Effect of ethanol on central mechanisms of alimentary and defensive motivation in the rabbit

A single intravenous administration of ethanol (0.5 g/kg) to rabbits had different effects on the excitability of feeding and defensive motivational centers of the lateral and ventromedial hypothalamus. Ethanol abolished both inhibitory effects of the dorsal hippocampus and facilitatory action of the midbrain reticular formation on alimentary and defensive motivations. It elicited new power distributions of the main rhythms of general electrical cortical activity in the background and under stimulation of limbic-midbrain structures. Analysis of the activity of organello-specific enzymes in limbic-midbrain neurones revealed disturbances of cellular energetic processes caused by ethanol.     

Substance P and effects of ethanol on the central mechanisms of the escape reaction in rabbits

Substance P (SP) effects on the central mechanisms of escape reaction, elicited by threshold electrical stimulation of the ventromedial hypothalamus were investigated in rabbits pretreated with ethanol (0.5 g/kg). SP (30 micrograms/kg) was demonstrated to normalize in 71.4% of cases the excitability of the ventromedial hypothalamus which was decreased by ethanol and restored in 83.3% of cases the facilitatory effects of the midbrain reticular formation in escape reactions. However, SP was ineffective in the restoration of the inhibitory effects of the dorsal hippocamp on the excitability of the ventromedial hypothalamus that was obvious in intact animals. Partial normalizing effect of SP on escape reaction in rabbits after previous ethanol administration can be accounted for by the fact that both undecapeptide and ethanol are similar in their realization of central effects such as an interaction with the same brain neurotransmitters, interference with neuronal enzyme processes and reactions with opiate receptors.     

Enhancement of the resistance of the escape reaction to ethanol after substance P]

An ability of substance P (30 micrograms/kg intravenously) to prevent deleterious effects of ethanol (E) (0.5 g/kg intravenously) on central mechanisms of escape reaction elicited by threshold electrical stimulation of the ventromedial hypothalamus was investigated in chronic experiments upon rabbits. Substance P was found to prevent E effects on excitability of the ventromedial hypothalamus (VMH) and on facilitatory influences of the midbrain reticular formation on this emotional centre which were observed in intact animals. Inhibitory effects of the dorsal hippocampus on the VMH could not be evaluated due to its alterations in response to previous substance P administration. The authors suggest that substance P can be considered to be a possible endogenous factor to increase a tolerance of emotional behavioural reactions of an organism to alcohol.     

Substance P in the central mechanism of the rabbit feeding response evoked by stimulation of the lateral hypothalamus

The effects of substance P on the central mechanisms of food motivation elicited by electrical stimulation of the lateral hypothalamus were studied in chronic experiments on rabbits. Intravenous injection of substance P (30 micrograms/kg) brought about a dramatic reduction in the excitability of the "food center" in the hypothalamus, which returned to normal 45-60 minutes after injection. Higher concentrations of substance P provoked food behavior inversion up to the replacement of food motivation by avoidance behavior. Intravenous injections of substance P disturbed the relationships between the hippocamp, midbrain reticular formation and hypothalamus seen in health. This manifested in complete cessation of the inhibitory effects of the dorsal hippocamp and facilitating influences of the midbrain reticular formation on the excitability of the hypothalamic "food center". It is assumed that disorders of the central mechanisms of food motivation may arise from the effects produced by substance P directly on the central nervous system or on the brain via changes in the hormonal balance and responses of the autonomous nervous system.     

Substance P in the central mechanisms of the escape reaction

The role of substance P in the central mechanisms of escape reaction elicited by electrical stimulation of the ventromedial hypothalamus was investigated in chronic experiments on rabbits. Intravenous injection of substance P (30 micrograms/kg) led to a short-term (less than 10 min) increase in the threshold of stimulation of the ventromedial hypothalamus and to more stable (up to 1.5 h) disorders of the hippocampal-hypothalamic relations. After substance P injection the inhibitory effects of the dorsal hippocampus but not the facilitating influences of the midbrain reticular formation on excitability of the hypothalamic motivation center were found to be lacking. Disorders of the central mechanisms of escape reaction after substance P injection correlated with new patterns of the main EEG rhythms in different areas of the brain cortex in response to the ascending excitations of the limbic-midbrain structures. Interpreting the mechanisms of substance P involvement in escape reaction the authors point to the ability of the given peptide to interact with different transmitter systems of the brain and opiate receptors and to alter the brain blood circulation.     

