Interaction between histamine and vagal stimulation on tracheal smooth muscle in dogs

We examined the interaction between histamine and vagal efferent activity on airway smooth muscle reactivity in 11 anesthetized vagotomized dogs using an isolated closed segment of the intrathoracic trachea filled with Tyrode solution under an isovolumetric condition. Intratracheal pressure change was measured as an index of tracheal smooth muscle tone. The administration into the tracheal segment of histamine (0.1 or 1.0 mg/ml) in six dogs and methacholine chloride (0.001 or 0.01 mg/ml) in the other five dogs elevated intratracheal pressure by about 5 cmH2O. The electrical stimulation of the peripheral ends of both of the cut cervical vagus nerves in the presence of histamine produced significantly greater responses than the additive responses of these two stimuli applied individually (two-way analysis of variance, P less than 0.025). However, the combined effects of vagal stimulation and methacholine were not significantly different from the additive responses of these two stimuli applied individually. The average values of intratracheal pressure elevated by the combined effects of vagal stimulation and histamine were significantly higher than those obtained by the combination of vagal stimulation and methacholine (two-way analysis of variance, P less than 0.01). This suggests that histamine potentiates tracheal smooth muscle reactivity to electrical vagal stimulation, which may contribute to the hyperreactivity observed in patients with asthma.     

Absence of nonadrenergic noncholinergic relaxation in the cat cervical trachea

Published in vivo experiments have not supported in vitro reports of the presence of nonadrenergic noncholinergic (NANC) inhibitory pathways in the cat trachea. We therefore examined these pathways, measuring tension in an innervated tracheal segment, flow resistance in more distal airways, and dynamic compliance, in 10 anesthetized mechanically ventilated cats. Initially, cervical vagal stimulation evoked contraction followed by relaxation of smooth muscle of trachea and lower airways; sympathetic stimulation evoked relaxation only. After muscarinic blockade and restoration of smooth muscle tone with 5-hydroxytryptamine (5-HT) applied topically to the tracheal mucosa, vagal stimulation did not affect tracheal segment tension, whereas sympathetic-evoked relaxation was preserved. Similar results were found when tone was restored with intravenous 5-HT, with vagal stimulation also decreasing resistance and increasing compliance. We conclude that NANC pathways are present in lower airways but not in the cervical trachea of the cat. We hypothesize that parasympathetic constriction of cat airway smooth muscle can occur without simultaneous NANC activation, whereas NANC activity occurs only in tandem with parasympathetic stimulation.     

Influence of ventrolateral surface of medulla on reflex tracheal constriction

To assess the role of structures located superficially near the ventrolateral surface of the medulla on the reflex constriction of tracheal smooth muscle that occurs when airway and pulmonary receptors are stimulated mechanically or chemically, experiments were conducted in alpha-chloralose-anesthetized, paralyzed, and artificially ventilated cats. Pressure changes within a bypassed segment of the trachea were used as an index of alterations smooth muscle tone. The effects of focal cooling of the intermediate areas or topically applied lidocaine on the ventral surface of the medulla on the response of the trachea to mechanical and chemical stimulation of airway receptors were examined. Atropine abolished tracheal constriction induced by mechanical stimulation of the carina or aerosolized histamine, showing that the responses were mediated over vagal pathways. Moderate cooling of the intermediate area (20 degrees C) or local application of lidocaine significantly decreased the tracheal constrictive response to mechanical activation of airway receptors. Furthermore, when the trachea was constricted by histamine, cooling of the intermediate area significantly diminished the increased tracheal tone, whereas rewarming restored tracheal tone to the previous level. These findings suggest that under the conditions of the experiments the ventral surface of the medulla plays an important role in constriction of the trachea by inputs from intrapulmonary receptors and in the modulation of parasympathetic outflow to airway smooth muscle.     

