健康人体的口腔气道流动动力学

Oral airway flow dynamics in healthy humans.

Amis T C, O'Neill N, Wheatley J R

Department of Respiratory Medicine, Westmead Hospital, and University of Sydney, Westmead, NSW 2145, Australia.

J Physiol. 1999 Feb 15;515 ( Pt 1)(Pt 1):293-8. doi: 10.1111/j.1469-7793.1999.293ad.x.

Abstract

Oral airway resistance (RO) is an important determinant of oro-nasal partitioning of airflow (e.g. during exercise and sleep); however, little is known of factors influencing its magnitude and measurement. 2. We developed a non-invasive standardized technique for measuring RO (based on a modification of posterior rhinomanometry) and examined inspiratory RO in 17 healthy male subjects (age, 36 +/- 2 years (mean +/- s.e.m.); height, 177 +/- 2 cm; weight, 83 +/- 3 kg). 3. Inspiratory RO (at 0.4 l s-1) was 0.86 +/- 0.23 cmH2O l-1 s-1 during resting mouthpiece breathing in the upright posture. RO was unaffected by assumption of the supine posture, tended to decrease with head and neck extension and increased to 1.22 +/- 0.19 cmH2O l-1 s-1 (n = 10 subjects, P < 0.01) with 40-45 deg of head and neck flexion. When breathing via a mouth-mask RO was 2.98 +/- 0.42 cmH2O l-1 s-1 (n = 7) and not significantly different from nasal airway resistance. 4. Thus, in awake healthy male subjects with constant jaw position, RO is unaffected by body posture but increases with modest degrees of head and neck flexion. This influence on upper airway patency may be important when oral route breathing is associated with alterations in head and neck position, e.g. during sleep.

摘要

口腔气道阻力（RO）是气流口鼻分配的一个重要决定因素（例如在运动和睡眠期间）；然而，对于影响其大小和测量的因素知之甚少。2. 我们开发了一种用于测量RO的非侵入性标准化技术（基于后鼻测压法的改进），并在17名健康男性受试者中检测了吸气RO（年龄，36±2岁（平均值±标准误）；身高，177±2厘米；体重，83±3千克）。3. 在直立姿势下通过咬嘴静息呼吸时，吸气RO（流量为0.4升/秒时）为0.86±0.23厘米水柱·升⁻¹·秒⁻¹。仰卧姿势对RO无影响，随着头颈部伸展RO往往降低，当头颈部屈曲40 - 45度时，RO增加至1.22±0.19厘米水柱·升⁻¹·秒⁻¹（n = 10名受试者，P < 0.01）。通过口鼻面罩呼吸时，RO为2.98±0.42厘米水柱·升⁻¹·秒⁻¹（n = 7），与鼻气道阻力无显著差异。4. 因此，在清醒的健康男性受试者中，当颌位固定时，RO不受身体姿势影响，但随着头颈部适度屈曲而增加。当经口呼吸与头颈部位置改变相关时，例如在睡眠期间，这种对上气道通畅性的影响可能很重要。