Centrally administered NPY stimulated gastric acid and pepsin secretion by a vagally mediated mechanism

We investigated the possible roles of centrally administered neuropeptide Y (NPY) on gastric secretion, serum gastrin levels and gastric mucosal blood flow in anesthetized rats. Centrally administered NPY dose-dependently stimulated gastric acid and pepsin secretion. The stimulatory effect of intracerebroventricular administration of NPY was more potent than that of intracisternal administration. Centrally administered NPY also increased gastric secretion in the central noradrenaline depleted rats. In contrast, intravenously administered NPY had no influence on gastric secretion. These stimulatory effects were abolished by vagotomy or atropine pretreatment. The serum gastrin levels did not change after central NPY injection. Although intravenously administered NPY slightly increased gastric mucosal blood flow, centrally administered NPY slightly diminished gastric mucosal blood flow. These results indicate that centrally administered NPY markedly influences gastric functions in the rat.     

Endogenous opiates and stress ulceration

Parenteral administration of the opiate antagonist, naltrexone, had a cytoprotective effect against stress-induced ulceration. This effect appears to be due to blockade of peripheral rather than central endogenous opiates and is not related to the central inhibitory effect of opiates on gastric acid secretion. Opiates have complex effects on gastric mucosal blood flow which may explain their role in stress ulceration.     

Effects of L-glutamic acid on acid secretion and mucosal blood flow in the rat stomach

The effect of intravenous administration of L-glutamic acid (L-Glu) on gastric acid secretion and gastric mucosal blood flow (GMBF) in anesthetized rats were investigated. Infusion with synthetic L-Glu alone had no effect on spontaneous acid secretion. However, L-Glu reduced histamine- (2 mg/kg/hr) or oxotremorine- (1 microg/kg/hr) stimulated acid secretion, whereas L-Glu had no effect on acid secretion induced by pentagastrin (8 microg/kg/hr). Furthermore, this inhibitory effect of L-Glu on histamine- or oxotremorine-stimulated acid secretion was blocked by 6,7-dinitroquinoxaline-2,3-dione (DNQX), a non-NMDA receptor antagonist. The effect of L-Glu on gastric mucosal microcirculation in the anesthetized rats was evaluated by using Laser Doppler Flowmetry (LDF). The results showed that L-Glu did not significantly reduce both mucosal and serosal blood flow in stomach. No significant modulatory effect on histamine- or oxotremorine-stimulated increase in GMBF was noted after infusion with L-Glu. It is concluded that L-glutamic acid is capable of the modulating of gastric acid secretion via ionotropic non-NMDA receptors, but do not affect on GMBF. However, L-glutamic acid showed no effect on acid secretion by itself.     

Gastric secretion and gastrin under progressive doses of somatostatin-14 and -28 administered intraperitoneally to the rat

The actions of progressive doses of intraperitoneally (IP) administered somatostatin-14 (SS-14) and -28 (SS-28) on gastric secretion (acid, pepsin) and mucosal blood flow (MBF) were studied in conscious gastric fistula rats both under basal conditions and under additional administration of pentagastrin. Also, somatostatin-like immunoreactivity was measured in aortal blood in all groups as well as aortal gastrin levels under basal conditions. IP infusion of equimolar doses of SS-14 and SS-28 resulted in an equal and dose-dependent inhibition of basal as well as pentagastrin-stimulated gastric acid secretion. MBF was reduced by either peptide both in the basal and pentagastrin experiments. Under basal conditions pepsin secretion was significantly increased by infusion of SS-14 at the higher doses, by infusion of SS-28 only at the intermediate dose (3.1 nmole kg-1.hr-1). In the pentagastrin experiments, low and intermediate doses of SS-14 tended to lower pepsin outputs but the highest dose of SS-14 stimulated pepsin secretion, whereas SS-28 had no effect on pepsin. Administration of SS-28 inhibited gastrin only at the highest dose (12.3 nmole kg-1.hr-1), and SS-14 had no influence at all on gastrin. After IP infusion of both peptides, plasma SLI rose dose-dependently under basal and stimulated conditions. Gel chromatography indicated an in-vivo conversion of SS-28 to SS-14 or intermediate fragments. It is concluded that SS-14 and SS-28 delivered by IP infusion, inhibit basal and stimulated gastric acid equally in the rat without suppressing gastrin. The mechanism underlying SS-mediated pepsin stimulation is unknown.     

