Chronic Hypoxia Accentuates Dysanaptic Lung Growth

Chronic Hypoxia Accentuates Dysanaptic Lung Growth

Adults born and raised at high altitudes have larger lung volumes and greater pulmonary diffusion capacity compared with adults at low altitude; however, it remains unclear whether the air and tissue volumes have comparable increases and whether there is a difference in airway size. To assess the ef...

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Bibliographic Details
Published in:American journal of respiratory and critical care medicine Vol. 194; no. 3; pp. 327 - 332
Main Authors: Llapur, Conrado J, Martínez, Myriam R, Grassino, Pedro T, Stok, Ana, Altieri, Héctor H, Bonilla, Federico, Caram, María M, Krowchuk, Natasha M, Kirby, Miranda, Coxson, Harvey O, Tepper, Robert S
Format: Journal Article
Language:English
Published: United States American Thoracic Society 01-08-2016
Subjects:
Adult
Altitude
Argentina
Female
Forced Expiratory Volume - physiology
Humans
Hypoxia - physiopathology
Lung - anatomy & histology
Lung - physiology
Male
Organ Size
Respiratory Function Tests - statistics & numerical data
Spirometry - statistics & numerical data
Tidal Volume - physiology
Tomography, X-Ray Computed
airway size
altitude
lung density
pulmonary diffusion capacity
lung volume
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Summary:Adults born and raised at high altitudes have larger lung volumes and greater pulmonary diffusion capacity compared with adults at low altitude; however, it remains unclear whether the air and tissue volumes have comparable increases and whether there is a difference in airway size. To assess the effect of chronic hypoxia on lung growth using in vivo high-resolution computed tomography measurements. Healthy adults born and raised at moderate altitude (2,000 m above sea level; n = 19) and at low altitude (400 m above sea level; n = 23) underwent high-resolution computed tomography. Differences in total lung, air, and tissue volume, mean lung density, as well as airway lumen and wall areas in anatomically matched airways were compared between groups. No significant differences for age, sex, weight, or height were found between the two groups (P > 0.05). In a multivariate regression model, altitude was a significant contributor for total lung volume (P = 0.02), air volume (P = 0.03), and tissue volume (P = 0.03), whereby the volumes were greater for the moderate- versus the low-altitude group. However, altitude was not a significant contributor for mean lung density (P = 0.35) or lumen and wall areas in anatomically matched segmental, subsegmental, and subsubsegmental airways. Our findings suggest that the adult lung did not increase lung volume later in life by expansion of an existing number of alveoli, but rather from increased alveolarization early in life. In addition, chronic hypoxia accentuates dysanaptic lung growth by increasing the lung parenchyma but not the airways.
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ISSN:1073-449X
1535-4970
DOI:10.1164/rccm.201509-1851OC