Responses of diencephalic neurons to olfactory bulb stimulation, odor, and arousal

The metabolic basis of dual periodicity of feeding in rats

This article examines how the depletion and replenishment of various energy stores give rise to periodic eating and how constant body-energy levels are maintained over time.

Measures of the energy expended throughout the 24-hour feeding pattern in rats indicate that two different energy stores (one of small capacity and one of large) determine two superimposed feeding periodicities: one from meal to meal (prandial), the other from day to night (nycthemeral). The article reviews how experimental overrepletion or overdepletion of gastrointestinal content, blood glucose, or body fats affect food intake. These data suggest that gastrointestinal content determines both meal size and meal-to-meal periodicity. Other evidence indicates that glucose uptake rate in tissues, which is modulated by fat synthesis and fat mobilization, affects the periodic onset of feeding and the difference between nocturnal and diurnal postprandial satiety.

There follows an examination of the neuroendocrine bases for the interacting mechanisms governing energy input and output balance and of the role of the ventromedial hypothalamus in body-fat regulation and the lateral hypothalamus in feeding.

The lateral hypothalamic area revisited: neuroanatomy, body weight regulation, neuroendocrinology and metabolism

This article reviews findings that have accumulated since the original description of the syndrome that follows destruction of the lateral hypothalamic area (LHA). These data comprise the areas of neuroanatomy, body weight regulation, neuroendocrinology, neurochemistry, and intermediary metabolism. Neurons in the LHA are the largest in the hypothalamus, and are topographically well organized. The LHA belongs to the parasympathetic area of the hypothalamus, and connects with all major parts of the brain and the major hypothalamic nuclei. Rats with LHA lesions regulate their body weight set point in a primary manner and not because of destruction of a "feeding center". The lower body weight is not due to finickiness. In the early stages of the syndrome, catabolism and running activity are enhanced, and so is the activity of the sympathetic nervous system (SNS) as shown by increased norepinephrine excretion that normalizes one mo later. The LHA plays a role in the feedback control of body weight regulation different from ventromedial (VMN) and dorsomedial (DMN). Tissue preparations from the LHA promote glucose utilization and insulin release. Although it does not belong to the classical hypothysiotropic area of the hypothalamus, the LHA does affect neuroendocrine secretions. No plasma data on growth hormone are available following electrolytic lesions LHA but electrical stimulation fails to elicit GH secretion. Nevertheless, antiserum raised against the 1-37 fragment of human GHRF stains numerous perikarya in the dorsolateral LHA. The plasma circadian corticosterone rhythm is disrupted in LHA lesioned rats, but this is unlikely due to destruction of intrinsic oscillators. Stimulation studies show a profound role of the LHA in glucose metabolism (glycolysis, glycogenesis, gluconeogenesis), this mechanism being cholinergic. Its role in lipolysis appears not to be critical. In general, stimulation of the VMN elicits opposite effects. Lesion studies in rats show altered in vitro glucose carbon incorporation into several tissue fractions both a few days, and one mo after lesion production. Several of these changes may be due to the reduced food intake, others appear to be due to a "true" lesion effect.

Modulation of lateral hypothalamic activity by olfactory bulb and sciatic stimulation

Lateral hypothalamic area (LHA) single unit activity (extracellular) was studied in response to electrical stimulation of the olfactory bulb (OB) or sciatic nerve in adult albino rats (n = 39) anesthetized with dialurethane. Olfactory stimulation resulted in a greater proportion of LHA units showing inhibitory rather than excitatory responses, while sciatic nerve stimulation resulted in similar proportions of units showing inhibitory and excitatory responses. Of the 76 LHA units tested with both OB and sciatic nerve stimulation, 36% responded to both stimulation sites, 18% responded only to OB stimulation, 26% responded only to sciatic nerve stimulation, and 20% were unresponsive to either stimulation. The locations of responsive units were diffuse throughout the LHA sampled. The response characteristics of LHA neurons to external sensory stimulation are consistent with the anatomy and putative integrative functions of this brain region.

