Peripharyngeal tissue deformation and stress distributions in response to caudal tracheal displacement: pivotal influence of the hyoid bone?

Caudal tracheal displacement (TD) leads to improvements in upper airway (UA) function and decreased collapsibility. To better understand the mechanisms underlying these changes, we examined effects of TD on peripharyngeal tissue stress distributions [i.e., extraluminal tissue pressure (ETP)], deform...

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Published in:Journal of applied physiology (1985) 2014-04, Vol.116 (7), p.746-756
Main Authors: Amatoury, Jason, Kairaitis, Kristina, Wheatley, John R, Bilston, Lynne E, Amis, Terence C
Format: Article
Language:English
Subjects:
Adaptation, Physiological
Airway management
Animals
Biomechanical Phenomena
Deformities
Geometry
Hyoid Bone - diagnostic imaging
Hyoid Bone - physiology
Lung Volume Measurements
Male
Mechanotransduction, Cellular
Models, Animal
Movement
Pharynx - diagnostic imaging
Pharynx - physiology
Pressure
Rabbits
Respiration
Stress response
Stress, Mechanical
Throat
Tomography, X-Ray Computed
Trachea - diagnostic imaging
Trachea - physiology
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Summary:Caudal tracheal displacement (TD) leads to improvements in upper airway (UA) function and decreased collapsibility. To better understand the mechanisms underlying these changes, we examined effects of TD on peripharyngeal tissue stress distributions [i.e., extraluminal tissue pressure (ETP)], deformation of its topographical surface (UA lumen geometry), and hyoid bone position. We studied 13 supine, anesthetized, tracheostomized, spontaneously breathing, adult male New Zealand white rabbits. Graded TD was applied to the cranial tracheal segment from 0 to ∼ 10 mm. ETP was measured at six locations distributed around/along the length of the UA, covering three regions: tongue, hyoid, and epiglottis. Axial images of the UA (nasal choanae to glottis) were acquired with computed tomography and used to measure lumen geometry (UA length; regional cross-sectional area) and hyoid bone displacement. TD resulted in nonuniform decreases in ETP (generally greatest at tongue region), ranging from -0.07 (-0.11 to -0.03) [linear mixed-effects model slope (95% confidence interval)] to -0.27 (-0.31 to -0.23) cmH2O/mm TD, across all sites. UA length increased by 1.6 (1.5-1.8)%/mm, accompanied by nonuniform increases in cross-sectional area (greatest at hyoid region) ranging from 2.8 (1.7-3.9) to 4.9 (3.8-6.0)%/mm. The hyoid bone was displaced caudally by 0.22 (0.18-0.25) mm/mm TD. In summary, TD imposes a load on the UA that results in heterogeneous changes in peripharyngeal tissue stress distributions and resultant lumen geometry. The hyoid bone may play a pivotal role in redistributing applied caudal tracheal loads, thus modifying tissue deformation distributions and determining resultant UA geometry outcomes.
ISSN:8750-7587
1522-1601
DOI:10.1152/japplphysiol.01245.2013