Cholinergic nature of the primary afferent vagus synapsed in cross anastomosed superior cervical ganglia.

The superior cervical ganglion was reinnervated by vagal afferent fibers following heterologous cross anastomosis between the superior cervical preganglionic trunk and the vagal trunk at the level of the supranodose ganglion in cats. The contractions of the nictitating membrane and the postganglionic action potentials from the external carotid sinus nerve in response to electrical stimulation of the vagal artificial preganglionic trunk in these operated cats were inhibited by treatment with tetraethylammonium and atropine. The choline acetyltransferase activities were measured by the radiometric method. The activities in cross anastomosed superior cervical ganglion were lower than those of normal superior cervical ganglion, but higher than those of chronically decentralized superior cervical ganglion. The activities in cross anastomosed nodose ganglion were lower than those of normal nodose ganglion, but higher than those of chronically decentralized superior cervical ganglion. These results further support the view that the primary afferent vagus artificially synapsed in the superior cervical ganglion is cholinergic.     

c-Fos expression in rat brain stem and spinal cord in response to activation of cardiac ischemia-sensitive afferent neurons and electrostimulatory modulation

The purpose of this study was to identify central neuronal sites activated by stimulation of cardiac ischemia-sensitive afferent neurons and determine whether electrical stimulation of left vagal afferent fibers modified the pattern of neuronal activation. Fos-like immunoreactivity (Fos-LI) was used as an index of neuronal activation in selected levels of cervical and thoracic spinal cord and brain stem. Adult Sprague-Dawley rats were anesthetized with urethane and underwent intrapericardial infusion of an "inflammatory exudate solution" (IES) containing algogenic substances that are released during ischemia (10 mM adenosine, bradykinin, prostaglandin E2, and 5-hydroxytryptamine) or occlusion of the left anterior descending coronary artery (CoAO) to activate cardiac ischemia-sensitive (nociceptive) afferent fibers. IES and CoAO increased Fos-LI above resting levels in dorsal horns in laminae I-V at C2 and T4 and in the caudal nucleus tractus solitarius. Dorsal rhizotomy virtually eliminated Fos-LI in the spinal cord as well as the brain stem. Neuromodulation of the ischemic signal by electrical stimulation of the central end of the left thoracic vagus excited neurons at the cervical and brain stem level but inhibited neurons at the thoracic spinal cord during IES or CoAO. These results suggest that stimulation of the left thoracic vagus excites descending inhibitory pathways. Inhibition at the thoracic spinal level that suppresses the ischemic (nociceptive) input signal may occur by a short-loop descending pathway via signals from cervical propriospinal circuits and/or a longer-loop descending pathway via signals from the nucleus tractus solitarius.     

Acetylcholine content in superior cervical ganglion following reinnervation of vagal afferent fibers in cat

The superior cervical ganglion (SCG) was reinnervated by vagal afferent fibers by cross anastomosis between the cranial end of nodose ganglion and the caudal end of SCG in cats. Formation of functional synapses was evidenced by unilateral mydriasis and contraction of the nictitating membrane in response to inflation of the stomach with a balloon or to electrical stimulation of the afferent vagus. The acetylcholine (ACh) content in the cross-anastomosed SCG (reinnervated by vagal afferent fibers) was measured. In anastomosed SCG, the ACh content was about half of normal SCG, but significantly higher than chronically decentralized SCG. Also the ACh content in nodose ganglion (NDG) was investigated in situations in which there was anastomosis, chronic supra, infra, or supra-/infranodose vagotomy. The ACh content of anastomosed NDG was near that of supranosdose vagotomized ganglion. The ACh content of supra-/infranodose vagotomized NDG, which can be considered the NDG itself, was as much as that of normal intact NDG. It was found that the ACh content of infranodose vagotomized NDG was increased, possibly the result of vagal efferent axonal flow or transport. The ACh content of vagal trunk with or without infranodose vagotomy was also measured. The ACh content of vagal trunk with infranodose vagotomy was smaller than that of the normal trunk, but there was still a considerable quantity of ACh. There was no significant change in wet weight of the SCG and NDG before or after the operations. From these results we have concluded that the transmission of the cross-anastomosed SCG (reinnervated with vagal afferent nerve) was cholinergic; and that the vagal afferent nerve have afferent cell bodies not only in NDG but also in peripheral vagal trunks (infranodose portion). These results strongly suggest that vagal afferent fibers are in part cholinergic.     