Catecholamines abolish vagal but not acetylcholine tone in the intact cat trachea

To obtain evidence in the airways that catecholamines inhibit cholinergic neurotransmission, we recorded transverse tension in the posterior wall of an upper tracheal segment in anesthetized cats and compared the inhibitory effect of stimulating cervical sympathetic nerves when segment contraction was evoked by endogenous acetylcholine (vagal tone) with the effect when contraction was evoked by exogenous acetylcholine applied directly to the mucosal surface of the tracheal segment (ACh tone). We found that sympathetic stimulation abolished all contraction evoked by vagal tone but reduced ACh tone by only one-half. In a second group of cats we compared the inhibitory effects of sympathetic stimulation and intravenous isoproterenol during vagal and ACh tone and also during tone evoked by exogenous 5-hydroxytryptamine (5-HT tone). Sympathetic stimulation or isoproterenol injection abolished all vagal and 5-HT tone but again reduced ACh tone by only one-half. Our results suggest that catecholamines released from sympathetic nerves or injected into the circulation completely inhibit vagal tone. This inhibition may be partially responsible for inducing relaxation in airway smooth muscle.     

Effects of bulbar stimulation on smooth muscle tone in the feline airway

Changes induced in tracheal smooth muscle tone by bulbar electrical stimulation were investigated in 30 cats anesthetized with a chloralose-urethane mixture and paralyzed with succinyl choline bromide. Raised tonus was mainly observed during stimulation of the caudal section of the dorsal motor nucleus of the vagus nerve, the vicinity of the nucleus ambiguus, and the adjoining reticular formation structures. Attenuation, however, was produced by stimulating bulbar reticular formation nuclei at a level 1 mm caudal and 6 mm rostral to the obex. Raised tonus is thought to be connected with activation of efferent neurons belonging to the motor nucleus of the vagal nerve, as well as axons of nucleus ambiguus neurons in transit through the medial zone, whilst attenuation is connected with excitation of sympathotonic reticular neurons, inhibitory neurons activated by pulmonary stretch receptors, and possibly with vagal efferent neurons activating the non-adrenergic inhibitory nervous system of the bronchi.Medical Institute, Latvian Ministry of Health, Riga. Cardiology Research Institute. Latvian Ministry of Health, Riga. Translated from Neirofiziologiya, Vol. 21, No. 3, pp. 320–326, May–June, 1989.     

Inspiratory rhythm in airway smooth muscle tone

In anesthetized paralyzed open-chested cats ventilated with low tidal volumes at high frequency, we recorded phrenic nerve activity, transpulmonary pressure (TPP), and either the tension in an upper tracheal segment or the impulse activity in a pulmonary branch of the vagus nerve. The TPP and upper tracheal segment tension fluctuated with respiration, with peak pressure and tension paralleling phrenic nerve activity. Increased end-tidal CO2 or stimulation of the carotid chemoreceptors with sodium cyanide increased both TPP and tracheal segment tension during the increased activity of the phrenic nerve. Lowering end-tidal CO2 or hyperinflating the lungs to achieve neural apnea (lack of phrenic activity) caused a decrease in TPP and tracheal segment tension and abolished the inspiratory fluctuations. During neural apnea produced by lowering end-tidal CO2, lung inflation caused no further decrease in tracheal segment tension and TPP. Likewise, stimulation of the cervical sympathetics, which caused a reduction in TPP and tracheal segment tension during normal breathing, caused no further reduction in these parameters when the stimulation occurred during neural apnea. During neural apnea the tracheal segment tension and TPP were the same as those following the transection of the vagi or the administration of atropine (0.5 mg/kg). Numerous fibers in the pulmonary branch of the vagus nerve fired in synchrony with the phrenic nerve. Only these fibers had activity which paralleled changes in TPP and tracheal tension. We propose that the major excitatory input to airway smooth muscle arises from cholinergic nerves that fire during inspiration, which have preganglionic cell bodies in the ventral respiratory group in the region of the nucleus ambiguus and are driven by the same pattern generators that drive the phrenic and inspiratory intercostal motoneurons.     

