Role of nonesterified fatty acids in necrotizing pancreatitis: an in vivo experimental study in rats.

INTRODUCTION: In acute pancreatitis, nonesterified fatty acids (NEFA) might be released by lipase and cause tissue necrosis by their detergent properties, but this has not been established in vivo. AIMS: To measure the release of NEFA in the blood stream, pancreatic tissue, and peritoneal cavity during taurocholate-induced acute necrotizing pancreatitis in rats. METHODOLOGY: Ascites and blood were repeatedly sampled; after 24 hours, pancreatic lesions were scored, and NEFA were measured in the pancreas. The effects of a specific lipase inhibitor (Tetrahydrolipstatin [THL]) were also studied. RESULTS: A slight transient increase (22%) of NEFA concentration was observed in systemic circulation but did not parallel the time course of lipase activity, arguing against an intravascular production of NEFA by circulating lipase. Pancreatic NEFA did not differ between rats with pancreatitis and control rats. NEFA in ascites increased to threefold the basal value immediately after taurocholate and decreased rapidly thereafter, whereas lipase increased later in ascites and remained elevated during the 24-hour duration of the experiment. Lipase inhibition by THL neither modified the early increase of NEFA in ascites, nor altered the macroscopic, enzymatic, and histologic evolution of pancreatitis. CONCLUSION: This in vivo study does not confirm the hypothetical role of NEFA produced by pancreatic lipase in the necrotic process and its systemic complications, up to now mainly suggested on the basis of ex vivo experiments.

Caseinomacropeptide specifically stimulates exocrine pancreatic secretion in the anesthetized rat.

The effect of caseinomacropeptide (CMP) (the [106-169] fragment of kappa-casein produced during digestion of milk protein), was studied in anesthetized rats using bile diversion for a pure pancreatic juice collection system. Intraduodenal administration of CMP induced a dose-related specific stimulation of pancreatic secretion which was nearly abolished by devazepide, atropine, hexamethonium, vagotomy or perivagal capsaicin pretreatment. Moreover, CMP did not inhibit in vitro trypsin activity. These results demonstrate that CMP is more likely to stimulate pancreatic secretion specifically through cholecystokinin release and activation of a vago-vagal cholinergic reflex loop than by inhibition of luminal trypsin, in anesthetized rats.

Oxyntomodulin inhibits pancreatic secretion through the nervous system in rats.

Glicentin (GLIC), oxyntomodulin (OXM), and peptide YY (PYY) released in blood by ileocolonic L-cells after meals may inhibit pancreatic secretion. Whereas OXM interacts with glucagon and tGLP-1 receptors, OXM 19-37, a biologically active fragment, does not. The purpose of this study was to measure the effect of OXM, OXM 19-37, GLIC, tGLP-1, and PYY on pancreatic secretion stimulated by 2 deoxyglucose (2DG), electrical stimulation of the vagus nerves (VES), acetylcholine and cholecystokinin octapeptide (CCK8) in anesthetized rats. The effect of OXM was also studied in dispersed pancreatic acini. Plasma oxyntomodulin-like immunoreactivity (OLI) was measured by radioimmunoassay after the exogenous infusion of OXM and after an intraduodenal meal. OXM 19-37, infused at doses mimicking postprandial plasma levels of OLI, decreased pancreatic secretion stimulated by 2DG, VES, or CCK8. Similar effects were found with OXM and GLIC. OXM 19-37 did not change the pancreatic stimulation induced by acetylcholine in vivo, or CCK-induced amylase release in isolated acini. Vagotomy completely suppressed the inhibitory effect of OXM 19-37 on CCK8-stimulated pancreatic secretion. PYY inhibited the effect of 2DG, but not that of CCK8, whereas tGLP-1, even in pharmacologic doses, had no effect on stimulated pancreatic secretion. OXM, OXM 19-37, but not tGLP-1, inhibit pancreatic secretion at physiologic doses, through a vagal neural indirect mechanism, different from that used by PYY, and probably through a GLIC-related peptide-specific receptor.

Neural mechanism of the antisecretory effect of peptide YY in the rat colon in vivo.

