Vagal modulation of arginine- and glucagon-induced pancreatic somatostatin secretion

In order to elucidate the role of the vagus nerve in the regulation of pancreatic somatostatin secretion, the effect of electrical stimulation of the vagus on the isolated perfused rat pancreas was studied. Somatostatin release induced by 19 mM arginine in the presence of 11 mM glucose or 10(-6)M glucagon in the presence of 5.5 mM glucose was suppressed by vagal stimulation. This suppressive effect on somatostatin was eliminated in the presence of 10(-5)M atropine plus glucagon, while somatostatin release was significantly enhanced in the presence of atropine plus arginine. We conclude that pancreatic somatostatin secretion may be regulated not only by a cholinergic inhibitory neuron but also by a stimulatory non-cholinergic neuron.     

Motor reactivity of isolated heart of the grass-snake (Natrix natrix L.)

Stimulation of the vagus nerve with a volley of electric impulses changed the action of grass-snake heart producing a negative chronotropic and inotropic effect. The effect of vagal stimulation was not different from the effect of acetylcholine administration and it was absent in the presence of atropine and hexamethonium. It was not possible to demonstrate sympathetic nervous fibres in the stimulated segment of the vagus nerve and trials of finding a separate nerve increasing the heart rate were unsuccessful. Parasympathicotonic agents caused bradycardia and a fall in the amplitude of cardiac contractions, and in sufficiently high doses they arrested the heart in diastole. The action of muscarine-like agents was stronger than that of nicotine, and the anticholinergic action of tubocurarine was weaker than that of atropine. Catecholamines exerted a positive inotropic and chronotropic effect which was completely blocked by propranolol in some tests only.     

Effects of naloxone on basal and vagus nerve-induced secretions of GRP, gastrin, and somatostatin from the isolated perfused rat stomach

The effects of naloxone, an opiate antagonist, on basal and vagus nerve-induced secretions of GRP, gastrin, and somatostatin were examined using the isolated perfused rat stomach prepared with vagal innervation. Naloxone (10(-6) M) significantly inhibited basal somatostatin secretion in the presence and absence of atropine and of hexamethonium, whereas basal GRP and gastrin secretion was not affected by naloxone. Electrical stimulation (10 Hz, lms duration, 10V) of the distal end of the subdiaphragmatic vagal trunks elicited a significant increase in both GRP and gastrin but a decrease in somatostatin. Naloxone (10(-6) M) failed to affect these responses in the presence or absence of atropine. On the other hand, when hexamethonium was infused, naloxone significantly inhibited both the GRP and gastrin responses to electrical vagal stimulation. Somatostatin secretion was unchanged by vagal stimulation during the infusion of hexamethonium with or without naloxone. These findings suggest that basal somatostatin secretion is under the control of an opiate neuron and that opioid peptides might be involved in vagal regulation of GRP and gastrin secretion.     

The spectrogram of heart rate in cats following burst stimulation of the vagus nerve

Denervation of the heart (bilateral vagotomy and propranolol) in artificially ventilated cats didn't remove respiratory peaks on the spectrogram of heart rate, while burst stimulation of vagus nerve increased or decreased them several times by synchronization of the heart and vagus rhythms, which in its turn was observed under the bradycardia only. At the same time, the desynchronization of rhythms provoked severe sinus arrhythmia which had a distinct periodic character. Under these conditions, there were high non-respiratory peaks appearing at the spectrogram of the heart rate that indicated existence of two vagus chronotropic effects: a well known tonic one and special intracycle synchronizing effect correcting duration of every cardiac cycle.     

Effect of systemic B-type natriuretic peptide on cardiac vagal motoneuron activity