Histopathologic features of the vagus nerve after electrical stimulation in swine

This paper describes the histological features of the vagus nerve after its stimulation with an electrostimulation system that is being developed for morbid obesity treatment. An electrostimulation system was implanted laparoscopically around the ventral vagal trunk of five Large White female pigs (49.63+/-1.94 kg.). Vagal nerve stimulation was performed by continuous constant voltage current pulses. Thoracic samples of both ventral and dorsal vagal trunks were obtained thoracoscopically one month after implantation. Animals were sacrificed one month after thoracoscopic vaguectomy. Tissue samples were then harvested from the vagal nerve at the implantation site, 1cm cranial to it, thoracic portion of ventral and dorsal vagal trunks, sub-diaphragmatic dorsal vagal trunk, left and right vagus nerves. Specimens were analysed with light microscope. The severity of the lesions was graded from 0 to 4 (0: no lesion, 1: mild, 2: moderate, 3: severe and 4: extremely severe), taking into account fibrosis, vascularization, necrosis, fiber degeneration and inflammation. Electrode implantation resulted in thickened epineurium and endoneural connective tissue. The greatest lesion score was evidenced at the leads implantation site in the ventral vagal trunk, followed by, in order of decreasing lesion severity, left vagus nerve, thoracic portion of ventral vagal trunk, subdiaphragmatic dorsal vagal trunk, thoracic portion of dorsal vagal trunk and right vagus nerve. The stimulation device used in this study caused connective tissue growth, greatest in the samples located closer to the implantation site. However, there was no sign of altered vascularization in any studied specimen.     

The protective effect of vagus nerve stimulation on catecholamine-halothane-induced ventricular fibrillation in dogs

Parasympathetic neural activity modulates some ventricular arrhythmias in man. Therefore, a canine model of arrhythmias produced by the interaction of halothane and catecholamines was used to study the effects of vagal stimulation on the induction of ventricular fibrillation. The dose of catecholamine required to induce ventricular fibrillation was determined during a constant heart rate. Vagal stimulation reversibly raised the norepinephrine dose that produced ventricular fibrillation from 16.4 +/- 2.4 to 30.0 +/- 3.8 micrograms (p less than 0.001, n = 10), and the epinephrine dose from 15.5 +/- 2.0 to 22.5 +/- 2.6 micrograms (p less than 0.001, n = 5). Following atropine, vagal stimulation failed to raise the threshold dose of norepinephrine (16.8 +/- 2.4 vs. 18.3 +/- 3.3 micrograms, nonsignificant, n = 6) or epinephrine (15.5 +/- 2.0 vs. 16.0 +/- 2.3 micrograms, nonsignificant, n = 5). Ligation of the cervical vagus nerves did not affect the epinephrine threshold dose (16.3 +/- 3.3 vs. 17.5 +/- 2.7 micrograms, nonsignificant, n = 5). Following elevation of basal vagal tone by morphine premedication, the norepinephrine threshold of 53.0 +/- 9.2 micrograms declined by a nonsignificant amount to 46.5 +/- 11.5 micrograms after vagotomy (nonsignificant, n = 5). Thus resting vagal tone does not prevent catecholamine-halothane-induced ventricular fibrillation, whereas increasing vagal tone by electrical stimulation substantially protects against this arrhythmia. The protection is mediated through a muscarinic cholinergic receptor.     

The upper esophageal sphincter in the cat: the role of central innervation assessed by transient vagal blockade

Studies were performed on four cats to assess the role of extrinsic innervation via the cervical nerve trunks in the control of upper esophageal sphincter function. Transient vagal nerve blockade was accomplished by cooling the cervical vagosympathetic nerve trunks previously isolated in skin loops on each side of the neck. Upper esophageal sphincter pressure was measured using a multilumen oval manometry tube and a rapid pull-through technique. The upper esophageal sphincter response to cervical intraesophageal balloon distention and acid perfusion was assessed. The feline upper esophageal sphincter has a distinct asymmetric pressure profile, whereby anterior pressure greater than posterior pressure greater than left pressure greater than right pressure. Bilateral vagal nerve blockade lowered the mean upper esophageal sphincter pressure from 18.5 +/- 1.5 to 12.0 +/- 2.8 mmHg (1 mmHg = 133.3 Pa) (p less than 0.001), with a significant reduction in pressure in all four quadrants. Intraesophageal balloon distention and acid perfusion both produced a significant increase in upper esophageal sphincter pressure. Bilateral vagal nerve blockade completely abolished the response of the upper esophageal sphincter to balloon distention and acid perfusion. We conclude that normal upper esophageal sphincter tone in the cat is partially mediated by excitatory neural input via the cervical nerve trunks, presumably via the recurrent laryngeal nerves; and cervical intraesophageal balloon distention and acid perfusion produce reflex contraction of the upper esophageal sphincter, which is dependent on neural pathways via the cervical vagal nerve trunks, but the relative contribution of afferent and efferent pathways remains unknown.     