兔腹部迷走神经、内脏大神经活动在孤束核中的相互作用

本实验在67只家兔身上分别观察了电解损毁孤束核(NTS)前后刺激腹迷走神经和内脏大神经中枢端对血压的影响,以及刺激这两种神经中枢端对 NTS 神经元放电活动的影响。结果表明:来自腹迷走神经和内脏大神经的感觉冲动不仅都可以投射至 NTS,而且这两种传入冲动在 NTS 还存在着会聚现象。一种传入神经的阈下刺激(背景刺激)可以削弱另一传入神经的血压效应,一种传入神经的(背景刺激)可以抑制另一种神经元引起的 NTS 神经元电活动。本文对这两种传入冲动之间存在的相互作用关系的可能机制及意义进行了讨论。     

Subdiaphragmatic vagal afferent nerves modulate visceral pain

Activation of the vagal afferents by noxious gastrointestinal stimuli suggests that vagal afferents may play a complex role in visceral pain processes. The contribution of the vagus nerve to visceral pain remains unresolved. Previous studies reported that patients following chronic vagotomy have lower pain thresholds. The patient with irritable bowel syndrome has been shown alteration of vagal function. We hypothesize that vagal afferent nerves modulate visceral pain. Visceromotor responses (VMR) to graded colorectal distension (CRD) were recorded from the abdominal muscles in conscious rats. Chronic subdiaphragmatic vagus nerve sections induced 470, 106, 51, and 54% increases in VMR to CRD at 20, 40, 60 and 80 mmHg, respectively. Similarly, at light level of anesthesia, topical application of lidocaine to the subdiaphragmatic vagus nerve in rats increased VMR to CRD. Vagal afferent neuronal responses to low or high-intensity electrical vagal stimulation (EVS) of vagal afferent Adelta or C fibers were distinguished by calculating their conduction velocity. Low-intensity EVS of Adelta fibers (40 microA, 20 Hz, 0.5 ms for 30 s) reduced VMR to CRD at 40, 60, and 80 mmHg by 41, 52, and 58%, respectively. In contrast, high-intensity EVS of C fibers (400 microA, 1 Hz, 0.5 ms for 30 s) had no effect on VMR to CRD. In conclusion, we demonstrated that vagal afferent nerves modulate visceral pain. Low-intensity EVS that activates vagal afferent Adelta fibers reduced visceral pain. Thus EVS may potentially have a role in the treatment of chronic visceral pain.     

The abdominal visceral innervation and the emetic reflex: pathways, pharmacology, and plasticity

In recent years the role of the area postrema in the emetic reflex has been predominant and the involvement of the abdominal visceral innervation has tended to be overlooked. This paper attempts to redress the balance reflex by reviewing aspects of the existing literature and complementing this with original studies from the ferret. In view of the widespread use of the ferret in studies of emesis and particularly in the characterization of the antiemetic actions of 5-HT3 receptor antagonist, the opportunity is taken to assess the suitability of this species for studies of emesis. It is concluded that the ferret is sensitive to a wide range of emetic stimuli including intragastric irritants, opiate and dopamine receptor agonists, many cytotoxic drugs, and radiation. For several stimuli it is more sensitive than other species and for radiation on the basis of its ED100 it appears to be the most sensitive of the laboratory animals studied. Using electrical stimulation of the central end of the dorsal vagal trunk in the abdomen in conscious and anaesthetized animals, the vagal afferents were shown to be capable of eliciting emesis. Using lesioning studies an involvement of the vagus in the emetic response to a number of cytotoxic drugs (e.g., cisplatinum, cyclophosphamide, mustine) and radiation was demonstrated, although the magnitude of the effect varied with the different stimuli. An attempt is made to reconcile these observations with previous studies of area postrema ablation. The problems of interpreting the effects of nerve lesions are critically discussed in light of preliminary evidence presented here that there may be a degree of plasticity in the emetic pathway following such lesions. The range of antiemetic effects of 5-HT3 receptor antagonists is reviewed and an attempt is made to identify the site(s) at which these agents act. Results are presented that suggest a link between the vagus and 5-HT3 receptor antagonism. These studies are discussed together with others and lead us to propose that (in the ferret) 5-HT3 receptor antagonists have their main antiemetic effect by acting on vagal afferent terminals in the wall of the upper gut with an additional minor site either in the nucleus tractus solitarius or presynaptically on the vagal afferent terminals in the medulla where binding sites for 5-HT3 receptor ligands have recently been demonstrated in this species.     

