Mechanisms underlying CO2 retention during flow-resistive loading in patients with chronic obstructive pulmonary disease.

The present study examined the respiratory responses involved in the maintenance of eucapnea during acute airway obstruction in 12 patients with chronic obstructive disease (COPD) and 3 age-matched normal subjects. Acute airway obstruction was produced by application of external flow-resistive loads (2.5 to 30 cm H2O/liter per s) throughout inspiration and expiration while subjects breathed 100% O2. Application of loads of increasing severity caused progressive increases in PCO2 in the patients, but the magnitude of the increase in PCO2 varied substantially between subjects. On a resistance of 10 cm H2O/liter per s, the highest load that could be tolerated by all COPD patients, the increase in PCO2 ranged from 1 to 11 mm Hg, while none of the normal subjects retained CO2. Based on the magnitude of the increase in PCO2 the patients could be divided into two groups: seven subjects whose PCO2 increased by less than or equal to 3 mm Hg (group I) and five subjects whose PCO2 increased by greater than 6 mm Hg (group II). Base-line ventilation and the pattern of breathing were similar in the two groups. During loading group I subjects maintained or increased tidal volume while all group II patients decreased tidal volume (VT). The smaller tidal volume in group II subjects was mainly the result of their shorter inspiratory time as the changes in mean inspiratory flow were similar in the two groups. The magnitude of CO2 retention during loading was inversely related to the magnitude of the change in VT (r = -0.91) and inspiratory time (Ti) (r = -0.87) but only weakly related to the change in ventilation (r = -0.53). The changes in PCO2, VT, and Ti during loading correlated with the subjects' maximum static inspiratory pressure, which was significantly lower in group II as compared with group I patients. These results indicate that the tidal volume and respiratory timing responses to flow loads are impaired in some patients with COPD. This impairment, presumably due to poor inspiratory muscle function, appears to lead to CO2 retention during loaded breathing.

A critical assessment of the mechanism by which hyperoxia attenuates exercise-induced asthma.

Recent data demonstrate that the magnitude of the heat loss that occurs from the respiratory tract during exercise correlates with the degree of post-exertional obstruction that develops in asthmatics. Respiratory heat loss relates directly to the minute ventilation and heat capacity of the inspired gas and inversely to its water content and temperature. Because it has been shown that inhaling 100% oxygen during exercise blunts the obstructive response, we wondered if this effect could be accounted for by differing values of heat exchange with air and oxygen breathing. To examine this question, we studied 10 asthmatics by measuring multiple aspects of pulmonary mechanics before and after four bouts of exhausting leg work during which the subjects inhaled either air or oxygen conditioned to provide widely differing thermal burdens on their airways. Under all inspired gas conditions, oxygen breathing produced significantly less obstruction than air. Minute ventilation was also significantly less with oxygen as was the total heat lost. As the latter fell, so did the magnitude of the postexercise obstruction. When the differences in ventilation and respiratory heat loss between air and oxygen were eliminated by eucapnic hyperventilation, the differences in the obstructive responses also disappeared. Thus, the effects of hyperoxia on exercise-induced asthma can be accounteed for solely by alterations in heat exchange.

Influence of heat and humidity on the airway obstruction induced by exercise in asthma.

We examined the degree of airway obstruction that developed in eight asthmatics who exercised while breathing air under four conditions: (a) ambient room temperature and water content; (b) body temperature and ambient water content; (c) ambient room temperature fully saturated; and (d) body temperature fully saturated. These test conditions were performed in random order. Multiple aspects of pulmonary mechanics were measured before and 5 min after exercise. When air at ambient conditions was inhaled, the expected airway obstruction developed after exercise, and all variables changes significantly from their pre-challenge values. Heating the air to body temperature did not influence this response. Increasing the humidity at ambient temperatures significantly blunted the response, and by inhaling body temperature, fully saturated air completely prevented it from occurring. Thus, the water content of inspired air is an important variable in the development of exercise induced asthma.

Evaluation of role played by mediators of immediate hypersensitivity in exercise-induced asthma.

