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The Predisposition to Inspiratory Upper Airway Collapse during Partial Neuromuscular Blockade

Klinik für Anästhesiologie und Intensivmedizin, and Klinik für Diagnostische Radiologie, Universitätsklinikum Essen; and Universität Duisburg-Essen, Essen, Germany

Correspondence and requests for reprints should be addressed to Priv. Doz. Dr. Matthias Eikermann, Oberarzt der Klinik für Anästhesiologie und Intensivmedizin, Universitätsklinikum Essen, Hufelandstrasse 55, D-45122 Essen, Germany. E-mail: meikermann{at}rics.bwh.harvard.edu

	ABSTRACT

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Rationale: Partial neuromuscular transmission failure by acetylcholine receptor blockade (neuromuscular blockade) or antibody-mediated functional loss (myasthenia gravis), even with a magnitude of muscle weakness that does not evoke respiratory symptoms, can evoke dysphagia and decreased inspiratory airflow, and increases the risk of susceptible patients to develop severe pulmonary complications.

Objectives: To assess whether impaired neuromuscular transmission predisposes individuals to inspiratory upper airway collapse, we assessed supraglottic airway diameter and volume by respiratory-gated magnetic resonance imaging, upper airway dilator muscle function (genioglossus force and EMG), and changes in lung volume, respiratory timing, and peripheral muscle function before, during, and after partial neuromuscular blockade in healthy, awake volunteers.

Measurements and Main Results: Partial neuromuscular blockade (train-of-four [TOF] ratio: 0.5 and 0.8) was associated with the following: (1) a decrease of inspiratory retropalatal and retroglossal upper airway volume to 66 ± 22 and 82 ± 12% of baseline, which was significantly more intense in the retropalatal area; (2) an attenuation of the normal increase in anteroposterior upper airway diameter during forced inspiration to 74 ± 18% of baseline; (3) a decrease in genioglossus activity during maximum voluntary tongue protrusion to 39 ± 19% (TOF, 0.5) and 73 ± 29% (TOF, 0.8) of baseline; and (4) no effects on upper airway size during expiration, lung volume, and respiratory timing.

Conclusions: Thus, impaired neuromuscular transmission, even to a degree insufficient to evoke respiratory symptoms, markedly impairs upper airway dimensions and function. This may be explained by an impairment of the balance between upper airway dilating forces and negative intraluminal pressure generated during inspiration by respiratory "pump" muscles.

Key Words: partial neuromuscular transmission failure • forced inspiration • upper airway size • upper airway dilator muscles • lung volume

AT A GLANCE COMMENTARY TOP ABSTRACT AT A GLANCE COMMENTARY METHODS RESULTS DISCUSSION REFERENCES   Scientific Knowledge on the Subject It is unclear how important neuromuscular factors (in the absence of anatomic insufficiency) are in the pathogenesis of obstructive sleep apnea (OSA). What This Study Adds to the Field Our data show that impaired neuromuscular transmission, even to a degree insufficient to evoke respiratory symptoms, markedly impairs upper airway dimensions and function of the upper airway dilator muscles.

 
Partial neuromuscular transmission failure by acetylcholine receptor blockade (neuromuscular blockade) or antibody-mediated functional loss (myasthenia gravis), evokes dysphagia (1, 2), aspiration (1, 2), and a decrease in maximum airflow during inspiration (3–5). These signs and symptoms (1–5) are observed even with a magnitude of muscle weakness insufficient to evoke respiratory symptoms or a decrease in vital capacity (3–5), suggesting that upper airway muscles are susceptible to neuromuscular blockade.

The impetus for studying the effects of partial paralysis on upper airway function has been twofold. First, partial paralysis may serve as a model of upper airway behavior with low muscle tone, as observed during sleep in healthy individuals due to loss of a "wakefulness" stimulus (6), which is particularly marked in patients with obstructive sleep apnea (OSA) (7–10). This is interesting in terms of the pathophysiology of OSA, because effects of decreased muscle tone can be isolated from other pathogenetic factors of OSA, such as abnormalities in the anatomy of the pharynx, and instability of ventilatory control (8–10).

