation of the neocortex. The results obtained indicated an important role of the posterior hypothalamus in the function of the ascending activating system.     

Brain activation by photic stimulation in normal cats and after transection of afferent pathways to the mesencephalic reticular formation

In chronic experiments on waking, unimmobilized cats with implanted electrodes, the EEG activation reaction evoked by short flashes of varied intensity was recorded in normal animals and after blocking excitatory influences of the visual sensory system on the brain-stem reticular formation by transection of the brachium colliculi superioris bilaterally. The intensity of the activation reaction in intact animals increased steadily with an increase in intensity of the photic stimuli. No clear dependence of response amplitude on stimulus intensity was observed in the cats with transection; the changes were largely random in character. It is suggested that these disturbances were due to interruption both of the ascending flow excitatory afferent impulses to the brain-stem reticular formation through the brachia and superior colliculi and of corticofugal volleys descending from the cortex to the mesencephalic reticular formation via the same brachia, and controlling the level of its activation.I. P. Pavlov Institute of Physiology, Academy of Sciences of the USSR, Leningrad. Translated from Neirofiziologiya, Vol. 13, No. 5, pp. 500–505, September–October, 1981.     

Hypothalamic evoked potentials to vagus and sciatic nerve stimulation

Hypothalamic evoked potentials to stimulation of the cervical portion of the vagus nerve and the sciatic nerve were recorded in experiments on cats anesthetized with chloralose and immobilized with succinylcholine. When both monopolar and bipolar recording techniques were used the focus of maximal activity of both "visceral" and "somatic" evoked potentials was located in the supramammillary and posterolateral region of the hypothalamus. Responses in the tuberal and anterior hypothalamus occurred in most experiments after a longer latent period, their amplitude was lower, and they were less stable. Evoked potentials in the focus of maximal activity of the posterior hypothalamus are similar in all parameters to responses of the mesencephalic reticular formation. Evoked potentials to stimulation of the visceral nerve have a higher threshold of generation and a lower amplitude than the "somatic" responses and they are inhibited more strongly when the frequency of stimulation is increased. Evoked potentials arising in the hypothalamus in response to stimulation of the vagus and sciatic nerves are regarded as nonspecific responses of reticular type.L. A. Orbeli Institute of Physiology, Academy of Sciences of the Armenian SSR, Erevan. Translated from Neirofiziologiya, Vol. 5, No. 3, pp. 253–260, May–June, 1973.     

A crossed projection from the optic tectum to craniocervical premotor areas in the brainstem reticular formation. An anterograde and retrograde tracing study in the mallard (Anas platyrhynchos L.)

The optic tectum in birds receives visual information from the contralateral retina. This information is passed through to other brain areas via the deep layers of the optic tectum. In the present study the crossed tectobulbar pathway is described in detail. This pathway forms the connection between the optic tectum and the premotor area of craniocervical muscles in the contralateral paramedian reticular formation. It originates predominantly from neurons in the ventromedial part of stratum griseum centrale and to a lesser extent from stratum album centrale. The fibers leave the tectum as a horizontal fiber bundle, and cross the midline through the caudal radix oculomotorius and rostral nucleus oculomotorius. On the contralateral side fibers turn to ventral and descend caudally in the contralateral paramedian reticular formation to the level of the obex. Labeled terminals are found in the ipsilateral medial mesencephalic reticular formation lateral to the radix and motor nucleus of the oculomotor nerve, and in the contralateral paramedian reticular formation, along the descending tract. Neurons in the medial mesencephalic reticular formation in turn project to the paramedian reticular formation. Through the crossed tectobulbar pathway visual information can influence the activity of craniocervical muscles via reticular premotor neurons.     

Participation of the thalamic reticular nucleus in the shaping of the interrelations of the mesencephalic reticular formation and the lateral geniculate body

On the awake rabbits and cats under nembutal anesthesia it has been shown that the reticular nucleus of the thalamus takes considerable part in the formation of reticulogeniculate response of the lateral geniculate body (LGB) to electrostimulation of the mesencephalic reticular formation. It is assumed that the reticular nucleus of the thalamus takes basic part in a realization of "rapid" physical influences of the reticular formation on the LGB.     

Changes in neurochemical properties of mesencephalic reticular neurons during negative emotional reactions

On microiontophoretic application of acetylcholine, noradrenalin, and serotonin to single neurons of the mesencephalic reticular formation of unanesthetized rabbits, qualitative changes in responses to one or more of these biologically active substances were discovered in about 50% of cells after electrical stimulation of the negative emotiogenic zone of the ventromedial hypothalamus. Changes in chemical sensitivity of reticular neurons to noradrenalin and serotonin were observed twice as often as to acetylcholine. It is suggested that a reorganization of the neurochemical properties of the central neurons may be one of the mechanisms of formation of negative emotional states.P. K. Anokhin Research Institute of Normal Physiology, Academy of Medical Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 13, No. 5, pp. 506–514, September–October, 1981.     