The purpose of this work was to determine the mechanism of the antisecretory effect of peptide YY in the rat colon and whether this effect is physiological. In this prospect, doses of exogenous peptide YY producing physiological and supraphysiological plasma levels were intravenously infused in rats provided with colonic and jejunal ligated loops in vivo, under secretory stimulation by vasoactive intestinal peptide. Peptide YY decreased the secretory effect of VIP in a dose-related fashion. The effect of peptide YY was blocked or strongly decreased by tetrodotoxin, hexamethonium, idazoxan, haloperidol, and the sigma antagonist BMY 14, 802 in both the colon and jejunum. We conclude that peptide YY decreases water and electrolyte secretion in the colonic mucosa by a complex neural mechanism involving at least two neurons connected through a nicotinic synapse, alpha-2 adrenoceptors and sigma receptors, and that this effect can occur with physiological doses of peptide YY.

Antisecretory effect of peptide YY through neural receptors in the rat jejunum in vitro.

Basal short circuit current (Isc) was measured in stripped rat jejunum after addition of neural antagonists and of peptide YY (PYY). Basal Isc was slightly (by 10-21%) but significantly inhibited by tetrodotoxin, hexamethonium, idazoxan, and the sigma antagonist BMY 14,802. PYY (10(-7) M) reduced basal Isc by approximately 54%. This inhibition was unchanged by hexamethonium but reduced by 44-68% in the presence of tetrodotoxin, idazoxan, haloperidol, BMY 14,802, and atropine. The Y2 agonist pYY(3-36) was more potent than the Y1 agonist (Leu31,Pro34)PYY. In conclusion, PYY reduces basal Isc in rat jejunum in part through a neural mechanism involving muscarinic receptors, alpha2 adrenoceptors, and sigma receptors and, in part, through a direct effect on enterocytes. The PYY effect seems mainly carried out through Y2-receptor activation.

Cerium-based histochemical demonstration of oxidative stress in taurocholate-induced acute pancreatitis in rats. A confocal laser scanning microscopic study.

Direct in vivo histological detection of oxygen-derived free radicals (OFRs) in inflammatory conditions is not fully resolved. We report an application of cerium histochemistry (in which capture of OFRs by Ce atoms results in laser-reflectant cerium-perhydroxide precipitates) combined with reflectance confocal laser scanning microscopy (CLSM) to demonstrate the evolution of oxidative stress in taurocholate-induced acute pancreatitis (AP) in rats. Animals were perfused with CeCl(3) in vivo and cryostat sections of pancreata were studied by CLSM. Vascular endothelium was immunolabeled for PECAM-1. OFR production by isolated polymorphonuclear leukocytes (PMNs) incubated in vitro with CeCl(3) was quantified by image analysis. In the pancreas, strong OFR-derived cerium reflectance signals were seen in acinar cells at 1-2 hr, capillaries and small venules were frequently engorged by cerium precipitates, and adherent PMNs presented weak intracellular reflectance signals. At 8-24 hr, acinar cell OFR production decreased, whereas adherent/transmigrated PMNs displayed abundant intra- and pericellular reflectance. PECAM-1 expression was unchanged. PMNs from ascites or blood showed significant (p<0.01) time-dependent OFR production, plateauing from 2 hr. The modified cerium capture/CLSM method allows the co-demonstration of in vivo oxidative stress and cellular structures labeled with fluorescent markers. In vivo oxidative stress was shown histologically for the first time in experimental AP.

Comparison of the postprandial release of peptide YY and proglucagon-derived peptides in the rat.