Gastric mucosal integrity: gastric mucosal blood flow and microcirculation. An overview

The stomach is in a state of continuous exposure to potentially hazardous agents. Hydrochloric acid together with pepsin constitutes a major and serious threat to the gastric mucosa. Reflux of alkaline duodenal contents containing bile and pancreatic enzymes are additional important injurious factors of endogenous origin. Alcohol, cigarette smoking, drugs and particularly aspirin and aspirin-like drugs, and steroids are among exogenous mucosal irritants that can inflict mucosal injury. The ability of the stomach to defend itself against these noxious agents has been ascribed to a number of factors constituting the gastric mucosal defense. These include mucus and bicarbonate secreted by surface epithelial cells, prostaglandins, sulfhydryl compounds and gastric mucosal blood flow. The latter is considered by several researchers to be of paramount importance in maintaining gastric mucosal integrity. The aim of this paper is to review the experimental and clinical data dealing with the role of mucosal blood flow and in particular the microcirculation in both damage and protection of the gastric mucosa.     

Correlation of gastric mucosal damage with sialic acid profile in rats: effect of hydrochloric acid, pepsin and hypertonic saline

Sialic acids occupy terminal positions on gastric mucus glycoprotein where they contribute to the high viscosity of mucin. Desialylation of mucus may lead to degradation of the mucus and eventually to the breakdown of the gastric mucus barrier. The effect of a variety of damaging agents (0.1 M HCl, 2 mg ml(-1) pepsin and 2 M NaCl) on sialic acid profile was determined in pylorus-ligated rats. The relationship between sialic acid, galactose, pyruvate and the extent of gastric mucosal damage were studied. Instillation of pepsin significantly increased total sialic acid, galactose and macroscopic mucosal lesions in the stomach. Instillation of 0.1 M HCl reduced the total sialic acid but this decrease was not significant. Acidity led to a significant increase in the amount of free sialic acid in the gastric instillates and the macroscopic lesions induced by acid was not significantly different from the control animals (0.15 M NaCl). 2 M NaCl induced the macroscopic lesions in the stomach and also free sialic acid in the instillates. Pepsin potentiates the action of 2 M NaCl. In all the agents examined with the exception of acid, it was observed that an increase in free sialic acid and galactose was accompanied by gastric mucosal erosion and elevation of pyruvate concentration. It is concluded that gastric acidity alone is not inherently damaging and that resistance of gastric mucosa to destructive agents may be dependent on the integrity of the sialic acids.     

Effects of morphine, enkephalins and naloxone on postprandial gastric acid secretion, gastric emptying and gastrin release in dogs

The effects of intravenous infusions of morphine, met-enkephalin and leu-enkephalin on gastric acid secretion, gastrin release and gastric emptying were investigated in four dogs with gastric cannulas stimulated by a liquid peptone meal. The actions of a potent opiate antagonist, naloxone, used alone or combined with opiates were also studied. Morphine, met-and leu-enkephalin decreased the fractional gastric emptying rate. Acid secretion was decreased by enkephalins and increased by high doses of morphine. Enkephalins and to a lesser degree morphine inhibited gastrin release during the first hour following the administration of the meal. Only leu-enkephalin decreases significantly the integrated gastrin response. Naloxone at the doses used antagonized partly or totally the effects of opiates on gastric emptying but not those on gastric secretion or gastrin release. Naloxone infused alone had no significant effect on the gastric functions tested. These studies indicate that in dogs stimulated by a liquid test meal, enkephalins inhibit gastric emptying, acid secretion and gastrin release. Morphine inhibits gastric emptying and gastrin release and enhances acid secretion.     

Potentiation of the gastro-protective effect of sulglicotide in the presence of cimetidine in the rat

The effects of sulglicotide, alone or combined with cimetidine, have been investigated on mucosal lesions induced in rats by pylorus ligation. In the same animals, the measurement of acid and pepsin output and of soluble and barrier mucus has been performed. Dose-dependent sulglicotide prevented the development of mucosal lesions and its protective effect was achieved without significant modifications in gastric acid secretion. The secretion of pepsin and of mucus was markedly inhibited at every dosage of the compound. Neither the damage to gastric mucosa nor the secretion of acid, pepsin and mucus were affected by cimetidine. The combination of the highest doses of both compounds resulted in a synergistic gastro-protective effect, not dependent on a synergistic effect on the reduction in acid secretion.     