Second, partial neuromuscular transmission failure from residual effects of neuromuscular blocking agents (train-of-four [TOF] ratio of the adductor pollicis muscle of 0.5–0.9) is an issue after anesthesia and in critical care medicine. In fact, partial paralysis may persist more than 7 d (11), but is difficult to detect clinically (12). Moreover, residual neuromuscular blockade increases anesthesia-associated mortality (13), which may be explained by an increased risk of severe postoperative pulmonary complications observed with a postoperative TOF ratio less than 0.8 (14). Thus, investigating upper airway behavior is also important in the context of postoperative complications, especially in patients at risk for upper airway obstruction, such as patients with sleep apnea.

Therefore, we assessed effects of partial neuromuscular blockade on upper airway volume and dimensions, genioglossus muscle function, lung volume, and respiratory timing.

	METHODS

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Subjects
After approval by the local ethics committee and informed, written consent, we enrolled 10 healthy male volunteers (age, 36 ± 4 yr [mean ± SD]) of normal height (186 ± 7 cm), weight (82 ± 12 kg), and body mass index (24 ± 1) not taking chronic medications.

Techniques
T1-weighted images in transverse and sagittal orientations were obtained using a 1.5-T scanner (Magnetom Sonata; Siemens, Erlangen, Germany) in the retropalatal and retroglossal region (i.e., from the top of the hard palate to the vocal cords) (Figure 1) (15). The analysis of magnetic resonance data was split into two domains: (1) assessment of upper airway volume and minimal cross-sectional area in the transverse orientation during quiet breathing (Figure 2) and (2) functional exploration of the upper airway during forced inspiration in the sagittal plane to evaluate minimum retroglossal upper airway diameter. Acquisition of images was triggered by respiratory excursions using a respiratory belt (Siemens "Physiological Measurements Unit") (16).

View larger version (137K): [in this window] [in a new window]   Figure 1. A representative T1-weighted spin echo magnetic resonance midsagittal image of a subject before neuromuscular blockade (baseline). Two distinct regions were identified: the retropalatal and the retroglossal part of the upper airway.

View larger version (142K): [in this window] [in a new window]   Figure 2. A representative T1-weighted spin echo magnetic resonance axial image in the retropalatal region. Image was generated before neuromuscular blockade (baseline). The important anatomic structures are indicated. A = anterior; R = right.

Changes in end-expiratory lung volume were measured with two pairs of magnetometers (EOL Eberhard, Oberwil, Switzerland) placed in the anteroposterior (AP) axis of the chest and abdomen (19, 20). Subjects breathed through a nasal mask (Respironics, Murraysville, PA) with airflow measured with a calibrated pneumotachograph (Hans Rudolf, Kansas City, MO), which we used for calculation of respiratory timing (main variable: flow rate [VT/TI]). Magnetometers were calibrated to volumes obtained from pneumotachography and changes in end-expiratory lung volumes were determined using a previously validated formula (19, 20). We compared values recorded at baseline with those obtained during and after neuromuscular blockade. At each measurement, we analyzed and averaged values of variables obtained from 12 consecutive breaths.

Neuromuscular blockade was evoked by rocuronium, and was monitored by accelerometry of the adductor pollicis muscle (TOF-Watch SX; Organon, Roseland, NJ) (TOF stimulation of the ulnar nerve) (3). During the magnetic resonance imaging (MRI) study, we evaluated, in parallel, volunteers' grip strength.

Protocol
Subjects were studied on two or three different study days. In 10 volunteers, we measured upper airway anatomy (MRI). On another study day, we measured in the same volunteers force and EMG activity of the genioglossus muscle. Six of the 10 volunteers were studied a third time to evaluate possible effects of partial neuromuscular blockade on lung volume and respiratory timing. With all protocols, measurements were performed at baseline, at TOF ratios of 0.5, 0.8, and 1.0 (recovery), and 15 min after recovery, as depicted in Figure E1.

