Vagal afferent and reflex responses to changes in surface osmolarity in lower airways of dogs.

In anesthetized dogs we examined the sensitivity of afferent vagal endings in the lungs to changes in airway fluid osmolarity. Injection of 0.25-0.5 ml/kg water or hyperosmotic sodium chloride solutions (1,200-2,400 mmol/l) into a lobar bronchus caused bradycardia, arterial hypotension, apnea followed by rapid shallow breathing, and contraction of tracheal smooth muscle. All effects were abolished by vagotomy. We examined the sensory mechanisms initiating these effects by recording afferent vagal impulses arising from the lung lobe into which the liquids were injected. Water stimulated pulmonary and bronchial C-fibers and rapidly adapting receptors; isosmotic saline and glucose solutions were ineffective. Hyperosmotic saline (1,200-9,600 mmol/l, 0.25-1 ml/kg) stimulated these afferents in a concentration-dependent manner. Stimulation began 1-10 s after the injection and sometimes continued for several minutes. Responses of slowly adapting stretch receptors varied. Our results suggest that non-isosmotic fluid in the lower airways initiates defense reflexes by stimulating pulmonary and bronchial C-fibers and rapidly adapting receptors. Conceivably, stimulation of these afferents as a result of evaporative water loss from airway surface liquid could contribute to exercise-induced asthma.

Rapidly adapting receptors monitor lung compliance in spontaneously breathing dogs.

We examined the ability of rapidly adapting receptors (RARs) to monitor changes in dynamic lung compliance (Cdyn) in anesthetized spontaneously breathing dogs by recording RAR impulses from the vagus nerves. We decreased Cdyn in steps through the physiological range by briefly restricting lung expansion with an inflatable cuff around the chest and recording the response after deflating the cuff; we restored Cdyn to control by hyperinflating the lungs. Of 45 RARs, 34 were stimulated by a 40 +/- 2% reduction in Cdyn, their inspiratory discharge increasing on average more than threefold. Two-thirds of responsive RARs were stimulated by less than or equal to 20% reductions in Cdyn; in most, firing increased proportionately with lung stiffness (1/Cdyn) as Cdyn was decreased further. Stimulation by reduced Cdyn was not simply a function of the concomitant increase in transpulmonary pressure, because similar increases in pressure produced by increasing tidal volume produced smaller increases in firing. RAR stimulation was unaffected by atropine and, hence, was not dependent on neurally mediated changes in bronchomotor tone. Our results indicate that during spontaneous breathing RARs provide a signal inversely proportional to Cdyn.

Response of slowly adapting pulmonary stretch receptors to reduced lung compliance.

We examined the steady-state response of slowly adapting pulmonary stretch receptors (SAPSRs) to reduced lung compliance in open-chest cats with lungs ventilated at eupneic rate and tidal volume (VT) and with a positive end-expiratory pressure (PEEP) of 3-4 cmH2O. Transient removal of PEEP decreased compliance by approximately 30% and increased transpulmonary pressure (Ptp) by 1-2.5 cmH2O. Reduction of compliance significantly decreased SAPSR discharge in deflation and caused a small increase in discharge at the peak of inflation; it had little effect on discharge averaged over the ventilatory cycle. Increasing VT to produce a comparable increase in Ptp significantly increased peak discharge. Thus unlike rapidly adapting receptors, whose discharge is increased more effectively by reduced compliance than by increased VT, SAPSRs are stimulated by increased VT but not by reduced compliance. We speculate that the most consistent effect of reduced compliance on SAPSRs (the decrease in deflation discharge) was due to the decreased time constant for deflation in the stiffer lung. This alteration in firing may contribute to the tachypnea evoked as the lungs become stiffer.

Rapidly adapting receptor activity in dogs is inversely related to lung compliance.

We examined the response of pulmonary rapidly adapting receptors (RAR's) to changes in dynamic lung compliance (Cdyn) in the physiological range. RAR impulse activity was recorded from the cervical vagus nerves in anesthetized open-chest dogs whose lungs were ventilated at constant rate and tidal volume (VT), with a positive end-expiratory pressure (PEEP) of 3-4 cmH2O. After hyperinflation to produce maximal Cdyn, RAR's were silent or fired sparsely and irregularly. Reducing Cdyn in steps by briefly removing PEEP increased firing proportionately, and RAR's began to discharge vigorously in inflation. Activity was restored to control by hyperinflating the lungs. Activity also increased when we increased inflation rate, and hence the rate of change of airway pressure (dP/dt), by reducing inflation time, keeping VT and cycle length constant. RAR's were stimulated more when dP/dt was increased by reducing compliance than when dP/dt was increased by increasing inflation rate. We conclude that RAR's are sensitive to changes in Cdyn and speculate that excitatory input from RAR's may help to maintain VT as the lungs become stiffer.