Intravenous B-type natriuretic peptide (BNP) enhances the bradycardia of reflexes from the heart, including the von Bezold-Jarisch reflex, but its site of action is unknown. The peptide is unlikely to penetrate the blood-brain barrier but could act on afferent or efferent reflex pathways. To investigate the latter, two types of experiment were performed on urethane-anesthetized (1.4 g/kg iv) rats. First, the activity was recorded extracellularly from single cardiac vagal motoneurons (CVMs) in the nucleus ambiguus. CVMs were identified by antidromic activation from the cardiac vagal branch and by their barosensitivity. Phenyl biguanide (PBG), injected via the right atrium in bolus doses of 1-5 mug to evoke the von Bezold-Jarisch reflex, caused a dose-related increase in CVM activity and bradycardia. BNP infusion (25 pmol.kg(-1).min(-1) iv) significantly enhanced both the CVM response to PBG (n = 5 rats) and the reflex bradycardia, but the log-linear relation between those two responses over a range of PBG doses was unchanged by BNP. The reflex bradycardia was not enhanced in five matched time-control rats receiving only vehicle infusions. In five other rats the cervical vagi were cut and the peripheral right vagus was stimulated supramaximally at frequencies of 1-20 Hz. The bradycardic responses to these stimuli were unchanged before, during, and after BNP infusion. We conclude that systemic BNP in a moderate dose enhances the von Bezold-Jarisch reflex activation of CVM, in parallel with the enhanced reflex bradycardia. That enhancement is due entirely to an action before the vagal efferent arm of the reflex pathway.     

Chlordiazepoxide inhibition of reflex vagal bradycardia in the cat

The effect of chlordiazepoxide (CDZ) on phenylephrine-induced reflex vagal bradycardia was studied in cats anesthetized with chloralose. The sympathetic component of the reflex was eliminated by either pretreating the animals with propranolol (1 mg/kg, i.v.) or sectioning the spinal cord. In animals pretreated with propranolol, CDZ (3, 10 and 20 mg/kg, i.v.) produced a dose-related inhibition of phenylephrine-induced bradycardia. These doses of CDZ had no significant effect on phenylephrine-induced pressor responses. Similar results were obtained with CDZ in animals with spinal cords transected. Chlordiazepoxide did not prevent bradycardia evoked by electrical stimulation of the peripheral cut-end of the right vagus nerve. These results indicate that CDZ can inhibit reflex vagal bradycardia and that the inhibition involves a central action of the drug.     

Bimodal delta-opioid receptors regulate vagal bradycardia in canine sinoatrial node

Methionine-enkephalin-arginine-phenylalanine (MEAP) introduced into the interstitium of the canine sinoatrial (SA) node by microdialysis interrupts vagal bradycardia. In contrast, raising endogenous MEAP by occluding the SA node artery improves vagal bradycardia. Both are blocked by the same delta-selective antagonist, naltrindole. We tested the hypothesis that vagal responses to intranodal enkephalin are bimodal and that the polarity of the response is both dose- and opioid receptor subtype dependent. Ultralow doses of MEAP were introduced into the canine SA node by microdialysis. Heart rate frequency responses were constructed by stimulating the right vagus nerve at 1, 2, and 3 Hz. Ultralow MEAP infusions produced a 50-100% increase in bradycardia during vagal stimulation. Maximal improvement was observed at a dose rate of 500 fmol/min with an ED50 near 50 fmol/min. Vagal improvement was returned to control when MEAP was combined with the delta-antagonist naltrindole. The dose of naltrindole (500 fmol/min) was previously determined as ineffective vs. the vagolytic effect of higher dose MEAP. When MEAP was later reintroduced in the same animals at nanomoles per minute, a clear vagolytic response was observed. The delta1-selective antagonist 7-benzylidenenaltrexone (BNTX) reversed the vagal improvement with an ED50 near 1 x 10-21 mol/min, whereas the delta2-antagonist naltriben had no effect through 10-9 mol/min. Finally, the improved vagal bradycardia previously associated with nodal artery occlusion and endogenous MEAP was blocked by the selective delta1-antagonist BNTX. These data support the hypothesis that opioid effects within the SA node are bimodal in character, that low doses are vagotonic, acting on delta1-receptors, and that higher doses are vagolytic, acting on delta2-receptors.     

Cold wind stimulation reflex.

