Increased lung water and tissue damage in bronchopulmonary dysplasia.

OBJECTIVES: To test the hypothesis that high and asymmetrical water content persists in infants with bronchopulmonary dysplasia (BPD) and that this is associated with nonuniform lung damage. STUDY DESIGN: Magnetic resonance imaging was used to assess lung water content in 20 infants and tissue injury in 35 infants of 23 to 33 weeks' gestational age (15 with severe BPD, 13 with mild BPD, and 7 without BPD). Relative proton density provided an index of water content and distribution. The location and extent of focal densities and cyst-like appearances indicating lung damage were defined. RESULTS: Proton density was significantly higher in dependent regions. Average proton density, proton density gradient, and severity of lung damage were greater in infants with severe BPD. Indicators of damage were greatest in dorsal lung regions. BPD was associated with a higher lung water burden and gravity-dependent atelectasis and/or alveolar flooding. Lesions were more common in dorsal lung regions in infants with severe lung damage. CONCLUSIONS: Infants with BPD have increased lung water and are susceptible to gravity-induced collapse and/or alveolar flooding in the dependent lung. Focal tissue damage appears to be distributed inhomogenously.

Magnetic resonance imaging of lung water content and distribution in term and preterm infants.

An increase in lung liquid may contribute to respiratory disease in preterm infants. Uneven distribution of lung liquid may cause heterogeneity in the lung disease seen in these infants. We used magnetic resonance imaging to investigate lung water content and distribution in 16 preterm (24-31 weeks) and 9 term infants in the first week of life. Images of lung parenchyma were examined and relative proton density quantified to give an index of lung water. Lung water content and distribution were compared between preterm and term infants, and in preterm infants regional signal distribution between dependent and nondependent lung on T1 weighted images was also compared after turning between prone and supine positions. Relative proton density was higher in preterm than in term lung (p < 0.008) and greater in dependent than in nondependent regions, particularly in the preterm (p < 0.001). Repositioning preterm infants rapidly redistributed signal intensities, with more even distribution lying prone than supine (p < 0.001). Small, low-signal regions were seen in the lung parenchyma in preterm but not in term infants, which may indicate peribronchial fluid or overdistension of compliant lung units. We conclude that lung water content is higher in preterm than in term infants and is associated with gravity-related changes consistent with dependent atelectasis.