Statistical Analysis
On the basis of data showing that effects of partial neuromuscular blockade on forced and peak inspiratory flow are significantly greater than those on expiratory flow variables (3, 4), we tested the a priori hypothesis that inspiratory upper airway volume during quiet breathing would be lower during partial paralysis (TOF ratio, 0.5 and 0.8). Differences in values during neuromuscular blockade were compared with baseline values using paired t tests. Means and SD were used to summarize continuous variables. Additional details on the methods for making these measurements are provided in the online supplement.

	RESULTS

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MRI
Upper airway volume during quiet breathing (respiratory gated transverse images).
At baseline and with recovery from neuromuscular blockade, upper airway volume was always greater at end inspiration than at end expiration (24.89 ± 5.2 vs. 22.15 ± 4.2 ml at baseline, p < 0.05). During partial neuromuscular blockade, end-inspiratory upper airway volume decreased to a minimum of 78 ± 11% of baseline, remained significantly decreased even with recovery of the TOF ratio to 0.8 (88 ± 9%), and recovered to baseline values with recovery of the TOF ratio to unity. End-expiratory upper airway volume did not change during partial neuromuscular blockade. At a TOF ratio of 0.5, end-inspiratory upper airway volume was even lower than end-expiratory values (19.35 ± 4.2 vs. 22.13 ± 4.22 ml, p < 0.05), as depicted in Figure 3.

View larger version (8K): [in this window] [in a new window]   Figure 3. End-inspiratory and end-expiratory upper airway volume before neuromuscular blockade (baseline) at a steady-state train-of-four (TOF) ratio of 0.5 and 0.8, after recovery of the TOF ratio to 1.0, and 15 min later. Before neuromuscular blockade and with recovery from neuromuscular blockade, end-inspiratory volume was significantly greater than end-expiratory volume. End-inspiratory volume decreased significantly during partial neuromuscular blockade, and was even lower than end-expiratory upper airway volume at a TOF ratio of 0.5. *p < 0.05 for decrease in volume at end inspiration versus baseline; #p < 0.05 for increase in end-inspiratory volume versus end-expiratory volume (same TOF ratio); +p < 0.05 for decrease in end-inspiratory volume versus end-expiratory volume (same TOF ratio).

View larger version (10K): [in this window] [in a new window]   Figure 4. Upper airway volume at end inspiration (quiet breathing) before neuromuscular blockade, at a steady-state TOF ratio of 0.5 and 0.8, after recovery of the TOF ratio to 1.0, and 15 min later. Upper panel: retroglossal area; lower panel: retropalatal area. During partial neuromuscular blockade, upper airway volume decreased significantly both in the retroglossal and retropalatal part of the upper airway, but was no longer significantly different from baseline values with recovery of the TOF ratio to 1.0. However, 4 of 10 volunteers still showed a marked impairment of retropalatal airway volume despite recovery of the TOF ratio to unity, which disappeared within 15 min. *p < 0.05 versus baseline.

View larger version (13K): [in this window] [in a new window]   Figure 5. Changes in upper airway volume at end inspiration (quiet breathing) from baseline during steady-state neuromuscular blockade. The percentage decrease of retroglossal and retropalatal upper airway volume. At a TOF ratio of 0.5, upper airway volume decrease was significantly greater in the retropalatal area compared with the retroglossal area. *p < 0.05 versus retroglossal area.

View larger version (9K): [in this window] [in a new window]   Figure 6. Minimum cross-sectional area at end inspiration of the retroglossal and retropalatal part of the upper airway. Measurements during quiet breathing before neuromuscular blockade (baseline) at a steady-state TOF ratio of 0.5 and 0.8, after recovery of the TOF ratio to 1.0, and 15 min later. During neuromuscular blockade, airway cross-sectional area decreased significantly in both regions of the upper airway and recovered to baseline values with a TOF ratio of unity. The smallest cross-sectional area of the retropalatal area was significantly less than the smallest cross-sectional area of the retroglossal area of the upper airway. *p < 0.05 versus baseline values; +p < 0.05 versus retroglossal cross-sectional area (at same TOF ratio).

