Modulation of neuronal impulse activity of the anterior hypothalamus as a functional basis of the mechanisms underlying hypothalamic control

We examined the neuronal activity of hypothalamic neurons in acute experiments on cats under ketamine anesthesia. Using glass microelectrodes, we extracellularly recorded the impulse activity (IA) of neurons of the anterior hypothalamus in the absence of controlled influences (background IA, BIA) and after stimulation of evolutionary heterogeneous zones of the brain cortex projecting to the hypothalamus (hippocampal CA3 area, pyriform, cingular, and proreal gyri). Electrical 5-sec-long stimuli were applied with frequencies of 12, 30, or 100 sec⁻¹. In another experimental series, we recorded changes in the IA of hypothalamic neurons induced by visceral stimuli (heating or cooling by 7°C of the foot pad, cooling of the body of the animal, and infusions of 5% glucose, 0.2% NaCl, 3.0% NaCl, or phenylephrine in the carotid artery), modeling in such a way shifts of the constants of homeostasis within physiological limits. We also compared the parameters of neuronal BIA and stimulation-influenced IA in equal epochs of the analysis and classified the types of BIA. About 50% of the cells of the total studied sampling of hypothalamic neurons responded by a considerable modulation of their BIA with a significant change in the frequency in the course of and after stimulations of the above-mentioned modalities. In some neurons after cortical or visceral stimulation, a significant transformation of the temporal structure of the IA with no changes in the mean frequency occurred. We hypothesize that stimulation-induced transformation of the IA pattern with preservation of the mean discharge frequency can be one of the modes of encoding of information necessary for triggering of one efferent reaction or another, which are controlled by the hypothalamus. Examination of the BIA parameters of subcortical neurons, as well as comparison of the parameters of such an activity with the localization of cells and with the modality of stimulation that leads to modification of the IA, should allow one to reveal reasons for the formation and modification of the IA on neurons of the anterior hypothalamus. Since functional peculiarities of the neurons correlate with their BIA pattern, such data can provide an insight into the functional bases of the neurophysiological mechanisms underlying regulatory functions of the hypothalamus. Neirofiziologiya/Neurophysiology, Vol. 37, Nos. 5/6, pp. 463–474, September–December, 2005.     

Responses of neurons of the preoptic region to an increase in systemic blood pressure in cats

Responses of neurons of the lateral and medial parts of the preoptic regionRPO (LPO andMPO, respectively) and the supraoptic nucleus (SO) of the hypothalamus to an increase in systemic blood pressure were studied in acute experiments on ketamine-anesthetized cats. The blood pressure increase resulted from the injection of a 0.002% phenylephrine hydrochloride solution in the femoral vien. Responses of theRPO neurons to suprathreshold pressor stimulation were monophasic activation (48% of units), monophasic inhibition (10%), or two-phase activational-inhibitory complex (14%). The rest of the neurons did not respond to the systemic pressure increase. Pressor stimulations evoked the responses only of the first and third type inMPO neurons, and only of the first and second type inLPO neurons, whileSO neurons generated responses only of the first type. Hysteresis of a varying degree was manifested in the changes of neuronal spike activity accompanying shifts of the systemic pressure. In some neurons there was no strict correlation between the pressor effect and the onset of neuronal response. Osmosensitivity of a part of neurons was tested. The responses of most of theRPO andSO neurons to pressor influences and infusions of hypertonic saline were of similar direction, whereas responses to infusions of hypotonic saline were opposite.Neirofiziologiya/Neurophysiology, Vol. 26, No. 2, pp. 132–140, March–April, 1994.     