Cigarette smoke in lungs evokes reflex increase in tracheal submucosal gland secretion in dogs.

Stimulation of pulmonary C-fibers (PCs) by capsaicin and of rapidly adapting receptors (RARs) by reduced lung compliance reflexly increases airway submucosal gland secretion in dogs. Because both PCs and RARs are stimulated by cigarette smoke (nicotine being the primary stimulus), we performed experiments in anesthetized open-chest artificially ventilated dogs (with aortic nerves cut) to determine whether cigarette smoke reflexly stimulates airway secretion. We measured submucosal gland secretion by counting the hillocks in a 1.2-cm2 field of tracheal epithelium coated with tantalum dust. Secretion was stimulated by delivery of 40-320 ml smoke from high-nicotine cigarettes to the lower trachea, secretion rate increasing from 7.4 +/- 1.3 to 48.1 +/- 5.1 hillocks.cm-2.min-1. Results of cutting the pulmonary vagal branches or carotid sinus nerves or both indicated that the secretory response was initiated by stimulation of lower respiratory vagal afferents and augmented several seconds later by stimulation of carotid chemoreceptors. Results of cooling the cervical vagus nerves to 7 and 0 degrees C indicated that most of the vagally mediated increase in secretion was due to stimulation of afferent lung C-fibers.

Reflex bronchial vasodilation in dogs evoked by injection of a small volume of water into a bronchus.

Injection of water into a lobar bronchus stimulates airway C-fibers and rapidly adapting receptors and evokes airway defense reflexes. To determine whether this stimulus also evokes a reflex increase in bronchial blood flow (Qbr), we injected 1-2 ml of water into a lobar bronchus in anesthetized dogs. Injection decreased arterial pressure but increased Qbr from 9 +/- 1 to 21 +/- 3 ml/min. The increase had a latency of 6-8 s and reached a peak after approximately 20 s; Qbr returned to control after 60-90 s. Airway mucosal blood flow, measured by colored microspheres, increased in proportion to Qbr. In contrast, flow in an adjacent intercostal artery that did not supply the airway decreased slightly. Injection of isosmotic saline had little effect. In 13 of 16 dogs, the water-induced increase in Qbr was abolished by cutting or cooling the cervical vagus nerves and hence was entirely dependent on centrally mediated vagal pathways. When the vagus nerves were intact, about one-third of the vasodilator response remained after pharmacological blockade of muscarinic and adrenergic receptors. We conclude that in dogs the defense response to water in the lower airways includes a large increase in Qbr that is partly due to activation of nonadrenergic noncholinergic autonomic pathways.

Capsaicin-induced bronchial vasodilation in dogs: central and peripheral neural mechanisms.

In 21 anesthetized dogs, we placed a flow probe around the right bronchial artery and examined changes in bronchial blood flow and bronchial vascular conductance when pulmonary C-fibers were stimulated by right atrial injection of capsaicin. When vagus nerves were intact, capsaicin evoked a pulmonary depressor chemoreflex and increased bronchial blood flow by 125% and bronchial vascular conductance by 175%; flow in an adjacent intercostal artery did not increase. Injection of color-coded microspheres revealed that blood flow to mucosa of lower trachea and to a peripheral bronchus doubled, whereas flow to posterior tracheal wall increased little. Cooling (to -1 degree C) or cutting cervical vagi (in 17 dogs) abolished the pulmonary chemoreflex and abolished all bronchial vascular effects in nine dogs but 33% of the vasodilation persisted in eight. In five of six dogs, this persisting vasodilation was potentiated by phosphoramidon (a neutral endopeptidase inhibitor that retards breakdown of neuropeptides released by C-fibers). Atropine reduced the capsaicin-induced bronchial vasodilation by approximately 30%. We conclude that the bronchial vasodilation was largely due to a centrally mediated vagal reflex and that a neuropeptide-dependent axon-reflex component was also present in about one-half the dogs.

Pulmonary C-fiber stimulation by capsaicin evokes reflex cholinergic bronchial vasodilation in sheep.