To determine whether mediators of immediate hypersensitivity played a role in the pathogenesis of exercise-induced asthma, we measured the concentration of histamine and neutrophil-chemotactic activity present in systemic arterial blood during thermal challenges in five asymptomatic asthmatics. Because exercise-induced asthma has been shown to be a result of respiratory heat loss and because respiratory heat loss during isocapnic hyperventilation has been shown to give identical responses, we chose the latter provocational method in order to minimize increases in cardiac output that might interfere with the interpretation of mediator concentrations in arterial blood. Multiple aspects of pulmonary mechanics were also recorded before and after provocation. The results of these studies were then compared with the effects observed when the same subjects inhaled aerosols of specific antigens on the same day. Each challenge produced identical alterations in lung function, and neither was associated with consistent changes in arterial histamine. However, antigen provocation evoked a sustained and prolonged release of neutrophil chemotactic activity in each subject, whereas isocapnic hyperventilation with cold air was without effect. These data strongly suggest that mast-cell derived mediators are not involved in the development or maintenance of the bronchial obstruction that follows exercise in asthmatics.

Comparison of the respiratory responses to external resistive loading and bronchoconstriction.

The effects of resistive loads applied at the mouth were compared to the effects of bronchospasm on ventilation, respiratory muscle force (occlusion pressure), and respiratory sensations in 6 normal and 11 asthmatic subjects breathing 100% O2. External resistive loads ranging from 0.65 to 13.33 cm H2O/liter per s were applied during both inspiration and expiration. Bronchospasm was induced by inhalation of aerosolized methacholine. Bronchospasm increased ventilation, inspiratory airflow, respiratory rate, and lowered PACO2. External resistive loading, on the other hand, reduced respiratory rate and inspiratory flow, but left ventilation and PACO2 unaltered. FRC increased to a greater extent with bronchospasm than external flow resistive loads. With both bronchospasm and external loading, occlusion pressure increased in proportion to the rise in resistance to airflow. However, the change in occlusion pressure produced by a given change in resistance and the absolute level of occlusion pressure at comparable levels of airway resistance were greater during bronchospasm than during external loading. These differences in occlusion pressure responses to the two forms of obstruction were not explained by differences in chemical drive or respiratory muscle mechanical advantage. Although the subjects' perception of the effort involved in breathing was heightened during both forms of obstruction to airflow, at any given level of resistance the sense of effort was greater with bronchospasm than external loading. Inputs from mechanoreceptors in the lungs (e.g., irritant receptors) and/or greater stimulation of chest wall mechanoreceptors as a result of increases in lung elastance may explain the differing responses elicited by the two forms of resistive loading.

Protocol therapy for acute asthma: therapeutic benefits and cost savings.

BACKGROUND: To evaluate the therapeutic and financial benefits of protocol therapy for acute asthma using standard medications. MATERIALS AND METHODS: This study employed a sequential design in which the influence of an asthma care path on hospital admissions, length of stay (LOS) in the emergency department, and return visits were evaluated for 1 year. This information was contrasted with similar data obtained from the 8 months immediately before the protocol was implemented (preprotocol) and a 12-month period after strict adherence to it had declined (admixture). RESULTS: In all, 526 acute exacerbations of asthma were treated with the care path, and 429 and 558 episodes were evaluated during the preprotocol and admixture periods, respectively. There were no significant differences between the presenting clinical or physiologic features of any group. With the protocol, 77% of the patients resolved their symptoms within 1:47 +/- 0.02 hours:minutes of arrival in the emergency department with a 2% return rate within 24 hours. The algorithms used quickly identified those needing hospitalization. Patients not meeting the criteria for discharge after receiving the treatments employed typically did not resolve their symptoms for days (average hospital stay 4.1 +/- 0.2 days). Compared with the preprotocol period, the care path significantly reduced the LOS by 50 minutes, the number of urgent and intensive care unit admissions by 27% and 41%, respectively, and the frequency of return visits within 24 hours by 66%. Charges to patients and third-party payors decreased $395,000. When adherence to the protocol diminished, LOS, admissions, and returns rose significantly toward preprotocol values and the financial benefits were lost. CONCLUSIONS: Asthma protocol therapy, based primarily upon aggressive use of sympathomimetics in association with serial monitoring of key indices of improvement, provides prompt and efficient relief for acute exacerbations of asthma. Such an approach yields significant financial benefit while quickly identifying individuals who require hospitalization, and it also detects physician practice patterns that can have potentially detrimental impacts on patient care.