An Informational Approach to the Analysis of the Low-Frequency Neuronal Impulse Activity in the Rostral Hypothalamus

Statistical analysis of the low-frequency (1.0 sec^-1 and lower) neuronal impulse activity (IA) meets a few fundamental difficulties. Among them, the most significant is the small number of measurements (interspike intervals) recorded within an acceptable analysis epoch. In our study, we examined the possibility of using the normalized (by its maximum value) informational entropy (Hn) for estimation of the significance of changes in the IA generated by low-frequency neurons of the rostral hypothalamus after electrical stimulation of the prefrontal cortex. We compared the efficiencies of using the U-test (Kolmogorov–Mann–Whitney) and Hn estimate for the analysis of the same samples of neuronal responses. The results allow us to conclude that Hn is a significantly more acceptable estimate for detection of stimulation-induced modifications of the IA generated by low-frequency neurons, as compared with the U-test. The direction of shifts in the Hn value makes it possible to estimate the pattern of neuronal response. This value reflects the state of the neuron and correlates with the type of neuronal responses.     

Modulation of Inhibitory Synaptic Transmission in the Cat Motor Cortex Related to Realization of an Operant Reflex Evoked by a Complex of Stimuli

In non-anesthetized cats, we examined the effects of iontophoretic microinjections of GABA, a blocker of GABAergic synaptic transmission, and modulators of noradrenergic transmission on impulse activity (IA) generated by motor cortex neurons in the course of realization of an operant motor reflex to the action of a complex of stimuli (warning and imperative ones). We tried to elucidate the role of different membrane receptors in modulation of spiking of cortical neurons. Microiontophoretic applications of GABA and noradrenaline resulted in decreases in the frequency of background IA of cortical neurons and suppression of their reactions related to realization of the operant reflex. The use of selective adrenoactive substances showed that applications of an α1 agonist, Mezaton, suppressed background spiking and impulsation generated within an interspike interval and in the course of the movement. An α2 blocker, yohimbine, exerted an opposite effect; the neuronal IA was intensified within the background period and other examined time intervals. There are reasons to believe that noradrenergic modulation of IA of cortical neurons is realized via direct effects on pyramidal neurons and also indirectly, through changes in the activity of inhibitory cortical interneurons.     

Rhythmic aftereffects in the osmotic stimulation-induced spike activity of thermosensitive neurons of the preoptic region

Acute experiments on cats showed that mild shifts in osmotic homeostasis (within physiological limits) result in modifications of the spike activity in a significant share of thermosensitive neurons of the Preoptic region (RPO); in particular, rhythmic aftereffects (RAE) are induced in these units. The neurons were identified as thermosensitive cells according to their responses to local heating/cooling (±7°C) of the pad surface of the contralateral forelimb. Osmotic stimulation was performed by infusions of 0.1–0.3 ml of 3.0 or 0.2% NaCl solutions in thea. carotis communis dextra. The RAE phenomenon more frequently developed in thermosensitive neurons after infusions of the hyportonic solution (13/34) than after hypotonic infusions (6/34), while in non-thermosensitive neurons the situation was reverse: hypotonic infusions induced RAE more frequently. Certain specificities were also observed in localization of the thermosensitive RPO neurons, in which osmotic stimulation-induced RAE was observed. The mechanisms of such induction and possible functional role of spike grouping in the activity of thermosensitive neurons are discussed.     

Effect of changing the frequency of conditioning tetanus on depressor responses evoked by stimulation of the aortic nerve.

The effect of changes in frequency of the conditioning tetanus on the magnitude of the testing depressor response was studied in rabbits anaesthetized with urethane. Conditioning and testing stimulations were applied to the same aortic nerve. The duration of the conditioning tetani was set at 3 and 60 sec and the interval between stimulations amounted to 40 and 120 sec. At the testing interval of 40 sec the increase in frequency both of short and long conditioning tetani reduces the magnitude of the testing response which attains a minimum at frequency of about 30 cycles/sec. Conditioning stimulations of higher frequency are gradually less effective and cause the testing response to increase. Similar depression is observed at the testing interval of 120 sec but only following long-lasting conditioning tetanus. Short conditioning trains at the testing interval of 120 sec facilitate the testing response. The frequency of the conditioning stimulation which produces the greatest reduction of the depressor response indicates the range of control exerted by the conditioning tetanus over the testing blood pressure effect. The size of this control is determined by the lowest level of depression and the highest value of facilitation of the testing response.     