We investigated changes in bronchial blood flow (Qbr) associated with capsaicin-induced stimulation of pulmonary C-fibers in seven anesthetized and two unanesthetized sheep. A Doppler flow probe chronically implanted around the common bronchial artery provided a signal (delta F, kHz) linearly related to bronchial arterial blood velocity (Vbr, cm/s), which was proportional to Qbr. An index of bronchial vascular conductance (Cbr, in arbitrary units) was calculated as the ratio of Vbr to systemic arterial pressure (Pa). Right atrial injection of capsaicin evoked a prompt pulmonary chemoreflex (apnea, bradycardia, and hypotension), with immediate increases in Vbr (average +34%) and Cbr (+63%) that reached a maximum approximately 7 s after the injection. A second increase in Vbr, but not in Cbr, occurred approximately 12 s later, coinciding with an increase in Pa. Vagal cooling (0 degrees C) prevented the pulmonary chemoreflex; it also abolished the immediate increases in Vbr and Cbr in four of six sheep and substantially reduced them in two sheep; it did not affect the late increases in Vbr and Pa. Results after atropine indicated that the immediate increases in Vbr and Cbr were mainly cholinergic. In two sheep a small residual vasodilation survived combined cholinergic and adrenergic blockade and may have been due to peripheral release of neurokinins.

Effect of pulmonary arterial PCO2 on slowly adapting pulmonary stretch receptors.

We recorded pulmonary stretch receptor (PSR) activity in anesthetized dogs and examined the effect of varying pulmonary arterial PCO2 (PpCO2) in both the naturally perfused and vascularly isolated pulmonary circulations while ventilating the lungs with room air. Steady-state increases in PpCO2 from approximately 25 to 50 Torr and from 50 to 70 Torr decreased PSR activity (impulses/ventilatory cycle) by 15 and 9%, respectively (P less than 0.001). Rapid increases in PpCO2 from approximately 50 to 80 Torr in a right-heart bypass preparation (with pulmonary blood flow constant) decreased PSR activity by 27%. Depression of firing, which was proportionately greater in deflation, was not dependent on changes in lung mechanics. Results show that loading CO2 intravascularly depresses PSR activity, the effects extending above as well as below resting PpCO2. Rapidly increasing PpCO2 above the resting level markedly depresses PSR activity during the transient. We conclude that PSRs may contribute to altered breathing resulting from changes in mixed venous PCO2 over the physiological range.

Bronchial vasodilator pathways in the vagus nerve of dogs.

Bronchial vasodilation in dogs is mediated largely by vagal pathways. To examine the relative contribution of cholinergic and noncholinergic parasympathetic pathways and of sensory axon reflexes to vagal bronchial vasodilation, we electrically stimulated the peripheral vagus nerve in 10 chloralose-anesthetized dogs and measured bronchial artery flow. Moderate-intensity electrical stimulation (which did not activate C-fiber axons) caused a rapid voltage- and frequency-dependent vasodilation. After atropine, vasodilation was slower in onset and reduced at all voltages and frequencies: bronchial vascular conductance increased by 9.0 +/- 1.5 (SE) ml. min-1. 100 mmHg-1 during stimulation before atropine and 5. 5 +/- 1.4 ml. min-1. 100 mmHg-1 after (P < 0.02). High-intensity stimulation (sufficient to recruit C fibers) was not studied before atropine because of the resulting cardiac arrest. After atropine, high-intensity stimulation increased conductance by 12.0 +/- 2.5 ml. min-1. 100 mmHg-1. Subsequent blockade of ganglionic transmission, with arterial blood pressure maintained by a pressure reservoir, abolished the response to moderate-intensity stimulation and reduced the increase to high-intensity stimulation by 82 +/- 5% (P < 0.01). In 13 other dogs, we measured vasoactive intestinal peptide-like immunoreactivity in venous blood draining from the bronchial veins. High-intensity vagal stimulation increased vasoactive intestinal peptide concentration from 5.7 +/- 1.8 to 18.4 +/- 4.1 fmol/ml (P = 0.001). The results suggest that in dogs cholinergic and noncholinergic parasympathetic pathways play the major role in vagal bronchial vasodilation.

Pulmonary C-fibers reflexly increase secretion by tracheal submucosal glands in dogs.