Hospital-acquired viral respiratory illness on a pediatric ward.

All 171 patients admitted to four study rooms containing cribs were under surveillance during the winter and spring for development of nosocomial respiratory and infection. One sixth of the 90 children at risk acquired respiratory illness while in the hospital. Viruses were isolated from two thirds of the patients with nosocomial infections: rhinovirus, respiratory syncytial virus, parainfluenza, and influenza A and B. Serial viral cultures of the children under surveillance suggested that nine of 11 virus-positive nosocomial infections were not acquired from a roommate. Furthermore, the risk to a patient of becoming infected with a virus being shed by a roommate was only 3%. The need for isolation of all children with respiratory illness in a single room with a separate air exhaust system is not suggested by these data.

Effects of verapamil on histamine-and carbachol-induced contraction of pulmonary tissues in vitro.

It has been hypothesized that calcium antagonists may be useful in the management of airway hyperreactivity. In these studies, we evaluated the effects of verapamil on guinea pig tracheal spirals and parenchymal lung strips in vitro. Preincubation of both tissues with verapamil caused concentration-dependent inhibition of contraction with significant effects noted at a 10 micromolar concentration. At this concentration of verapamil, approximately fivefold greater concentrations of either histamine or carbachol were required to produce contraction of tracheal spirals; and 21-fold greater concentrations of histamine and 630-fold greater concentrations of carbachol were required to contract parenchymal strips. We also assessed the ability of verapamil to reverse contraction. Significant reversal of both histamine- and carbachol induced contraction was observed with concentrations of 3 micromolar verapamil and contraction was nearly abolished with a 100 micromolar concentration. These data demonstrate that verapamil can both inhibit airway contraction and reverse contraction once it is present and further suggest that verapamil or other calcium antagonists may prove useful in the management of airway hyperreactivity.

Role of costal and crural diaphragm and parasternal intercostals during coughing in cats.

The inspiratory phase of coughs often consists of large inspired volumes and increased motor discharge to the costal diaphragm. Furthermore, diaphragm electrical activity may persist into the early expiratory portion of coughs. To examine the role of other inspiratory muscles during coughing, electromyograms (EMG) recorded from the crural diaphragm (Dcr) and parasternal intercostal (PSIC) muscles were compared to EMG of the costal diaphragm (Dco) in anesthetized cats. Tracheal or laryngeal stimulation typically produced a series of coughs, with variable increases in peak inspiratory EMGs of all three muscles. On average, peak inspiratory EMG of Dco increased to 346 +/- 60% of control (P less than 0.001), Dcr to 514 +/- 82% of control (P less than 0.0002), and PSIC to 574 +/- 61% of control (P less than 0.0005). Augmentations of Dcr and PSIC EMG were both significantly greater than of Dco EMG (P less than 0.05 and P less than 0.002, respectively). In most animals, EMG of Dco correlated significantly with EMG of Dcr and of PSIC during different size coughs. Electrical activity of all three muscles persisted into the expiratory portions of many (but not all) coughs. The duration of expiratory activity lasted on average 0.17 +/- 0.03 s for Dco, 0.25 +/- 0.06 s for Dcr, and 0.31 +/- 0.09 s for PSIC. These results suggest that multiple respiratory muscles are recruited during inspiration of coughs, and that the persistence of electrical activity into expiration of coughs is not unique to the costal diaphragm.

Effects of hypercapnia on inspiratory and expiratory muscle activity during expiration.