Augmentation of parasympathetic contraction in tracheal and bronchial airways by PGF2 alpha in situ

We studied the effect of exogenous prostaglandin F2 alpha (PGF2 alpha) on airway smooth muscle contraction caused by parasympathetic stimulation in 22 mongrel dogs in situ. Voltage (0-30 V, constant 20 Hz) and frequency-response (0-25 Hz, 25 V) curves were generated by stimulating the cut ends of both cervical vagus nerves. Airway response was measured isometrically as active tension (AT) in a segment of cervical trachea and as change in airway resistance (RL) and dynamic compliance (Cdyn) in bronchial airways. One hour after 5 mg/kg iv indomethacin, a cumulative frequency-response curve was generated in nine animals by electrical stimulation of the vagus nerves at 15-s intervals. Reproducibility was demonstrated by generating a second curve 7 min later. A third frequency-response curve was generated during active contraction of the airway caused by continuous intravenous infusion of 10 micrograms X kg-1 X min-1PPGF2 alpha. Additional frequency-response studies were generated 15 and 30 min after PGF2 alpha, when airway contractile response (delta RL = +2.8 +/- 0.65 cmH2O X 1(-1) X s; delta Cdyn = -0.0259 +/- 0.007 1/cmH2O) returned to base line. Substantial augmentation of AT, RL, and Cdyn responses was demonstrated in every animal studied (P less than 0.01 for all points greater than 8 Hz) 15 min after PGF2 alpha. At 30 min, response did not differ from initial base-line control. In four animals receiving sham infusion, all frequency-response curves were identical. We demonstrate that PGF2 alpha augments the response to vagus nerve stimulation in tracheal and bronchial airways. Augmentation does not depend on PGF2 alpha-induced active tone.     

Effects of neutrophil depletion and repletion on PAF-induced hyperresponsiveness of canine trachea.

Platelet-activating factor (PAF) has been implicated as a mediator of airway hyperresponsiveness. PAF, infused intra-arterially into the canine cervical trachea, causes adherence of neutrophils to vascular endothelium, increases vascular permeability, and increases the responsiveness of tracheal muscle to parasympathetic stimulation. We hypothesized that the increase in airway responsiveness induced by PAF in this model depends on the presence of neutrophils. To test this hypothesis, we perfused a cervical tracheal segment with autologous blood depleted of leukocytes or with similar leukocyte-depleted blood that had been repleted with its neutrophils. Fifteen minutes after the onset of perfusion with either leukocyte-depleted or neutrophil-repleted blood, PAF infusion was begun into the tracheal arterial vasculature. The contractile response of the tracheal muscle to parasympathetic stimulation was measured before and 15 and 30 min after the onset of PAF infusion. PAF did not significantly change the response of tracheal muscle during perfusion with neutrophil-depleted blood but increased the response of tracheal muscle during perfusion with neutrophil-repleted blood. We conclude that the increase in canine tracheal muscle response induced by intra-arterial PAF depends on neutrophils.     