电刺激室旁核对大鼠应激性胃粘膜损伤的影响

电刺激室旁核(PVN)有加重大鼠应激性胃粘膜损伤的作用;PVN内微量注射神经元胞体兴奋剂L-谷氨酸钠和电刺激PVN的效应相同;电解损毁双侧PVN或对其电刺激后,使应激性胃粘膜损伤明显减轻,切断膈下迷走神经或皮下注射阿托品后,可显著减轻电刺激PVN加重大鼠应激性胃粘膜损伤的效应;电刺激PVN使胃粘膜血流量减少,但对胃液量、胃酸排出量、胃蛋白酶活性及胃壁结合粘液量均无显著影响。从而表明,PVN是影响应激性胃粘膜损伤的特异性中枢部位之一,当其兴奋时,可加重应激性胃粘膜损伤,并可能是通过迷走神经胆碱能纤维起作用的,且与胃粘膜血流量的减少有关;电刺激PVN加重胃粘膜损伤似不是由胃液量、胃酸、胃蛋白酶活性及胃壁结合粘液量等因素的改变引起的。     

Phytohaemagglutinin inhibits gastric acid but not pepsin secretion in conscious rats

Phytohaemagglutinin (PHA), a kidney bean lectin, is known for its binding capability to the small intestinal surface. There has been no data available, however, on the biological activity of PHA in the stomach. Recent observations indicate that PHA is able to attach to gastric mucosal and parietal cells. Therefore, we examined whether PHA affects gastric acid and pepsin secretion in rats. Rats were surgically prepared with chronic stainless steel gastric cannula and with indwelling polyethylene jugular vein catheter. During experiments, animals were slightly restrained. Gastric acid secretion was collected in 30 min periods. Acid secretion was determined by titration of the collected gastric juice with 0.02 N NaOH to pH 7.0. Pepsin activity was estimated by measuring enzymatic activity. Saline, pentagastrin and histamine were infused intravenously. PHA or bovine serum albumin (BSA) were dissolved in saline and given intragastrically through the gastric cannula. PHA significantly inhibited basal acid secretion. Inhibition of acid output reached 72% during the first collection period following PHA administration when compared, then gradually disappeared. Pentagastrin-stimulated acid secretion was repressed dose-dependently by PHA as well. Maximal inhibition was observed during the first 30 min following application of PHA. Histamine-stimulated acid secretion was inhibited by PHA in a similar manner. Pepsin secretion was not affected by PHA under either basal or stimulated conditions. These results provide evidence that PHA is a potent inhibitor of gastric acid secretion in conscious rats, but it does not affect pepsin output from the stomach.     

Actions of prostacyclin (PGI2) and its product, 6-oxo-PGF1alpha on the rat gastric mucosa in vivo and in vitro.

The effects of prostacyclin (PGI2) and its breakdown product 6-oxo-PGF1alpha on various aspects of gastric function were investigated in the rat. PGI2 increased mucosal blood flow when infused intravenously. PGI2 was a more potent inhibitor of gastric acid secretion in vivo than PGE2. Like PGE2, PGI2 inhibited acid secretion from the rat stomach in vitro. PGI2 had comparable activity to PGE2 in inhibiting indomethacin-induced gastric erosions. Thus prostacyclin shares several of the activities of PGE2, and may be involved in the regulation of gastric mucosal function.     

Gastric microcirculatory change and development of acute gastric mucosal lesions (stress ulcer)

Concerning the pathogenesis of acute gastric mucosal lesions, gastric microcirculatory change has drawn attention as an important factor. In view of this fact, gastric mucosal blood flow and microvascular structure were investigated in normal and in burn stressed rats. Moreover, alterations in acid and pepsin activities in by morphological and biochemical procedures in order to evaluate the relationship between defensive and aggressive factors of the gastric mucosa. Gastric mucosal blood flow decreased significantly in early period after induction of stress (p less than 0.01). The incidence of ulceration showed a correlative relation with the decrease of mucosal blood flow. Reduction of blood flow in burn was due to opening of arteriovenular shunt and it appeared that this was responsible for mucosal ischemia and congestion. Following the decrease of blood flow, acid output was lower in stress than that in control. Finally, the results of these studies demonstrated the importance of defensive factors. The reduction of mucosal blood flow resulted in the sequence of events that led to formation of acute gastric mucosal lesion.     