Persistence of inspiratory muscle activity during the early phase of expiratory airflow slows the rate of lung deflation, whereas heightened expiratory muscle activity produces the opposite effect. To examine the influence of increased chemoreceptor drive and the role of vagal afferent activity on these processes, the effects of progressive hypercapnia were evaluated in 12 anesthetized tracheotomized dogs before and after vagotomy. Postinspiratory activity of inspiratory muscles (PIIA) and the activity of expiratory muscles were studied. During resting breathing, the duration of PIIA correlated with the duration of inspiration but not with expiration. Parasternal intercostal PIIA was directly related to that of the diaphragm. Based on their PIIA, dogs could be divided into two groups: one with prolonged PIIA (mean 0.57 s) and the other with brief PIIA (mean 0.16 s). Hypercapnia caused progressive shortening of the PIIA in the dogs with prolonged PIIA during resting breathing. The electrical activity of the external oblique and internal intercostal muscles increased gradually during CO2 rebreathing in all dogs both pre- and postvagotomy. After vagotomy, abdominal activity continued to increase with hypercapnia but was less at all levels of PCO2. The internal intercostal response to hypercapnia was not affected by vagotomy. The combination of shorter PIIA and augmented expiratory activity with hypercapnia might, in addition to changes in lung recoil pressure and airway resistance, hasten exhalation.

Influence of respiratory drive on airway responses to excitation of lung C-fibers.

To determine whether the responses of tracheal smooth muscle and the nasal vasculature to stimulation of lung C-fiber receptors depend on the level of respiratory drive, the effects of right atrial injection of capsaicin and phenyldiguanide were studied in chloralose-anesthetized, paralyzed, artificially ventilated cats. Studies were performed while the animals were hyperventilated to apnea and, in addition, when breathing was stimulated by inhalation of 7% CO2 or by N-methyl-D-aspartic acid (NMDA) applied to the ventral surface of the medulla. When the cats were hyperventilated to apnea with O2, injection of capsaicin into the right atrium increased tracheal tone and slightly raised nasal resistance. However, when the animals were ventilated with 7% CO2 in O2 or respiratory activity was stimulated by the application of NMDA, administration of capsaicin eliminated spontaneous phrenic nerve activity and caused an abrupt decrease in tracheal tone but still increased nasal resistance. Similar responses were also obtained with right atrial injection of phenyldiguanide. These results showed for the first time that in the cat the direction of the reflex effects on tracheal tone but not nasal resistance depends on the preexisting level of respiratory drive and on cholinergic activity to airway smooth muscle.

Effects of bronchoconstriction on respiratory muscle activity during expiration.

The effect of methacholine-induced bronchoconstriction on the electrical activity of respiratory muscles during expiration was studied in 12 anesthetized spontaneously breathing dogs. Before and after aerosols of methacholine, diaphragm, parasternal intercostal, internal intercostal, and external oblique electromyograms were recorded during 100% O2 breathing and CO2 rebreathing. While breathing 100% O2, five dogs showed prolonged electrical activity of the diaphragm and parasternal intercostals in early expiration, postinspiratory inspiratory activity (PIIA). Aerosols of methacholine increased pulmonary resistance, decreased tidal volume, and elevated arterial PCO2. During bronchoconstriction, when PCO2 was varied by CO2 rebreathing, PIIA was shorter at low levels of PCO2, and external oblique and internal intercostal were higher at all levels of PCO2. Vagotomy shortened PIIA in dogs with prolonged PIIA. After vagotomy, methacholine had no effects on PIIA but continued to increase external oblique and internal intercostal activity at all levels of PCO2. These findings indicate that bronchoconstriction influences PIIA through a vagal reflex but augments expiratory activity, at least in part, by extravagal mechanisms.

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.

Respiratory changes in thoracic muscle length during bronchoconstriction.