Neuroinhibition in the regulation of emesis

Elucidation of an inhibitory system in the regulation of emesis is presented in this report. Emesis preceded by retching, can be induced in the dog by appropriate electrical stimulation of abdominal vagus nerves at the supradiaphragmatic level. Failure to produce retching or emesis by electrical stimulation of the cervical vagus trunk suggests either that the abdominal vagal emetic afferent does not course in the cervical vagus or that fibers inhibitory to emesis are present. This report presents evidence for afferent fibers inhibitory to retching and emesis in the cervical vagus. Retching and emesis resulting from stimulation of the supradiaphragmatic vagus can be prevented by either transection of the cervical vagus or simultaneous stimulation of the cervical vagus trunk. In addition, retching and emesis occur with stimulation of a fine nerve bundle dissected from the cervical vagus trunk. That the afferent pathway inhibitory to retching and emesis involves pulmonary afferents is suggested by the observation that hyperventilation occurs with stimulation of the cervical vagus trunk.Research supported by U.S.P.H.S. Grant No. FR05339-07     

AV blocking due to asynchronous vagal stimulation in rats

The parasympathetic nervous system innervates the heart through two cervical vagal branches. The right vagal branch mainly influences the heart rate by the modulation of the rhythmogenesis of the sinoatrial node. The left branch predominantly influences the conduction properties of the atrioventricular (AV) node. We investigated the effect of asynchronous stimulation by the vagal nerves on the occurrence of irregularities in heart rate. In rats, the vagal nerves were isolated and cut. Different vagal stimulation patterns (continuous, pulsed) were applied. The heart was beating spontaneously under continuous vagal stimulation. In case of pulsed vagal stimulation, the atria were paced at different rates. Asynchronicity was induced by delaying the right stimulus with respect to the left stimulus (early right) or the left stimulus with respect to the right stimulus (early left). The value of the fraction of deviated R-R or P-Q intervals in the distribution in the histogram was used to characterize irregularities during a stimulation protocol (duration in case of continuous stimulation: 20 s; pulsed stimulation: 120 s). Under both stimulation patterns (continuous or pulsed), we found that early left vagal stimulation introduced a much larger fraction of deviated intervals in the R-R or P-Q histogram (in R-R: 29.1 +/- 4.9%; in P-Q: 12.90 +/- 1.95%) than early right vagal stimulation (in R-R: 7.4 +/- 2.0%; in P-Q: 1. 05 +/- 0.50%) or synchronous stimulation (in R-R: 8.2 +/- 3.6%; in P-Q: 2.15 +/- 0.75%). We conclude that early stimulation by the left vagal nerve can introduce irregularities in heart rate, mainly due to different degrees of AV nodal blockade.     

Stimulation of vagal C-fibers alters timing and distribution of respiratory motor output in cats

Pulmonary vascular congestion or pulmonary embolism in humans produces shallow tachypnea, and indirect experimental evidence suggests that this characteristic breathing pattern may result from activation of vagal unmyelinated afferents from the lung. We have investigated, in decerebrate cats, reflex changes in breathing pattern and in the activation of the diaphragm, posterior cricoarytenoid, and thyroarytenoid muscles caused by activating C-fiber afferents in the vagus nerve. The right vagus nerve was sectioned distal to the origin of the recurrent laryngeal nerve, eliminating vagal afferent traffic although preserving motor innervation of the larynx on that side. The left cervical vagus was stimulated electrically, and efferent activation of the laryngeal muscles was avoided by cutting the left recurrent laryngeal nerve. Transmission to the brain of vagal afferent traffic resulting from this stimulation was controlled by graded cold block of the nerve cranial to the site of application of the stimulus. Activation of C-fibers, when A-fibers were blocked, significantly decreased respiratory period and amplitude of diaphragm inspiratory burst. In addition, this selective activation of vagal C-fibers augmented postinspiratory activity of the diaphragm and recruited phasic expiratory bursts in the thyroarytenoid. We conclude that, in unanesthetized decerebrate cats, afferent traffic of vagal C-fibers initiates a pontomedullary reflex that increases respiratory frequency, decreases tidal volume, and augments braking of expiratory airflow.     

