Safety and efficacy of nitric oxide in chronic lung disease.

BACKGROUND: Therapies for neonatal chronic lung disease (CLD) of prematurity have had limited success. AIMS: To determine whether inhaled nitric oxide (INO) administered to very low birthweight infants with developing CLD might improve oxygenation without adverse effects. METHODS: Subjects were 10-30 days of age, birth weight < 1250 g, with developing or established CLD, and requiring mechanical ventilation with mean airway pressure > or = 7 cm H2O and FIO2 . or = 0.40. We monitored changes in oxygenation and FIO2 requirement during treatment with INO (initial dose 20 ppm). Tracheal aspirate samples obtained before, during, and after treatment were analysed for interleukin 1beta (IL-1beta), IL-8, 8-epi-prostaglandin F2alpha (8-epi-PGF2alpha), laminin, and endothelin 1 (ET-1) to assess any potential effects of INO on markers of inflammation peroxidation, basement membrane injury, or vasoactivity. RESULTS: Thirty three patients met entry criteria. Mean gestational age was 25 (SD 2) weeks; birth weight was 736 (190 g); age of study infants was 19 (6) days (range 9-29). Mean FIO2 decreased from baseline (0.75) to 0.58 at 72 hours. Duration of therapy was seven days. Tracheal aspirate concentrations of IL-1beta, IL-8, 8-epi-PGF2alpha, ET-1, and laminin were unchanged between baseline and 48 hours of INO, and 48 hours after discontinuation of INO. No new cases of, nor extension of, intraventricular haemorrhage occurred. Four infants died. CONCLUSION: INO (< or = 20 ppm) improved oxygenation in most infants with early CLD, without inducing changes in markers of inflammatory or oxidative injury.

Monocyte chemoattractant protein-1 and its receptor CCR-2 in piglet lungs exposed to inhaled nitric oxide and hyperoxia.

Monocyte chemoattractant protein-1 (MCP-1), acting through its C-C chemokine receptor 2 (CCR-2), has important roles in inflammation, angiogenesis, and wound repair. The individual and combined effects of inhaled nitric oxide (NO) and hyperoxia on lung MCP-1 and CCR-2 in relation to lung leukocyte dynamics are unknown. Because MCP-1 gene is up-regulated by oxidants, we hypothesized that inhaled NO with hyperoxia will increase MCP-1 production and CCR-2 expression more than either gas alone. We randomly assigned young piglets to breathe room air (RA), RA+50 ppm NO (RA+NO), O(2), or O(2)+NO for 1 or 5 d before sacrifice. Lungs were lavaged and tissues preserved for hybridization studies, Western blotting, histology, and immunohistochemistry. The results show that lung MCP-1 production and alveolar macrophage count were significantly elevated in the 5-d O(2) and O(2)+NO groups relative to the RA group (p < or = 0.05). In contrast, lung CCR-2 abundance was diminished in the O(2) group (p

High-dose inhaled nitric oxide and hyperoxia increases lung collagen accumulation in piglets.

Nitric oxide (NO), a pro-oxidant gas, is used with hyperoxia (O(2)) to treat neonatal pulmonary hypertension and recently bronchopulmonary dysplasia, but great concerns remain regarding NO's potential toxicity. Based on reports that exposure to oxidant gases results in pulmonary extracellular matrix injury associated with elevated lavage fluid levels of extracellular matrix components, we hypothesized that inhaled NO with or without hyperoxia will have the same effect. We measured alveolar septal width, lung collagen content, lavage fluid hydroxyproline, hyaluronan and laminin levels in neonatal piglets after 5 days' exposure to room air (RA), RA + 50 ppm NO (RA + NO), O(2) (FiO(2) > 0.96) or O(2) + NO. Matrix metalloproteinase (MMP) activity and MMP-2 mRNA were also measured. In recovery experiments, we measured lung collagen content in piglets exposed to RA + NO or O(2) + NO and then allowed to recover for 3 days. The results show that lung collagen increased 4-fold in the RA + NO piglets, the O(2) and O(2) + NO groups had only a 2-fold elevation relative to RA controls. Unlike the RA + NO piglets, the O(2) and O(2) + NO groups had more than 20-fold elevation in lung lavage fluid hydroxyproline compared to the RA group. O(2) and O(2) + NO also had increased lung MMP activity, extravascular water, and lavage fluid proteins. MMP-2 mRNA levels were unchanged. After 3 days' recovery in room air, the RA + NO groups' lung collagen had declined from 4-fold to 2-fold above the RA group values. The O(2) + NO group did not decline. Alveolar septal width increased significantly only in the O(2) and O(2) + NO groups. We conclude that 5 days' exposure to NO does not result in pulmonary matrix degradation but instead significantly increases lung collagen content. This effect appears potentially reversible. In contrast, hyperoxia exposure with or without NO results in pulmonary matrix degradation and increased lung collagen content. The observation that NO increased lung collagen content represents a new finding and suggests NO could potentially induce pulmonary fibrosis.