Structure of Neuronal Impulse Trains of the Rat Inferior Olive under Conditions of Long-Lasting Vibrational Influence

In acute experiments on albino rats anesthetized with Nembutal (40 mg/kg, i.p.), we recorded the background impulse activity (BIA) generated by neurons of the inferior olive in the norm and after 5-, 10-, and 15-daylong vibrational influence (60 Hz, 2 h, daily). We characterized the distributions of neurons according to the regularity of impulse successions, their dynamics, and pattern of histograms of interspike intervals (ISIs); we also calculated the mean frequency of impulsation and the coefficient of variation of ISIs. It was demonstrated that the most significant shifts of the characteristics of BIA generated by neurons of the inferior olive were formed within the first 10 days of the vibrational influence. These shifts were observed mainly in the mean discharge frequency (increased within the initial period) and, to a lesser extent, in the intrinsic structure of impulse trains. Such shifts in the background activity of the inferior olive caused by long-lasting vibrational influence result, perhaps, from intensification of the influences of excitatory cerebellar/mesodiencephalic inputs to olivary neurons within the early periods of action of the above factor and prevalence of GABAergic influences within the later periods. It seems possible that, under such conditions, the characteristics of electrical synapses of the olivary neurons are also subjected to modification. Neirofiziologiya/Neurophysiology, Vol. 40, No. 4, pp. 340–347, July–August, 2008.     

Corticofugal effects on the neuronal activity in the emotiogenic/motivational zones of the hypothalamus

Neuronal responses to stimulation of the proreal (field 8) and cingular (field 24) cortices, pyriform lobe (periamygdalar cortex), and hippocampus (CA3) were studied in the lateral (HL) and ventromedial (Hvm) hypothalamus, dorsal hypothalamic region (aHd), and projection region of the medial forelimb bundle (MFB); single and repeated (series of a 6–300 sec⁻¹ frequency) stimuli were used. At single stimulations, the minimum proportion of inhibitory responses with respect to excitatory effects was observed when the neocortex (the proreal gyrus) was stimulated; this proportion became successively greater at stimulations of the intermediate cortex (the cingular gyrus) and paleocortex (the pyriform cortex), while stimulation of the archicortex (the hippocampus) evoked mostly inhibitory responses. At repeated stimulation of the cortical structures, inhibitory responses prevailed in the neurons under study: their total number was nearly four times larger than that of excitatory reactions. The response patterns to single and serial stimulations of the cortical structures allowed us to demonstrate: (i) significant diversity of the influences received by hypothalamic neurons from the cortical structures and (ii) the dependence of the pattern of these influences on the phylogenetic specificity of the above structures.     

Blood flow and pO2 in the posterior hypothalamus of cats during paradoxical sleep

In chronic experiments on cats it has been found by recording of the brain local blood flow (BLBF) and of oxygen tension (pO2) in the posterior and anterior hypothalamus, that at sleep phases alternation, the changes of these parameters are differently directed: during the paradoxical sleep the level of BLBF and pO2 oscillations frequency increased in the posterior hypothalamus and decreased in the anterior one. During slow-wave sleep opposite relations were observed. Opposite directions of changes of BLBF level and pO2 oscillations frequency in one and the same phase of sleep show that they are of local origin and must be determined by functional-metabolic shifts. In particular, the increase of BLBF level and frequency of pO2 oscillations must reflect a rise of posterior hypothalamus functional-metabolic activity during paradoxical sleep.     