In contrast, during forced inspiration with neuromuscular transmission intact, minimal retroglossal upper airway diameter increased markedly from 9.0 ± 3.1 to 20.2 ± 5.2 mm (p < 0.01; see movies E1 and E2 in the online supplement). During partial paralysis, however, the increase of minimal retroglossal upper airway diameter during forced inspiration was attenuated and amounted to 74 ± 18 and 81 ± 18% of baseline (p < 0.05; Figure 7) at TOF ratios of 0.5 and 0.8, respectively. The retroglossal upper airway diameter increase observed during forced inspiration recovered to baseline values with recovery of the TOF ratio to unity.

View larger version (31K): [in this window] [in a new window]   Figure 7. Minimum retroglossal upper airway diameter during forced inspiration (A) before neuromuscular blockade (baseline), at a steady-state TOF ratio of (B) 0.5 and (C) 0.8, (D) after recovery of the TOF ratio to 1.0, and (E) 15 min later. Assessments were performed in the anteroposterior orientation within the median sagittal plane 150–300 ms after onset of inspiration. Images from the volunteer show that a partial paralysis evokes an impairment of upper airway diameter increase during forced inspiration. *p < 0.05 versus baseline.

End-Expiratory Lung Volume and Respiratory Timing
End-expiratory lung volume and respiratory timing did not change significantly during partial neuromuscular blockade. Mean differences from baseline of end-expiratory lung volume amounted to –9 ± 203, 42 ± 169, 97 ± 252, and –56 ± 54 ml at TOF ratios of 0.5, 0.8, and 1.0, and 15 min later, respectively. At the same measurement points, inspiratory flow rates (VT/TI) remained unchanged, amounting to 0.35 ± 0.04, 0.33 ± 0.05, 0.32 ± 0.05, and 0.33 ± 0.03 L/s, respectively.

At baseline, VT, TI, and respiratory rate amounted to 0.62 ± 0.03 L, 1.64 ± 0.23 s, and 13 ± 3.3 min^–1, respectively, and values did not change significantly during neuromuscular blockade.

Maximum voluntary grip strength decreased from 462 ± 67 N at baseline to 56 ± 64 and 272 ± 119 N during partial neuromuscular blockade (TOF ratios: 0.5 and 0.8, respectively), and recovered to baseline values with recovery of the TOF ratio to unity. Maximum voluntary grip strength immediately before and after the respective MRI sequences did not differ.

	DISCUSSION

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During partial neuromuscular blockade, even to a degree that does not evoke dyspnea or oxygen desaturation, inspiratory upper airway volume decreases markedly whereas expiratory volume does not change from baseline, demonstrating a predisposition to upper airway collapse. Partial upper airway collapse was paralleled by a marked dysfunction of the genioglossus muscle, whereas end-expiratory lung volume and respiratory timing did not change.

Study Design and Methodology
For study design and methodology limitations, see the online supplement.

