BACKGROUND: Supplemental oxygen is necessary in the respiratory support of very preterm infants, but it may contribute to bronchopulmonary dysplasia and an increased risk of poor lung function in later life. It is well established that hyperoxia can inhibit alveolarization, but effects on the developing conducting airways, which are important determinants of lung function, are poorly understood. It is possible that prolonged exposure of the immature lung to hyperoxic gas alters the development of small conducting airways (bronchioles), and that these effects may persist throughout life. OBJECTIVES: To examine the effects of neonatal inhalation of hyperoxic gas on the bronchiolar walls in adulthood. METHODS: Neonatal mice (C57BL/6J) born at term inhaled 65% O2 from birth until postnatal day 7; thereafter, they were raised in room air until 10 months postnatal age (P10mo), which is advanced adulthood. Age-matched controls inhaled room air from birth. We investigated small conducting airways with a diameter between 105-310 µm. RESULTS: At P10mo, bronchiolar walls of hyperoxia-exposed mice contained ∼18% more smooth muscle than controls (p < 0.05), although there was no effect on bronchiolar epithelium or collagen. Neonatal hyperoxia resulted in significantly fewer bronchiolar-alveolar attachments at P10mo (p < 0.05); this was accompanied by persistent simplification of the lung parenchyma, as indicated by greater mean linear intercept and less parenchymal tissue (p < 0.05). CONCLUSIONS: Neonatal exposure to hyperoxia induces remodeling of the bronchiolar walls and loss of bronchiolar-alveolar attachments in adulthood, both of which could contribute to impaired lung function and airway hyper-reactivity.
BACKGROUND: Supplemental oxygen is necessary in the respiratory support of very preterm infants, but it may contribute to bronchopulmonary dysplasia and an increased risk of poor lung function in later life. It is well established that hyperoxia can inhibit alveolarization, but effects on the developing conducting airways, which are important determinants of lung function, are poorly understood. It is possible that prolonged exposure of the immature lung to hyperoxic gas alters the development of small conducting airways (bronchioles), and that these effects may persist throughout life. OBJECTIVES: To examine the effects of neonatal inhalation of hyperoxic gas on the bronchiolar walls in adulthood. METHODS: Neonatal mice (C57BL/6J) born at term inhaled 65% O2 from birth until postnatal day 7; thereafter, they were raised in room air until 10 months postnatal age (P10mo), which is advanced adulthood. Age-matched controls inhaled room air from birth. We investigated small conducting airways with a diameter between 105-310 µm. RESULTS: At P10mo, bronchiolar walls of hyperoxia-exposed mice contained ∼18% more smooth muscle than controls (p < 0.05), although there was no effect on bronchiolar epithelium or collagen. Neonatal hyperoxia resulted in significantly fewer bronchiolar-alveolar attachments at P10mo (p < 0.05); this was accompanied by persistent simplification of the lung parenchyma, as indicated by greater mean linear intercept and less parenchymal tissue (p < 0.05). CONCLUSIONS: Neonatal exposure to hyperoxia induces remodeling of the bronchiolar walls and loss of bronchiolar-alveolar attachments in adulthood, both of which could contribute to impaired lung function and airway hyper-reactivity.
Authors: Thomas M Raffay; Koby Bonilla-Fernandez; Anjum Jafri; Ramadan B Sopi; Laura A Smith; Feifei Cui; Maureen O'Reilly; Rongli Zhang; Craig A Hodges; Peter M MacFarlane; Gail Deutsch; Richard J Martin; Benjamin Gaston Journal: Am J Respir Cell Mol Biol Date: 2021-07 Impact factor: 6.914
Authors: Hua Wang; Anjum Jafri; Richard J Martin; Jerry Nnanabu; Carol Farver; Y S Prakash; Peter M MacFarlane Journal: Am J Physiol Lung Cell Mol Physiol Date: 2014-06-20 Impact factor: 5.464
Authors: Helly J Einisman; Benjamin Gaston; Christiaan Wijers; Laura A Smith; Tristan H Lewis; Stephen J Lewis; Thomas M Raffay Journal: Pediatr Pulmonol Date: 2019-09-04
Authors: Brent Reyburn; Juliann M Di Fiore; Thomas Raffay; Richard J Martin; Y S Prakash; Anjum Jafri; Peter M MacFarlane Journal: Neonatology Date: 2015-09-23 Impact factor: 4.035
Authors: Thomas Raffay; Prabha Kc; James Reynolds; Juliann Di Fiore; Peter MacFarlane; Richard J Martin Journal: Neonatology Date: 2014-06-20 Impact factor: 4.035