Analysis of the relationships between self-stimulation sniffing and brain-stimulation sniffing

Determination of current thresholds for self-stimulation and electrically elicited sniffing from electrodes placed into lateral hypothalamic and ventral tegmental areas of rats revealed a tight correlative relationship between the two phenomena (r values of approx 0.9 at both sites). Thresholds for sniffing were never higher than those for self-stimulation, while approximately half the animals had higher self-stimulation than sniffing thresholds, suggesting that electrically elicited sniffing may better index the underlying psychobiological process that mediates self-stimulation. That both phenomena reflect the same basic process was suggested by the fact that 48 h of food deprivation consistently reduced the thresholds for both self-stimulation and sniffing, while 24 h of food deprivation had only marginal effects on both. The implications for understanding the nature of self-stimulation processes is discussed.

Characteristics of rat lateral hypothalamic neuron responses to smell and taste in emotional behavior

Single unit activity in the lateral hypothalamus (LHA) of the rat was recorded while the animal learned to discriminate cue signals. Normally preferred potables (glucose, orange, or grape solution) or intracranial self-stimulation (ICSS) were used as rewards. Electric shock or tail pinch were used as aversive stimuli. The same behavior, licking, was the response required to either obtain the rewarding stimuli or avoid the aversive ones. For positive reinforcement a rat was rewarded with fluid or ICSS upon licking a spout presented in front of its mouth. In negative reinforcement experiments, an aversive stimulus, electric shock or tail pinch, was applied if the rat did not lick the spout. Solutions having smell only, taste only, or smell-plus-taste, were prepared from oranges or grape extract. Of 392 neurons analyzed, 256 responded differentially to rewarding and aversive stimuli, and 138 of these were tested with the 3 different solutions. Similar LHA neural responses occurred during actual drinking of the 3 kinds of solutions, as well as on recognition of the cue signal. Responses to smell only had shorter latency than responses to taste only. Neural activity in response to solutions that could be both smelled and tasted was the sum of activity in response to taste-only solutions plus that in response to smell-only solutions. Cue signal responses were rapidly acquired, usually within 2-5 trials, for both taste-only and smell-only solutions. The results indicate the integration of both taste and olfactory information by the same LHA neurons, and these neurons are involved in cue signal learning. Present results of LHA neuronal responses to taste and smell suggest that the intensity of gustation and olfaction may add together to enhance instinctive hedonic sensations. These neurons are involved in the formation of stimulus-reinforcement association in learning, and in elicitation of conditioned emotional responses.

Supraoptic nucleus afferents from the main olfactory bulb--II. Intracellularly recorded responses to lateral olfactory tract stimulation in rat brain slices

To establish the functional nature of the anatomically demonstrated main olfactory bulb inputs to the supraoptic nucleus, electrophysiological responses of intracellularly recorded supraoptic neurons to lateral olfactory tract stimulation were recorded in horizontal slices of basal forebrain and hypothalamus. A total of 71 synaptically influenced neurons were studied in slices from adult rats of both sexes. Of these, 60 cells (84%) were monosynaptically activated by olfactory tract stimulation; seven cells (10%) were activated via polysynaptic pathways; and four cells (6%) were characterized by long latency inhibitory responses. Lucifer Yellow was injected into 64 cells and subsequent immunocytochemical identification of 44 of these neurons showed that both oxytocin and vasopressin cells, in approximately equal numbers, were excited by olfactory stimulation. Polysynaptically mediated excitation, however, was only associated with oxytocin cells (six of the six identified cells). These results corroborate anatomical tract tracing data showing main olfactory bulb efferents to both supraotic neurons and to neurons of the perinuclear zone. Also supported are earlier speculations of olfactory participation in release of oxytocin and vasopressin during various physiological states.