Responses of neurons of the frontal area of the cortex of the rabbit to electric stimulation of certain limbic-mesencephalic structures after administration of substance P

In rabbits tested on behavioural reactions by electrical stimulation of certain limbic-midbrain structures, intravenous injection of substance P (30 mcg/kg) led after 10 min of silent period to a decrease of spontaneous neuronal activity in the frontal cortex. Convergence of excitations arising from the lateral hypothalamus, the dorsal hippocampus and the midbrain reticular formation was also found to decrease after the substance P injection. Analysis of neuronal responses allowed to establish that substance P markedly changed the ascending excitations of the lateral hypothalamus and was less effective for the influences from the midbrain reticular formation.     

The effect of intracerebroventricular administration of substance P fragment and met-enkephalin on the transmission of nervous impulses between the midbrain reticular formation and two generators of the hippocampal theta rhythm in rabbits

The effect of intracerebroventricular administration of Substance P fragment and met-enkephalin on the excitability of two generators of hippocampal theta rhythm was investigated in the experiments performed on chronic rabbits. Substance P had a strong facilitatory effect on the threshold of the generator of the hippocampal theta rhythm of the frequency 4-7 c/s and an inhibitory effect on the threshold of the generator of the 7-12 c/s frequency evoked by stimulation of the midbrain reticular formation. These effects were dose dependent. The effects of met-enkephalin were opposite. They increased the threshold of the 4-7 c/s hippocampal generator and decreased the threshold of the other generator. The effect of these two compounds was evaluated according to the energy of electrical trains of pulses maintaining the continuous arousal pattern in the hippocampus.     

Interaction of reticular structures in the brain of the cat

In acute and chronic experiments on 35 cats an inhibitory influence was found of the caudal reticular nucleus of pons Varolii on unit activity of the sensorimotor cortex and dorsal part of the midbrain reticular formation. The influence of this structure on unit activity of the ventral part of the midbrain reticular formation was mainly of a facilitatory character. Activation of the ventral part inhibited the unit activity of the dorsal part of the same structure. Consequently, the caudal reticular nucleus of pons Varolii elicits inhibition at the level not only of the cerebral cortex but also of the midbrain reticular formation (of its dorsal part). The character of these influences coincides with that of unit activity changes of these two areas of the midbrain reticular formation during the development of the paradoxical phase of sleep. The obtained facts must underlie the stopping of convulsive activity in this phase of sleep.     

Influence of renin on the effects of electric stimulation on the ventromedial hypothalamus

The influence of intraventricular injection of different doses of renin on the effects of electrical stimulation of the ventromedial hypothalamus was studied. Injection of renin (10 micrograms/kg) into the lateral ventricles of the brain of experimental animals elicited a prolonged elevation of arterial pressure and a decrease of the heart rate, while given in doses of 20 and 30 micrograms/kg it also provoked arrhythmias and ventricular extrasystoles, and a lowering of the threshold of ventromedial hypothalamus stimulation. It was found that under the central action of renin, a short-term stimulation of the ventromedial hypothalamus provoked ventricular extrasystoles.     

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.     

Hypothalamic influences on unit activity in the cat superior colliculus

Experiments on immobilized unanesthetized cats showed that hypothalamic stimulation effectively modified spontaneous unit activity and activity evoked by photic stimulation in the superior colliculus. Long-latency responses, often with a tonic type of formation, were predominant. Meanwhile, definite differences were found in the character of influences from different regions of the hypothalamus. Stimulation of the anterior hypothalamic region and lateral hypothalamus led more frequently to inhibition of spontaneous activity, often expressed as the development of initial inhibition, especially during stimulation of the lateral hypothalamus. Definite modulation of spontaneous activity of cyclic type also developed. Influences from these structures on activity evoked by photic stimulation were chiefly facilitatory and modulating in character. Stimulation of the ventromedial nucleus could produce inhibitory and facilitatory effects equally on activity of tectal neurons, with a tendency for the frequency of manifestation of facilitation to increase when a series of stimuli was used. The mechanisms of triggering and realization of hypothalamic influences on activity in the superior colliculus are discussed.Ivano-Frankovsk State Medical Institute, Ministry of Health of the Ukrainian SSR. Translated from Neirofiziologiya, Vol. 11, No. 6, pp. 560–568, November–December, 1979.     

