| scholarly article | Q13442814 |
| P356 | DOI | 10.1007/BF00187819 |
| P698 | PubMed publication ID | 7771683 |
| P2093 | author name string | W L Neuhuber | |
| H E Raybould | |||
| H R Berthoud | |||
| M Kressel | |||
| P2860 | cites work | Vagal afferent innervation of the rat fundic stomach: morphological characterization of the gastric tension receptor | Q31084018 |
| Vagal innervation of the rat pylorus: an anterograde tracing study using carbocyanine dyes and laser scanning confocal microscopy | Q36674042 | ||
| Lipid Digestion and Absorption | Q40148842 | ||
| Intraduodenal infusions of fats elicit satiety in sham-feeding rats | Q41235557 | ||
| Sensory vagal innervation of the rat esophagus and cardia: a light and electron microscopic anterograde tracing study | Q41467402 | ||
| Ultrastructural evidence for an innervation of epithelial enterochromaffine cells in the guinea pig duodenum | Q42054381 | ||
| Scanning electron microscopy of the muscle coat of the guinea-pig small intestine | Q42524428 | ||
| Dual capsaicin-sensitive afferent pathways mediate inhibition of gastric emptying in rat induced by intestinal carbohydrate | Q43451524 | ||
| Effect of actively transported hexoses on afferent nerve discharge from rat small intestine | Q43968260 | ||
| Vagal glucoreceptors in the small intestine of the cat | Q44115776 | ||
| Small intestinal capsaicin-sensitive afferents mediate feedback inhibition of gastric emptying in rats. | Q46000159 | ||
| Intestinal lipid inhibits gastric emptying via CCK and a vagal capsaicin-sensitive afferent pathway in rats. | Q46015220 | ||
| Duodenal acid-induced inhibition of gastric motility and emptying in rats | Q46292808 | ||
| Selective labeling of vagal sensory nerve fibers in the lower esophageal sphincter with anterogradely transported WGA-HRP. | Q48192972 | ||
| Central representation of arrival of nutrient in the duodenum | Q48659267 | ||
| A fluorescent labeling strategy for staining the enteric nervous system | Q48821722 | ||
| Central and peripheral vagal transport of cholecystokinin binding sites occurs in afferent fibers | Q48915657 | ||
| Nerve plexuses of the duodenal villi. Light and electron microscopic studies | Q53784591 | ||
| Mucosal receptors in the gastric antrum and small intestine of the rat with afferent fibres in the cervical vagus. | Q53978268 | ||
| An anterograde tracing study of the vagal innervation of rat liver, portal vein and biliary system | Q67464352 | ||
| CCK-receptor antagonists attenuate suppression of sham feeding by intestinal nutrients | Q67534381 | ||
| Integration of vagal afferent responses to gastric loads and cholecystokinin in rats | Q67924420 | ||
| Afferent nerve endings in the small intestine and the stomach. Light and electron microscopic studies | Q68281782 | ||
| Mechanical properties and sensitivity to CCK of vagal gastric slowly adapting mechanoreceptors | Q68429270 | ||
| Purification and sequencing of a trypsin-sensitive cholecystokinin-releasing peptide from rat pancreatic juice. Its homology with pancreatic secretory trypsin inhibitor | Q69060906 | ||
| Autoradiographic study on the distribution of vagal afferent nerve fibers in the gastroduodenal wall of the rabbit | Q69745095 | ||
| Vagal receptors sensitive to lipids in the small intestine of the cat | Q70157888 | ||
| Effects of cholecystokinin (CCK-8) on two classes of gastroduodenal vagal afferent fibre | Q70261597 | ||
| Capsaicin attenuates suppression of sham feeding induced by intestinal nutrients | Q70407525 | ||
| Duodenal lipid inhibits gastric acid secretion by vagal, capsaicin-sensitive afferent pathways in rats | Q70666362 | ||
| Vagal acido- and glucoreceptors in the gastro-duodenal region (author's transl) | Q70793346 | ||
| Subunit b of cholera toxin labels interstitial cells of Cajal in the gut of rat and mouse | Q71619902 | ||
| Experimentally induced granule release in the endocrine cells of dog pyloric antrum | Q71837120 | ||
| Plexus muscularis profundus and associated interstitial cells. I. Light microscopical studies of mouse small intestine | Q72672455 | ||
| A time sequence study of fat absorption in the rat jejunum | Q72789556 | ||
| Evidence for indirect dietary regulation of cholecystokinin release in rats | Q72848705 | ||
| Vagal unitary responses to intestinal amino acid infusions in the anesthetized cat: A putative signal for protein induced satiety | Q72930917 | ||
| P433 | issue | 3 | |
| P1104 | number of pages | 10 | |