The purpose of the present study was to assess the effects of bronchoconstriction on respiratory changes in length of the costal diaphragm and the parasternal intercostal muscles. Ten dogs were anesthetized with pentobarbital sodium and tracheostomized. Respiratory changes in muscle length were measured using sonomicrometry, and electromyograms were recorded with bipolar fine-wire electrodes. Administration of histamine aerosols increased pulmonary resistance from 6.4 to 14.5 cmH2O X l-1 X s, caused reductions in inspiratory and expiratory times, and decreased tidal volume. The peak and rate of rise of respiratory muscle electromyogram (EMG) activity increased significantly after histamine administration. Despite these increases, bronchoconstriction reduced diaphragm inspiratory shortening in 9 of 10 dogs and reduced intercostal muscle inspiratory shortening in 7 of 10 animals. The decreases in respiratory muscle tidal shortening were less than the reductions in tidal volume. The mean velocity of diaphragm and intercostal muscle inspiratory shortening increased after histamine administration but to a smaller extent than the rate of rise of EMG activity. This resulted in significant reductions in the ratio of respiratory muscle velocity of shortening to the rate of rise of EMG activity after bronchoconstriction for both the costal diaphragm and the parasternal intercostal muscles. Bronchoconstriction changed muscle end-expiratory length in most animals, but for the group of animals this was statistically significant only for the diaphragm. These results suggest that impairments of diaphragm and parasternal intercostal inspiratory shortening occur after bronchoconstriction; the mechanisms involved include an increased load, a shortening of inspiratory time, and for the diaphragm possibly a reduction in resting length.

Central effects of somatostatin and atrial natriuretic peptide on tracheal tone.

The effects of somatostatin and atrial natriuretic peptide applied topically to the ventral surface of the medulla (VMS) on tracheal tone and phrenic nerve activity (Phr) were studied in chloralose-anesthetized and paralyzed cats artificially ventilated with 7% CO2 in O2. Surface application of drugs to the chemosensitive areas of the VMS significantly decreased tracheal tension measured by changes in pressure in a balloon placed in a bypassed segment of the trachea (Ptseg). Application of somatostatin (9 cats) caused a mean decrease in Ptseg from 17.3 +/- 1.8 (SE) to 4.3 +/- 1.4 cmH2O (P < 0.01) and a reduction in Phr from 24.9 +/- 3.4 to 10.3 +/- 3.4 units (P < 0.05). Like somatostatin, application of atrial natriuretic peptide to the VMS (5 cats) produced tracheal relaxation (Ptseg decreased from 19.3 +/- 2.6 to 9.9 +/- 1.3 cmH2O, P < 0.01), but in contrast there was an insignificant reduction in Phr (from 18.5 +/- 3.6 to 16.1 +/- 3.8 units, P > 0.05). When parasympathetic activity was abolished by atropine methylnitrate and tracheal tone was restored with 5-hydroxytryptamine, somatostatin and atrial natriuretic peptide applied on the VMS had no effect on tracheal pressure, suggesting that observed changes were not caused by direct action of peptides on tracheal smooth muscle via the bloodstream or by facilitation of inhibitory pathways. Both somatostatin and atrial natriuretic peptide applications were associated with a slight but significant decrease in arterial blood pressure. These data suggest that somatostatin and atrial natriuretic peptide acting on the chemosensitive structure of the VMS may play significant roles in modulating para-sympathetic outflow to airway smooth muscle.

Effect of N-methyl-D-aspartate applied to the ventral surface of the medulla on the trachea.

Structures located near the ventral surface of the medulla (VMS) affect both cardiovascular tone and respiratory activity. In addition cooling the intermediate area of the VMS blocks the increases in parasympathetic activity and tracheal tone resulting from ventilation with hypercapnic or hypoxic gas mixtures, or due to stimulation of mechanoreceptors within the lung. Since cooling the surface of the VMS may affect fibers of passage as well as cell bodies, we performed studies in which pledgets containing N-methyl-D-aspartic acid (NMDA), a synthetic excitatory amino acid, were applied to intermediate area of the VMS. The studies were performed in chloralose-anesthetized, artificially ventilated cats. Application of pledgets containing NMDA (10(-7) mol at 10(-3) M) caused increases in tracheal pressure and the onset of phasic phrenic activity, but application of 10(-8) mol at 10(-4) M of NMDA could produce tracheal constriction without the appearance of phasic phrenic activity. Applying to the entire VMS either 2-amino-5-phosphonovalerate (2-APV, 10(-6) M), a specific antagonist to NMDA, or lidocaine (2%), a local anesthetic, 60 s before the application of pledgets containing NMDA, prevented the increase in tracheal tone and phasic phrenic activity. Intravenous administration of atropine methyl nitrate 0.5 mg/kg, a cholinergic antagonist, blocked tracheal responses to local application of pledgets containing NMDA but did not affect the increase in phasic phrenic nerve activity. These findings suggest that when stimulated, neurons near the surface of the VMS in the vicinity of the intermediate area increase the activity of parasympathetic fibers to the airway.