Role of substance P in regulating the feeding behavior and the avoidance reaction in the rabbit

Similar changes in feeding and avoidance reaction in spite of the way of substance P administration (30 mgk/kg intravenously or 14,8 nmol intraventricular) were found in rabbits with electrodes implanted in various limbic-midbrain structures. Feeding was found to be more sensitive to substance P administration, as it was shown by the decrease of excitability of the hypothalamic "feeding center" and abolishing of the inhibitory and facilitatory effects on this center from the dorsal hippocampus and the midbrain reticular formation, correspondingly. New cortical-subcortical integration under substance P was presented in new characteristics of EEG activity in neocortical areas, both background and in response to stimulation of various limbic-midbrain structures. Biochemical data let to suggest that at the neural level substance P led to destabilization of membrane structures in endoplasmatic reticulum and to redistribution of membrane-connected N-acetylneuramine acid which was directly involved in neurotransmission.     

Limbico-reticular relations during formation of various motivation responses in rabbits subjected to ethanol administration

Chronic experiments on rabbits with electrodes implanted into different limbic-midbrain structures were made to study the effects of a single intravenous injection of ethanol (0.5 g/kg) on the background EEG during formation of food motivation and avoidance behavior from the criterion of the power of the main EEG rhythms. Intravenous injection of ethanol resulted in an increase in the power of beta-, alpha- and theta-rhythms in the frontal cortex, and in that of alpha- and theta-rhythms in the occipital area of the neocortex. New patterns of the powers of the main EEG rhythms recorded in animals exposed to ethanol during electric stimulation of the lateral and ventromedial hypothalamus, evoking food motivation and avoidance behavior, as well as during electrical stimulation of the dorsal hippocamp and mesencephalic reticular formation that correlate with changes in the functions of the study limbic-mesencephalic structures attest to profound ethanol-induced abnormalities of the central mechanisms of food motivation and avoidance behavior.     

Postnatal development of the scratch reflex in rabbits]

The development of the scratch reflex was studied in newborn (up to 2 months old) rabbits in norm and after elimination or activation of some parts of their nervous system (reticular formation, cerebellum, caudate nucleus, cerebral cortex, superior cervical sympathetic ganglia). The experiments with the section of the brain stem at the border between the medulla and the midbrain showed that in very young (5-10 days old) rabbits in norm the scratch reflex is controlled by the spinal cord with no influences of structures situated above the section's level. Later on the spinal mechanism of the scratch reflex becomes subject to supraspinal influences, among which in 2-3 weeks old animals facilitatory effects are predominant produced, in particular, by the reticular formation and the cerebellum, whereas in older age prevail inhibitory influences of the cerebral cortex, cerebellum, caudate nucleus and the sympathetic nervous system.     

Adaptive changes in the evoked electrical activity of the rat brain while training it in a controlled experiment]

A programmed change of a certain phase of cortical EP to a photic flash was reinforced in an unrestrained chronically operated animal (a rat) in the course of an operant controlled experiment. A painful subcutaneous stimulation or stimulation of the emotionally positive zone of the lateral hypothalamus was used as a reinforcing agent. It has been shown that painful stimulation is a more effective reinforcing agent than brain stimulation. Synchronous recordings pointed to a distinct correlation of activity in some structures (field CA1 of the hippocampus) with that of the visual cortex, while in others the EP form characteristically changed at different stages of learning (thalamic reticular nucleus), and in still others, there were no EP changes (midbrain reticular formation) at any stage of learning.     