Feeding related lateral hypothalamic neuron responses to odors depend on food deprivation in rats

It has been investigated feeding related LHA neuronal activity and responses to odor stimulation in rats at various levels of satiation. Extracellular responses of 168 neurons to three odors, isoamylacetate (AA), cineole (CL), and isovaleric acid (VA), were recorded from 168 LHA neurons of Wistar-SPF male rats. Of 168 units, 107 (63.7%) responded to from one to three odors, but not to light or phonic stimulation. Of the responding units, 94.4% (101/107) were excited, and 5.6% were inhibited. In response to a single electrical stimulation (0.5 msec, 1-10 V) of the OB, 61 units were excited with latencies of 6-43 msec (19.8 +/- 12.0 msec, mean +/- S.D.) indicating compound OB-LHA relations--mono- and polysynaptic through myelinated and nonmyelinated fibers. The results suggest predominantly excitatory effects of both electrical stimulation of the OB and odor stimulation on the LHA. Firing frequency in response to AA or VA was significantly (p less than 0.05) greater for the long fasting group (38 hr, LF, n = 8) than for the NF (nonfasting, n = 12) group; differences between the LF and MF (24 hr, n = 6) groups were not significant. Glucose-sensitive neurons (GSN, n = 19) responded more to odors than non-GSNs (n = 86), and discharge frequency increase depended markedly on food deprivation. Food deprivation results suggest that responsiveness of feeding related LHA neurons to odors depends on the degree of satiation. In conclusion, it was confirmed that olfactory functions are important in the responses of hypothalamic feeding related neurons.

Olfactory input to the lateral hypothalamus of the old world monkey

Responses of lateral hypothalamic neurons to 8 odors were studied in chronic unanesthetized old world monkeys (Macaca irus). Many neurons (54.5%) responded to a single odor only, and the number of neurons responding to 2, 3 and 4 odors decreased successively. No neuron responded to as many as 5 odors. Thus, the presence of olfactory input and a highly discriminative ability for odors were found in the lateral hypothalamic area (LHA). Neuronal responses to the same odors were also studied in the septum (Spt). In anesthetized old world monkeys, evoked potentials were recorded in the LHA and in areas of the Spt and the nucleus accumbens (Acc) during stimulation of the olfactory bulb (OB). When the Spt (and probably the Acc with it) was subsequently destroyed, OB-evoked potentials in the LHA disappeared. Next, by injecting horseradish peroxidase (HRP) into the LHA, an olfactory pathway to the LHA was examined. Labeled neurons were found mainly in the Spt and the Acc, and only partly in other areas. However, labeled neurons were scarcely found in the prepyriform (PPF)-entorhinal (ER) area or in the olfactory tubercle (OT). The present study thus shows that an olfactory pathway to the LHA passes through the Spt and probably also the Acc, but not through the PPF-ER areas nor through the OT in the old world monkey.

Absence of complete internasal-interocular transfer of habituation of exploratory behavior in rats

Normal, blind, anosmic, and unilaterally blind and contralaterally anosmic albino rats were submitted to unilateral peripheral sensory (olfactory and/or visual) occlusion and observed in an initially unfamiliar arena. Next day, either the same sensory periphery (control subjects) or the contralateral one (experimental subjects) was occluded and a new observation in the arena was made. The duration of the exploratory behavior of control and experimental subjects, on each occasion, was compared. There was not a complete internasal-interocular transfer of long-term habituation of exploratory behavior, either when olfaction and vision were suppressed on opposite sides or when they were suppressed on the same side, but there was a complete internasal transfer of this habituation in blind animals and a complete interocular transfer of this habituation in anosmic animals. These results suggest that long-term habituation of the exploratory behavior elicited by one olfactory and one visual periphery activation and that of the exploratory behavior elicited by the other olfactory and the other visual periphery activation depend upon different representations of the stimulatory situation in the central nervous system. These representations would, however, have only a small number of elements which are not shared.

Studies on the olfactory nervous system of the Old World monkey

From the results of our electrophysiological and HRP studies in the old world monkey, multiple olfactory pathways have been clarified. The old world monkey has two neocortical olfactory areas, but no functional vomeronasal system. The response patterns to odors in various olfactory areas have also been studied. On the other hand, in the rabbit (Onoda and Iino, 1980) and dog (Onoda et al., 1981, 1982), which do have active vomeronasal systems, only one neocortical olfactory area was found. This important difference had already been indicated in three previous papers in which Takagi (1979, 1980, 1981) theorized that mammals can be divided into two groups according to their olfactory nervous mechanisms. One group includes old world monkeys, higher primates and man, and the other new world monkeys and lower mammals.