Endocrine L-cells of the distal intestine synthesize both peptide YY (PYY) and proglucagon-derived peptides (PGDPs), whose release has been reported to be either parallel or selective. Here we compare the release mechanisms of PYY, glucagon-like peptide-1 (GLP-1), and oxyntomodulin-like immunoreactivity (OLI) in vivo. Anaesthetized rats were intraduodenally (ID) given either a mixed semi-liquid meal or oleic acid, or they received oleic acid or short chain fatty acids (SCFA) intracolonically (IC). The ID meal released the three peptides with a similar time-course (peak at 30 min); ID oleic acid produced a progressive release of PYY and OLI, while GLP-1 release was less. IC oleic acid or SCFA released smaller (but significant) amounts of PYY but no OLI or GLP-1. Hexamethonium inhibited most of the response to the ID meal and ID oleic acid, but did not change the PYY response to IC oleic acid. NG-nitro-l-arginine methyl ester (l-NAME, a nitric oxide synthase inhibitor) inhibited meal-induced PYY release and left OLI and GLP-1 unaffected. BW10 (a gastrin-releasing peptide antagonist) had no effect on the meal-induced release of either peptide. These results suggest a parallel initial release of PYY, OLI and GLP-1 after the ID meal, or oleic acid, by an indirect mechanism triggered in the proximal bowel, using nicotinic synapses, and involving nitric oxide release for PYY and an unknown mediator for PGDPs. For PYY there is a later phase of peptide release, probably induced by direct contact between nutrients and colonic L-cells.

Effect of sumatriptan on external pancreatic secretion and its interaction with endogenous norepinephrine in the rat.

We reported previously that blocking norepinephrine reuptake by nisoxetine could modulate external pancreatic secretion in the rat. We report in this study the interaction of serotonin (5-HT) with endogenous catecholamines by using sumatriptan, an agonist of 5-HT1 receptors, in combination with nisoxetine. Urethane-anesthetized male Wistar rats were fitted with an acute pancreatic fistula. Nisoxetine (0.3 mg/kg, i.v.) and sumatriptan (0.1-1 mg/kg, s.c.) were administered alone or in combination. Pancreatic secretion was measured under stimulation by 2-deoxy-D-glucose (2DG; 75 mg/kg, i.v.), by vagal electrical stimulation (4 V, 2 ms, 10 Hz), or by acetylcholine (60-1,800 microg/kg.h). (i) 2DG: Nisoxetine alone inhibited 2DG-induced pancreatic secretion (p < 0.01). Sumatriptan alone also produced a dose-related inhibition of 2DG-induced pancreatic secretion (p < 0.01). When sumatriptan and nisoxetine were combined, protein response to 2DG remained inhibited, whereas water and electrolyte secretion was restored. (ii) Vagal stimulation: Nisoxetine did not modify water and electrolyte output in response to vagal electrical stimulation (VES), whereas it inhibited protein response by 75%. Sumatriptan alone strongly inhibited pancreatic response to VES (p < 0.01). When nisoxetine and sumatriptan were combined, the protein response to VES remained inhibited, whereas water and electrolyte response to VES was restored. (iii) Acetylcholine: Nisoxetine and sumatriptan alone or combined did not modify pancreatic response to acetylcholine. These results indicate that noradrenergic and serotonergic agents can indirectly affect pancreatic secretion through a modulation of the vagal cholinergic pathway. Nisoxetine and sumatriptan interact negatively on hydroelectrolytic pancreatic secretion, whereas they inhibit the secretion of enzymes both alone and in combination.

Modulation of external pancreatic secretion by endogenous norepinephrine: study with a norepinephrine uptake blocker in the rat.

The effect of endogenous catecholamines on pancreatic secretion was analyzed with nisoxetine, a specific norepinephrine uptake blocker, and specific adrenoceptor antagonists in anesthetized acute fistula rats. Nisoxetine was administered alone or with alpha-1 (prazosin), alpha-2 (idazoxan or yohimbine), or beta (propranolol) adrenoceptor antagonists. Pancreatic secretion was measured in basal conditions or after stimulation by 2-deoxy-D-glucose (2DG), electrical vagal stimulation, or acetylcholine. (a) Basal. Nisoxetine alone had no effect. Associated with idazoxan or yohimbine, nisoxetine produced a dose-related stimulation (p < 0.01) of water and electrolyte without changing protein output. Addition of propranolol abolished this stimulation. (b) 2DG. Nisoxetine inhibited 2DG-induced secretion (p < 0.01). Idazoxan or yohimbine suppressed the nisoxetine inhibition of water and electrolyte output (p < 0.01) but had no effect on protein output, which was restored only by adding a mixture of idazoxan, prazosin, and propranolol. (c) Electrical stimulation. Nisoxetine did not modify water and electrolyte but inhibited protein response by 75%. Adding idazoxan to nisoxetine significantly increased (p < 0.01) water and bicarbonate response and partly restored protein response. Water and bicarbonate response was restored by propranolol, whereas protein response was only restored by adding a mixture of idazoxan, prazosin, and propranolol. (d) Nisoxetine did not modify pancreatic response to acetylcholine. In conclusion, endogenous norepinephrine affects the response to vagally mediated effects through several subtypes of adrenoceptors, without changing basal or acetylcholine stimulated secretion.

