Swallowing during ongoing fluid ingestion in the rat

MSG-Evoked c-Fos Activity in the Nucleus of the Solitary Tract Is Dependent upon Fluid Delivery and Stimulation Parameters

The marker of neuronal activation, c-Fos, can be used to visualize spatial patterns of neural activity in response to taste stimulation. Because animals will not voluntarily consume aversive tastes, these stimuli are infused directly into the oral cavity via intraoral cannulae, whereas appetitive stimuli are given in drinking bottles. Differences in these 2 methods make comparison of taste-evoked brain activity between results that utilize these methods problematic. Surprisingly, the intraoral cannulae experimental conditions that produce a similar pattern of c-Fos activity in response to taste stimulation remain unexplored. Stimulation pattern (e.g., constant/intermittent) and hydration state (e.g., water-restricted/hydrated) are the 2 primary differences between delivering tastes via bottles versus intraoral cannulae. Thus, we quantified monosodium glutamate (MSG)-evoked brain activity, as measured by c-Fos, in the nucleus of the solitary tract (nTS; primary taste nucleus) across several conditions. The number and pattern of c-Fos neurons in the nTS of animals that were water-restricted and received a constant infusion of MSG via intraoral cannula most closely mimicked animals that consumed MSG from a bottle. Therefore, in order to compare c-Fos activity between cannulae-stimulated and bottle-stimulated animals, cannulated animals should be water restricted prior to stimulation, and receive taste stimuli at a constant flow.

Hindbrain neurons as an essential hub in the neuroanatomically distributed control of energy balance

This Review highlights the processing and integration performed by hindbrain nuclei, focusing on the inputs received by nucleus tractus solitarius (NTS) neurons. These inputs include vagally mediated gastrointestinal satiation signals, blood-borne energy-related hormonal and nutrient signals, and descending neural signals from the forebrain. We propose that NTS (and hindbrain neurons, more broadly) integrate these multiple energy status signals and issue-output commands controlling the behavioral, autonomic, and endocrine responses that collectively govern energy balance. These hindbrain-mediated controls are neuroanatomically distributed; they involve endemic hindbrain neurons and circuits, hindbrain projections to peripheral circuits, and projections to and from midbrain and forebrain nuclei.

EMG activity in hyoid muscles during pig suckling

Infant suckling is a complex behavior that includes cycles of rhythmic sucking as well as intermittent swallows. This behavior has three cycle types: 1) suck cycles, when milk is obtained from the teat and moved posteriorly into the valleculae in the oropharynx; 2) suck-swallow cycles, which include both a rhythmic suck and a pharyngeal swallow, where milk is moved out of the valleculae, past the larynx, and into the esophagus; and 3) postswallow suck cycles, immediately following the suck-swallow cycles. Because muscles controlling these behaviors are active in all three types of cycles, we tested the hypothesis that different patterns of electromyographic (EMG) activity in the mylohyoid, hyoglossus, stylohyoid, and thyrohyoid muscles of the pig characterized each cycle type. Anterior mylohyoid EMG activity occurred regularly in every cycle and was used as a cycle marker. Thyrohyoid activity, indicating the pharyngeal swallow, was immediately preceded by increased stylohyoid and hyoglossus activity; it divided the suck-swallow cycle into two phases. Timed from the onset of the suck-swallow cycle, the first phase had a relatively fixed duration while the duration of the second phase, timed from the thyrohyoid, varied directly with cycle duration. In short-duration cycles, the second phase could have a zero duration so that thyrohyoid activity extended into the postswallow cycle. In such cycles, all swallowing activity that occurred after the thyrohyoid EMG and was associated with bolus passage through the pharynx fell into the postswallow cycle. These data suggest that while the activity of some muscles, innervated by trigeminal and cervical plexus nerves, may be time locked to the cycle onset in swallowing, the cycle period itself is not. The postswallow cycle consequently contains variable amounts of pharyngeal swallowing EMG activity. The results exemplify the complexity of the relationship between rhythmic sucking and the swallow.