Firing activity of preoptic and supraoptic neurons upon mild alterations in osmo- and glucohomeostasis

Responses of neurons of the lateral (LPO) and medial (MPO) subdivisions of the preoptic region (RPO) and of the supraoptic nucleus (SO) of the hypothalamus at infusions of up to 400 µl of a hypotonic (0.2%) or a hypertonic (0.3%) NaCl solution or an isotonic (5.5%) glucose solution into the homolateral internal carotid artery were studied in acute experiments on ketamine-anesthetized cats. Changes in the firing frequency were exhibited by 69% of the examinedRPO andSO neurons, the response being of four different types: a monophasic increase (1st-type) or a monophasic decrease (2nd-type) in the activity; biphasic responses where an initial frequency rise was followed by inhibition (3rd-type) and vice versa (4th-type). Of all the neuronal responses to all stimulations, 50% (121/245) were of the 1st type; 11% (26/245), of the 2nd type; 5% (14/245), of the 3rd type; and 3% (7/245), of the 4th type. No neurons with 1st-type responses to infusion of the hypotonic NaCl solution were found in the medial sections of theMPO, and of the hypertonic solution, in the lateral sections of theLPO. Neurons with 2nd-type responses to infusion of hypo- and hypertonic NaCl solutions were almost solely detected in theSO, whereas units with such responses to glucose infusions were observed only in theRPO, being fully absent in theSO, where this stimulation gave rise only to 1st-type responses. Neurons with 3rd- and 4th-type responses to hypo- and hyperosmotic stimulations were detected predominantly in theMPO andSO, and to glucose stimulation, in theMPO andLPO.Neirofiziologiya/Neurophysiology, Vol. 25, No. 4, pp. 281–291, July–August, 1993.     

Responses of spinohypothalamic tract neurons in the thoracic spinal cord of rats to somatic stimuli and to graded distention of the bile duct

Anatomical studies indicate that a relatively large percentage of spinohypothalamic tract (SHT) neurons are located within thoracic spinal segments. The aim of this study was to characterize the responses of SHT neurons in these segments of rats to innocuous and noxious stimulation of the skin and of a visceral structure, the bile duct. In addition, we attempted to determine the trajectories of the axons of the examined neurons within the diencephalon and brainstem. Fifty-three SHT neurons were recorded within segments T8-T13 in urethane anesthetized rats. Each cell was antidromically activated using current pulses < or = 30 microA delivered from the tip of an electrode located within the contralateral hypothalamus. The recording points were located in the superficial dorsal horn (9) and deep dorsal horn (44). All examined SHT neurons had receptive fields on the posterior thorax and anterior and ventral abdomen of the ipsilateral side. Ninety percent of the 41 SHT neurons responded exclusively (13) or preferentially (24) to noxious cutaneous stimuli. Thirteen of 27 (48%) examined units were activated by forceful distention of the bile duct. Response thresholds ranged from 30 to 40 mmHg. Responses incremented as pressures were increased to 50-80 mmHg. The axons of 22 of 28 (79%) examined SHT neurons appeared to cross the midline within the hypothalamus and terminate in the ipsilateral hypothalamus, thalamus or midbrain. The results indicate that SHT neurons in thoracic spinal cord of rats are capable of conveying somatic and visceral nociceptive information from the bile duct directly to targets at various levels of the brain bilaterally.     

Effects of modulation of GABA-and noradrenergic transmission on impulse activity of neurons of the cat motor cortex related to realization of an operant reflex to the action of two signals

On unanesthetized cats trained to perform placing movements to the action of two subsequent signals (warning and imperative stimuli), we examined reflex-related impulse activity (IA) of neurons of the motor cortex (field 4) and simultaneous changes in the “slow” cortical potentials (SCP) in the vertex zone. In almost all cases under study, the shift in the SCP toward negativity was associated with a decrease in the frequency of IA within interstimulus intervals; this corresponded to a period of focusing of the animal’s attention on the expected imperative stimulus. Using a microiontophoretic technique, we tried to elucidate the role of GABA-and adrenergic cerebral systems in the genesis of such inhibitory periods. We conclude that, independently of each other but synchronously, both these systems can be involved in the maintenance of processes of active inhibition in the cerebral cortex under conditions of realization of an operant reflex. Neirofiziologiya/Neurophysiology, Vol. 39, No. 1, pp. 62–68, January–February, 2007.     