| P304 | page(s) | 203-212 | |
| P577 | publication date | 1995-03-01 | |
| P1433 | published in | Anatomy and Embryology | Q1983570 |
| P1476 | title | Vagal sensors in the rat duodenal mucosa: distribution and structure as revealed by in vivo DiI-tracing | |
| P478 | volume | 191 |
| Q81305585 | A cluster of gustducin-expressing cells in the mouse stomach associated with two distinct populations of enteroendocrine cells |
| Q91596748 | A gut-brain neural circuit for nutrient sensory transduction |
| Q64265404 | A novel role for the extracellular matrix glycoprotein-Tenascin-X in gastric function |
| Q90746895 | Abdominal vagotomy reveals majority of small intestinal mucosal afferents labeled in nav 1.8cre-rosa26tdTomato mice are vagal in origin |
| Q33635973 | Age-related changes in vagal afferents innervating the gastrointestinal tract |
| Q58560352 | Altered bile acid profile in mild cognitive impairment and Alzheimer's disease: Relationship to neuroimaging and CSF biomarkers |
| Q48721928 | Apolipoprotein A-IV is involved in detection of lipid in the rat intestine |
| Q35491959 | Axon-like basal processes in enteroendocrine cells: characteristics and potential targets |
| Q36387897 | Brainstem circuits regulating gastric function |
| Q73083230 | Capsaicin-resistant vagal afferent fibers in the rat gastrointestinal tract: anatomical identification and functional integrity |
| Q38192977 | Chronic functional bowel syndrome enhances gut-brain axis dysfunction, neuroinflammation, cognitive impairment, and vulnerability to dementia |
| Q34068418 | Counterregulation of insulin by leptin as key component of autonomic regulation of body weight |
| Q35214345 | Development of the vagal innervation of the gut: steering the wandering nerve |
| Q41957252 | Devices for the treatment of obesity: will understanding the physiology of satiety unravel new targets for intervention? |
| Q38019927 | Early postnatal overnutrition: potential roles of gastrointestinal vagal afferents and brain-derived neurotrophic factor |
| Q37396988 | Effects of ghrelin on interdigestive contractions of the rat gastrointestinal tract |
| Q46529965 | Endogenous ghrelin and 5-HT regulate interdigestive gastrointestinal contractions in conscious rats |
| Q43596009 | Expression of 5-HT3 receptors by extrinsic duodenal afferents contribute to intestinal inhibition of gastric emptying |
| Q38886397 | Extrinsic Sensory Innervation of the Gut: Structure and Function. |
| Q33934014 | Functional and chemical anatomy of the afferent vagal system |
| Q37350024 | Gastrin, cholecystokinin and gastrointestinal tract functions in mammals |
| Q57107261 | Gut adaptation after metabolic surgery and its influences on the brain, liver and cancer |
| Q30235568 | Gut-Brain Cross-Talk in Metabolic Control |
| Q47597532 | Harnessing Gut Microbes for Mental Health: Getting From Here to There |
| Q35666224 | How many kinds of visceral afferents? |
| Q33664676 | Identifying the Ion Channels Responsible for Signaling Gastro-Intestinal Based Pain |
| Q77896212 | In vitro recordings of afferent fibres with receptive fields in the serosa, muscle and mucosa of rat colon |
| Q36099657 | Innervation of the gastrointestinal tract: patterns of aging |
| Q28817940 | Interdigestive migrating motor complex -its mechanism and clinical importance |
| Q28346075 | Intestinal serotonin acts as a paracrine substance to mediate vagal signal transmission evoked by luminal factors in the rat |
| Q43737833 | Intestinal serotonin acts as paracrine substance to mediate pancreatic secretion stimulated by luminal factors |
| Q54939638 | Meal-Sensing Signaling Pathways in Functional Dyspepsia. |
| Q30465489 | Mechanism of interdigestive migrating motor complex |
| Q40113119 | Melanocortin-4 receptor expression in a vago-vagal circuitry involved in postprandial functions |
| Q30494936 | Mice deficient in brain-derived neurotrophic factor have altered development of gastric vagal sensory innervation |
| Q44350989 | Modulation of bradykinin-induced mechanical hyperalgesia in the rat by activity in abdominal vagal afferents |
| Q34975061 | Musings on the wanderer: what's new in our understanding of vago-vagal reflexes? I. Morphology and topography of vagal afferents innervating the GI tract |
| Q37976164 | Nerveless and gutsy: intestinal nutrient sensing from invertebrates to humans |
| Q34836430 | Neural networks in intestinal immunoregulation |
