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Abstract

Objective

Obstructive sleep apnea events are more common in REM sleep, although there is no relationship between sleep phase and pharyngeal airway status. We studied the patency of the nasal airway during REM and non-REM sleep with the use of acoustic rhinometry.

Methods

Serial acoustic rhinometric assessment of nasal cross-sectional area was performed in 10 subjects, before sleep and during REM and non-REM sleep. All measurements were standardized to a decongested baseline with mean congestion factor (MCF).

Results

MCF in the seated position was 10.6% (±3.7) and increased with supine positioning to 16.2% (±2.3). In REM sleep, MCF was highest, at 22.3% (±1.7). In non-REM sleep, MCF was lowest, at 2.3% (±3.1). All interstage comparisons were statistically significant on repeated measures ANOVA (P < 0.05).

Conclusion

REM sleep is characterized by significant nasal congestion; non-REM sleep, by profound decongestion. This phenomenon may be attributable to REM-dependent variation in cerebral blood flow that affects nasal congestion via the internal carotid system. REM-induced nasal congestion, an indirect effect of augmented cerebral perfusion, may contribute to the higher frequency of obstructive events in REM sleep.

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References

Virkkula

, Maasilta

, Hytonen

Nasal obstruction and sleep-disordered breathing: the effect of supine body position on nasal measurements in snorers. Acta Otolaryngol 2003; 123: 648–54.

Morris

L.G.

, Burschtin

, Lebowitz

R.A.

Nasal obstruction and sleep-disordered breathing: a study using acoustic rhinometry. Am J Rhinol 2005; 19: 33–9.

Findley

, Wilhoit

S.C.

, Suratt

P.M.

. Apnea duration and hypoxemia during REM sleep in patients with obstructive sleep apnea. Chest 1985; 87: 432–6.

Series

, Cormier

, LaForge

. Influence of apnea type and sleep stage on nocturnal postapneic desaturation. Am Rev Respir Dis 1990; 141: 1522–6.

Somers

V.K.

, Dyken

M.E.

, Mark

A.L.

Sympathetic-nerve activity during sleep in normal subjects. N Engl J Med 1993; 328: 303–7.

Rowley

J.A.

, Sanders

C.S.

, Zahn

B.R.

Effect of REM sleep on retroglossal cross-sectional area and compliance in normal subjects. J Appl Physiol 2001; 91: 239–48.

Rowley

J.A.

, Zahn

B.K.

, Babcock

M.A.

The effect of rapid eye movement sleep on upper airway mechanics in normal human subjects. J Physiol (Lond) 1998; 510: 963–76.

Wiegand

, Zwillich

C.W.

, Wiegand

Changes in upper airway muscle activation and ventilation during phasic REM sleep in normal men. J Appl Physiol 1991; 71: 488–97.

Morris

L.G.

, Setlur

, Burschtin

O.E.

Acoustic rhinometry predicts tolerance of nasal continuous positive airway pressure: a pilot study. Am J Rhinol 2006; 20: 133–7.

10.

Cankurtaran

, Celik

, Coşkun

Acoustic rhinometry in healthy humans: accuracy of area estimates and ability to quantify certain anatomic structures in the nasal cavity. Ann Otol Rhinol Laryngol 2007; 116: 906–16.

11.

Hein

, Mullaner

, Magnussen

. Fluctuations of required CPAP related to sleep stage and body position. Sleep Res Online 2005; 5: 1–5.

12.

Wiegand

D.A.

, Latz

, Zwillich

C.W.

Upper airway resistance and geniohyoid muscle activity in normal men during wakefulness and sleep. J Appl Physiol 1990; 69: 1252–61.

13.

Kase

, Hilberg

, Pedersen

O.F.

. Posture and nasal patency: evaluation by acoustic rhinometry. Acta Otolaryngol 1994; 114: 70–4.

14.

Lal

, Gorges

M.L.

, Ungkhara

Physiological change in nasal patency in response to changes in posture, temperature, and humidity measured by acoustic rhinometry. Am J Rhinol 2006; 20: 456–62.

15.

Miki

, Oda

, Kamijyo

Lumbar sympathetic nerve activity and hindquarter blood flow during REM sleep in rats. J Physiol 2004; 261–71.

16.

Zoccoli

, Bach

, Cianci

Brain blood flow and extracerebral carotid circulation during sleep in rat. Brain Res 1994; 641: 46–50.

17.

Lenzi

, Cianci

, Guidalotti

P.L.

Brain circulation during sleep and its relation to extracerebral hemodynamics. Brain Res 1987; 415: 14–20.

18.

Klingelhofer

, Hajak

, Matzander

Dynamics of cerebral blood flow velocities during normal human sleep. Clin Neurol Neurosurg 1995; 97: 142–8.

19.

Bangash

M.F.

, Xie

, Skatrud

J.B.

Cerebrovascular response to arousal from NREM and REM sleep. Sleep 2008; 31: 321–7.

20.

Busaba

. The nose in snoring and obstructive sleep apnea. Curr Opin Otolaryngol Head Neck Surg 1999; 7: 1–11.

21.

Tarhan

, Coksun

, Cakmak

Acoustic rhinometry in humans: accuracy of nasal passage area estimates. J Appl Physiol 2005; 99: 616–23.

22.

Cakmak

, Tarhan