The bradycardia induced by cold wind blown on the face and the early cephalic release of insulin induced by feeding have been shown to be caused by a vagal reflex stimulation. An experiment was designed to determine whether cold wind blown on the face would induce both pancreatic and cardiac stimulation. A 4 degrees C wind blown on the face for 4 min produced a rapid and persistent bradycardia, which interestingly persisted for up to 35 min after the test. The effect on respiration rate is more gradual and vanishes immediately after cold wind stimulation. Cold wind produced a slight reduction of insulin secretion, as evidenced by the fall of both plasma insulin and C-peptide, and caused a significant increase in plasma norepinephrine. These results suggest that the cold wind action of the vagus nerve is exerted on the heart and that of the sympathetic on the pancreas, whereas during the cephalic phase of feeding a vagal influence is observed on the pancreas and a sympathetic action on the heart. The mechanisms of the quantitative and qualitative control of these autonomic responses are not known and deserve further investigation.     

Vagal function impairment after exercise training.

The present investigation was undertaken to evaluate the vagal function of trained (T) and sedentary (S) rats by use of different approaches in the same animal. After 13 wk of exercise training (treadmill for 1 h 5 times/wk at 26.8 m/min and 15% grade), T rats had a resting heart rate (HR) slightly but significantly lower than S rats (299 +/- 3 vs. 308 +/- 3 beats/min). T rats had marked reduction of the intrinsic HR (329 +/- 4 vs. 369 +/- 5 beats/min) after blockade by methylatropine and propranolol. They also exhibited depressed vagal and sympathetic tonus. Baroreflex bradycardia (phenylephrine injections) was reduced, bradycardic responses produced by electrical stimulation of the vagus were depressed, and responses to methacholine injection were decreased in T rats. Therefore several evidences of vagal function impairment were observed in T rats. The resting bradycardia after exercise training is more likely to be dependent on alterations of the pacemaker cells, inasmuch as the intrinsic HR was markedly reduced.     

Sensitive control of heart rate in monkeys using burst stimulation of the vagus nerve

Burst vagus stimulation led to synchronization of the cardiac and vagal rhythms at certain frequency ranges. The increase of the number of impulses in a burst from 1 to 16 extended the range of synchronization and shifted it towards lower frequencies forming a total range of exact regulation of the heart rate within 85--40% of the initial rate. It was suggested that vagal effect consists of tonic and synchronizing components.     

Cardiac enkephalins attenuate vagal bradycardia: interactions with NOS-1-cGMP systems in canine sinoatrial node

Endogenous opioids and nitric oxide (NO) are recognized modulators of cardiac function. Enkephalins and inhibitors of NO synthase (NOS) both produce similar interruptions in the vagal control of heart rate. This study was conducted to test the hypothesis that NO systems within the canine sinoatrial (SA) node facilitate local vagal transmission and that the endogenous enkephalin methionine-enkephalin-arginine-phenylalanine (MEAP) attenuates vagal bradycardia by interrupting the NOS-cGMP pathway. Microdialysis probes were inserted into the SA node, and they were perfused with nonselective (Nomega-nitro-l-arginine methyl ester) and neuronal (7-nitroindazole) NOS inhibitors. The right vagus nerve was stimulated and both inhibitors gradually attenuated the resulting vagal bradycardia. The specificity of these inhibitions was verified by an equally gradual reversal of the inhibition with an excess of the NOS substrate l-arginine. Introduction of MEAP into the nodal interstitium produced a quickly developing but quantitatively similar interruption of vagal bradycardia that was also slowly reversed by the addition of l-arginine and not by d-arginine. Additional support for convergence of opioid and NO pathways was provided when the vagolytic effects of MEAP were also reversed by the addition of the NO donor S-nitroso-N-acetyl-penicillamine, the protein kinase G activator 8-bromo-cGMP, or the phosphodiesterase inhibitor 3-isobutyl-1-methylxanthine. MEAP and 7-nitroindazole were individually combined with the direct acting muscarinic agonist methacholine to evaluate potential interactions with muscarinic receptors within the SA node. MEAP and 7-nitroindazole were unable to overcome the bradycardia produced by methacholine. These data suggest that NO and enkephalins moderate the vagal control of heart rate via interaction with converging systems that involve the regulation of cAMP within nodal parasympathetic nerve terminals.     