Interpretation of Results
Upper airway patency depends on the balance between the dilating force of pharyngeal muscles and the collapsing force of negative intraluminal pressure that is generated by respiratory "pump" muscles (7–10), and our data support the view that the upper airway dilator muscles are susceptible to the effects of partial paralysis. Accordingly, during partial neuromuscular blockade, the weakened upper airway dilator muscles may no longer be able to balance the negative intraluminal airway pressures evoked by the inspiratory thoracic pump muscles. This suggestion is supported by several arguments. It has been observed that the maximum inspiratory flow is more affected by partial neuromuscular blockade than the maximum expiratory flow (3, 4), which can be explained by an upper airway obstruction (21, 22). This suggestion is in line with our observation that force and EMG of the genioglossus (i.e., the main upper airway dilator function) are impaired during inspiration and partial neuromuscular blockade, even with a degree of neuromuscular blockade (TOF ratio, 0.5–0.8) not evoking dyspnea or a decrease in oxygen saturation. In theory, the decrease in upper airway volume during partial neuromuscular blockade could also be the result of neuromuscular blocking drug (NBD) effects on lung volume (19, 20, 23) and/or respiratory drive (24). However, in accordance with previous reports (25–27), we did not find significant effects of partial neuromuscular blockade on end-expiratory lung volume (25, 26), VT, and respiratory rate (27). Moreover, we observed that inspiratory flow rate (VT/TI) does not change during neuromuscular blockade, suggesting that respiratory drive was not affected from partial neuromuscular blockade (28, 29). Therefore, partial inspiratory upper airway collapse observed in our study was not the result of a decrease in lung volume or effects on respiratory drive but can rather be explained by weakness of the upper airway dilator muscles from neuromuscular blockade.

Weakness of the upper airway muscles evoked by neuromuscular transmission impairment is particularly profound during forced inspiration. During forced inspiration, minimum retroglossal upper airway diameter increased by more than 200% at baseline and this increase was markedly impaired during partial neuromuscular blockade. This marked effect of partial neuromuscular blockade observed under conditions of high physiologic activity of the upper airway dilator muscles is not unexpected, because the response of skeletal muscle to neuromuscular blocking drug exposure increases with increasing force output (30, 31).

We found that the decrease of inspiratory upper airway volume was significantly greater in the retropalatal region compared with the retroglossal region. In accordance with this finding, Trudo and coworkers showed that the soft palate plays the predominant role in mediating airway narrowing during sleep (32), which is believed to be related to a decrease in upper airway dilator muscle activity (7–10). Thus, the integrity of the retropalatal area seems to be particularly susceptible to a decrease in upper airway dilator tone. This observation may be explained by several mechanisms. First, the retropalatal upper airway cross-sectional area is smaller than the retroglossal area, which must be accompanied by a higher velocity of air during inspiration. During partial neuromuscular blockade, the resistance will increase more rapidly in the high-resistance retropalatal airway area, and given a constant gas (air) density and referring to the Bernoulli equation (33), the higher velocity in the high-resistance retropalatal area will be accompanied by a lower local intraluminal pressure in the retroglossal area. Thus, physiologic differences in the flow resistance between the retropalatal and retroglossal area that should be particularly marked with decreased upper airway dilator tone may contribute to differences in airway volume and collapsibility. Second, the genioglossus muscle (retroglossal area), but not the predominantly tonically active tensor palatini (retopalatal area), increases its activity with negative pharyngeal pressure by the negative pressure reflex (34). Therefore, effects on genioglossus function of partial paralysis could be attenuated by a compensatory increase in neural firing rate mediated by the negative pressure reflex, whereas the neural drive to the tensor palatini muscle should remain roughly unchanged. This suggestion is also supported by the observation that phasic reflexes are very resistant to the effects of neuromuscular blocking agents (35).

Isolation of the effects of decreased muscle tone on upper airway function, as accomplished in our study, has implications for the pathophysiology of OSA. Patients with OSA have small airways for anatomic reasons (36, 37), and decreased EMG activity during sleep onset that parallels the upper airway collapse (7–10). Our data show that a decrease in the muscle tone evokes OSA-typical effects on upper airway size (a decrease in upper airway volume and decrease in retropalatal area [38]). To our knowledge, however, upper airway size in patients with OSA has always been studied in the awake state, which is a condition that in OSA is clearly not associated with a decrease in upper airway dilator activity (39). Thus, anatomic changes and decreased pharyngeal dilator tone likely have synergistic effects on net upper airway dimensions. Enhanced monitoring may be useful when patients with OSA are exposed to additional risk factors for development of neuromuscular transmission failure (e.g., after anesthesia), or when given drugs known to enhance neuromuscular blockade (magnesium, antibiotics).

