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Pain Medicine  |   December 2001
Unventilated Airway Is Time-dependently Constricted in Paralyzed Dogs
Author Affiliations & Notes
  • Kazuyoshi Hirota, M.D.
    *
  • Eiji Hashiba, M.D.
  • Shizuko Kabara, M.D.
  • Hideki Yoshioka, M.D.
  • Hironori Ishihara, M.D.
    §
  • Akitomo Matsuki, M.D.
  • * Assistant Professor, † Clinical and Research Fellow, ‡ Postgraduate Student, § Associate Professor, ∥ Professor and Chairman.
  • Received from the Department of Anesthesiology, University of Hirosaki School of Medicine, Hirosaki, Japan.
Article Information
Pain Medicine
Pain Medicine   |   December 2001
Unventilated Airway Is Time-dependently Constricted in Paralyzed Dogs
Anesthesiology 12 2001, Vol.95, 1480-1484. doi:
Anesthesiology 12 2001, Vol.95, 1480-1484. doi:
ANESTHESIOLOGISTS often treat apnea patients in the emergency room, the intensive care unit, and the operating room. Moreover, they sometimes experience difficult ventilation during induction of anesthesia and manage one-lung ventilation during thoracic surgery. However, the influence of apnea or the absence of ventilation on the airway tone is not fully understood.
Apnea causes hypoxia, hypercapnia, and acidosis, and these modulate airway smooth muscle tone. 1–7 Several articles 2,8,9 indicate that apnea (except hypocapnic apnea) produces airway constriction. Several in vitro  studies 4,5 show that hypoxia impairs the contractile function of airway smooth muscle strips. However, in vivo  studies 2,3,7 suggest that hypoxia produces airway constriction. Similarly, hypercapnia and decrease in intracellular p  H have been reported to produce airway smooth muscle relaxation in vitro  5,6 and increase in pulmonary resistance or airway tone in vivo  . 1,7 
In addition, each inspiration and expiration also changes airway tone via  pulmonary stretch receptors. 10 Mitchell et al.  10 reported that the major excitatory input to airway smooth muscle arises from cholinergic nerves that fire during inspiration. They also found that airway smooth muscle contraction occurs at each inspiration. 4 In addition to slowly adapting stretch receptors, rapidly adapting stretch receptors, bronchial C fibers and pulmonary C fibers, which are vagal afferent nerves, exist in the airway and contribute to the modulation of airway tone. 11 Therefore, some of these afferent nerves may be involved in the mechanism of the bronchoconstriction.
Although apnea may induce airway constriction, it remains unknown whether airway constriction occurs only during the absence of ventilation of the whole lung or in the unventilated airways even though other airways are ventilated, e.g.  , one-lung ventilation. In this study, to determine whether the airway constriction is due to hypercapnia, hypoxemia, acidosis, or the absence of inflation of the whole lung or of some lobes (e.g.  , one lung), we studied the effect of apnea and one-lung ventilation on bronchial tone in intact and vagotomized dogs using our previously reported bronchoscopic method. 12–15 
Materials and Methods
Our study protocol was approved by Animal Care and Use Committee of the University of Hirosaki School of Medicine (Hirosaki, Japan). Twenty-one adult mongrel dogs (8–12 kg) were anesthetized with intravenous pentobarbital (30 mg/kg + 2.0 mg · kg1· h1) and were assigned to three groups: an apnea–100% O2group (n = 7), an apnea plus vagotomy group (n = 7), and a one-lung ventilation group (n = 7). The lungs of these dogs were ventilated with 100% O2. The tracheas were intubated with single- or double-lumen endotracheal tubes in the apnea and apnea plus vagotomy or one-lung ventilation groups, respectively. The distal cuff of the double lumen endotracheal tube was inflated in the left lung. Neuromuscular blockade was obtained with pancuronium at 0.2 mg · kg1· h1for mechanical ventilation with oxygen using a volume-controlled respirator (Servoventilator 900C; Siemens-Elema AB, Solna, Sweden), and end-tidal carbon dioxide was maintained at 4.0–4.5%. The femoral artery was cannulated for monitoring of arterial blood pressure and blood sampling. The femoral vein was also cannulated for insertion of a double-lumen catheter through which fluid and drugs were administered. In the apnea plus vagotomy group, the vagus nerves were isolated and then cut bilaterally.