Study of tonic and evoked electrical activity in efferent fibers of the sympathetic nerve in white rats

In anaesthetised Wistar rats, electrical sympathetic activity and a somatosympathetic reflex in the cervical sympathetic trunk elicited by a single electrical shock to forelimb or hindlimb afferent nerves, were recorded. The spontaneous activity was shown to conform with the pulse and respiratory waves of arterial pressure. Somatosympathetic reflex consists of early and late discharges evoked by somatic myelinated afferent fibres stimulation, and C-response elicited by stimulation of unmyelinated afferent fibres in spinal nerves.     

c-fos expression in trigeminal spinal nucleus after electrical stimulation of the hypoglossal nerve in the rat

The expression of the immediate early gene, c-fos, was used to determine the distribution of brainstem neurons activated by stimulation of the distal hypoglossal nerve (XIIn) trunk. The traditional view of the XIIn is one of purely motor function; however, stimulation of XIIn excites neurons in the trigeminal spinal nucleus. The rationale for this study was to use c-fos expression as a marker for postsynaptic activity to define the pattern of brainstem neurons excited by XIIn stimulation. It was further hypothesized that if the afferent fibers that course within XIIn supply deep lingual tissues, then c-fos expression after direct stimulation of XIIn should display a pattern similar to that seen after chemical irritant stimulation of the deep tongue muscle. In barbiturate-anesthetized male rats electrical stimulation of XIIn produced a significant increase in Fospositive neurons in the dorsal paratrigeminal nucleus (dPa5) and laminae I-II of caudal subnucleus caudalis (Vc) and upper cervical dorsal horn. Mustard oil injection into the deep tongue muscle also produced an increase in c-fos expression in dPa5; however, the highest density of expression occurred in laminae I-II at the dorsomedial aspect of rostral Vc. Both electrical stimulation of XIIn and mustard oil stimulation of the deep tongue increased c-fos expression in the caudal ventrolateral medulla, an autonomic relay nucleus. These results suggest that one site of innervation for afferent fibers that travel within the distal trunk of XIIn is to supply the deep tongue muscle and to terminate in the dPa5. A second group of postsynaptic neurons activated only by XIIn stimulation was located in lamina I-II in caudal portions of Vc and upper cervical dorsal horn, a laminar distribution consistent with a role for XIIn afferents in sensory or autonomic aspects of lingual function.     

c-fos expression in trigeminal spinal nucleus after electrical stimulation of the hypoglossal nerve in the rat

The expression of the immediate early gene, c-fos, was used to determine the distribution of brainstem neurons activated by stimulation of the distal hypoglossal nerve (XIIn) trunk. The traditional view of the XIIn is one of purely motor function; however, stimulation of XIIn excites neurons in the trigeminal spinal nucleus. The rationale for this study was to use c-fos expression as a marker for postsynaptic activity to define the pattern of brainstem neurons excited by XIIn stimulation. It was further hypothesized that if the afferent fibers that course within XIIn supply deep lingual tissues, then c-fos expression after direct stimulation of XIIn should display a pattern similar to that seen after chemical irritant stimulation of the deep tongue muscle. In barbiturate-anesthetized male rats electrical stimulation of XIIn produced a significant increase in Fos-positive neurons in the dorsal paratrigeminal nucleus (dPa5) and laminae I-II of caudal subnucleus caudalis (Vc) and upper cervical dorsal horn. Mustard oil injection into the deep tongue muscle also produced an increase in c-fos expression in dPa5; however, the highest density of expression occurred in laminae I-II at the dorsomedial aspect of rostral Vc. Both electrical stimulation of XIIn and mustard oil stimulation of the deep tongue increased c-fos expression in the caudal ventrolateral medulla, an autonomic relay nucleus. These results suggest that one site of innervation for afferent fibers that travel within the distal trunk of XIIn is to supply the deep tongue muscle and to terminate in the dPa5. A second group of postsynaptic neurons activated only by XIIn stimulation was located in lamina I-II in caudal portions of Vc and upper cervical dorsal horn, a laminar distribution consistent with a role for XIIn afferents in sensory or autonomic aspects of lingual function.     