Leptin and the systems neuroscience of meal size control

The development of effective pharmacotherapy for obesity will benefit from a more complete understanding of the neural pathways and the neurochemical signals whose actions result in the reduction of the size of meals. This review examines the neural control of meal size and the integration of two principal sources of that control--satiation signals arising from the gastrointestinal tract and CNS leptin signaling. Four types of integrations that are central to the control of meal size are described and each involves the neurons of the nucleus tractus solitarius (NTS) in the dorsal hindbrain. Data discussed show that NTS neurons integrate information arising from: (1) ascending GI-derived vagal afferent projections, (2) descending neuropeptidergic projections from leptin-activated arcuate and paraventricular nucleus neurons, (3) leptin signaling in NTS neurons themselves and (4) melanocortinergic projections from NTS and hypothalamic POMC neurons to NTS neurons and melanocortinergic modulation of vagal afferent nerve terminals that are presynaptic to NTS neurons.

Swallowing motor pattern triggered and modified by sucrose stimulation in the larvae of the silkworm, Bombyx mori

To determine the contribution of sucrose signals to swallowing motor patterns, a series of behavioral, morphological and electrophysiological experiments were carried out in the larvae of the silkworm, Bombyx mori. The larvae ingested a droplet of sucrose solution applied to the mouth. The rate of ingestion was increased for higher sucrose concentrations. The swallowing movements were produced by a cibarial pump system that consisted of a circular compressor and pairs of dilators. The circular compressor was innervated by at least two dorsal motor neurons with the somata in the frontal ganglion. One of these neurons with arborized in both the frontal ganglion and the tritocerebrum of the brain. Both extra- and intracellular recording from the compressor showed that the rhythmic motor patterns were modified by different concentration of sucrose. A higher concentration of sucrose lengthened the duration of a burst or caused more excitatory junction potentials (EJPs) in the compressor, resulting in stronger swallowing contractions. Transection of both frontal connectives deleted the sucrose response, but spontaneous rhythmic motor patterns remained in the compressor, suggesting that the motor rhythm could be generated in the frontal ganglion, and triggered and/or modified by sucrose signals processed through the tritocerebrum of the brain.

A 5-HT2C agonist elicits hyperactivity and oral dyskinesia with hypophagia in rabbits

Serotonergic 5-HT2C and 5-HT1B receptors mediate inhibitory controls of eating. Questions have arisen about potential behavioral and neurological toxicity of drugs that stimulate the 2C site. We evaluated eating and other motor responses in male Dutch-belted rabbits after administration of m-chlorophenylpiperazine (mCPP). Studies conducted in vitro and in vivo assessed the pharmacological specificity of the ingestive actions of this agent. mCPP (0.15-10 micromol/kg sc) reduced consumption of chow and 20% sucrose solution with equal potencies (ED50 approximately equal 0.6 micromol/kg). In radioligand binding to rabbit cortex, mCPP displayed 15-fold higher affinity for 5-HT2C than for 5-HT1B receptors. The serotonin antagonist mesulergine (7000-fold selective for 5-HT2C) reversed the hypophagic action of mCPP, but the 5-HT1B/1D antagonist GR127,935 did not. GR127,935 (0.5 micromol/kg) did prevent hypophagia produced by the highly selective 5-HT1B/1D agonist GR46,611. Observational methods demonstrated that mCPP decreased the frequency of eating chow but increased other motor activities. When rabbits consumed sucrose, videoanalysis revealed that mCPP reduced total time licking and the duration of individual bouts, but not bout frequency or the actual rate of consumption. mCPP increased locomotor and other activities, and greatly increased vacuous oromotor stereotypies and tongue protrusions. Nonetheless, rabbits licked accurately at the spout for sucrose. When sucrose was infused intraorally through a cheek catheter, mCPP actually increased the peak amplitude and overall magnitude of jaw movements. We conclude that mCPP stimulates 5-HT2C receptors to reduce food intake in rabbits. This hypophagia involves disruption of appetitive components of eating and is accompanied by adverse motor actions. This profile raises questions about the use of the 5-HT2C receptor as a target for novel therapeutic agents for obesity.