Inputs to the torus semicircularis in the electric fish Eigenmannia virescens

Summary The posterior lateral-line lobe, contrary to present belief, projects bilaterally to the torus semicircularis, although the contralateral projection is considerably more extensive. The torus also receives bilateral inputs from the medial octavo-lateralis nuclear complex, the reticular formation, a sublemniscal nucleus, and the nucleus prae-eminentialis. Unilateral inputs to the torus were found originating from the ipsilateral mesencephalic tectum and the contralateral lobus caudalis of the cerebellum. Extensive commissural systems between the right and left torus are also described for the first time.     

Electrical activity of the cortex and subcortical structures during the development of hypoxia due to blood loss

Previous experiments on dogs showed that in several cases, along with the development of hypoxia, polymorphous delta-waves changed into synchronous oscillations, also of delta range, the so-called standard slow complexes (SSC). The new experimental data showed discharges of neuronal pool during SSC to be present in the caudate nucleus, lateral and medial thalamus, hypothalamus, hypocampus, n. amygdale, and mesencephalic reticular formation. The most frequent neuronal pulse activity was connected with the second half of the SSC negative phase (P is less than 0.01). Discharge flashes of the neuronal pool during the SSC indicated that SSC reflected the physiological processes occurring in these structures.     

Influence of lithium hydroxybutyrate on the electroencephalographic effects of fenamin

Lithium hydroxybutyrate (10 mg/kg) prevents the amphetamine-induced EEG arousal and amplitude frequency alterations in the motor and visual cortex, posterior hypothalamus, midbrain reticular formation, and caudate nucleus but potentiates the action of the psychostimulant on the EEG of the hippocamp and amygdala. The response to the light flickering rhythm in the visual cortex remains within initial upon concurrent administration of both the drugs.     

Caffeine tolerance: behavioral, electrophysiological and neurochemical evidence

The development of tolerance to the stimulatory action of caffeine upon mesencephalic reticular neurons and upon spontaneous locomotor activity was evaluated in rats after two weeks of chronic exposure to low doses of caffeine (5-10 mg/kg/day via their drinking water). These doses are achievable through dietary intake of caffeine-containing beverages in man. Concomitant measurement of [3H]-CHA binding in the mesencephalic reticular formation was also carried out in order to explore the neurochemical basis of the development of tolerance. Caffeine, 2.5 mg/kg i.v., markedly increased the firing rate of reticular neurons in caffeine naive rats but failed to modify the neuronal activity in a group exposed chronically to low doses of caffeine. In addition, in spontaneous locomotor activity studies, our data show a distinct shift to the right of the caffeine dose-response curve in caffeine pretreated rats. These results clearly indicate that tolerance develops to the stimulatory action of caffeine upon the reticular formation at the single neuronal activity level as well as upon spontaneous locomotor activity. Furthermore, in chronically caffeine exposed rats, an increase in the number of binding sites for [3H]-CHA was observed in reticular formation membranes without any change in receptor affinity. We propose, therefore, that up-regulation of adenosine receptors may underlie the development of tolerance to the CNS effects of caffeine.     

Brain areas implicated in cholinergic regulation of sexual behavior

Sexual behavior in female rats was facilitated by infusion of a cholinergic agent into specific brain regions. Carbachol, a cholinergic receptor agonist, increased the incidence of lordosis in estrogen-primed female rats following bilateral infusion (0.5 μg/cannula) into either the medial preoptic area or the ventromedial hypothalamus. The behavioral response was highest 15 min after carbachol infusion and returned to control levels within 90 min after infusion. Carbachol failed to activate lordosis following infusion into the mesencephalic reticular formation or frontal cortex. These results indicate that the potential of a brain area to respond to cholinergic stimulation may be related to the ability of that area to concentrate estrogen.     

Preference and aversion for brain stimulations estimated by the conditioned place preference

Rats implanted with chronic electrode into the medial forebrain bundle at the level of the hypothalamus (which elicited self-stimulation behaviour) display conditioned place preference after repeated stimulations of this area; conversely rats implanted into the mesencephalic dorso-medial tegmentum (which elicited switch-off behaviour) present conditioned place aversion after such repeated stimulations. Furthermore rats implanted in these two area without exhibiting self-stimulation or switch-off behaviours also display preference or aversion for the location paired with the brain stimulations. It was thus hypothesized that the conditioned place preference procedure seemed to present a higher sensitivity than the bar pressing procedures to detect preference or aversion for brain stimulation. Moreover the activation of the medial forebrain bundle which was associated with positive affect is more effective for a long term retention of the preferred location than midbrain periventricular reticular activation which induces a negative affect.     