Postnatal development of sensory influences on neurons in the ventromedial hypothalamic nucleus of the rat

Extracellular unitary records were obtained from neurons in the ventromedial hypothalamic nucleus (VMH) of very young (1-25 days of postnatal age) and adult rats. Spontaneous unitary activity and evoked responses to both external (somatic, gustatory, and olfactory) and internal sensory (systemic administration of hypertonic saline and glucose solutions) stimulation were determined in order to assess the functional development of VMH neurons and their afferents. The basic electrophysiological characteristics of VMH neurons were established prenatally. From the date of birth, many VMH neurons had: spontaneous action potential generation; evoked responses to external or internal sensory stimulation; and convergent sensory inputs. In contrast, the major developmental change in the neurophysiological properties of VMH neurons was the diminution with increasing age of the convergence of external and internal sensory influences. This developmental 'fine-tuning' of a complex functional feature of VMH neurons is important because the maturation of convergence coincides with a 'critical period' of VMH ontogenesis demonstrated in behavioral and experimental brain damage reports.

Temporal matching of sensory-motor behavior and limbic theta rhythm deteriorates in aging rats

The correlations between investigatory sniffing and rhythmic slow-wave activity (RSA) in the dorsal hippocampal formation were studied during free behavior in Fischer 344 rats aged 3, 18, 30, and 36 months. The amount and vigor of spontaneous exploratory behavior was reduced in older animals, and the frequency distributions of investigatory sniffing and hippocampal RSA both shifted with age toward the lower end of their normal ranges. In the youngest animals, the dominant frequency of sniffing matched that of hippocampal RSA (frequency entrainment) more often than would be predicted by chance; preferred phase differences between sniffing and hippocampal RSA were reliably observed in the 5-9 Hz range; and these preferred phase differences varied linearly as a function of frequency, implying an underlying latency relationship. These correlations changed progressively with age as follows: the incidence of frequency entrainments decreased; the frequency range within which preferred phase differences were observed became lower and narrower; and the incidence of preferred phase differences decreased. However, animals of all ages exhibited similar preferred phase differences for those frequencies at which significant preferences were expressed. These findings are discussed in relation to the hypothesis that alterations of forebrain theta rhythms may accompany aberrations of the medial septum-diagonal band-nucleus basalis complex and may be importantly involved in aging-related impairments of cognitive and learning abilities.

Postnatal development of sensory influences on lateral hypothalamic neurons of the rat

Extracellular unitary records were obtained from neurons in the lateral hypothalamic area (LHA) of very young (1-25 days of postnatal age) and adult rats. Spontaneous unitary activity and evoked responses to external sensory (somatosensory, gustatory and olfactory) and internal sensory (administration of hypertonic saline and glucose solutions) stimulation were determined in these neurons in order to assess their functional development. The basic electrophysiological characteristics of LHA neurons were established prenatally. From the day of birth, many LHA neurons had: (1) spontaneous spike generation; (2) evoked responses to external and internal sensory stimulation; and (3) convergent sensory inputs. However, each of these neurophysiological properties was modified considerably during postnatal ontogenesis: (4) spontaneous activity of LHA neurons with evoked responses to sensory stimulation increased with age; (5) internal sensory influences tended to diminish while evoked response magnitude and complexity were augmented developmentally; and (6) convergence of sensory influences decreased in older rats. This developmental 'fine tuning' of the functional features of LHA neurons is important because their maturation coincides with certain 'critical periods' of LHA ontogenesis demonstrated in behavioral, morphological, pharmacological and experimental brain damage reports.