Effect of stimulation of the reticular formation on the motivational and reinforcing effects of the self stimulation zones

The influence was studied on the midbrain reticular formation (RF) on motivational and reinforcing effects of stimulation of the same selfstimulation zones (SS) of hypothalamic area. A current of gradually increasing intensity was used, by means of which three groups of functionally (behaviourally) specific reticular points were revealed: motivationaly neutral, positive and negative. The data obtained show that influences of RF on SS zones of hypothalamus differand depend on functional properties of various RF areas. Changes of motivational effects in SS zones reflex the specificity of reticular foci in a lesser degree than changes in reinforcing effects. It has been suggested that reinforcing effects of the SS hypothalamic zones possess their own activating mechanism specifically related to its "positive" link and differing from reticular mechanism of unspecific activation.     

Differentiation of efferent projections of the medial (cuneiform nucleus) and lateral regions of the reticular formation in cat midbrain

Efferent connections of medial (nucleus cuneiformis) and lateral regions of the midbrain reticular formation (MRF) were investigated using an anterograde autoradiographic technique in cats. Efferent fibers from the MRF ascend to the globus pallidus, substantia innominata, hypothalamus, subthalamus, and nonspecific associative and relay nuclei of the thalamus. Descending pathways to the conclusion that the cuneiform nucleus is more of a nonspecific structure than an association auditory center. The lateral reticular region had numerous projections to the lateral geniculate body and, together with the parabigeminal nucleus, forms the midbrain visual complex.I. P. Pavlov Institute of Physiology, Academy of Sciences of the USSR, Leningrad. Translated from Neirofiziologiya, Vol. 17, No. 5, pp. 646–652, September–October, 1985.     

Urethane modification of EEG-like activity and acoustically evoked field potentials recorded from deep nuclei.

Average acoustic-evoked responses (AAER) and EEGs were recorded from the lateral hypothalamus (LH), ventromedial hypothalamus (VMH), medial forebrain bundle (MFB) and reticular formation (RF) of freely behaving rats before and after various doses (0.2, 0.4, 0.8, 1.2 g/5g) of the anesthetic drug, urethane. The effect of a surgical level of urethane (1.2 g/5g) over time (8--14 h) was also studied. Urethane produced a dose-dependent slowing in the EEG frequency. The effect of 1.2 g/kg over time was a bimodal depression of the EEG frequency. Three components of the AAER were recorded consistently and evaluated in terms of amplitude. With increasing doses, the early component (P2) was depressed in the LH2, VMH and MFB, but not in the RF which remained at control values or higher. The later components (N2 and P2) were depressed in all four structures. This suggests that urethane may be blocking the integrative function of the RF, as well as in the thalamus, resulting in lower sensory input to higher CNS structures.     

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.     

A contributory role for midbrain progesterone in the facilitation of female sexual behavior in rats

Progesterone (P) facilitation of sexual receptivity in rodents has been achieved by intracranial administration to the ventral hypothalamus; the preoptic area; and midbrain areas such as central gray, mesencephalic reticular formation, and ventral tegmental nucleus. In our laboratory, by far the most effective site in rats has been the ventromedial nucleus of the hypothalamus (VMN). However, several reports of sensitivity to P in the midbrain of rats and other rodent species led us to investigate whether stimulation of the ventral midbrain of female rats might contribute to facilitation of sexual receptivity. Ovariectomized Long-Evans rats received one cannula aimed at the VMN, and another aimed at the contralateral ventral mesencephalon. P in both cannulae, following a priming dose of estradiol, caused significantly higher lordosis quotients (LQ) than blank tubes. Controls with bilateral cannulae in the VMN responded when both tubes were filled with P, but did not respond to unilateral VMN P stimulation. P in the VMN and contralateral anterior preoptic area did not result in a greater degree of receptivity than did the empty tubes. These studies indicate that although progesterone stimulation in the midbrain alone is not sufficient to facilitate receptivity in female rats with our methods, the midbrain may play an auxiliary role. P implants in the midbrain appear to facilitate receptivity in the case of VMN implant treatments that are subthreshold for stimulating lordosis. The results are discussed in light of similar studies in other rodent species, and in the context that more than one brain site may be important in the natural stimulation of sexual receptivity by gonadal hormones.