Respiratory plasticity after perinatal hyperoxia is not prevented by antioxidant supplementation

Respiratory plasticity after perinatal hyperoxia is not prevented by antioxidant supplementation

Abstract Perinatal hyperoxia attenuates the hypoxic ventilatory response in rats by altering development of the carotid body and its chemoafferent neurons. In this study, we tested the hypothesis that hyperoxia elicits this plasticity through the increased production of reactive oxygen species (ROS)...

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Bibliographic Details
Published in:Respiratory physiology & neurobiology Vol. 160; no. 3; pp. 301 - 312
Main Authors: Bavis, Ryan W, Wenninger, Julie M, Miller, Brooke M, Dmitrieff, Elizabeth F, Olson, E. Burt, Mitchell, Gordon S, Bisgard, Gerald E
Format: Journal Article
Language:English
Published: Amsterdarm Elsevier B.V 29-02-2008
Elsevier
Subjects:
Analysis of Variance
Animals
Animals, Newborn
Anorexia - physiopathology
Anorexia - prevention & control
Antioxidants - administration & dosage
Asphyxia - physiopathology
Asphyxia - prevention & control
Biological and medical sciences
Carotid body
Carotid Sinus - drug effects
Control of breathing
Developmental plasticity
Dose-Response Relationship, Drug
Drug Interactions
Fundamental and applied biological sciences. Psychology
Hyperoxia
Hyperoxia - pathology
Hyperoxia - prevention & control
Hypoxic ventilatory response
Medical Education
Metalloporphyrins - administration & dosage
Phrenic Nerve - drug effects
Phrenic Nerve - physiopathology
Protein Carbonylation - drug effects
Pulmonary/Respiratory
Rats
Rats, Sprague-Dawley
Reactive oxygen species
Sodium Cyanide - pharmacology
Vertebrates: respiratory system
Vitamin E - administration & dosage
Reactive oxygen species
Control of breathing
Carotid body
Hypoxic ventilatory response
Developmental plasticity
Hyperoxia
Oxygen
Perinatal
Antioxidant
Respiratory system
Chemoreceptor
Vertebrata
Mammalia
Ventilatory response
Plasticity
Development
Hypoxia
Respiration
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Summary:Abstract Perinatal hyperoxia attenuates the hypoxic ventilatory response in rats by altering development of the carotid body and its chemoafferent neurons. In this study, we tested the hypothesis that hyperoxia elicits this plasticity through the increased production of reactive oxygen species (ROS). Rats were born and raised in 60% O2 for the first two postnatal weeks while treated with one of two antioxidants: vitamin E (via milk from mothers whose diet was enriched with 1000 IU vitamin E kg−1 ) or a superoxide dismutase mimetic, manganese(III) tetrakis (1-methyl-4-pyridyl) porphyrin pentachloride (MnTMPyP; via daily intraperitoneal injection of 5–10 mg kg−1 ); rats were subsequently raised in room air until studied as adults. Peripheral chemoreflexes, assessed by carotid sinus nerve responses to cyanide, asphyxia, anoxia and isocapnic hypoxia (vitamin E experiments) or by hypoxic ventilatory responses (MnTMPyP experiments), were reduced after perinatal hyperoxia compared to those of normoxia-reared controls (all P < 0.01); antioxidant treatment had no effect on these responses. Similarly, the carotid bodies of hyperoxia-reared rats were only one-third the volume of carotid bodies from normoxia-reared controls ( P < 0.001), regardless of antioxidant treatment. Protein carbonyl concentrations in the blood plasma, measured as an indicator of oxidative stress, were not increased in neonatal rats (2 and 8 days of age) exposed to 60% O2 from birth. Collectively, these data do not support the hypothesis that perinatal hyperoxia impairs peripheral chemoreceptor development through ROS-mediated oxygen toxicity.
ISSN:1569-9048
1878-1519
DOI:10.1016/j.resp.2007.10.013