Neural modulation of cephalexin intestinal absorption through the di- and tripeptide brush border transporter of rat jejunum in vivo.

Intestinal absorption of beta-lactamine antibiotics (e.g., cefixime and cephalexin) has been shown to proceed through the dipeptide carrier system. In a previous study, nifedipine (NFP), an L-type calcium channel blocker, enhanced the absorption of cefixime in vivo but not in vitro, and it was suggested that neural mechanisms might be involved in the effect of NFP. The aim of the present study was to assess the involvement of the nervous system on the intestinal absorption of cephalexin (CFX). To investigate this, we used a single-pass jejunal perfusion technique in rats. NFP and diltiazem enhanced approximately 2-fold the plasma levels of CFX in treated rats versus untreated controls. NFP also increased approximately 2-fold the CFX level in portal plasma and increased urinary excretion of CFX, thus indicating that CFX did effectively increase CFX intestinal absorption. Perfusing high concentrations of dipeptides in the jejunal lumen competitively reduced CFX absorption and inhibited the enhancement of CFX absorption produced by NFP. Hexamethonium and lidocaine inhibited the effect of NFP, whereas atropine, capsaicin, clonidine, and isoproterenol enhanced CFX absorption by the same order of magnitude as NFP. Thus, complex neural networks can modulate the function of the intestinal di- and tripeptide transporter. Sympathetic noradrenergic fibers, intestinal sensory neurons, and nicotinic synapses are involved in the increase of CFX absorption produced by NFP.

Inhibitory effects of peptide YY on basal and VIP-stimulated short-circuit current in the rat jejunum: influence of technical conditions on observed results.

The interaction of PYY and VIP was studied in stripped and intact rat jejunum preparations mounted in Ussing chambers. PYY decreased basal Isc in intact as well as in stripped jejunum. Stripping was necessary to evidence a stimulation of basal Isc by VIP. When PYY and VIP were administered at the same time in the serosal bath, their effects seemed additive; VIP stimulation took over when VIP was present in ten times larger amounts than PYY, while PYY inhibition predominated at isomolar concentrations (10(-7) M) of both peptides. However, when PYY was administered three to six minutes before isomolar amounts of VIP, the VIP stimulation developed without being notably hampered. At this time, however, the amount of radioimmunoassayable PYY in the serosal compartment represented still 60% of the added amount. In conclusion, the experimental conditions can significantly change the results: stripping the longitudinal muscle/myenteric plexus impairs the effect of PYY and VIP in a different fashion, while the timing and order of administration of the peptides may change the apparent interaction between VIP stimulation and PYY inhibition.

Neural modulation of the antisecretory effect of peptide YY in the rat jejunum.

The endocrine and neural peptide, peptide YY, inhibits intestinal secretion of water and electrolytes in several animal species and in man. Peptide YY receptors have been evidenced on isolated rat jejunal crypt cells, but neural receptors are also likely to participate in the antisecretory effect of peptide YY in vivo. The aim of the present study was to investigate the mechanisms of the peptide YY effect on vasoactive intestinal peptide (VIP)-stimulated jejunal net water flux in the rat. Antagonist experiments using several drugs affecting neurally mediated processes were done for the purpose. A small peptide YY dose (10 pmol/kg) inhibited significantly (P < 0.005) the jejunal net water flux produced by 30 microg/kg per h of VIP. The inhibitory effect of peptide YY was suppressed, or strongly and significantly reduced, by tetrodotoxin, hexamethonium, lidocaine, idazoxan and BMY14,802 (51-(4-fluorophenyl)-4-(-4-(5-fluoro-2pyrimidinyl)-1-piperazinyl)- 1-butanol), whereas devazepide and L-NAME (L-omega-N-arginine methyl ester) had no effect. These results suggest that peptide YY inhibits VIP-stimulated jejunal net water flux in vivo through a neural mechanism implicating the participation of nicotinic synapses, alpha2-adrenoceptors and sigma receptors.