The modulatory effects of noradrenaline on vagal control of heart rate in the dogfish,Squalus acanthias

The possible interactions between inhibitory vagal control of the heart and circulating levels of catecholamines in dogfish (Squalus acanthias) were studied using an in situ preparation of the heart, which retained intact its innervation from centrally cut vagus nerves. The response to peripheral vagal stimulation typically consisted of an initial cardiac arrest, followed by an escape beat, leading to renewed beating at a mean heart rate lower than the prestimulation rate (partial recovery). Cessation of vagal stimulation led to a transient increase in heart rate, above the prestimulation rate. This whole response was completely abolished by 10(-4) M atropine (a muscarinic cholinergic antagonist). The degree of vagal inhibition was evaluated in terms of both the initial, maximal cardiac interval and the mean heart rate during partial recovery, both expressed as a percentage of the prestimulation heart rate. The mean prestimulation heart rate of this preparation (36+/-4 beats min(-1)) was not affected by noradrenaline but was significantly reduced by 10(-4) M nadolol (a beta-adrenergic receptor antagonist), suggesting the existence of a resting adrenergic tone arising from endogenous catecholamines. The degree of vagal inhibition of heart rate varied with the rate of stimulation and was increased by the presence of 10(-8) M noradrenaline (the normal in vivo level in routinely active fish), while 10(-7) M noradrenaline (the in vivo level measured in disturbed or deeply hypoxic fish) reduced the cardiac response to vagal stimulation. In the presence of 10(-7) M noradrenaline, 10(-4) M nadolol further reduced the vagal response, while 10(-4) M nadolol + 10(-4) M phentolamine had no effect, indicating a complex interaction between adrenoreceptors, possibly involving presynaptic modulation of vagal inhibition.     

Receptor subtype specific activation of the rat gastric vagal afferent fibers to serotonin

Systemic administration (i.v.) of serotonin (5-HT) evoked a transient vagal afferent nerve discharge, bradycardia, and hypotension in the rat. The half-effective dose of 5-HT for nerve discharge was 13 micro g/kg. The time- and dose-dependent kinetics of the nerve discharge rate were similar to the change of heart rate. The afferent neuronal discharge was mimicked by a selective 5-HT3 receptor agonist, 1-phenylbiguanide hydrochloride (PBA), and inhibited by a selective 5-HT3 antagonist, granisetron. The 5-HT(3/4) agonist, cisapride partially activated the vagus nerve, but the 5-HT4 agonist, RS6733 had no effect on the vagal afferent activity. Intra-gastric perfusion of lidocaine, moreover, abolished the 5-HT-induced vagal activation. These results indicate that the 5-HT transmission signal in the gastric mucosa inputs to the brain stem via 5-HT3 receptor-mediated vagal nerve afferent.     

Increased vagal tone in adaptation to the effects of continuous stress and termination of cardiac arrhythmias

It was established in experiments on rats exposed to 5 day stress that 1 day stress resulted in a twofold decreased heart fibrillation threshold (HFT) and 5 day stress resulted in bradycardia and in the restoration of HFT to the control level. The restoration of the heart electric stability was due to an increased vagal tone because atropine eliminated the bradycardia and reduced HFT again. Adaptation to continuous 5 day stress increased 3-7-fold the heart resistance to ischemic and reperfusion arrhythmias. This protective effect was completely abolished with atropine. Thus adaptation to continuous mild stress has a potent antiarrhythmic effect which occurs due to the increased vagal tone.     

Paradoxical vagal effects on the cardiac rhythm in cats

In anaesthetised cats, an increase in the vagal burst rate resulted in a paradoxical decrease of vagal bradycardia. This seems to be due to a shift of the vagal stimulus position towards early phase of cardiac cycle. The mechanism of this paradoxical effect depends on the magnitude of vagal chronotropic effect upon the time of vagal stimulus delivery within cardiac cycle.     

Disordered cardiac electrical stability in beta-adrenergic damage and antioxidant protection]

The electrical threshold of ventricular fibrillation induced by premature single impulses and the ectopic activity and also an abnormal conduction during vagus inhibition of sinus node were estimated 24 hours after the administration of isoproterenol (10 mg/kg, s/c, on time) in rats. In addition the cardiac contractile function of the left ventricle was studied. The study was performed on male Wistar rats, 250-300 body weight, under nembutal anesthesia. Isoproterenol had no effect on the contractile function in the rest and during maximal isometric load, induced by coarctation of ascending aorta. But in the treated animals the threshold of fibrillation fell more than 2-fold and the vagal bradycardia was more 2-fold then in the untreated animals. The AB-block, idioventricular rhythm and extrasystoles appeared during vagal bradycardia in treated animals, while in the untreated ones there were no any disturbances. The preliminary administration of the antioxidant ionol (BMT, 30 mg/kg, per os, in sun oil) prevented the enumerated shifts.     