We found a significant decrease in upper airway volume at a TOF ratio of 0.8. Moreover, in several volunteers, effects on upper airway size persisted for some minutes even after recovery of the TOF ratio to unity. Accordingly, although a TOF ratio of 0.9 to 1 after anesthesia predicts statistically the absence of upper airway obstruction (as assessed by a maximal expiratory flow/maximal inspiratory flow ratio at 50% of vital capacity greater than unity [21, 22]) in the majority of patients (3, 40), upper airway obstruction still occurs in some individuals even with recovery of the TOF ratio to 0.9 to 1 (3, 40). A combination of the recommended (1, 3, 14) TOF monitoring with other techniques that have been shown to be sensitive for detection of partial paralysis (e.g., spirometry) (4) or testing the ability to swallow normally (40) may increase the ability to detect those "outliers" (i.e., patients with persistent upper airway obstruction from partial paralysis despite recovery of the TOF ratio) (40).

In summary, our data show that partial neuromuscular transmission failure, even to a degree that does not evoke dyspnea or oxygen desaturation, markedly decreases inspiratory upper airway volume and can evoke partial inspiratory airway collapse. This may be explained by an impairment of the balance between upper airway dilating forces and negative intraluminal pressure generated during inspiration by respiratory pump muscles.

	Acknowledgments

 
The authors thank David P. White and Atul Malhotra, Division of Sleep Medicine, Brigham and Women's Hospital, and Harvard Medical School (Boston, MA), for their useful comments and criticism.

	FOOTNOTES

 
Supported by grant EI 684/2-1 from the Deutsche Forschungsgemeinschaft to M.E. and J.P.

This article has an online supplement, which is accessible from this issue's table of contents at www.atsjournals.org

Originally Published in Press as DOI: 10.1164/rccm.200512-1862OC on October 5, 2006

Conflict of Interest Statement: None of the authors has a financial relationship with a commercial entity that has an interest in the subject of this manuscript.

Received in original form December 6, 2005; accepted in final form October 5, 2006

	REFERENCES

TOP ABSTRACT AT A GLANCE COMMENTARY METHODS RESULTS DISCUSSION REFERENCES

 