Stimulation of bronchial C-fibers evokes a reflex increase in secretion by tracheal submucosal glands, but the influence of pulmonary C-fibers on tracheal gland secretion is uncertain. In anesthetized dogs with open chests, we sprayed powdered tantalum on the exposed mucosa of a segment of the upper trachea to measure the rate of secretion by submucosal glands. Secretions from the gland ducts caused elevations (hillocks) in the tantalum layer. We counted hillocks at 10-s intervals for 60 s before and 60 s after we injected capsaicin (10-20 micrograms/kg) into the right atrium to stimulate pulmonary C-fiber endings. Right atrial injection of capsaicin increased the rate of hillock formation fourfold, but left atrial injection had no significant effect. The response was abolished by cutting the vagus nerves or cooling them to 0 degree C. We conclude that the reflex increase in tracheal submucosal gland secretion evoked by right atrial injection of capsaicin was initiated as capsaicin passed through the pulmonary vascular bed, and hence that pulmonary C-fibers, like bronchial C-fibers, reflexly increase airway secretion.

Contribution of vagal afferents to respiratory reflexes evoked by acute inhalation of ozone in dogs.

Acute inhalation of ozone induces vagally mediated rapid shallow breathing and bronchoconstriction. In spontaneously breathing anesthetized dogs, we attempted to determine whether afferent vagal C-fibers in the lower airways contributed to these responses. Dogs inhaled 3 ppm ozone for 40-70 min into the lower trachea while cervical vagal temperature was maintained successively at 37, 7, and 0 degrees C. At 37 degrees C, addition of ozone to the inspired air decreased tidal volume and dynamic lung compliance and increased breathing frequency, total lung resistance, and tracheal smooth muscle tension. Ozone still evoked significant effects when conduction in myelinated vagal axons was blocked selectively by cooling the nerves to 7 degrees C. Ozone-induced effects were largely abolished when nonmyelinated vagal axons were blocked by cooling to 0 degree C, breathing during ozone inhalation at 0 degree C being generally similar to that during air breathing at 0 degree C, except that minute volume and inspiratory flow were higher. We conclude that afferent vagal C-fibers in the lower airways make a major contribution to the acute respiratory effects of ozone and that nonvagal afferents contribute to the effects that survive vagal blockade.

Acute inhalation of ozone stimulates bronchial C-fibers and rapidly adapting receptors in dogs.

To identify the afferents responsible for initiating the vagally mediated respiratory changes evoked by acute exposure to ozone, we recorded vagal impulses in anesthetized, open-chest, artificially ventilated dogs and examined the pulmonary afferent response to ozone (2-3 ppm in air) delivered to the lower trachea for 20-60 min. Bronchial C-fibers (BrCs) were the lung afferents most susceptible to ozone, the activity of 10 of 11 BrCs increasing from 0.2 +/- 0.2 to 4.6 +/- 1.3 impulses/s within 1-7 min of ozone exposure. Ten of 15 rapidly adapting receptors (RARs) were stimulated by ozone, their activity increasing from 1.5 +/- 0.4 to 4.7 +/- 0.7 impulses/s. Stimulation of RARs (but not of BrCs) appeared secondary to the ozone-induced reduction of lung compliance because it was abolished by hyperinflation of the lungs. Ozone had little effect on pulmonary C-fibers or slowly adapting pulmonary stretch receptors. Our results suggest that both BrCs and RARs contribute to the tachypnea and bronchoconstriction evoked by acute exposure to ozone when vagal conduction is intact and that BrCs alone are responsible for the vagally mediated tachypnea that survives vagal cooling to 7 degrees C.

Cooling the pulmonary blood in dogs alters activity of pulmonary vagal afferents.

In open-chest anesthetized dogs with left and right lungs ventilated separately, we recorded changes in firing of right lung vagal receptors when 1.25 ml/kg cold (5 degrees C, 20 degrees C) blood were injected into the nonperfused right pulmonary artery. With the right lung inflated at constant pressure, effects of cold blood on individual pulmonary stretch receptors (PSRs) were frequency dependent, with discharge increasing or remaining unchanged if control frequency was low and decreasing if it was high. Consequently average PSR discharge was unchanged by cold blood when airway pressure was maintained at 5 cmH2O, but it decreased at pressures of 10 and 15 cmH2O. Cold blood stimulated rapidly adapting receptors (RARs) at all three pressures. Injection of blood at 37 degrees C had no effect. We conclude that changes in PSR activity account for the tachypnea induced by pulmonary arterial injection of cold blood (G. G. Giesbrecht and M. Younes. J. Appl. Physiol. 69: 1435-1441, 1990). With the right lung phasically ventilated, cold blood decreased PSR discharge in inflation, caused high-threshold PSRs to fire in deflation, and stimulated RARs. Pulmonary C-fibers were unaffected by cold blood. We suggest that PSRs and RARs initiate respiratory changes during hypothermia or exercise-induced asthma.