The dynamics of the chronotropic effect of a single vagal stimulus in cats under the action of met-enkephalin and neurotensin]

Following a burst of pulses applied to the vagus nerve with progressively incremental delay after the P wave of the ECG, the narrow zone of the cardiac cycle was identified where even a small shift of the vagal burst position evoked an abrupt alteration of the chronotropic effect magnitude. Met-enkephalin potentiated the phase-dependent vagal chronotropic effect, whereas neurotensin moved its limits toward the initial part of the P-P interval.     

The structural dynamics of vagus influence on the heart rhythm in exposures directed at altering the acting acetylcholine concentration]

In 29 experiments on anaesthetized cats burst stimulation of peripheral cut end of right vagus nerve leads to synchronization of heart and vagus rhythm. Influence of proserine, pilocarpine and prolonged vagus stimulation upon extent of vagus chronotropic effect and its components--tonic and synchronizing--was investigated. In all cases changes of vagus chronotropic effect during this actions were caused by unidirectional shifts of tonic component. Extent of synchronizing vagus chronotropic influences did not depend on the changes of acetylcholine concentration.     

The chronotropic action of neurotensin in the guinea pig isolated heart

Neurotensin (NT) infusions into isolated, perfused, spontaneously beating hearts of guinea pigs evoked a concentration-dependent, positive chronotropic effect which was preceded in some hearts by transient bradycardia. The tachycardia caused by NT was not affected by propranolol, cimetidine, indomethacin, a mixture of methysergide and morphine or by atria removal. The incidence and amplitude of bradycardia caused by NT were increased by neostigmine but reduced by atropine. Neostigmine and atropine also tended to decrease and increase respectively, the tachycardia caused by NT. These results suggest that the positive chronotropic effect of NT in guinea pig isolated heart results from a direct effect on the specialized conduction system of the heart while its negative chronotropic effect is likely to reflect the activation by NT of cardiac vagal cholinergic neurons.     

电刺激家兔迷走神经中枢端诱导的黑-伯反射中的非联合型学习现象

本文旨在研究电刺激家兔迷走神经诱导的黑-伯（Hering-Breuer,HB）反射中的学习和记忆现象。选择性电刺激家兔迷走神经中枢端（频率10～100Hz,强度20～60μA,波宽0．3ms,持续60s）,观察对膈神经放电的影响。以不同频率电刺激家兔迷走神经可模拟HB反射的两种成分,即类似肺容积增大所致抑制吸气的肺扩张反射和类似肺容积缩小所致加强吸气的肺萎陷反射。（1）长时高频（≥40Hz,60s）电刺激迷走神经可模拟呼吸频率减慢,呼气时程延长的肺扩张反射。随着刺激时间的延长,膈神经放电抑制的程度逐渐衰减,表现为呼吸频率的减慢（主要由呼气时程延长所致）在刺激过程中逐渐减弱或消失,显示为适应性或“习惯化”的现象;刺激结束时呼吸运动呈现反跳性增强,表现为一过性的呼气时程缩短,呼吸频率加快,然后才逐渐恢复正常。长时低频（〈40Hz,60s）电刺激迷走神经可模拟呼吸频率加快、呼气时程缩短的肺萎陷反射。随着刺激时间的延长,膈神经放电增强的程度逐渐衰减,同样表现出“习惯化”现象;刺激结束后,膈神经放电不是突然降低,而是继续衰减,表现为呼气时程逐渐延长,呼吸频率逐渐减慢,直至恢复到前对照水平,表现了刺激后的短时增强效应。（2）HB反射的适应性或“习惯化”程度反向依赖于刺激强度和刺激频率,表现为随着刺激强度和频率的增加,膈神经放电越远离正常基线水平,即爿惯化程度减弱。结果表明,家兔HB反射具有“习惯化”这一非联合型学习现象,反映与其有关的呼吸神经元网络具有突触功能的可翅性,呼吸的中枢调控反射具有一定的适应性。