Afferent pathways and responses of T3–T4 spinal neurons to cervical and thoracic esophageal distensions in rats

The purposes of this study were to (1) compare responses of T(3)-T(4) spinal neurons to thoracic and cervical esophageal distension (TED, CED) and (2) determine afferent pathways for esophageal input to these neurons. Extracellular potentials of single superficial and deeper T(3)-T(4) neurons were recorded in pentobarbital anesthetized male rats. Graded TED or CED was produced by water inflation (0.1-0.5 ml) of a latex balloon. TED changed activity of 121/432 (28%) neurons (114 were excited); CED activated 69/269 (26%) neurons (56 were excited). Of 151 neurons that were tested for responses to both TED and CED, 40 (26%) neurons responded to both TED and CED. Mean duration of excitatory responses in convergent neurons to TED was significantly longer than the duration of responses to CED (31.4+/-2.8 vs. 25.4+/-1.0 s, n=34, P<0.05). A total of 105 out of 121 (87%) and 66 out of 69 (96%) neurons responsive to TED and CED had somatic fields. Spinal transection at rostral C(1) and at C(7)-C(8) indicated that excitatory responses to TED resulted from activation of afferent input that entered thoracic spinal segments; whereas, excitatory responses to CED resulted from afferent inputs entering cervical or thoracic spinal segments. These data showed that the upper thoracic spinal cord received sensory information from the esophagus through cervical and/or thoracic spinal visceral afferent pathways.

Behavioral analysis of anorexia produced by hindbrain injections of AMPA receptor antagonist NBQX in rats

The caudal brain stem integrates short-term feedback signals from the oral cavity and the food-handling abdominal viscera, as well as long-term homeostatic, cognitive, and emotional signals from the forebrain, to control ingestive behavior. Glutamate, acting on various receptor subtypes, plays a prominent role in this integrative process. Fourth ventricular injection of the alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionate (AMPA)/kainate receptor blocker 1,2,3,4-tetrahydro-6-nitro-2,3-dioxobenzo[f]quinoxaline-7-sulfonamide (NBQX, 0.5-5 nmol/3 microl) dose dependently suppressed intake of 15% sucrose in food-deprived and non-food-deprived rats compared with saline injection. Two consecutive paired NBQX injections (5 nmol) into the fourth ventricle did not produce conditioned taste aversion to saccharin, but LiCl did. Intraburst lick rate and lick efficiency were not affected, but burst size and number and initial lick rate were significantly decreased by NBQX. Local injection of NBQX (2 nmol) into and near the nucleus tractus solitarius also suppressed sucrose intake. These results suggest a general role for non-N-methyl-D-aspartate receptors in the transmission of positive (feedforward) signals, but do not identify the exact processing step involved, such as taste input, sensory-motor processing, or descending facilitation. More localized injections and response measures will be necessary.

The neuroanatomical axis for control of energy balance

The hypothalamic feeding-center model, articulated in the 1950s, held that the hypothalamus contains the interoceptors sensitive to blood-borne correlates of available or stored fuels as well as the integrative substrates that process metabolic and visceral afferent signals and issue commands to brainstem mechanisms for the production of ingestive behavior. A number of findings reviewed here, however, indicate that sensory and integrative functions are distributed across a central control axis that includes critical substrates in the basal forebrain as well as in the caudal brainstem. First, the interoceptors relevant to energy balance are distributed more widely than had been previously thought, with a prominent brainstem complement of leptin and insulin receptors, glucose-sensing mechanisms, and neuropeptide mediators. The physiological relevance of this multiple representation is suggested by the demonstration that similar behavioral effects can be obtained independently by stimulation of respective forebrain and brainstem subpopulations of the same receptor types (e.g., leptin, CRH, and melanocortin). The classical hypothalamic model is also challenged by the integrative achievements of the chronically maintained, supracollicular decerebrate rat. Decerebrate and neurologically intact rats show similar discriminative responses to taste stimuli and are similarly sensitive to intake-inhibitory feedback from the gut. Thus, the caudal brainstem, in neural isolation from forebrain influence, is sufficient to mediate ingestive responses to a range of visceral afferent signals. The decerebrate rat, however, does not show a hyperphagic response to food deprivation, suggesting that interactions between forebrain and brainstem are necessary for the behavioral response to systemic/ metabolic correlates of deprivation in the neurologically intact rat. At the same time, however, there is evidence suggesting that hypothalamic-neuroendocrine responses to fasting depend on pathways ascending from brainstem. Results reviewed are consistent with a distributionist (as opposed to hierarchical) model for the control of energy balance that emphasizes: (i) control mechanisms endemic to hypothalamus and brainstem that drive their unique effector systems on the basis of local interoceptive, and in the brainstem case, visceral, afferent inputs and (ii) a set of uni- and bidirectional interactions that coordinate adaptive neuroendocrine, autonomic, and behavioral responses to changes in metabolic status.