In addition, to determine whether inspiratory O2concentration affected the results, seven dogs were studied with the same protocol as the apnea–100% O2group, except that apnea was produced after ventilation with 50% O2plus 50% N2(apnea–50% O2group). In this group, we measured airway tone not only during apnea but also after ventilation was restarted.
In all groups, the bronchial cross-sectional area (BCA) of the third bronchial bifurcation in the right lung was monitored via  a superfine fiberoptic bronchoscope (2.2 mm OD, AF type 22A; Olympus, Tokyo, Japan) to assess bronchial tone as reported previously. 12–15 Briefly, the image of the third bifurcation was printed out with a video printer (VY-170; Hitachi, Tokyo, Japan) during the end-expiratory pause and then was taken into a Macintosh computer (Power Macintosh 7100/80 AV; Apple Computer Inc, Cupertino, CA) by the scanner (Scan-Jet 4c; Hewlett Packard Co., Singapore) to measure the BCA using image-analyzing software (MacSCOPE 2.56; Mitani Co., Fukui, Japan). This image processing was performed by an investigator who was blinded to the study protocol.
In the apnea–100% O2and apnea plus vagotomy groups, a respirator was turned off at the end-expiratory pause to produce apnea for 5 min. However, in the apnea–50% O2group, the respirator was turned off only for 3 min because we preliminarily found that apnea for more than 3 min causes hypoxemia (< 60 mmHg). In the one-lung ventilation group, the right-sided lumen was blocked for 5 min to cause an absence of ventilation of the right lung, and 15 min later, the left-sided lumen was blocked for 5 min to cause only right-lung ventilation. The BCA was assessed before and 1, 2, and 3 min after the ventilator was turned off (at the end-expiratory pause) and on again in the apnea–50% O2group, and it was assessed before and 1, 2, 3, 4, and 5 min after absence of ventilation began in the other groups. When the ventilator was turned off or one-lung ventilation was started, the lumen of the endotracheal tube was occluded by the clamp. In addition, arterial blood (1 ml) was simultaneously sampled to assess arterial oxygen tension (Pao2), arterial carbon dioxide tension (Paco2), and p  H.
Statistical Analysis
All data are expressed as mean ± SD. The BCA is presented as percent of basal BCA. Data were appropriately analyzed with one-way or two-way repeated-measures analysis of variance followed by Student-Newman-Keuls test using Sigma Stat for Windows (Jandel Scientific Software, Chicago, IL). P  < 0.05 was considered significant.
Results
Effects of Apnea on the Airway Tone
In the apnea plus vagotomy group, vagotomy increased the basal BCA by 10.3 ± 9.7%. After the start of apnea, BCA decreased time-dependently in the apnea–100% O2group, whereas it did not in the apnea plus vagotomy group (fig. 1). In the apnea–50% O2group, BCA was reduced time-dependently, similar to the apnea–100% O2group. In addition, the reduction in BCA rapidly returned to baseline after ventilation was restarted (fig. 2).
Fig. 1. Changes in percent of bronchial cross-sectional area after apnea started. Apnea–100% O2group: apnea after inhalation of 100% O2; *P  < 0.05, **P  < 0.01 versus  apnea–100% O2group. All values are presented as mean ± SD.
Fig. 1. Changes in percent of bronchial cross-sectional area after apnea started. Apnea–100% O2group: apnea after inhalation of 100% O2; *P 
	< 0.05, **P 
	< 0.01 versus 
	apnea–100% O2group. All values are presented as mean ± SD.
Fig. 1. Changes in percent of bronchial cross-sectional area after apnea started. Apnea–100% O2group: apnea after inhalation of 100% O2; *P  < 0.05, **P  < 0.01 versus  apnea–100% O2group. All values are presented as mean ± SD.
×
Fig. 2. Changes in percent of bronchial cross-sectional area during apnea and after rebreathing was started. The lungs were ventilated with 50% O2and 50% N2before and after apnea (apnea–50% O2group). All values are presented as mean ± SD.
Fig. 2. Changes in percent of bronchial cross-sectional area during apnea and after rebreathing was started. The lungs were ventilated with 50% O2and 50% N2before and after apnea (apnea–50% O2group). All values are presented as mean ± SD.
Fig. 2. Changes in percent of bronchial cross-sectional area during apnea and after rebreathing was started. The lungs were ventilated with 50% O2and 50% N2before and after apnea (apnea–50% O2group). All values are presented as mean ± SD.