Pulmonary rapidly adapting receptors reflexly increase airway secretion in dogs.

We attempted to determine whether stimulation of pulmonary rapidly adapting receptors (RARs) increase tracheal submucosal gland secretion in anesthetized open-chest dogs. Electroneurographic studies of pulmonary afferents established that RARs but not lung C-fibers were stimulated by intermittent lung collapse during deflation, collapse being produced by removing positive end-expiratory pressure (PEEP, 4 cmH2O) or by applying negative end-expiratory pressure (NEEP, -4 cmH2O). We measured tracheal secretion by the "hillocks" method. Removing PEEP or applying NEEP for 1 min increased secretion from a base line of 6.0 +/- 1.1 to 11.8 +/- 1.7 and 22.0 +/- 2.8 hillocks.cm-2.min-1, respectively (P less than 0.005). After PEEP was restored, dynamic lung compliance (Cdyn) was 37% below control, and secretion remained elevated (P less than 0.05). A decrease in Cdyn stimulates RARs but not other pulmonary afferents. Hyperinflation, which restored Cdyn and RAR activity to control, returned secretion rate to base line. Secretory responses to lung collapse were abolished by vagal cooling (6 degrees C), by pulmonary vagal section, or by atropine. We conclude that RAR stimulation reflexly increases airway secretion. We cannot exclude the possibility that reduced input from slowly adapting stretch receptors contributed to the secretory response.

Stimulation of vagal pulmonary C-fibers by a single breath of cigarette smoke in dogs.

Inhalation of cigarette smoke into the lower airway via a tracheostomy evokes immediate apnea, bradycardia, and systemic hypotension in dogs. These responses can still be evoked when conduction in myelinated vagal fibers is blocked preferentially by cooling but are abolished by vagotomy, suggesting that they are mediated by afferent vagal C-fibers. To examine this possibility, we recorded impulses in pulmonary C-fibers in anesthetized, open-chest dogs and delivered 120 ml cigarette smoke to the lungs in a single ventilatory cycle. Pulmonary C-fibers were stimulated within 1 or 2 s of the delivery of smoke generated by high-nicotine cigarettes, activity increasing from 0.3 +/- 0.1 to a peak of 12.6 +/- 1.3 (SE) impulses/s, (n = 60); the evoked discharge usually lasted 3-5 s. Smoke generated by low-nicotine cigarettes evoked a milder stimulation in 33% of pulmonary C-fibers but did not significantly affect the overall firing frequency (peak activity = 2.2 +/- 1.1 impulses/s, n = 36). Hexamethonium (0.7-1.2 mg/kg iv) prevented C-fiber stimulation by high-nicotine cigarette smoke (n = 12) but not stimulation by right atrial injection of capsaicin. We conclude that pulmonary C-fibers are stimulated by a single breath of cigarette smoke and that nicotine is the constituent responsible.

Reflex tracheal contraction evoked in dogs by bronchodilator prostaglandins E2 and I2.

Bronchodilator prostaglandins E2 and I2 may cause airway irritation and bronchoconstriction in human subjects. These experiments were designed to test the hypothesis that this paradoxical bronchoconstriction is a vagal reflex triggered by stimulation of airway afferents. We recorded smooth muscle tension in an innervated upper tracheal segment in anesthetized dogs and injected prostaglandins into the general circulation or into a bronchial artery or administered them as aerosol to the lungs. Prostaglandins usually caused tracheal contraction, which survived vagal cooling to 5-7 degrees C but was abolished at 0 degrees C. Vagally mediated tracheal contraction was also evoked when prostacyclin was injected into the pulmonary circulation of dogs whose pulmonary and systemic circulations were independently pump perfused. Recordings of afferent vagal impulses indicated that bronchial arterial injection of prostaglandins stimulated bronchial C-fibers; aerosols of prostaglandin stimulated pulmonary and bronchial C-fibers and C-fibers in extrapulmonary airways. We postulate that in susceptible human subjects concentrations of these prostaglandins too low to have direct bronchodilator effects may cause reflex bronchoconstriction by stimulating afferent vagal C-fibers in the lower airways.