Potentiation of vagal contractile response by thromboxane mimetic U-46619

We studied the effect of the thromboxane mimetic U-46619 on tracheal smooth muscle contraction caused by bilateral stimulation of the vagus nerves in 14 mongrel dogs in situ. The parasympathetic contractile response was studied isometrically after beta-adrenergic blockade with 2 mg/kg iv propranolol plus 20 micrograms X kg-1 X min-1 continuous intravenous infusion and blockade of endogenous prostaglandin synthesis with 5 mg/kg iv indomethacin. An initial frequency-response curve was generated by electrical stimulation of the caudal ends of cut cervical vagi over the range of frequencies 2-25 Hz (constant 25 V) at 15-s intervals. In five dogs, 10(-10) to 10(-8) mol of the thromboxane mimetic (15S)-hydroxyl-11 alpha,9 alpha-(epoxymethano)prosta-5Z,13E-dienoic acid (U-46619) was injected selectively into the tracheal arterial circulation, causing a transient contractile response (less than or equal to 10 g/cm). Additional frequency response studies were generated 7 min before and 1, 15, 30, 45, and 60 min after U-46619. Substantial augmentation of tracheal contraction to efferent vagal stimulation was observed after U-46619 for all frequencies greater than 4 Hz (P less than 0.02). Augmentation of vagally mediated contraction was not observed in four other dogs after equivalent tracheal contraction was elicited without U-46619. Similarly, in four separate dogs, augmentation of tracheal contraction was not observed when acetylcholine was given instead of vagal stimulation after U-46619. We conclude that the thromboxane analogue, U-46619, causes augmentation of tracheal contractile response induced by efferent vagus nerve stimulation. Potentiation is caused by a prejunctional action of U-46619 and is not induced by nonspecific precontraction with another agonist.     

Cigarette smoke-induced bronchoconstriction in dogs: vagal and extravagal mechanisms

We reassessed the severity of cigarette smoke-induced bronchoconstriction and the mechanisms involved in anesthetized dogs. To evaluate the severity of smoke-induced bronchoconstriction, we measured airway pressure and airflow resistance (Rrs, forced oscillation method). We studied the mechanisms in other dogs by measuring airway pressure, central airway smooth muscle tone in tracheal segments in situ, and respiratory center drive by monitoring phrenic motor nerve output, including the role of vagal and extravagal nerves vs. the role of blood-borne materials during inhalation of cigarette smoke. Rrs increased more than fourfold with smoke from one cigarette delivered in two tidal volumes. About half the airway response was due to local effects of smoke in the lungs. The remainder was due to stimulation of the respiratory center, which activated vagal motor efferents to the airway smooth muscle. Of this central stimulation, about half was due to blood-borne materials and the rest to vagal pulmonary afferents from the lungs. We conclude that inhalation of cigarette smoke in dogs causes severe bronchoconstriction which is mediated mainly by extravagal mechanisms.     

Influence of peripheral targets on the expression of calcitonin gene-related peptide immunoreactivity in rat cranial motoneurones

Calcitonin gene-related peptide-like immunoreactivity (CGRP-ir) is displayed by motoneurons that innervate striated muscle but is absent from preganglionic parasympathetic motoneurons. One hypothesis to explain this is that CGRP gene expression in motoneurons is, in part, dependent on influences from the innervated organ. To test this hypothesis, we cross-anastomosed the right hypoglossal and cervical vagal nerves of rats so that the vagal motoneurons grew to innervate the musculature of the tongue. Following a recovery period of 17 to 52 weeks, the distribution of CGRP-ir in the dorsal motor vagal nucleus was determined in both cross-anastomosed animals and self-anastomosed control animals. Successful reinnervation of the tongue musculature by vagal motoneurons was demonstrated by showing that electrical stimulation of the central vagus/peripheral hypoglossal nerve produced a twitch of the tongue muscles. Motoneurones of the dorsal motor vagal nucleus, which now innervated the tongue were found to express CGRP-ir, which was evident from the double labeling of neurons with both horseradish peroxidase and CGRP-ir. Motoneurones of the dorsal motor vagal nucleus contralateral to the cross-anastomosis remained CGRP negative. Similarly, motoneurons of the dorsal motor vagal nucleus in control animals where the vagus nerve was self-anastomosed remained CGRP negative, showing that an induction of CGRP expression is not a result of nerve section itself. We suggest that a signal from the striated muscle transported retrogradely via the motor axon regulates expression of CGRP-ir in motoneurons. © 1995 John Wiley & Sons, Inc.     