Food deprivation does not potentiate glucose taste reactivity responses of chronic decerebrate rats

The chronic supracollicular decerebrate (CD) rat fails to increase meal size in response to systemic/metabolic aspects of food deprivation. Here we asked whether or not deprivation increases immediate oral motor responding to taste stimuli (taste reactivity) in CD rats, as it does in neurologically intact controls. The responses of CD rats were evaluated as functions of glucose concentration and deprivation state, with taste reactivity responses recorded myographically during 15-s intraoral infusions and during 45-s post-infusion periods. Five glucose concentrations (0, 3.2, 6. 25, 12.5, 25%) were each presented three times during each test session. The rats were tested when not-deprived (i.e. receiving their full complement of gavage feedings), deprived (23.5 h) of food and water, and deprived of food but not water. The number of oral motor responses emitted increased monotonically with stimulus concentration; during oral infusions the increase was greatest over the lower half of the concentration range, whereas responding increased linearly with concentration in the post-infusion period. This CD response profile resembled that obtained previously with neurologically intact rats tested according to the same protocols. In contrast to results obtained in intact rats, deprivation did not influence the CD's response to glucose at any concentration or for any observation period. Although the caudal brainstem may receive and process information associated with deprivation state, neural interactions between forebrain and brainstem structures appear necessary for the behavioral expression of deprivation effects on meal size or, as we can now conclude, on immediate oral motor responses to taste stimuli.

Modulation of the inspiratory-related activity of hypoglossal premotor neurons during ingestion and rejection in the decerebrate cat

Single-unit activities of the bulbar reticular inspiratory neurons directly projecting to hypoglossal motoneurons were studied during fictive ingestion (e.g., swallowing) and rejection elicited by repetitive stimulation of the superior laryngeal nerve and by application of water to the pharynx in immobilized decerebrated cats. The single-unit activity was recorded during 113 episodes of fictive ingestion from 25 inspiratory neurons directly projecting to hypoglossal motoneurons (single projection neurons) and 7 inspiratory neurons directly projecting to both hypoglossal and phrenic motoneurons (dual projection neurons) in the regions ventrolateral to the nucleus tractus solitarii and dorsomedial to the nucleus ambiguus. All of single projection neurons ceased inspiratory-related rhythmical discharges coincidentally with the onset of repetitive stimulation of the superior laryngeal nerve. The majority of them (19/25, 76%, type A) showed a spike burst during ingestion, whereas the minority (6/25, 24%, type B) kept silent until the end of repetitive stimulation of the superior laryngeal nerve. During fictive ingestion elicited by application of water to the pharynx, the type-A neurons showed a spike burst activity, whereas the type-B neurons kept silent. All dual projection neurons (7/7, 100%, type C) ceased inspiratory-related rhythmical discharges at the onset of repetitive stimulation of the superior laryngeal nerve and showed no activity during fictive ingestion. Likewise, the type-C neurons kept silent during fictive ingestion elicited by application of water to the pharynx. A spike burst was induced during 33 episodes of fictive rejection in all of 5 tested type-A, 3 tested type-B, and 6 tested type-C neurons. It is concluded that the premotor neurons involved in the respiratory-related rhythmical activity of hypoglossal motoneurons is responsible for switching from respiration to ingestion and rejection.