Functional anatomy of the vagal innervation of the cervical trachea of the dog.

The canine cervical trachea has been used for numerous studies regarding the neural control of tracheal smooth muscle. The purpose of the present study was to determine whether there is lateral dominance by either the left or right vagal innervation of the canine cervical trachea. In anesthetized dogs, pressure in the cuff of the endotracheal tube was used as an index of smooth muscle tone in the trachea. After establishment of tracheal tone, as indicated by increased cuff pressure, either the right or left vagus nerve was sectioned followed by section of the contralateral vagus. Sectioning the right vagus first resulted in total loss of tone in the cervical trachea, whereas sectioning the left vagus first produced either a partial or no decrease in tracheal tone. After bilateral section of the vagi, cuff pressure was recorded during electrical stimulation of the rostral end of the right or left vagus. At the maximum current strength used, stimulation of the left vagus produced tracheal constriction that averaged 28.5% of the response to stimulation of the right vagus (9.0 +/- 1.8 and 31.6 +/- 2.5 mmHg, respectively). In conclusion, the musculature of cervical trachea in the dog appears to be predominantly controlled by vagal efferents in the right vagus nerve.     

Vagal innervation of guinea pig bronchial smooth muscle

We isolated the guinea pig right bronchus with the vagus nerves intact and evaluated the changes in isometric tension of the smooth muscle in response to nerve stimulation. Brief (10-s) trains of electrical field stimulation or vagus nerve stimulation caused a biphasic contraction: the "first phase" sensitive to atropine and the "second phase" sensitive to capsaicin. The two phases could be dissociated by adjusting the stimulus intensity; greater stimulus intensities (pulse durations or voltage) were required to evoke the capsaicin-sensitive phase. When stimulated at 30-min intervals, the magnitude of both phases of the contractions declined over a 2-h period of repeated stimulation; however, this was prevented by indomethacin. Stimulation of the left vagus nerve resulted in a monophasic contraction of the right bronchus, with little evidence of a capsaicin-sensitive phase. Blocking neurotransmission through the bronchial ganglion, as monitored by intracellular recording techniques, abolished the first-phase contraction but had no effect on the capsaicin-sensitive phase. Selective blockade of muscarinic M1 receptors had no effect on vagus nerve-mediated contractions. The results demonstrate that the left and right vagus nerves carry preganglionic fibers to the right bronchial ganglion. The right but not the left vagus nerve also carries capsaicin-sensitive afferent fibers that, when stimulated, result in a persistent contraction of the right bronchus. Finally, we provide functional and electrophysiological evidence supporting the hypothesis that capsaicin-sensitive afferent neurons communicate with postganglionic motoneurons within the bronchus.     