A study of the actions of naloxone and morphine on gastric acid secretion and gastric mucosal damage in the rat

There exists a considerable controversy in the literature with regard to the effect of either opiate receptor blockade or that of morphine in different gastric and intestinal ulcer models in the rat. We performed experiments to evaluate the effects of naloxone and morphine on gastric acid secretion and gastric mucosal damage in different experimental models of gastric mucosal injury, namely in indomethacin-, HCl (0.6N)- and ethanol (96%)-models. We found that: 1) 10 mg/kg naloxone ip given twice, effectively protected gastric mucosa against indomethacin (30 mg/kg ip) and against the acid-dependent injury caused by 0.6 N HCl (1 mL ig), but not against the non acid-dependent injury caused by 96% ethanol (1 mL ig); 2) morphine (10 + 10 mg/kg ip) increased ulcers in the HCl-model, but had no effect in the two other models; 3) this ulcer-aggravating effect of morphine in the HCl-model was blocked by pretreatment of 2 mg/kg ip naloxone; and 4) both naloxone (5 + 5 and 10 + 10 mg/kg ip) significantly decreased gastric acid secretion in 1-h pylorus ligated rats. We conclude that: 1) naloxone dose-dependently protects against the indomethacin- and HCl-, but not against the ethanol-induced gastric mucosal damage; 2) morphine aggravates the HCl-induced ulcerogenesis; and 3) both opiod receptor agonist and antagonist decrease gastric acid secretion.     

吗啡和纳洛酮对损毁下丘脑诱致的大鼠胃粘膜损伤之影响

本实验观察了静注吗啡和纳洛酮对电解损毁后部下丘脑诱致的大鼠胃粘膜损伤的影响并观察了在静注吗啡、纳洛酮后和侧脑室注射纳洛酮后其胃酸分泌和血清胃泌素水平之变化。实验揭示,吗啡仅略为降低该神经源性胃粘膜损伤程度,而纳洛酮则明显地减少其胃粘膜损伤;静注吗啡能抑制后部下丘脑损毁后大鼠的胃酸分泌,增加其血清胃泌素水平,而静注纳络酮后,这种大鼠的胃酸分泌增加,但血清胃泌素水平无明显变化;侧脑室注射纳洛酮对后部下丘脑损毁后大鼠胃酸分泌和血清胃泌素水平无明显影响。本结果表明,胃酸可能是导致这种消化道损伤的条件之一,而不是最重要因素;静注纳洛酮对后部下丘脑损毀后大鼠胃粘膜变化有保护作用。后者提示,内源性阿片样肽可能参与这种神经源性胃粘膜损伤的形成。     

Neurotensin inhibition of gastric exocrine secretions in the cat

The gastric exocrine inhibitory activities of neurotensin were characterized in conscious cats prepared with gastric fistulae. Neurotensin was a potent inhibitor of pentagastrin-stimulated pepsin secretion (ID50, approx. 0.3 mumol . kg-1 . h-1) but was approximately 60 times less potent against acid secretion. Neurotensin did not significantly reduce submaximal histamine-stimulated acid or pepsin secretions. the total 2 h acid and pepsin outputs in response to insulin-hypoglycaemia were not reduced by neurotensin, although the peak 15-min outputs were reduced. The reduction in peak secretion was possibly related to neurotensin antagonism of the ability of insulin to lower blood glucose concentrations. Neurotensin alone was not hyperglycaemic when given as an intravenous infusion. Two C-terminal fragments of neurotensin, the dodecapeptide and nonapeptide, inhibited pentagastrin-stimulated pepsin secretion, but were less potent than neurotensin. The observations with the C-terminal fragments indicate that the major determinants of gastric exocrine inhibitory activity of neurotensin reside in its C-terminal; this agrees with observations on other biological activities of neurotensin. The reduced potency of the dodecapeptide indicates the importance of the N-terminal pyroglutamyl residue for full gastric exocrine inhibitory activity.     

Effects of endothelin-1 on duodenal bicarbonate secretion and mucosal integrity in rats

Effects of endothelin-1 on gastric acid secretion, duodenal HCO3- secretion, and duodenal mucosal integrity were investigated in anesthetized rats, in comparison with those of TY-10957, a stable analogue of prostacyclin. A rat stomach mounted on an ex-vivo chamber or a proximal duodenal loop was perfused with saline, and gastric acid or duodenal HCO3- secretion was measured using a pH-stat method and by adding 100 mM NaOH or 10 mM HCl, respectively. Duodenal lesions were induced by mepirizole (200 mg/kg) given subcutaneously. Intravenous administration of endothelin-1 (0.6 and 1 nmol/kg) caused an increase of duodenal HCO3- secretion with concomitant elevation of blood pressure; this effect was antagonized by co-administrahon of BQ-123 (ET(A) antagonist; 3 mg/kg, i.v.) and significantly mitigated by vagotomy. Likewise, endothelin-1 caused a significant decrease in histamine-stimulated acid secretion, and this effect was also significantly antagonized by BQ-123. Although TY-10957 (10 and 30 mg/kg, i.v.) produced a temporal decrease of blood pressure, this agent caused not only an increase of duodenal HCO3- secretion, independent of vagal nerves, but also a decrease of acid secretion as well. In addition, both endothelin-1 and TY-10957 significantly prevented mepirizole-induced duodenal lesions at the doses that caused an increase of duodenal HCO3- secretion and a decrease of gastric acid secretion. These results suggest that endothelin-1 affects the duodenal mucosal integrity by modifying both gastric acid and duodenal HCO3- secretions, the effects being mediated by ET(A) receptors.     