Effect of oral versus gastric delivery on gastric emptying of corn oil emulsions

Several studies have shown that fluids delivered to the stomach tend to empty more rapidly than when ingested by mouth. To better characterize the "delivery route effect" for corn oil, rats received intragastric or intraoral infusions matched for concentration and for the rate and duration of stimulus delivery. We showed, first, that more than twice as much oil emptied by the end of 12-min intragastric versus intraoral infusions but that the emptying curves remained roughly parallel for 1 h after infusion offset. Remaining experiments therefore focused on stimulus parameters of relevance to emptying control during stomach fill. Emptying during intragastric infusions approximately doubled with doublings of oil concentration (25-50%), infusion duration (6-12 and 12-24 min), and infusion rate (0.5-1.0 ml/min). Emptying during intraoral infusions, by contrast, was entirely unaffected by these manipulations. Unlike oil emptying, glucose emptying did not vary as a function of delivery route. The nutrient specificity of the delivery route effect cannot be explained in terms of energy density, as the effect was obtained for oil but not for glucose when their energy densities were equated (50% glucose, 25% corn oil). In discussion, we suggest that the oral influence on corn oil emptying during stomach fill is a gating factor that enables the expression of inhibition derived from postgastric nutrient stimulation.

Motor and premotor mechanisms of licking

The location, organization and anatomical connections of a central pattern generator (CPG) for licking are discussed. Anatomical and physiological studies suggest a brainstem location distributed within several subdivisions of the medullary reticular formation (RF). The involvement of widespread RF regions is evident from brainstem recording experiments in awake freely moving preparations and studies employing electrical stimulation of the frontal cortex to produce ororhythmic activity. The complex multifunctional properties of RF neurons producing licking are indicated by their activity during licking, swallowing and the rejection of an aversive gustatory stimulus. Anatomical studies place descending inputs to a brainstem CPG for licking to widely distributed areas of both the medial and lateral RF. In contrast, most projections originating from brainstem orosensory nuclei terminate primarily within the lateral RF. Because many pre-oromotor neurons appear concentrated largely in the intermediate zone of the RF (IRt), it is hypothesized that neurons from both lateral and medial sites converge within the IRt to control oromotor function.

Effects of central oxytocin administration on intraoral intake of glucose in deprived and nondeprived rats

We evaluated the effects of lateral intracerebroventricular administration of oxytocin (OT) and/or a selective oxytocin-receptor antagonist (OTX), 1-deamino-2-D-Tyr-(OEt)-4-Thr-8-Orn-OT, on ingestion of intraorally delivered 12.5% glucose in rats that were either nondeprived or deprived of food for 20 h. In deprived rats, OT delivered 30 min before an initial intake test yielded a dose-related reduction of intraoral glucose intake. The highest dose tested, 20 nmol, reduced intraoral glucose intake by 45%. The effect was short-lived, however. Intraoral intake for a second test, initiated 60 min after the termination of the first, increased as a function of OT dose so that total session intake was unaffected by OT treatment. The suppression of intraoral intake by 20 nmol OT was reversed by pretreatment (45 min before testing) with OTX. In nondeprived rats, by contrast, OT yielded no effect on first-test, second-test, or total session intakes. Significant increases in first-test and total session intakes were obtained when OTX (20 nmol) was administered alone both in deprived (32% increase in first-test intake) and nondeprived (31% increase) rats. In general, the results obtained are consistent with the suggestion that OT contributes to the control of meal size and, in particular, to the process of satiation, which is the aspect of ingestive control highlighted by the specialized intake test used in the present study.

d-fenfluramine anorexia: dissociation of ingestion rate, meal duration, and meal size effects