Mechanisms of peptide YY release induced by an intraduodenal meal in rats: neural regulation by proximal gut.

Peptide YY (PYY) release in anaesthetized rats was studied during the 2 h following the intraduodenal administration of a semi-liquid meal of 21 kJ. Surgical and pharmacological manipulations were performed in order to analyse the mechanisms of PYY release. Postprandial PYY release was suppressed or strongly decreased by caecocolonectomy, truncal vagotomy, tetrodotoxin, hexamethonium, sensory denervation by perivagal capsaicin, and by the NO-synthase inhibitor L-N-arginine methyl ester, while atropine, adrenergic blockers, antagonists of type-A or type-B cholecystokinin (CCK) receptors or bombesin receptors had no effect. Comparing the digestive transit of the semi-liquid meal with the amount of PYY contained in the small bowel wall showed that nutrients had not reached the area rich in cells containing PYY by 30 min, the time at which there was a large PYY release in plasma. By 120 min, the meal front had travelled 72% of the small intestine length, just beginning to reach the PYY-rich part of the ileum. We conclude that the main postprandial PYY release studied in this model comes from ileal and colonic L-cells indirectly stimulated through a neural mechanism originating in the proximal gut and involving sensory vagal fibres, nicotinic synapses and NO release, while CCK and bombesin do not seem to be physiologically involved.

Several receptors mediate the antisecretory effect of peptide YY, neuropeptide Y, and pancreatic polypeptide on VIP-induced fluid secretion in the rat jejunum in vivo.

Several Y receptor subtypes have been cloned and/or pharmacologically characterized that mediate the effects of the regulatory peptides peptide YY (PYY), neuropeptide Y (NPY), and pancreatic polypeptide (PP). These peptides possess antisecretory properties on the intestine. This effect can be blocked in vivo by neural antagonists, suggesting the intervention of neural receptors, although epithelial PYY-preferring receptors have been evidenced on jejunal crypt cells. The purpose of the present experiments was to compare the antisecretory properties in vivo of a series of PYY and NPY derivatives with various affinities for different Y receptor subtypes, in order to determine which subtypes were involved. A model of VIP-stimulated secretion by rat jejunal loops was used. The results were compared with the binding affinities for PYY-preferring receptors determined on rat jejunal crypt cell membranes. Full-length PYY(1-36) was about three times more potent than NPY(1-36), and 10 times more potent than PP in the low dose range. PP, however, had a low efficacy limited to about 50% inhibition of VIP effect. Both Y1 agonists ([Leu31, Pro34]PYY and [Leu31,Pro34]NPY), and Y2 agonists [C-terminal fragments ranging from PYY (3-36) and NPY(3-36) to PYY(22-36) to NPY(22-36)] displayed potent antisecretory properties. PYY derivatives and fragments were always more potent than their respective NPY counterparts. In contrast, Y1 derivatives and PP had very low affinity for the epithelial PYY receptor as measured in vitro by radioreceptor assay. These data suggest that the antisecretory effect of PYY/NPY/PP peptides in vivo involves the effects of several receptors: a Y2-like, PYY-preferring receptor identical to the epithelial receptor, a Y1-like receptor, and a third receptor with high affinity for PP.

Release of nonesterified fatty acids during cerulein-induced pancreatitis in rats.

During acute pancreatitis, data obtained in vitro suggest that pancreatic lipase, acting on circulating or tissular triglycerides, might generate nonesterified fatty acids (NEFA) that could promote pancreatic and fat tissue necrosis. This work determined whether NEFA were actually produced in vivo in pancreatic tissue and in blood during cerulein-induced pancreatitis in rats. Intraperitoneal injections of cerulein induced pancreatitis. To promote the possible NEFA release by pancreatic lipase, a venous infusion of human very low density lipoprotein (VLDL) was used to cause hypertriglyceridemia. NEFA were measured in portal and aortic blood and in tissue extracts prepared from pancreas homogenates. NEFA did not increase either in peripheral or in portal blood. In pancreatic tissue, NEFA levels did not differ from controls. The major hypertriglyceridemia produced by human VLDL intravenous infusion neither altered the course of the disease nor promoted plasma NEFA release. The role commonly attributed to NEFA in acute pancreatitis seems questionable.

