Rationale: Inhaled nitric oxide (NO) has been used to prevent bronchopulmonary dysplasia, but with variable results. Ethyl nitrite (ENO) forms S-nitrosothiols more readily than does NO, and resists higher-order nitrogen oxide formation. Because S-nitrosylation is a key pathway mediating many NO biological effects, treatment with inhaled ENO may better protect postnatal lung development from oxidative stress than NO. Objectives: To compare inhaled NO and ENO on hyperoxia-impaired postnatal lung development. Methods: We treated newborn rats beginning at birth to air or 95% O 2 ؎ 0.2-20.0 ppm ENO for 8 days, or to 10 ppm NO for 8 days. Pups treated with the optimum ENO dose, 10 ppm, and pups treated with 10 ppm NO were recovered in room air for 6 more days. Measurements and Main Results: ENO and NO partly prevented 95% O 2 -induced airway neutrophil influx in lavage, but ENO had a greater effect than did NO in prevention of lung myeloperoxidase accumulation, and in expression of cytokine-induced neutrophil chemoattractant-1. Treatment with 10 ppm ENO, but not NO, for 8 days followed by recovery in air for 6 days prevented 95% O 2 -induced impairments of body weight, lung compliance, and alveolar development. Conclusions: Inhaled ENO conferred protection superior to inhaled NO against hyperoxia-induced inflammation. ENO prevented hyperoxia impairments of lung compliance and postnatal alveolar development in newborn rats.
Keywords: bronchopulmonary dysplasia; O-nitrosoethanol; S-nitrosylationInhaled nitric oxide (NO) has been used to prevent and treat bronchopulmonary dysplasia (BPD) in premature newborns, with mixed success (1-4). The rationale underlying clinical trials has included improvement of ventilation-perfusion matching through classical effects on guanylyl cylase-mediated pulmonary vascular tone and remodeling (5), alveolar capillary development (6), and reducing inflammation (7). However, many, if not most NO biological effects are mediated through reversible S-nitrosylation of critical thiols that govern multiple biological pathways (8-10).Inhaled agents preferentially forming S-nitrosothiols may "deliver" NO biological effects more efficiently, which may be of particular benefit in treating patients subjected to high levels of inhaled oxygen, as NO tends to rapidly form peroxynitrite in
What This Study Adds to the FieldInhaled ethyl nitrite dose-dependently prevents hyperoxiainduced lung inflammation in newborn rats, and, at an equivalent dose, afforded better protection of postnatal lung function and development than nitric oxide. the presence of superoxide. Inhaled ethyl nitrite (ENO) has been used to treat newborns with pulmonary hypertension (11), and efficiently achieves S-nitrosation of glutathione compared with NO, without releasing significant amounts of reactive• NO species (12), so it should be less susceptible to forming higherorder nitrogen oxides.We therefore compared the effects of inhaled NO and ENO in hyperoxia-exposed newborn rats, which we have previously shown to develop an acute inf...