1. Sundman E, Witt H, Olsson R, Ekberg O, Kuylenstierna R, Eriksson LI. The incidence and mechanisms of pharyngeal and upper esophageal dysfunction in partially paralyzed humans: pharyngeal videoradiography and simultaneous manometry after atracurium. Anesthesiology 2000;92:977–984.[CrossRef][Medline]
2. Koopman WJ, Wiebe S, Colton-Hudson A, Moosa T, Smith D, Bach D, Nicolle MW. Prediction of aspiration in myasthenia gravis. Muscle Nerve 2004;29:256–260.[CrossRef][Medline]
3. Eikermann M, Groeben H, Hüsing J, Peters J. Accelerometry of adductor pollicis muscle predicts the recovery of respiratory function from neuromuscular blockade. Anesthesiology 2003;98:1333–1337.[CrossRef][Medline]
4. Eikermann M, Groeben H, Bünten B, Peters J. Fade of pulmonary function during residual neuromuscular blockade. Chest 2005;127:1703–1709.
5. Magyar P, Szathmary I, Szobor A. Myasthenia gravis: lung-function studies without and with edrophonium chloride. Eur Neurol 1979;18:59–65.[Medline]
6. Fogel RB, White DP, Pierce RJ, Malhotra A, Edwards JK, Dunai J, Kleverlaan D, Trinder J. Control of upper airway muscle activity in younger versus older men during sleep onset. J Physiol 2003;553:533–544.[Abstract/Free Full Text]
7. Fogel RB, Trinder J, White DP, Malhotra A, Raneri J, Schory K, Kleverlaan D, Pierce RJ. The effect of sleep onset on upper airway muscle activity in patients with sleep apnoea versus controls. J Physiol 2005;564:549–562.[Abstract/Free Full Text]
8. White DP. Pathogenesis of obstructive and central sleep apnea. Am J Respir Crit Care Med 2005;172:1363–1370.[Abstract/Free Full Text]
9. Malhotra A, White DP. Obstructive sleep apnoea. Lancet 2002;360:237–245.[CrossRef][Medline]
10. Ryan CM, Bradley TD. Pathogenesis of obstructive sleep apnea. J Appl Physiol 2005;99:2440–2450.[Abstract/Free Full Text]
11. Segredo V, Caldwell JE, Matthay MA, Sharma ML, Gruenke LD, Miller RD. Persistent paralysis in critically ill patients after long-term administration of vecuronium. N Engl J Med 1992;327:524–528.[Abstract]
12. Viby-Mogensen J, Jorgensen BC, Ording H. Residual curarization in the recovery room. Anesthesiology 1979;50:539–541.[CrossRef][Medline]
13. Arbous MS, Meursing AE, van Kleef JW, de Lange JJ, Spoormans HH, Touw P, Werner FM, Grobbee DE. Impact of anesthesia management characteristics on severe morbidity and mortality. Anesthesiology 2005;102:257–268.[CrossRef][Medline]
14. Berg H, Roed J, Viby-Mogensen J, Mortensen CR, Engbaek J, Skovgaard LT, Krintel JJ. Residual neuromuscular block is a risk factor for postoperative pulmonary complications: a prospective, randomised, and blind study of postoperative pulmonary complications after atracurium, vecuronium and pancuronium. Acta Anaesthesiol Scand 1997;41:1095–1103.[Medline]
15. Schwab RJ, Gefter WB, Hoffman EA, Gupta KB, Pack AI. Dynamic upper airway imaging during awake respiration in normal subjects and patients with sleep disordered breathing. Am Rev Respir Dis 1993;148:1385–1400.[Medline]
16. Arens R, Sin S, McDonough JM, Palmer JM, Dominguez T, Meyer H, Wootton DM, Pack AI. Changes in upper airway size during tidal breathing in children with obstructive sleep apnea syndrome. Am J Respir Crit Care Med 2005;171:1298–1304.[Abstract/Free Full Text]
17. Eastwood PR, Allison GT, Shepherd KL, Szollosi I, Hillman DR. Heterogeneous activity of the human genioglossus muscle assessed by multiple bipolar fine-wire electrodes. J Appl Physiol 2003;94:1849–1858.[Abstract/Free Full Text]
18. Mortimore IL, Fiddes P, Stephens S, Douglas NJ. Tongue protrusion force and fatigability in male and female subjects. Eur Respir J 1999;14:191–195.[Abstract]
19. Heinzer RC, Stanchina ML, Malhotra A, Fogel RB, Patel SR, Jordan AS, Schory K, White DP. Lung volume and continuous positive airway pressure requirements in obstructive sleep apnea. Am J Respir Crit Care Med 2005;172:114–117.[Abstract/Free Full Text]
20. Heinzer RC, Stanchina ML, Malhotra A, Jordan AS, Patel SR, Lo YL, Wellman A, Schory K, Dover L, White DP. Effect of increased lung volume on sleep disordered breathing in patients with sleep apnoea. Thorax 2006;61:435–439.[Abstract/Free Full Text]