Effects of stimulating the caudal zones of the mesencephalic reticular formation on the postcruciate cortex of the cat]

The influence of the electrical stimulation of the dorsolateral (DL) and the ventromedial (VM) portions of the caudal area of the mesencephalic reticular formation on the neuronal activity of the lateral zone of the gyrus sygmoideus posterior was investigated in cats. The mesencephalo-cortical influences were mainly excitatory in character; the predominance of the neuronal reactions with a short latency (3--12 msec) during the VM stimulation and reactions with a longer latency (20--25 msec) during the DL stimulation was revealed. The VM and the DL were found to influence both cortical neurones, the ones sensitive to somesthetic stimuli (mono-, di- and polyvalent) and the ones which failed to respond to the electrocutaneous stimulation of the limbs.     

Changes in the hypothalamus, reticular formation and pituitary of rats during development of subcutaneous tumors]

Dynamics of structural changes was studied in the hypothalamus, reticular formation and the hypophysis of rats, depending on the phases of development in them of 9m10-dimethyl-1,2-benzanthracene-induced tumours. The phase of subcutaneous tumours appearance proved to be accompanied by structural and functional changes in the hypothalamus, reticular formation and the hypophysis.     

Investigating cerebellar connections in the turtle using the horseradish peroxidase technique of axonal transport

Cerebellar connections were investigated in the turtle using a technique of unilateral application of horseradish peroxidase to the body and the nuclei of the cerebellum as well as the structures of the mesencephalic tegmentum. Findings showed that the origins of projections to the cerebellum in the caudal sections of the brain (vestibular nuclei, perihypoglossal complex, inferior reticular formation with the inferior olive, the spinal chord, etc.) were more numerous than in the rostral mesodiencephalic regions, such as the tegmentum and the pretectum. Extensive efferent cerebellar projections were detected both in the medulla, including the vestibular nuclei and nuclei of the dorsal columns of the spinal cord, and in the mesencephalic tegmentum, but were rare in the hypothalamus and the ventral somatic section of the thalamus. The conclusion was reached that the closest similarity between reptiles and mammals is seen in the afferent and efferent connections linking the cerebellum with the spinal cord, the caudal sections of the brain stem, and the mesencephalic brain structures, which have a common involvement in the regulation of muscle tonus and the coordination of locomotor activity.I. M. Sechenov Institute of Evolutionary Physiology and Biochemistry, Academy of Sciences of the USSR, Leningrad. Translated from Neirofiziologiya, Vol. 17, No. 6, pp. 786–794, November–December, 1985.     

Histofluorescence studies of monoamine neurons in the rat brain after cobaltous acetate intoxication

The aim was to study changes in brain monoamine neurons in an experimental animal model with an extrapyramidal motor syndrome of the parkinsonian type. The neurological signs were observed in rats after acute cobaltous acetate intoxication under mild ischemic conditions. Histofluorescence studies showed a decrease in catecholamine fluorescence (which signifies a decrease in the amine content) in the hypothalamus and mesencephalic reticular formation, but not in the substantia nigra or basal ganglia. Serotonin fluorescence was increased in nerve cell bodies of the dorsal and median raphe nuclei and in nerve terminals in some thalamic and preoptic regions. Histological staining of sections adjacent to the fluorescent ones showed no neuronal loss and some pathology of myelin. The disturbing effect of cobaltous ions on the neuronal transmission, and/or the imbalance between dopamine and serotonin in the extrapyramidal motor syndrome observed in poisoned rats have been discussed.     

Expression mapping of cytotoxic T-lymphocyte antigen-2α gene transcripts in mouse brain

Cytotoxic T-lymphocyte antigen-2alpha (CTLA-2alpha), an inhibitor peptide homologous to the proregion of mouse cathepsin L, was originally discovered and expressed in mouse-activated T-cells and mast cells. Expressed recombinant CTLA-2alpha is shown to exhibit selective inhibition to cathepsin L-like cysteine proteinases. However, its in vivo targets in mammalian tissues are yet to be identified. We carried out in situ hybridization studies to examine the expression pattern of CTLA-2alpha mRNA and determine the specific cell types synthesizing CTLA-2alpha in the mouse brain. CTLA-2alpha mRNA was detected in various neuronal populations within the telencephalon in cerebral cortices, olfactory system, septum, basal ganglia, amygdala and highest levels were observed in the hippocampus. Within the diencephalon high density of positive cells was found in mediodorsal and lateral posterior thalamic nuclei and medial habenular nucleus (MHb). In the hypothalamus, high density of CTLA-2alpha mRNA labeling was seen in the suprachiasmatic nucleus (Sch), optic tract, arcuate nucleus, and median eminence. The fasciculus retroflexus and its termination in the mesencephalic interpeduncular nucleus were also densely labeled. Other mesencephalic expression sites were the superior colliculus, periaqueductal gray, paramedian raphe nucleus, and inferior colliculus. In the rhombencephalon, strong labeling was detected in the pontine, vestibular, and reticular nuclei. Intense expression was also noted within cerebellar cortex in Purkinje neurons and at a moderate level in granule cell layer, stellate, and basket cells. A possible function of this novel inhibitor peptide in relation to learning, memory, and diseases is discussed.