Inhibitory innervation to the guinea pig trachealis muscle

The inhibitory innervation of the cervical trachea was studied in situ in anesthetized male guinea pigs. We measured effects of electrical stimulation of vagal motor and sympathetic trunk nerve fibers, during atropine, on trachealis muscle tension. Effects of direct transmural stimulation of trachealis muscle were also determined. We confirmed the dual nature of the inhibitory innervation to this muscle. Vagal motor inhibitory nerves are shown to be preganglionic. Neural transmission at the level of the ganglia is characterized by filtering of high frequency action potentials. The neurotransmitter at the myoneural junction is unidentified but is not norepinephrine. Maximal relaxation accounts for about 20-40% of maximal relaxations seen with transmural stimulation of trachealis muscle in the presence of atropine. Sympathetic trunk nerve fibers are also preganglionic. Neurotransmission at the level of the ganglia is apparently 1:1 at high-action potential frequencies. Norepinephrine released presynaptically has access to smooth muscle beta- but not alpha-receptors. Maximal adrenergic relaxations account for 60-80% of total transmural stimulation relaxations. Transmural stimulation relaxations appear to be accounted for by release of neurotransmitter from sympathetic adrenergic plus vagal nonadrenergic postganglionic nerve fibers.     

Electrical stimulation of afferent vagus nerve induces IL-1beta expression in the brain and activates HPA axis

Possible roles of the afferent vagus nerve in regulation of interleukin (IL)-1beta expression in the brain and hypothalamic-pituitary-adrenal (HPA) axis were examined in anesthetized rats. Levels of IL-1beta mRNA and protein in the brain were measured by comparative RT-PCR and ELISA. Direct electrical stimulation of the central end of the vagus nerve was performed continuously for 2 h. The afferent stimulation of the vagus nerve induced increases in the expression of mRNA and protein levels of IL-1beta in the hypothalamus and the hippocampus. Furthermore, expression of corticotropin-releasing factor mRNA was increased in the hypothalamus 2 h after vagal stimulation. Plasma levels of ACTH and corticosterone were also increased by this stimulation. The present results indicate that activation of the afferent vagus nerves itself can induce production of IL-1beta in the brain and activate the HPA axis. Therefore, the afferent vagus nerve may play an important role in transmitting peripheral signals to the brain in the infection and inflammation.     

A novel dodecadepsipeptide, cereulide, is an emetic toxin of Bacillus cereus

Abstract A vacuole-formation substance, cereulide of Bacillus cereus , is an emetic toxin in animals. Both oral administration and intraperitoneal injection of cereulide caused dose-dependent emesis in Suncus murinus , a new animal model of emesis. Vagotomy or a 5-HT₃ receptor antagonist completely abolished this emetic effect. Therefore, cereulide causes emesis through the 5-HT₃ receptor and stimulation of the vagus afferent. We also found that our purified cereulide caused swelling of mitochondria of HEp-2 cells.     

Reaction of the hypothalamo-hypophyseal system of cats to stimulation of the cervical sympathetic nerve and the afferent fibers of the vagus nerve]

Data are presented on the functional morphology of the hypothalamo-hypophysial neurosecretory system of cats in stimulation of the cervical sympathetic nerve and of the afferent fibers of the vagus. Stimulation of the sympathetic nerve selectively activated the supraoptic nucleus and caused the discharge of the neurohormones from the posterior lobe of the hypophysis, whereas its infundibular portion contained much neurosecretory material. In response to the stimulation of the vagus all the portions of the neurohypophysis were released of the Gomori-positive substance; both the supraoptic and the paraventricular nucleus were activated.     

Vagus nerve stimulation preferentially induces Fos expression in nitrergic neurons of rat esophagus