[Antisecretory effects of YY peptide and neuropeptide Y at three levels of the small intestine in rats]. / Effets antisécrétoires du peptide YY et du neuropeptide Y à trois niveaux de l'intestin grêle chez le rat.

OBJECTIVES AND METHODS: The purpose of this study was to compare the effects of peptide YY (PYY) and neuropeptide Y (NPY) on VIP- and PGE2-stimulated intestinal net water flux at three different levels of the small intestine (duodenum, jejunum, ileum), by a technique of in situ closed loops in anaesthetised rats. RESULTS: VIP-stimulated net water flux was efficiently inhibited by both peptides at all three intestinal levels studied; PYY (ID50 about 30 pmol/kg.h) was 3 to 18 fold more potent than NPY. PGE2-stimulated net water flux was also efficiently inhibited in the jejunum and ileum; PYY (ID50 about 10 pmol/kg.h) was 30 to 90 fold more potent than NPY. A 30% inhibition of PGE2-stimulated net water flux could only be achieved in the duodenum with the largest dose of either peptide used in this study. CONCLUSIONS: PYY and NPY display potent inhibitory effects of stimulated net water flux at the three studied levels of the small intestine, except in the PGE2-stimulated duodenum. The PYY ID50s measured suggest that PYY may have a physiological action in regulating small intestinal water flux in the rat.

Peptide YY release after intraduodenal, intraileal, and intracolonic administration of nutrients in rats.

Peptide YY (PYY) release was studied by measuring radioimmunoassayable PYY in the arterial plasma of anaesthetized rats receiving into the duodenum, ileum or colon either a complete semi-liquid meal (3ml, 21kJ) or elemental nutrients as isocaloric or isoosmolar solutions. PYY release induced by the intraduodenal meal peaked at 60min and lasted more than 120min. The integrated response of PYY over 120min was larger when the meal was administered into the duodenum than into the ileum. The undigested meal induced no release of PYY over a 120-min period when administered into the colon. When injected into the duodenum in isocaloric amounts to the meal, glucose and amino acids led to the release of as much PYY as did the meal, whereas oleic acid led to the release of less PYY. Part of these responses were due to osmolarity, since administration of intraduodenal hyperosmolar saline led to the release of about half as much PYY as did hyperosmolar glucose. In moderate amounts, and injected as a solution isoosmolar to plasma, oleic acid was a major PYY releaser; the amounts released were at least two times larger when oleic acid was administered into the duodenum than into the ileum and colon. Isoosmolar glucose and amino acids led to the release of no PYY when injected into the duodenum, but were nearly as active as oleic acid in the colon. Short-chain fatty acids induced the release of PYY when injected into the colon, but not into the ileum. Hexamethonium suppressed PYY release induced by the intraduodenal meal, but did not change PYY release induced by glucose or oleic acid in the colon. Urethane anaesthesia did not reduce PYY release induced by the intraduodenal meal. These results suggest that two mechanisms at least contribute to PYY release in the rat. An indirect, neural mechanism, involving nicotinic synapses, is prominent in the proximal small intestine; the stimulation is transmitted to ileal and colonic L-cells by undetermined pathways, but contact of nutrients with L-cells is not needed. Another mechanism, probably direct and quantitatively smaller, occurs in the distal intestine when nutrients come into contact with the mucosa containing L-cells. Glucose, fatty acids and amino acids stimulate differentially the proximal and distal mechanisms.

[Simultaneous study of duodenal and biliopancreatic bicarbonates in rats]. / Etude simultanée des bicarbonates duodénaux et bilio-pancréatiques chez le rat.