Activation of neurons of zone A5 of the rat brain upon hypoxic and thermonociceptive stimulation and switching off of the central respiratory generator

We recorded spike activity of noradrenergic neurons of zone A5 (n = 89) in the brain of anesthetized rats under conditions of hypoxic stimulation (breathing with pure N₂, 10 sec), thermonociceptive stimulation (tail-flick test), and reversible hypothermal blocking of the central respiratory activity. Hypoxic stimulation of peripheral O₂-sensitive chemoreceptors considerably increased the discharge frequency in all the examined neurons and induced tachypnea and a hypotensive reaction. Sixty-nine (77.5%) neurons of the studied group were tested using nociceptive stimulation (thermal stimulation of the tail); such stimulation resulted in a multifold increase in their discharge frequency. This was accompanied by tachypnea and a hypertensive response. Thus, we first demonstrated the role of nociception in the control of activity of noradrenergic neurons in zone A5 and the role of nociceptive afferent signals in the modulation of functions of the respiratory and cardiovascular systems mediated by neurons of the above zone. Under conditions of blocking of the central respiratory activity, we examined 36 (40.4%) neurons of zone A5 and first observed the effect of strong activation of a significant proportion of these cells upon switching off of respiration. This fact shows that there is an activating “respiratory” drive on neurons of zone A5 (probably, from the side of an expiratory neuronal population of the respiratory center) and allows us to hypothesize on the genesis of “respiratory” modulation of these cells. The activity of 16 (18.0%) cells was recorded under conditions of consecutive applications of the above stimuli; all the neurons were activated by the respective afferent influences. The simultaneously induced effects of hypoxic and nociceptive stimulations on the activity of neurons of zone A5 were additive. Thus, we first obtained proofs in favor of the multimodality of noradrenergic neurons of the above zone. This feature is a significant factor providing integrative interaction between the respiratory and cardiovascular systems and the system of nociception. Neirofiziologiya/Neurophysiology, Vol. 38, No. 4, pp. 305–313, July–August, 2006.     

Rhythmic background thalamic neuronal activity in patients with extrapyramidal motor disorders

The background activity of 123 thalamic neurons was recorded in 30 patients with motor extrapyramidal disorders applying microelectrode techniques to neurosurgical practice. Recordings were taken from the ventro-oral anterior and posterior thalamic nuclei and the adjacent reticular nucleus. A computer analysis was performed of neuronal activity in 44 units and plots produced of autocorrelation and spectral density functions. In patients with parkinsonism and double athetosis, rhythmic activity was found in 48% of cells. A wide variety of regular fluctuations in background neuronal discharges was noted: in the range of theta and delta rhythms (5–7 and 1–4 Hz respectively) with a periodicity of seconds (2–10 sec) and decaseconds (15–40 sec). It was thought possible that several types of regular waves may coexist: phenomena of 2 or 3 accelerated waves and reduced frequency of spike activity of differing periodicity were observed in eight neurons within the same train of spikes. The origin and significance of rhythmically occurring changes in thalamic neuronal spike activity are discussed.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR; Institute of Neurosurgery, Ministry of Public Health of the Ukrainian SSR. Translated from Neirofiziologiya, Vol. 19, No. 2, pp. 192–201, March–April, 1987.     

Comparative analysis of background activity of ventrolateral thalamic neurons in patients with parkinsonism and torsion muscle dystonia