Independent and combined effects of prolonged inhaled nitric oxide and oxygen on lung inflammation in newborn piglets.

Clinical use of nitric oxide (NO) is usually in conjunction with high oxygen concentrations, the effects of which may include lung neutrophil accumulation, apoptosis and upregulation of antioxidant enzyme activity. To define the effects of NO on neutrophils from young piglets and its relationship to lung neutrophil dynamics during hyperoxia we exposed thirty piglets to room air (RA), RA+NO (50 ppm NO), O2 (FiO2> or =0.96) or O2+NO for 5 days. Ten additional animals breathed RA+NO or O2+NO, then recovered in RA for 3 days before sacrifice. Neutrophil CD18 and intracellular oxidant production were measured by flow cytometry. Lung apoptosis were assessed by TUNEL assay. Lung myeloperoxidase, SOD and catalase were measured biochemically. When compared to RA group, there was significant reduction in neutrophil CD18 and intracellular oxidant production in the RA+NO group, but lung MPO was unchanged. The O2 and O2+NO groups did not differ in CD18 expression or in intracellular oxidant production, but had significant increase in lung myeloperoxidase compared to the RA group. Apoptosis increased significantly only in the O2+NO group. The O2 group showed significantly increased lung SOD and catalase activity compared to the RA group, whereas the RA+NO and O2+NO groups did not. We conclude that inhaled NO at 50 ppm decreases neutrophil CD18 expression as well as intracellular oxidant production. However, this effect does not impact lung neutrophil accumulation during concurrent hyperoxia. The combination of NO and O2 exposure produces an increase in lung apoptosis. Finally, NO may prevent upregulation of SOD and catalase activity during hyperoxia, potentially increasing injury.

Lung elastic tissue maturation and perturbations during the evolution of chronic lung disease.

BACKGROUND: Infants <30 weeks' gestation have difficulty maintaining adequate functional residual capacity after the first week of life without positive end-expiratory pressure. We hypothesized that this is caused, in part, by increased lung elastic recoil. Our aims were to quantitate parenchymal elastic tissue during normal fetal development and in infants born at 23 to 30 weeks' gestation with prolonged survival at risk for chronic lung disease (CLD). METHODS: The controls were 22 to 42 weeks' gestation (n = 71), received ventilator care, and died within 48 hours of birth, plus 7 term infants who died at 43 to 50 weeks' postconceptional age from nonpulmonary causes. Infants who were 23 to 30 weeks' gestation, at risk for CLD, and who lived 5 to 59 days (n = 44), were separated into groups based on respiratory score (SCORE; The integrated area under the curve of the average daily fraction of inspired oxygen x mean airway pressure (cm H(2)O) over the number of days lived). The SCORE groups, <20, 21 to 69 and 70 to 200, related clinically to mild to severe lung disease. The lungs were tracheally perfused and formalin-fixed and total lung volume (TLV) was measured by water displacement. The paraffin-embedded lung blocks were stained with Miller's elastic stain. The parenchyma and parenchymal elastic tissue were point-counted. The absolute elastic tissue was calculated by multiplying TLV by the parenchymal and elastic fractions. Septal width, alveoli and alveolar duct diameters, and internal surface area (ISA) were also measured. RESULTS: In the controls, the volume density of parenchymal elastic tissue and absolute quantity of elastic tissue increased progressively from 22 to 50 weeks. In infants with CLD and SCORE >/=20, the volume density and absolute quantity of elastic tissue increased significantly. Mean absolute elastic tissue in the 20 to 69 group was 0.76 +/- 0.20 cm(3) greater than in the <20 group (0.46 +/- 0.10 cm(3)) who were similar to the controls, and the 70 to 200 group was 1.32 +/- 0.56 cm(3) greater than the 20 to 69 group. Elastic tissue for infants at risk for CLD, as a percent of predicted for same-age controls, rose linearly with increasing SCORE (r = 0.73; r(2) = 0.55). Control TLV and ISA were linearly related to age. Thirty-nine of the 44 CLD-risk infants had TLVs greater than controls. However, 77% with SCORE 20 to 200 had ISAs less than or equal to the control 95% confidence interval. Control septal width decreased sharply from 23 to 30 weeks, then gradually decreased to term. All infants with SCORE 70 to 200 and 80% of those with SCORE 20 to 69 had widths more than the control 95% confidence interval. Control alveolar and duct diameters doubled from 23 to 50 weeks and were significantly greater in infants with SCORES 20 to 200. DISCUSSION: Lung elastic tissue maturation is tightly controlled during fetal development. With increasing SCORE, elastic tissue increased >200%, accounting, in part, for the positive end-expiratory pressure needed to maintain end-expiratory lung volume in infants at risk for CLD. Saccule and duct diameters more than doubled, and septa thickened significantly in CLD. We propose the following sequence to be operative in CLD: at birth, the preterm infant (