OBJECTIVES: The aim of the present study was to assess the relative contribution of duodenal and biliopancreatic bicarbonate secretion to acid neutralization in the duodenum, in basal conditions, during stimulation by PGE2 and during acid infusion in the duodenum. METHODS: Forty rats were anaesthetized and the duodenum was infused with 0.9% saline. Bicarbonate originating from duodenal mucosa and from biliopancreatic secretion was independently collected and measured. In neutralization studies, HCl was infused in the duodenum, and the amount of residual acid escaping from the duodenum was determined with and without bile and/or pancreatic juice diversion. RESULTS: Basal duodenal and biliopancreatic bicarbonate outputs were respectively 10.0 +/- 0.66 and 2.4 +/- 0.31 mumol/10 min. PGE2 increased duodenal mucosal bicarbonate by about 100%. Eighty-five percent of infused HCl was neutralized by duodenal mucosal bicarbonate. In neutralizing the remaining 15%, pancreatic secretion was slightly predominant, 46% for a HCl concentration of 5 mM and 71% for a HCl concentration of 40 mM. CONCLUSIONS: These results shows that in the anaesthetized rat, available bicarbonate in the duodenal lumen and HCl neutralization ability are mainly dependent upon bicarbonate secreted by the duodenal mucosa.

Nonesterified fatty acids in acute cerulein-induced pancreatitis in the rat. Are they really deleterious in vivo?

During acute pancreatitis, experimental data obtained in vitro suggested that pancreatic lipase generates nonesterified fatty acids (NEFA), noxious for acinar cells, by hydrolysis of pancreatic or circulating triglycerides. The purpose of this work was to determine whether experimentally induced high plasma NEFA levels do indeed aggravate in vivo cerulein-induced pancreatitis. Anesthetized Sprague-Dawley rats received cerulein and were simultaneously infused intravenously with either saline or a triglyceride + heparin mixture (TGH) in order to increase the amount of circulating NEFA. Plasma NEFA increased about fourfold (3.02 +/- 0.28 mumol/liter) in animals infused with TGH with respect to controls (0.75 +/- 0.05 mumol/liter). In rats receiving cerulein + TGH, pancreatic enzyme levels in plasma, ascites, and histological alterations of the pancreas did not differ from those observed in the rats receiving cerulein + saline. There was less macroscopic pancreatic edema (P < 0.01) in the cerulein + TGH group than in the cerulein + saline group. Separate infusion of either heparin alone or of triglycerides alone had no effect. We conclude that high levels of circulating NEFA do not aggravate cerulein pancreatitis in rats and may even induce a protective effect.

Differential effects of peptide YY, neuropeptide Y, and sigma ligands on neurally stimulated external pancreatic secretion in the rat.

The endocrine peptide YY (PYY) inhibits pancreatic secretion in animals and in man through indirect pathways. Neuropeptide Y (NPY), whose chemical structure is very close, displays similar effects. Recently, sigma ligands were shown to produce in vivo several neural pharmacologic effects that seemed indistinguishable from those of NPY. This might occur by interaction with the same (or closely related) receptors or by activation of a common final pathway. The purpose of the present work was to test whether PYY, NPY, and sigma agonists also display closely related activities on pancreatic secretion. The sigma ligands (+)-N-allyl normetazocine (d-NANM) and di(ortho-tolyl) guanidine (DTG) were used. Pancreatic secretion was stimulated by the centrally acting agent 2-deoxyglucose (2DG) in anesthetized rats. The rats were also administered either an infusion of peptide (PYY: 25-250 pmol/kg/h, NPY: 75-750 pmol/kg/h), continued for 2 h, or a bolus injection of d-NANM (3 mg/kg) or DTG (1 mg/kg). In antagonist experiments, the dopamine and sigma antagonist haloperidol (1 mg/kg, i.v.), the adrenoceptor antagonists idazoxan (0.3 mg/kg, s.c.), prazosin (0.5 mg/kg, s.c.), propranolol (1 mg/kg, s.c.) and the opiate receptor antagonist naloxone (1 mg/kg, s.c.) were injected, 5 min before the peptide infusion had begun. Neither PYY nor NPY changed basal pancreatic secretion. PYY and NPY produced a dose-related inhibition of 2DG-stimulated pancreatic secretion. The observed inhibition after 250 pmol/kg/h of PYY was volume, 78% (p < 0.01); bicarbonate, 84% (p < 0.01); protein, 78% (p < 0.01); whereas the physiologically relevant dose of 25 pmol/kg/h induced approximately 30% inhibition of these variables.(ABSTRACT TRUNCATED AT 250 WORDS)