In the course of neurosurgical interventions in 40 patients with parkinsonism and torsion muscle dystonia, the background activity (BA) was recorded from 124 neurons of the ventrolateral nucleus (VL) of the thalamus with the aid of microelectrodes during demarcation of boundaries between nuclear structures, and identification of zones within a nucleus. The following characteristic features of the BA in patients with parkinsonism were found: a relatively large proportion (71%) of cells with a burst pattern of activity; a great diversity of burst duration in the activity (short or prolonged bursts); a large proportion (67%) of cells with cyclic changes in the BA frequency; diverse patterns of cyclic modulation, where periods varied from fractions of a second (0.2–0.8 sec) to seconds (2–10 sec) or to tens of seconds (20–40 sec); cyclic successions of spike bursts with the rhythm typical of the peripheral tremor (3–7/sec) in a substantial proportion (40%) of the units.The background spike trains recorded in patients with torsion muscle dystonia consisted of separated spikes in the majority (69%) of units. Only short high-frequency discharges were found in the burst activity in this group; a cyclic BA pattern occurred much less frequently (in 23% of neurons); burst discharges at a 3–4/sec frequency were found only in 4% of the examined cells.The possible nature of motor disorders in patients with parkinsonism and torsion muscle dystonia and the mechanisms of the curing effects of cryodestruction of theVL of the thalamus in the treatment of the disease are discussed.Neirofiziologiya/Neurophysiology, Vol. 25, No. 4, pp. 246–253, July–August, 1993.     

Corticofugal influences on the neurons of different regions of the hypothalamus

Responses of the neurons of the lateral and ventromedial hypothalamic regions (HL andHvm, respectively), as well as of the area of the dorsal hypothalamus (aHd) and the projection region of the medial forelimb bundle (MFB), evoked by stimulation of the proreal cortex (field 8), cingular cortex (field 24), pyriform lobula (periamigdalar cortex), and hippocampus (CA3) were studied in acute experiments on cats under ketamine anesthesia. Distributions of the latent periods of the responses recorded from hypothalamic neurons at stimulation of the above cortical structures were analyzed. The responses were classified into primary excitatory and primary inhibitory. Stimulation of the proreal gyrus evoked four times more excitatory responses than inhibitory responses. With stimulation of the cingular gyrus, the ratio of excitatory/inhibitory responses was 1.5∶1. Stimulation of the pyriform cortex evoked activatory and inhibitory responses with a similar probability. With hippocampal stimulation, inhibitory responses appeared two times more frequently than excitatory reactions. The hypothalamus was found to be a zone of wide convergence: one-half of all responding neurons in theHL andHvm responded to stimulations of two or more tested cortical zones. In 26% of the cells, only excitatory convergence was observed, while in 10% only inhibitory convergence was found; 21% of the cells revealed mixed convergence.     

Impulsation of hypothalamic and amygdalar neurons in bilateral derivations in the state of food motivation

The character of impulsation of single neurons in the lateral hypothalamic and amygdalar central nucleus of rabbits recorded in bilateral derivations during quiet wakefulness, after 24-h food deprivation, and after satiation was studied by plotting autocorrelation histograms and by counting the mean frequency of discharges. During the transition from hunger to satiation, the character of impulsation of neurons in hypothalamus and amygdala changed in different ways: (1) a greater number of hypothalamic than amygdalar neurons changed their mean discharge frequency (85 versus 56%, respectively); (2) in hunger, the number of hypothalamic neurons with delta-frequency oscillations decreased as compared to quiet wakefulness and satiation, and in the amyglala the number of neurons with beta2-frequency oscillations increased; (3) in hunger, the number of hypothalamic neurons with bursting and periodic discharges decreased and the number of amygdalar neurons with equiprobabilistic discharges increased. During state alternation (according to the autocorrelation histograms) the strongest changes in the character of neuronal discharges took place in the left hypothalamus and left amygdala. The maximum differences in neuronal impulsation between the left and right hypothalamus were observed in the state of hunger and between the left and right amygdala, after satiation.     