Close arterial infusion of calcitonin gene-related peptide into the rat stomach inhibits aspirin- and ethanol-induced hemorrhagic damage

Afferent neuron-mediated gastric mucosal protection has been suggested to result from the local release of vasodilator peptides such as calcitonin gene-related peptide (CGRP) from afferent nerve endings within the stomach. The present study, therefore, examined whether rat alpha-CGRP, administered via different routes, is able to protect against mucosal injury induced by gastric perfusion with 25% ethanol or acidified aspirin (25 mM, pH 1.5) in urethane-anesthetized rats. Close arterial infusion of CGRP (15 pmol/min) to the stomach, via a catheter placed in the abdominal aorta proximal to the celiac artery, significantly reduced gross mucosal damage caused by ethanol and aspirin whereas mean arterial blood pressure (BP) was not altered. Intravenous infusion of CGRP (50 pmol/min) did not affect aspirin-induced mucosal injury but significantly enhanced ethanol-induced lesion formation. Intravenous CGRP (50 pmol/min) also lowered BP and increased the gastric clearance of [14C]aminopyrine, an indirect measure of gastric mucosal blood flow while basal gastric output of acid and bicarbonate was not altered. Intragastric administration of CGRP (260 nM) significantly inhibited aspirin-induced mucosal damage but did not influence damage in response to ethanol. BP, gastric clearance of [14C]aminopyrine, and gastric output of acid and bicarbonate remained unaltered by intragastric CGRP. These data indicate that only close arterial administration of CGRP to the rat stomach, at doses devoid of a systemic hypotensive effect, is able to protect against both ethanol- and aspirin-induced mucosal damage. As this route of administration closely resembles local release of the peptide in the stomach, CGRP may be considered as a candidate mediator of afferent nerve-induced gastric mucosal protection.     

Current concepts in gastric microcirculatory pathophysiology.

When the barrier to acid back-diffusion is disrupted, there is a protective increase in gastric mucosal blood flow to help remove the back-diffusing acid. Only recently has the mechanism for calling forth this protective hyperemia been determined. The gastric mucosa and submucosa are innervated by many capsaicin-sensitive sensory nerve fibers containing vasodilator peptides. The gastric mucosal sensory neurons monitor for acid back-diffusion, and, when this process occurs, signal for a protective increase in blood flow via release of calcitonin gene-related peptide from the submucosal periarteriolar fibers. The endothelium-derived vasodilator, nitric oxide, plays an important role both in the maintenance of basal gastric mucosal blood flow and in the increase in blood flow that accompanies pentagastrin-stimulated gastric acid secretion. It also interacts with the capsaicin-sensitive sensory nerves in the modulation of the microcirculation to maintain mucosal integrity. Finally, it has been shown that neutrophils play an important role in various forms of mucosal injury. The leukocytes adhere to the vascular endothelium and contribute to injury by reducing blood flow via occlusion of microvessels, as well as by releasing mediators of tissue damage.     

Homeostasis in the gastric mucosa and blood circulation. Part 1. Mechanisms of the adequate blood flow maintenance in the gastric mucosa]

The increase of mucosal blood flow in response to food entrance into stomach or different irritant action is the component of gastric mucosal defence barrier. Sufficient blood flow ensures normal acid-bicarbonate balance in gastric mucosa, supports the healing process and prevents superficial damages from developing into deep ones. Capsaicin-sensitive afferent nerve fibers play the large role in the blood flow regulation. The influence of these nerve fibers on the gastric blood flow is mediated by the calcitonin-gene related peptide. This peptide released from peripheral afferent terminals improves microcirculation in stomach walls. Moreover nerve impulses from afferent neurons modulate parasympathetic activity that in turn induces the increase of gastric mucosal blood flow through both choilinergic and noncholinergic mechanisms. The gastric mucosal blood flow may be also regulated by humoral and paracrine metabolites. Nitric oxide and prostaglandines are the most important low molecular weight compounds. They play the main role in the maintenance of the basal gastric mucosal blood flow and in the development of hyperemic responses to harmful agents.