Effect of stimulation of pulmonary C-fiber receptors on canine respiratory muscles.

The effects of stimulation of pulmonary C-fiber receptors on the distribution of motor activity to upper airway, rib cage, and abdominal muscles were studied in anesthetized, tracheotomized, spontaneously breathing dogs. Stimulation of pulmonary C-fiber receptors by injection of capsaicin (3-20 micrograms/kg) into the right atrium resulted in complete cessation of electrical activity of the upper airway dilating muscles (UADM) and the inspiratory chest wall pumping muscles. The activity of abdominal muscles was also inhibited. The duration of electrical silence was longer for the diaphragm than for the UADM. Upper airway constricting muscles and expiratory intercostal muscles, including the triangularis sterni, remained tonically active during the apneic period. The responses of these muscles were qualitatively the same when the animals breathed 100% O2, 7% CO2 in O2, or 12% O2 in N2, and without or in the presence of an expiratory threshold load. Bilateral vagotomy abolished the inhibitory effects of capsaicin on UADM, chest wall, and abdominal muscle activity, suggesting that the vagus is the major afferent pathway for the reflex. The qualitative difference in the response of intercostal expiratory muscles and abdominal muscles suggests that these two groups of synergistic muscles may be independently regulated.

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.

Nasal and tracheal responses to chemical and somatic afferent stimulation in anesthetized cats.

Respiratory chemical and reflex interventions have been shown to affect nasal resistance or tracheal tone, respectively. In the present study, nasal caliber (assessed from pressure at a constant flow) and tracheal tone (assessed from pressure in a fluid-filled balloon within an isolated tracheal segment) were monitored simultaneously in anesthetized, paralyzed, artificially ventilated (inspired O2 fraction = 100%) cats. We examined the effect of CO2 inhalation and sciatic nerve stimulation as well as the application of nicotine (6 X 10(-4) mol/l) or lidocaine (2% solution) to the intermediate area of the ventral medullary surface (VMS). CO2 and VMS nicotine resulted in a significant increase in tracheal pressure [147 +/- 73 and 91 +/- 86% (SD), respectively]; and a significant reduction in nasal pressure (-35 +/- 10 and -20 +/- 13%, respectively). In contrast, sciatic nerve stimulation resulted in a significant fall in both tracheal (-50 +/- 36%) and nasal pressure (-21 +/- 13%). Application of 2 or 4% lidocaine to the VMS reduced tracheal pressure but did not significantly affect nasal pressure. After VMS lidocaine, nasal and tracheal responses to CO2, sciatic nerve stimulation, or VMS nicotine, when present, were negligible. These results suggest a role for the VMS in the regulation and coordination of nasal and tracheal caliber responses.

Cold air inhalation and esophageal temperature in exercising humans.

This study was performed to examine the dynamics and localization of respiratory heat exchange in exercising humans breathing cold air. Eight normal individuals performed 10 min of exercise at 80% of their predicted Vo2max with inspired air at 22 degrees C, saturated with water vapor; or at -40 degrees C, dry. Rectal temperature (Tre) and temperature at various locations along the length of the esophagus were measured during the exercise period. Temperature in the lower third of the esophagus was in close agreement with Tre and was unaffected by the level of respiratory heat exchange. Upper esophageal temperature decreased substantially during exercise, the magnitude of the decrease being dependent upon proximity to intrathoracic airways and the level of respiratory heat exchange (RHE). We conclude that with high levels of RHE, the capacity of the nasopharynx and upper airways to completely condition inspired air is exceeded. As a consequence, heat and water exchange occur in regions of the respiratory tract not normally involved in this function.