×
Apnea also significantly decreased Pao2and p  H and increased Paco2in the apnea–50% O2, apnea–100% O2, and apnea plus vagotomy groups (tables 1 and 2). However, hypoxemia (< 60 mmHg) was not seen in all dogs of the apnea–50% O2group. In the apnea–100% O2group, no dogs showed hypoxemia until 4 min after apnea started, but 6 of 14 dogs did 5 min after apnea started. In addition, Pao2rapidly returned to baseline after ventilation was restarted in the apnea–50% O2group (table 2).
Table 1. Changes in pH, Paco2, and Pao2during Apnea after Ventilation with 100% O2
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Table 1. Changes in pH, Paco2, and Pao2during Apnea after Ventilation with 100% O2
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Table 2. Changes in pH, Paco2, and Pao2during Apnea after Ventilation with 50% O2and after Rebreathing
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Table 2. Changes in pH, Paco2, and Pao2during Apnea after Ventilation with 50% O2and after Rebreathing
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Effects of One-lung Ventilation on the Airway Tone
In the one-lung ventilation group, the BCA of the unventilated lung decreased time dependently, whereas the area of the ventilated lung did not change (fig. 3). Paco2slightly increased from 44 ± 7 to 46 ± 5 mmHg 5 min after one-lung ventilation was started. In addition, although Pao2significantly decreased from 468 ± 59 to 131 ± 158 mmHg, hypoxemia was seen in only 1 of 12 dogs (Pao2= 59 mmHg;table 3).
Fig. 3. Changes in percent of bronchial cross-sectional area of right lung after one-lung ventilation was started. Ventilation (+): right lung was ventilated; ventilation (−): right lung was not ventilated; *P  < 0.05, **P  < 0.01 versus  ventilation (+). All values are presented as mean ± SD.
Fig. 3. Changes in percent of bronchial cross-sectional area of right lung after one-lung ventilation was started. Ventilation (+): right lung was ventilated; ventilation (−): right lung was not ventilated; *P 
	< 0.05, **P 
	< 0.01 versus 
	ventilation (+). All values are presented as mean ± SD.
Fig. 3. Changes in percent of bronchial cross-sectional area of right lung after one-lung ventilation was started. Ventilation (+): right lung was ventilated; ventilation (−): right lung was not ventilated; *P  < 0.05, **P  < 0.01 versus  ventilation (+). All values are presented as mean ± SD.
×
Table 3. Effects of One-lung Ventilation on pH, Paco2, and Pao2
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Table 3. Effects of One-lung Ventilation on pH, Paco2, and Pao2
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Discussion
In the current study, during apnea, BCA decreased in a time-dependent manner with a decrease in Pao2and an increase in Paco2. Several factors should be considered to understand the mechanism of apnea-induced bronchoconstriction.
Apnea causes hypoxia and hypercapnia. Previous in vitro  studies 4–6 show that these attenuate contraction of airway smooth muscles. In contrast, in vivo  studies 1–3,7 suggest that these may induce airway constriction. Iscoe and Fisher 7 showed that pulmonary resistance in response to hypoxia (fraction of inspired oxygen [Fio2]= 0.1) and to hypercapnia (inhalation of 5% CO2) increased by 49% and 59%, respectively, in decerebrate cats. In the current study, although hypercapnia and respiratory acidosis occurred in all dogs, bronchoconstriction was observed even without hypoxia. Therefore, hypoxia may not be a main contributor to apnea-induced airway constriction.
The report of Iscoe and Fisher 7 suggests that the airway constriction may occur by means of hypercapnia and that it could be abolished by atropine or vagotomy, similar to the current study showing that vagotomy abolished apnea-induced bronchoconstriction. However, in the one-lung ventilation group, despite the fact that Paco2increased by only 2 mmHg 5 min after one-lung ventilation was started, the BCA of unventilated lung time-dependently decreased. Therefore, it is unlikely that hypercapnia is a main factor for apnea-induced airway constriction.
It is known that absorption atelectasis easily occurs by means of a high inspired O2concentration. 16 In addition, as apnea substantially decreases the ventilation–perfusion ratio, 16 lung collapse is likely to occur and may reflect reduction in BCA. However, it is also known that a lower inspired O2concentration causes lung collapse more slowly. 16 However, in the current study, reduction in BCA in the apnea–50% O2group was not less than that in the apnea–100% O2group. In addition, the reduction was not observed even after ventilation with 100% O2in vagotomized dogs. Therefore, the passive collapse is not involved in bronchoconstriction.