| Q38473807 | Neural reflex pathways in intestinal inflammation: hypotheses to viable therapy |
| Q47888757 | Neurochemical and morphological phenotypes of vagal afferent neurons innervating the adult mouse jejunum |
| Q42518107 | Neuroendocrine control of intestinal mucosal mast cells under physiological conditions |
| Q33749166 | Nutrient tasting and signaling mechanisms in the gut. I. Sensing of lipid by the intestinal mucosa |
| Q35054892 | Obesity surgery and gut-brain communication |
| Q39874830 | Oral inoculation with herpes simplex virus type 1 infects enteric neuron and mucosal nerve fibers within the gastrointestinal tract in mice |
| Q36166645 | Peripheral neural targets in obesity |
| Q39270817 | Plasticity of vagal afferent signaling in the gut. |
| Q44654052 | Reduction of NT-3 or TrkC results in fewer putative vagal mechanoreceptors in the mouse esophagus |
| Q35834277 | Regulation of energy balance by a gut-brain axis and involvement of the gut microbiota |
| Q38951451 | Role of the gut microbiota in host appetite control: bacterial growth to animal feeding behaviour |
| Q38766761 | Role of the vagus nerve in the development and treatment of diet-induced obesity |
| Q89106929 | Roles for gut vagal sensory signals in determining energy availability and energy expenditure |
| Q35035212 | SCFA transport in rat duodenum |
| Q37868939 | Sensing via intestinal sweet taste pathways |
| Q51556502 | Sensitivity of vagal mucosal afferents to cholecystokinin and its role in afferent signal transduction in the rat. |
| Q51520728 | Sensitivity to 5-hydroxytryptamine in different afferent subpopulations within mesenteric nerves supplying the rat jejunum. |
| Q34928837 | Sensory neurone responses to mucosal noxae in the upper gut: relevance to mucosal integrity and gastrointestinal pain |
| Q45271826 | Serotonin-type 3 receptors mediate intestinal Polycose- and glucose-induced suppression of intake |
| Q44391164 | Short-chain fatty acids stimulate colonic transit via intraluminal 5-HT release in rats |
| Q60046816 | Spinal Afferent Innervation of the Colon and Rectum |
| Q37117587 | TRPA1 regulates gastrointestinal motility through serotonin release from enterochromaffin cells |
| Q73209547 | Tension and stretch receptors in gastrointestinal smooth muscle: re-evaluating vagal mechanoreceptor electrophysiology |
| Q93367537 | The Functional and Neurobiological Properties of Bad Taste |
| Q90533544 | The Gut-Brain Axis, the Human Gut Microbiota and Their Integration in the Development of Obesity |
| Q38812536 | The Role of the Vagal Nucleus Tractus Solitarius in the Therapeutic Effects of Obesity Surgery and Other Interventional Therapies on Type 2 Diabetes. |
| Q34621785 | The gut and food intake: an update for surgeons. |
| Q45894561 | The gut as a sensory organ. |
| Q34081762 | The intestinal mucosa as a target and trigger for enteric reflexes |
| Q91304787 | The metabolic role of vagal afferent innervation |
| Q34071840 | The role of gastrointestinal vagal afferents in the control of food intake: current prospects |
| Q34778864 | The vagus nerve, food intake and obesity |
| Q21129253 | Upper gastrointestinal dysmotility after spinal cord injury: is diminished vagal sensory processing one culprit? |
| Q38020318 | Vagal afferent controls of feeding: a possible role for gastrointestinal BDNF. |
| Q37518154 | Vagal afferent innervation of the proximal gastrointestinal tract mucosa: chemoreceptor and mechanoreceptor architecture |
| Q43569477 | Vagal and spinal mechanosensors in the rat stomach and colon have multiple receptive fields |
| Q46066662 | Vagal branches involved in inhibition of bradykinin-induced synovial plasma extravasation by intrathecal nicotine and noxious stimulation in the rat. |
| Q30306809 | Vagal immune-to-brain communication: a visceral chemosensory pathway |
| Q34475450 | Vagal innervation of intestine contributes to weight loss After Roux-en-Y gastric bypass surgery in rats |
| Q35675478 | Vagal innervation of the hepatic portal vein and liver is not necessary for Roux-en-Y gastric bypass surgery-induced hypophagia, weight loss, and hypermetabolism |
| Q73466686 | Vagal innervation of the rat duodenum |
| Q47137050 | Visceral Inflammation and Immune Activation Stress the Brain |
| Q34699784 | Visceral perception: sensory transduction in visceral afferents and nutrients |
| Q38655873 | What is the Mechanism Behind Weight Loss Maintenance with Gastric Bypass? |
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