Maturation of respiratory reflex responses in the piglet

Stimulation of chemo-, irritant, and pulmonary C-fiber receptors reflexly constricts airway smooth muscle and alters ventilation in mature animals. These reflex responses of airway smooth muscle have, however, not been clearly characterized during early development. In this study we compared the maturation of reflex pathways regulating airway smooth muscle tone and ventilation in anesthetized, paralyzed, and artificially ventilated 2- to 3- and 10-wk-old piglets. Tracheal smooth muscle tension was measured from an open tracheal segment by use of a force transducer, and phrenic nerve activity was measured from a proximal cut end of the phrenic nerve. Inhalation of 7% CO2 caused a transient increase in tracheal tension in both age groups, whereas hypoxia caused no airway smooth muscle response in either group. The phrenic responses to 7% CO2 and 12% O2 were comparable in both age groups. Lung deflation and capsaicin (20 micrograms/kg iv) administration did not alter tracheal tension in the younger piglets but caused tracheal tension to increase by 87 +/- 28 and 31 +/- 10%, respectively, in the older animals (both P less than 0.05). In contrast, phrenic response to both stimuli was comparable between ages: deflation increased phrenic activity while capsaicin induced neural apnea. Laryngeal stimulation did not increase tracheal tension but induced neural apnea in both age groups. These data demonstrate that between 2 and 10 wk of life, piglets exhibit developmental changes in the reflex responses of airway smooth muscle situated in the larger airways in response to irritant and C-fiber but not chemoreceptor stimulation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Neuropeptides in guinea pig trachea: Distribution and evidence for the release of CGRP into tracheal lumen

The airways of the guinea pig are richly innervated by peptide-containing nerve fibers. Among the most abundant neuropeptides are calcitonin gene-related peptide (CGRP) and substance P (SP), which are stored in nerve fibers located predominantly within and beneath the epithelium, and vasoactive intestinal peptide (VIP), which is located in fibers running mainly among smooth muscle bundles and seromucous glands. Sensory denervation (capsaicin treatment) of adult guinea pigs caused an almost total disappearance of CGRP- and SP-containing nerve fibers, while the density of VIP-containing nerve fibers located in smooth muscle seemed to increase. In the isolated trachea, perfused luminally, CGRP was found to appear in the intraluminal fluid after exposure to capsaicin but not after electrical vagal stimulation. CGRP concentrations in the tracheal wall did not change significantly. Luminally applied CGRP did not affect smooth muscle tension, measured as intraluminal volume changes.     

Influence of the ventral surface of the medulla on tracheal responses to CO2

These studies investigated the role of the intermediate area of the ventral surface of the medulla (VMS) in the tracheal constriction produced by hypercapnia. Experiments were performed in chloralose-anesthetized, paralyzed, and artificially ventilated cats. Airway responses were assessed from pressure changes in a bypassed segment of the rostral cervical trachea. Hyperoxic hypercapnia increased tracheal pressure and phrenic nerve activity. Intravenous atropine pretreatment or vagotomy abolished the changes in tracheal pressure without affecting phrenic nerve discharge. Rapid cooling of the intermediate area reversed the tracheal constriction produced by hypercapnia. Graded cooling produced a progressive reduction in the changes in maximal tracheal pressure and phrenic nerve discharge responses caused by hypercapnia. Cooling the intermediate area to 20 degrees C significantly elevated the CO2 thresholds of both responses. These findings demonstrate that structures near the intermediate area of the VMS play a role in the neural cholinergic responses of the tracheal segment to CO2. It is possible that neurons or fibers in intermediate area influence the motor nuclei innervating the trachea. Alternatively, airway tone may be linked to respiratory motor activity so that medullary interventions that influence respiratory motor activity also alter bronchomotor tone.