The effects of influence of electromagnetic irradiation of millimeter wavelength on background impulse activity of supraoptic nucleus' neurons of rats' hypothalamus

In conditions of acute experiment on white rats anaesthetized by Nembutal (40 mg/kg, intraperitoneally), the registration and analysis of background impulse activity of the supraoptic nucleus neurons of rats' hypothalamus in norm and after electromagnetic irradiation of millimeter wavelength on organism, were carried out. Distributions of neurons by the degree of rhythm regularity, the character of types of dynamics of the following impulse flows, the modality of histograms of interspike intervals, the average discharge frequency, the coefficient of interspike intervals variation, were found out. Changes of the background impulse activity which were related mainly to the changes of the inner structure of registered impulse flows, were revealed. Significant shifts were generally observed in the character of dynamics of neuronal current flows and degree of regularity of the impulse activity. Statistically significant changes of the average frequency of discharges of different frequency range neurons' populations were revealed.     

Single unit responses of the reticular and ventral anterior nuclei of the thalamus to electrical stimulation of the centrum medianum

In acute experiments on cats anesthetized with thiopental (30–40 mg/kg, intraperitoneally) and immobilized with D-tubocurarine (1 mg/kg) responses of 145 neurons of the reticular and 158 neurons of the ventral anterior nuclei of the thalamus to electrical stimulation of the centrum medianum were investigated. An antidromic action potential appeared after a latent period of 0.3–2.0 msec in 4.1% of cells of the reticular nucleus and 4.4% of neurons of the ventral anterior nucleus tested in response to stimulation. The conduction velocity of antidromic excitation along axons of these neurons was 1.7–7.6 m/sec. Neurons responding with an antidromic action potential to stimulation both of the centrum medianum and of other formations were discovered, electrophysiological evidence of the ramification of such an axon. Altogether 53.8% of neurons of the reticular nucleus and 46.9% of neurons of the ventral anterior nucleus responded to stimulation of the centrum medianum by orthodromic excitation. Among neurons excited orthodromically two groups of cells were distinguished: The first group generated a discharge consisting of 6–12 action potentials with a frequency of 130–640 Hz (the duration of discharge did not exceed 60 msec), whereas the second responded with a single action potential. Inhibitory responses were observed in only 0.7% of neurons of the reticular nucleus and 4.4% of the ventral anterior nucleus tested. Afferent influences from the relay nuclei of the thalamus, lateral posterior nucleus, and motor cortex were shown to converge on neurons responding to stimulation of the centrum medianum.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 12, No. 1, pp. 36–45, January–February, 1980.     

Proposed pathways for vocal self-stimulation: Met-enkephalinergic projections linking the mibrain vocal nucleus,auditory-responsive thalamic vocal nucleus,auditory-responsive thalamic regions and neurosecretory hypothalamus

In this study, we have investigated the neuroanatomical pathways that may underlie the influence of a female bird's vocal behavior upon her own reproductive endocrine response. We traced the ascending efferent projections of the midbrain vocal control nucleus, the intercollicularis (ICo), using an anterograde tracer, PHAL, delivered by iontophoretic application. We found labelled terminal fields in the anterior regions of the hypothalamus that contained luteinizing hormone releasing hormone- (LHRH) immunoreactive neurons. We injected into the LHRH-rich anterior medial hypothalamus (AM) the retrograde tracer, fluorogold, to verify the results of PHAL anterograde tracing and exmine whether retrogradely labelled neurons in the ICo can be stained with met-enkephalin antiserum by the immunohistochemical method. Of the retrogradely labelled neurons in the medial division of ICo (mICo), between 5% and 15% were found to be met-enkephalin-immunoreactive positive perikarya. Our data suggest that axonal projections into the anterior medial hypothalamus may arise in part from enkephalin-immunoreactive neurons in the medial ICo. The mICo neurons distributed along the medial border of the midbrain auditory nucleus give rise to projections into the posterior medial hypothalamus (PMH) via synapses within the shell region of thalamic auditory nucleus, ovoidalis (Ov). We conclude that in the ring dove, the medial division of the vocal control nucleus, by virtue of its connection with the auditory thalamus and neurosecretory hypothalamus, is in a position to exert influence on endocrine response partly through enkephalinergic systems. Implications of similar connections in other species are discussed. 1994 John Wiley & Sons, Inc.