Dual olfactory representation in the rat thalamus: an anatomical and electrophysiological study

A combination of electrophysiological and anatomical techniques was used to determine the sites of termination of olfactory projections to the thalamus and the distribution of the cells of origin of these projections within the olfactory cortex. Following electrical stimulation of the olfactory bulb, short-latency unit responses were recorded not only in the central segment of the mediodorsal thalamic nucleus but also in the ventral and anterior parts of the submedial thalamic nucleus. Responses were not obtained in the ventral or lateral parts of the mediodorsal nucleus, in the dorsal part of the submedial nucleus, or in the intralaminar nuclei between the mediodorsal and submedial nuclei. The cells of origin of the projection were identified by making injections of horseradish peroxidase conjugated to wheat germ agglutinin (HRP WGA) into the thalamus and examining the olfactory cortex for retrogradely labeled cells. Following injections into the mediodorsal nucleus, labeled cells were found in the polymorphic cell zone deep to the olfactory tubercle, in the ventral endopiriform nucleus deep to the piriform cortex, and in an equivalent position deep to the periamygdaloid and lateral entorhinal cortices. After injections into the submedial nucleus, a smaller number of labeled cells were found in similar locations, except that they were restricted to the rostral olfactory cortical areas and were not found deep to the lateral part of the piriform cortex. Retrogradely labeled cells and anterogradely labeled axons were also found in the lateral orbital and ventral agranular insular areas of the prefrontal cortex with injections into the mediodorsal nucleus, and in the ventrolateral orbital area with injections into the submedial nucleus. Anterograde tracing experiments, using the autoradiographic method, have confirmed these results. Injections of 3H-leucine deep to the junction between the anterior piriform cortex and the olfactory tubercle label axons in both the central segment of the mediodorsal nucleus and the ventral part of the submedial nucleus, while injections deep to the posterior piriform cortex label axons in the mediodorsal nucleus only. Within the mediodorsal nucleus, the projection also appears to be organized so that fibers which arise more rostrally terminate ventrolaterally in the central segment, while fibers which arise more caudally terminate more dorsomedially. These results indicate that there is a substantial and possibly dual thalamocortical mechanism available for processing of olfactory stimuli.

Reexamination of functional subdivisions of the rodent prefrontal cortex

Selective patterns of behavioral deficits were observed on tests of spatial or olfactory learning after different cortical lesions in rats. The results clearly distinguished functional subdivisions of the rodent prefrontal cortex: Rats with lesions of the prefrontal cortex that primarily involve the dorsal bank of the rhinal sulcus were impaired selectively and exhibited increased perseveration of responses in a go, no-go odor discrimination task. In contrast, rats with lesions of the region of prefrontal cortex situated along the medial cortical wall were impaired selectively and exhibited increased perseveration of responses in a spatial delayed alteration task. These behavioral deficits were similar in magnitude and quality to those found in monkeys after discrete ablations of frontal lobe regions that are argued to be homologous prefrontal subdivisions.

Olfactory connections of substantia innominata and nucleus of the horizontal limb of the diagonal band in the rat: an electrophysiological study

Extracellular unit recordings performed on 113 spontaneously discharging neurons in the substantia innominata-nucleus of the horizontal limb of the diagonal band region revealed that 46 (41%) were transsynaptically discharged or inhibited following stimulation of the main and accessory olfactory bulb (MOB, AOB) and the prepyriform cortex (PPC). A significantly greater number of cells were responsive to MOB and PPC than to AOB shocks. Eight (7%) neurons were antidromically invaded following MOB volleys. These findings suggest that the MOB has functional reciprocal connections with the 'ventral striatum', a region which can function, presumably as a nodal point for convergence of visual, gustatory and olfactory information relevant to feeding and drinking behavior.