In the present study, we ask whether the suppressive effect of d-fenfluramine (d-FEN) on short-term intake can be better explained in terms of a primary action on particular behavioral parameters (e.g., ingestion rate or meal duration), as proposed by several investigators, or in terms of a primary effect on an intake "target" that can be achieved via diverse behavioral strategies. We applied two specialized intake testing paradigms that constrain the behavioral structure of the rat's meal in different ways, and determined whether or not the meal-size result varied in turn. (1) In the intraoral intake test, the rate of ingestion was clamped by the rate (1.0 ml/min) at which the test stimulus (12.5% glucose) was intraorally delivered. A d-FEN (3 mg/kg) suppression of intraoral intake was obtained demonstrating that ingestion rate adjustment is not necessary for the anorexic effect. In addition, for both d-FEN and vehicle conditions, comparable amounts were consumed when the intraoral intake test was either continuous or interrupted for 10 min beginning 6 min after test onset. For d-FEN, the increase in meal duration (mean = 11.98 min) required to compensate for the imposed interruption indicates that the drug does not specify an absolute limit for meal duration. (2) In the drop size-controlled spout-licking test, the volume of 12.5% glucose delivered for each lick was fixed at either 8 or 4 microliters. There was an overall reduction in intake with d-FEN (0.75 mg/kg), but as under vehicle injection conditions, the number of licks emitted approximately doubled when lick volume was halved. As a result, meal size was unaffected by the drop size manipulation. The drop size manipulation affected several other behavioral parameters under respective d-FEN and vehicle injection conditions, including: average rate of ingestion (ml/min), initial ingestion rate, and ingestion duration (meal duration minus pause time). The two experiments together demonstrate that the anorexic effect of d-FEN does not depend on adjustment of any particular behavioral parameter. The results suggest, rather, that given doses of d-FEN establish a particular degree of intake suppression that the rat defends via diverse behavioral strategies.

Functional characterization of caudal hypoglossal neurons by spectral patterns of neuronal discharges in the rat

This study evaluated the spectral characteristics of neuronal discharges in the caudal hypoglossal nucleus and their physiological relevance in adult, male Sprague Dawley rats which were anaesthetized and maintained with pentobarbital sodium. Based on auto-spectral analysis of extracellular single-neuron activity, three spectral patterns were identified in the spontaneous discharges of hypoglossal neurons. Neurons that exhibited a rhythmic pattern manifested a concentrated peak in the auto-spectrogram that corresponded to the mean discharge rate. A majority of hypoglossal neurons displayed the modulated pattern, which was manifested either as scattered power densities (wide-band modulated pattern) or with a peak frequency component that was different from the mean discharge rate (narrow-band modulated pattern). Neurons that exhibited a mixed pattern displayed both rhythmic and modulated spectral patterns. Cross-spectral analysis further revealed that respiratory modulation constituted a major physiological influence on caudal hypoglossal neurons. The respiratory modulated pattern, however, could be converted to a mixed pattern in the presence of a central dipsogen, angiotensin III. The results suggest that the spectral patterns of neuronal discharges in caudal hypoglossal neurons represent manifestations of multiple physiological information, including that regarding respiration and dipsogenesis, which is encoded in these neurons. It was also shown that this information may only be revealed by auto-spectral and cross-spectral analysis of neuronal discharge signals.

Ingestive taste reactivity as licking behavior

In ingestive taste reactivity analysis, the rhythmic oral motor responses observed during intraoral infusion of fluids normally ingested by rats are categorized and counted. These rhythmic movements can be likened to spout-licking in several respects. Both are emitted in the same frequency range (5-8 Hz), organized in a burst/pause pattern, and serve the function of intraoral transport of fluid into position for swallowing. The parallel suggests that a temporal pattern analysis, based on the spout-licking literature, can be fruitfully applied to the rhythmic movements that attend intraoral infusion. We provide a demonstration of such an analysis using an electromyographic (EMG) recording-based method for automated event detection. Eight rats received a 37.5% glucose solution (1.0 ml/min) in a series of 120 s infusion trials (45 s intertrial intervals) that was extended until the fluid was rejected. Movement counts declined 19.1% from the first to the last complete trial. Parameters derived from the pattern analysis (number of bursts, mean burst duration, pause durations, coefficient of variation for the distribution of within-burst intermovement intervals) were affected to a greater extent. The results indicate the potential value of temporal pattern analysis for various applications of the taste reactivity paradigm.