To identify neurochemical phenotypes of esophageal myenteric neurons synaptically activated by vagal preganglionic efferents, we immunohistochemically detected the expression of Fos, an immediate early gene product, in whole-mount preparations of the entire esophagus of rats following electrical stimulation of the vagus nerves. When electrical stimulation was applied to either the cervical left (LVN) or right vagus nerve (RVN), neurons with nuclei showing Fos immunoreactivity (IR) were found to comprise approximately 10% of the total myenteric neurons in the entire esophagus. These neurons increased from the oral toward the gastric end of the esophagus, with the highest frequency in the abdominal portion of the esophagus. A significant difference was not found in the number of Fos neurons between the LVN-stimulated and RVN-stimulated esophagus. Double-immunolabeling showed that nitric oxide synthase (NOS)-IR occurred in most (86% and 84% in the LVN-stimulated and RVN-stimulated esophagus, respectively) of the Fos neurons in the entire esophagus. Furthermore, the stimulation of either of the vagus nerves resulted in high proportions (71%-90%) of Fos neurons with NOS-IR, with respect to the total Fos neurons in each segment, in the entire esophagus. However, a small proportion (8% and 7% in the LVN-stimulated and RVN-stimulated esophagus, respectively) of the Fos neurons in the esophagus exhibited choline acetyltransferase (ChAT)-IR. The occurrence-frequency of Fos neurons with ChAT-IR was less than 4% of the total Fos neurons in any segment of the LVN-stimulated and RVN-stimulated esophagus. Some of the Fos neurons with ChAT-IR appeared to be innervated by numerous varicose ChAT-positive nerve terminals. The present results showing that electrical stimulation of the vagus nerves induces a high proportion of Fos neurons with NOS-IR suggests the preferential activation of NOS neurons in the esophagus by vagal preganglionic efferents. This connectivity between the vagal efferents and intrinsic nitrergic neurons might be involved in inhibitory actions on esophageal motility.This study was supported by Grant-in Aids for Scientific Research from Ministry of Education, Sports, and Culture of Japan to H.K. (no. 15500236) and to M.K. (no. 14570065).     

大鼠蓝斑核对迷走-迷走抑胃反射的加强作用

本文研究了蓝斑核对迷走-迷走抑胃反射的影响。实验结果表明,单独刺激迷走神经中枢端抑制胃电和胃运动,胃电慢波的振幅和胃内压分别下降到对照值的60.9％和45.7％,与对照值相比有明显的统计学意义(P<0.05)。刺激迷走神经中枢端的同时,以弱刺激刺激蓝斑核时,胃电慢渡的振幅和胃内压分别下降到对照值的42.1％和34.1％,与单独刺激迷走神经的效果相比较有非常显著的差异(P<0.01)。本文结果提示:蓝斑核的兴奋加强迷走-迷走抑胃反射。     

颈动脉窦区注入枸橼酸钠抑制家兔呼吸的机制

向颈总动脉头端注入枸橼酸钠能使大多数家兔发生呼气性呼吸暂停和呼吸频率变慢。此呼吸抑制效应可被地卡因麻醉颈动脉窦区所消除。切断窦神经不能阻断枸橼酸钠对呼吸的抑制。切断迷走神经窦支则使半数以上家兔的呼吸抑制减弱或消失,而在结状神经节上方切断迷走神经能阻断大多数家兔的呼吸抑制。结果提示,迷走神经窦支是颈动脉窦区感受器传入通路之一,向颈动脉窦区注入枸橼酸钠对呼吸的抑制主要是通过迷走神经传入引起的。     

孤束核内微量注射乙酰胆碱对刺激兔下丘脑诱发期前收缩的影响

电刺激兔下丘脑乳头体及其周围区域诱发期前收缩(HSE)。电刺激一侧颈迷走神经中枢端,或电刺激延髓孤束核区域(NTS),均使HSE数减少。而电刺激延髓最后区、网状结构内2/3区域的背侧部以及三叉脊束核等区域对HSE数影响不大。NTS内微量注射乙酰胆碱,使HSE数减少。NTS内微量注射阿托品,可减弱刺激迷走神经对HSE的抑制作用。上述结果提示:电刺激颈迷走神经中枢端对HSE有抑制作用,此作用可能与延髓孤束核内乙酰胆碱的释放有关。     

Mechanisms of cutaneous-cardial interconnections

Using the method of double stimuli, some features of inhibitory influences of conditioning stimulation of cutaneous zones on the afferent transmission from the heart were studied in the experiments on cats. It has been shown that when the interval between testing and conditioning stimuli is from 50 to 150 ms, the cutaneous stimulations effectively block the appearance of evoked potentials in the rostral parts of the cerebral cortex, which were induced by the electrical stimulation of the sinoatrial nodal zone. Bilateral vagotomy completely eliminated this reaction. Stimulation of the peripheral part of the cut vagus also effectively blocked the transmission of the afferent impulses from the heart. It was concluded that inhibitory cutaneo-cardiac effects are determined by the mechanisms of presynaptic inhibition, which develop at the level of intracardiac nervous system.