21. Melissant CF, Lammers JW, Demedts M. Rigid external resistances cause effort dependent maximal expiratory and inspiratory flows. Am J Respir Crit Care Med 1995;152:1709–1712.[Abstract]
22. Rotman HH, Liss HP, Weg JG. Diagnosis of upper airway obstruction by pulmonary function testing. Chest 1975;68:796–799.
23. Van de Graaff WB. Thoracic influence on upper airway patency. J Appl Physiol 1988;65:2124–2131.[Abstract/Free Full Text]
24. Series F, Cormier Y, Desmeules M, La Forge J. Effects of respiratory drive on upper airways in sleep apnea patients and normal subjects. J Appl Physiol 1989;67:973–979.[Abstract/Free Full Text]
25. Gal TJ, Arora NS. Respiratory mechanics in supine subjects during progressive partial curarization. J Appl Physiol 1982;52:57–63.[Abstract/Free Full Text]
26. Ali HH, Wilson RS, Savarese JJ. The effect of tubocurarine on indirectly elicited train-of-four muscle response and respiratory measurements in humans. Br J Anaesth 1975;47:570–574.[Abstract/Free Full Text]
27. De Troyer A, Bastenier-Geens J. Effects of neuromuscular blockade on respiratory mechanics in conscious man. J Appl Physiol 1979;47:1162–1168.[Abstract/Free Full Text]
28. Tobin MJ, Mador MJ, Guenther SM, Lodato RF, Sackner MA. Variability of resting respiratory drive and timing in healthy subjects. J Appl Physiol 1988;65:309–317.[Abstract/Free Full Text]
29. Clark FJ, von Euler C. On the regulation of depth and rate of breathing. J Physiol 1972;222:267–295.[Abstract/Free Full Text]
30. Ali HH, Savarese JJ, Lebowitz PW, Ramsey FM. Twitch, tetanus and train-of-four as indices of recovery from nondepolarizing neuromuscular blockade. Anesthesiology 1981;54:294–297.[Medline]
31. Rosenblueth A, Morrison RS. Curarisation, fatigue and wedensky inhibition. Am J Physiol 1937;119:236–256.[Free Full Text]
32. Trudo FJ, Gefter WB, Welch KC, Gupta KB, Maislin G, Schwab RJ. State-related changes in upper airway caliber and surrounding soft-tissue structures in normal subjects. Am J Respir Crit Care Med 1998;158:1259–1270.[Abstract/Free Full Text]
33. Fung YC. Biomechanics: motion, stress and growth. New York: Springer Verlag; 1990. pp. 83–87.
34. Malhotra A, Pillar G, Fogel RB, Beauregard J, Edwards JK, Slamowitz DI, Shea SA, White DP. Genioglossal but not palatal muscle activity relates closely to pharyngeal pressure. Am J Respir Crit Care Med 2000;162:1058–1062.[Abstract/Free Full Text]
35. Smith CM, Budris AV, Paul JW. Quantification of phasic and tonic stretch reflexes: effects of neuromuscular blocking agents. J Pharmacol Exp Ther 1962;136:267–275.[Abstract/Free Full Text]
36. Schwab RJ, Gupta KB, Gefter WB, Metzger LJ, Hoffman EA, Pack AI. Upper airway and soft tissue anatomy in normal subjects and patients with sleep-disordered breathing: significance of the lateral pharyngeal walls. Am J Respir Crit Care Med 1995;152:1673–1689.[Abstract]
37. Schwab RJ, Pasirstein M, Pierson R, Mackley A, Hachadoorian R, Arens R, Maislin G, Pack AI. Identification of upper airway anatomic risk factors for obstructive sleep apnea with volumetric magnetic resonance imaging. Am J Respir Crit Care Med 2003;168:522–530.[Abstract/Free Full Text]
38. Schwab RJ, Gefter WB, Hoffman EA, Gupta KB, Pack AI. Dynamic upper airway imaging during awake respiration in normal subjects and patients with sleep disordered breathing. Am Rev Respir Dis 1993;148:1385–1400.[Medline]
39. Mezzanotte WS, Tangel DJ, White DP. Waking genioglossal electromyogram in sleep apnea patients versus normal controls (a neuromuscular compensatory mechanism). J Clin Invest 1992;89:1571–1579.[Medline]
40. Eikermann M, Grote T, Blobner M, Groeben H, Rex C, Neuhäuser M, Peters J. Postoperative upper airway obstruction after recovery of the TOF-ratio of the adductor pollicis muscle from neuromuscular blockade. Anesth Analg 2006;102:937–942.[Abstract/Free Full Text]

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