An in vitro  study reported by Fredberg et al.  17 clearly showed that tidal stretch of airway smooth muscles attenuates active force or muscle stiffness. Such stretching of airway smooth muscle during tidal breathing may contribute to attenuation of bronchoconstriction. In fact, the airways in normal humans and dogs do not constrict to closure even when maximally stimulated. 18 In contrast, maximal stimulation can produce airway closure in isolated lobes and bronchial segments. 18 Thus, in the absence of tidal stretch, such as apnea, airway narrowing may easily occur. However, Fredberg et al.  17 reported that the attenuation of active force or muscle stiffness by tidal stretch may not be neurally mediated because tetrodotoxin did not affect the results. The current study shows that because vagotomy abolished apnea-induced airway narrowing, tidal stretch may not be involved in the mechanism.
The fact that vagotomy completely abolished apnea-induced bronchoconstriction suggests involvement of the neural reflex. Similarly, Brown et al.  19 also reported that breath holding after ventilation with 100% O2produces airway narrowing, which can be antagonized by atropine pretreatment. It is known that activation of airway afferent nerve fibers results in reflexes that serve to protect the airways. 11 Because vagotomy or atropine abolished the bronchoconstriction during apnea, the afferent neurons of the vagus nerve should be involved in the mechanism of apnea-induced bronchoconstriction. The afferent neurons have been classified into four subclasses: slowly adapting stretch receptors, rapidly adapting stretch receptors (irritant receptors), pulmonary C fibers, and bronchial C fibers. 11 Therefore, some of these vagal afferent nerves may be involved in apnea-induced bronchoconstriction.
The slowly adapting stretch receptors are located in the tracheobronchial tree but are concentrated in the large conducting airway and have an important role in the Hering-Breuer reflex. 11 In addition, the activation of these units decreases parasympathetic drive to the airway and leads to airway smooth muscle relaxation during inflation. 11 Therefore, it is possible that as a consequence of reduction of the slowly adapting stretch receptors by apnea, an increase in the parasympathetic drive may lead to bronchoconstriction. The current data showing that vagotomy abolished bronchoconstriction support this hypothesis.
The rapidly adapting receptors are located in circumference of the entire tracheobronchial tree but are concentrated in the large airway. 11 These receptors respond to mechanical stimulation with a burst of action potential during the dynamic phase and then rapidly adapt during the static phase of stimuli, although the activity of these receptors is not coordinated with inspiration or expiration of normal tidal breathing. 11 Relatively large changes in transmural pressure, evoked by either distention or collapse of the airway, are required to activate the rapidly adapting receptors. 11 In addition, activation of some of these fibers is known to produce cough, bronchoconstriction, and secretion, and these fibers are found in the large airway. 11 The current study shows that volumes of the large airway may not change for 5 min of apnea because BCA did not change in the vagotomized dogs. Therefore, unchanged volume in the large airway may not lead to bronchoconstriction, i.e.  , the rapidly adapting stretch receptors may not be involved.
The classification of pulmonary and bronchial C fibers are based on their location in the peripheral airways (J receptors) and the large airways, respectively. 11 Both C fibers are mechanically sensitive, and stimulation of these fibers results in defensive pulmonary reflexes, such as cough, apnea, bronchoconstriction, and mucous secretion. 11 Both C fibers are stimulated by hyperinflation of the lung but not by deflation. 11 In addition, a considerable increase in Paco2stimulates bronchial C fibers. 11 However, bronchoconstriction was observed without a considerable increase in Paco2in the one-lung ventilation group. Therefore, both C fibers may be uninvolved in apnea-induced bronchoconstriction.
Pentobarbital per se  has been reported to attenuate the airway reflex. 7 However, because vagotomy increased BCA by 10% during pentobarbital anesthesia in the current study, the dose of pentobarbital used could not inhibit the reflex completely. Similarly, using high-resolution computed tomography, Brown et al.  19 reported that 0.2 mg/kg atropine caused an increase in baseline airway area to 115 ± 5% during thiopental anesthesia in dogs. The bronchodilation could be due to blockade of parasympathetic drive to the airway by vagotomy or atropine.