Potentiation of pressor and behavioral responses to brain stimulation following bilateral olfactory bulbectomy in freely moving rats

The effects of bilateral olfactory bulb (OB) ablation on pressor and behavioral responses to stimulation of the posterior hypothalamic area (PHA) and midbrain reticular formation (MRF) were investigated in unanesthetized and unrestrained rats with chronic electrodes and arterial cannula implants. Bilateral olfactory bulbectomy induced a marked increase in emotional responses to given stimuli. A high incidence of muricide was also observed after olfactory bulbectomy. The threshold for inducing behavioral arousal and pressor response to PHA and MRF stimulation were markedly enhanced. The enhancement in pressor response to MRF stimulation occurred immediately after olfactory bulbectomy and persisted throughout the experiment, while that to PHA stimulation appeared gradually and reached maximum at 10 days after olfactory bulbectomy. These results suggested that olfactory bulbectomy has a great influence not only on emotionality but also on the central neural mechanisms of autonomic regulation.

Centrifugal influence on olfactory bulb activity in the rabbit

(1) Regions which exert centrifugal influences on the olfactory bulb activity were studied by applying systematic stimulation to various areas of the ipsilateral telencephalon in the rabbit. By delivering electric stimuli to the anterior commissure (AC), the deep lying structures in the projection areas of the lateral olfactory tract (LOT) and the medial forebrain bundle situated between the lateral hypothalamic area and the lateral preoptic area, negative field potentials were evoked in the granule cell layer (GCL) of the bulb. (2) Intracellular recordings from the mitral cells and the GCL neurons in the olfactory bulb were performed in order to clarify the modes of the centrifugal influences on the olfactory bulb neurons. (3) EPSPs were recorded in the GCL neurons by stimulation of the deep-lying structure of the prepiriform cortex as well as by stimulation of the AC. The onset time and duration of the EPSPs corresponded well to those of the negative field potentials in the GCL. Thus, it was suggested that these negative potentials were caused by the EPSPs of the number of granule cells. (4) In almost all of the mitral cells, IPSPs were recorded by stimulation of the AC and the deep-lying structures of the LOT projection areas. The onsets of the IPSPs were found with delays of several milliseconds from those of the negative field potentials in the GCL. (5) It was postulated that the excitation of the centrifugal system mainly exerts a depressive influence on the activity of the mitral cell, and that the GCL neuron (presumably the granule cell) seems to be an inhibitory interneuron interpolated between the extrinsic fibers from the telencephalon and the mitral cell.

Cortical projections of the thalamic mediodorsal nucleus in the rabbit

The cortical projection of the thalamic mediodorsal nuclear complex (MD) in the rabbit was mapped retrograde horseradish peroxidase and anterograde tritiated proline techniques. The projection field occupied the entire medial wall rostral to a mid corpus callosal level, wrapped around the frontal pole onto the lateral convexity and tailed off caudally on the dorsal bank of the rhinal sulcus. The projection of the lateral approximately one-half of MD, the half which does not receive olfactory input, was confined to medial cortex supply all but the most rostral region. This projection field of lateral MD was precisely organized in two dimensions with the most lateral part projecting most caudally and the most dorsal part projecting most ventrally. A representation for the third, anterior-posterior (A-P), dimension was not evident since any cortical point within the field was supplied by a cylinder of cells extending the entire A-P extent of lateral MD. The medial half of MD, which does receive olfactory input, projected to the remaining rostral medical cortex, the lateral convexity and rhinal sulcal region. The inverse dorsoventral relationship was partially preserved and on overlapping A-P gradient was present with sulcal projections originating more caudally in medial MD and the rostral medial projection originating more rostrally.

A measure of extracellular unit responses to repeated stimulation applied to observations of the time course of olfactory responses

A technique for measurement of small samples of unit behavior during regularly repeated stimulation is described. A correlation-based measure was computed over two successive stimulus presentation by summing the products of spike counts for corrsponding time bins and normalizing to the number of bins and the number of spike counts during the two stimulus presentations. This measure was combined with the mean frequency of spike occurrence during the stimulus presentation to give a characterization of neuronal activity sensitive to changes in both strength of temporal patterns and mean frequency. Examples are given of olfactory responsive neurons with comparison of measurement techniques. The time course of the response to odor of neurons recorded under urethane anesthesia from the olfactory bulb and the lateral hypothalamus was studied. By both simple mean frequency measures and the measures proposed in this study, the neurons recorded from the lateral hypothalamus underwent more rapid temporal decrements in the odor response.