Pancuronium was used to prevent spontaneous breathing during apnea in the current study. Cembela et al.  20 showed that a clinical concentration of pancuronium inhibits muscarinic receptor subtype M2 rather than M1 or M3. Okanlami et al.  21 also reported that a small dose of pancuronium produces M2 antagonistic effects and M3 effects predominantly at the larger dose. Because M2 activation inhibits the release of acetylcholine, 22 M2 antagonism by pancuronium is likely to potentiate vagally mediated bronchoconstriction. 21,23 Therefore, apnea-induced bronchoconstriction may also be potentiated by pancuronium.
In the current study, we used a fiberoptic bronchoscopy method to assess airway caliber. Although airway caliber has classically been assessed with indirect measurement methods, such as airway resistance and compliance, direct methods are more specific than the indirect ones that Brown et al.  24 reported. Therefore, we have developed a portable direct method using a fiberoptic bronchoscope. 12 To validate our method, we previously compared changes in BCA with percent of dynamic pulmonary compliance (%Cdyn) and percent of airway resistance (%Raw) in a histamine bronchoconstriction model. We observed that the %BCA completely returned to the prehistamine value by means of intravenous epinephrine, yet %Cdynand %Rawdid not. 12 In addition, there was a significant correlation between %BCA and %Cdynor %Raw. 12 Therefore, the bronchoscopic method can assess airway caliber more specifically than indirect ones can. 12 
In conclusion, the current study shows that the unventilated airway constricts spontaneously. This constriction could be vagally mediated (maybe slowly adapting stretch receptors) but is not due to hypoxia and hypercapnia. Further studies are required to elucidate the mechanism.
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Fig. 1. Changes in percent of bronchial cross-sectional area after apnea started. Apnea–100% O2group: apnea after inhalation of 100% O2; *P  < 0.05, **P  < 0.01 versus  apnea–100% O2group. All values are presented as mean ± SD.
Fig. 1. Changes in percent of bronchial cross-sectional area after apnea started. Apnea–100% O2group: apnea after inhalation of 100% O2; *P 
	< 0.05, **P 
	< 0.01 versus 
	apnea–100% O2group. All values are presented as mean ± SD.
Fig. 1. Changes in percent of bronchial cross-sectional area after apnea started. Apnea–100% O2group: apnea after inhalation of 100% O2; *P  < 0.05, **P  < 0.01 versus  apnea–100% O2group. All values are presented as mean ± SD.
×
Fig. 2. Changes in percent of bronchial cross-sectional area during apnea and after rebreathing was started. The lungs were ventilated with 50% O2and 50% N2before and after apnea (apnea–50% O2group). All values are presented as mean ± SD.
Fig. 2. Changes in percent of bronchial cross-sectional area during apnea and after rebreathing was started. The lungs were ventilated with 50% O2and 50% N2before and after apnea (apnea–50% O2group). All values are presented as mean ± SD.
Fig. 2. Changes in percent of bronchial cross-sectional area during apnea and after rebreathing was started. The lungs were ventilated with 50% O2and 50% N2before and after apnea (apnea–50% O2group). All values are presented as mean ± SD.
×
Fig. 3. Changes in percent of bronchial cross-sectional area of right lung after one-lung ventilation was started. Ventilation (+): right lung was ventilated; ventilation (−): right lung was not ventilated; *P  < 0.05, **P  < 0.01 versus  ventilation (+). All values are presented as mean ± SD.
Fig. 3. Changes in percent of bronchial cross-sectional area of right lung after one-lung ventilation was started. Ventilation (+): right lung was ventilated; ventilation (−): right lung was not ventilated; *P 
	< 0.05, **P 
	< 0.01 versus 
	ventilation (+). All values are presented as mean ± SD.
Fig. 3. Changes in percent of bronchial cross-sectional area of right lung after one-lung ventilation was started. Ventilation (+): right lung was ventilated; ventilation (−): right lung was not ventilated; *P  < 0.05, **P  < 0.01 versus  ventilation (+). All values are presented as mean ± SD.
×
Table 1. Changes in pH, Paco2, and Pao2during Apnea after Ventilation with 100% O2
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Table 1. Changes in pH, Paco2, and Pao2during Apnea after Ventilation with 100% O2
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Table 2. Changes in pH, Paco2, and Pao2during Apnea after Ventilation with 50% O2and after Rebreathing
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Table 2. Changes in pH, Paco2, and Pao2during Apnea after Ventilation with 50% O2and after Rebreathing
×
Table 3. Effects of One-lung Ventilation on pH, Paco2, and Pao2
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Table 3. Effects of One-lung Ventilation on pH, Paco2, and Pao2
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