Human umbilical cord blood mononuclear cells in a double-hit model of bronchopulmonary dysplasia in neonatal mice.

BACKGROUND: Bronchopulmonary dysplasia (BPD) presents a major threat of very preterm birth and treatment options are still limited. Stem cells from different sources have been used successfully in experimental BPD, induced by postnatal hyperoxia. OBJECTIVES: We investigated the effect of umbilical cord blood mononuclear cells (MNCs) in a new double-hit mouse model of BPD. METHODS: For the double-hit, date mated mice were subjected to hypoxia and thereafter the offspring was exposed to hyperoxia. Human umbilical cord blood MNCs were given intraperitoneally by day P7. As outcome variables were defined: physical development (auxology), lung structure (histomorphometry), expression of markers for lung maturation and inflammation on mRNA and protein level. Pre- and postnatal normoxic pups and sham treated double-hit pups served as control groups. RESULTS: Compared to normoxic controls, sham treated double-hit animals showed impaired physical and lung development with reduced alveolarization and increased thickness of septa. Electron microscopy revealed reduced volume density of lamellar bodies. Pulmonary expression of mRNA for surfactant proteins B and C, Mtor and Crabp1 was reduced. Expression of Igf1 was increased. Treatment with umbilical cord blood MNCs normalized thickness of septa and mRNA expression of Mtor to levels of normoxic controls. Tgfb3 mRNA expression and pro-inflammatory IL-1ß protein concentration were decreased. CONCLUSION: The results of our study demonstrate the therapeutic potential of umbilical cord blood MNCs in a new double-hit model of BPD in newborn mice. We found improved lung structure and effects on molecular level. Further studies are needed to address the role of systemic administration of MNCs in experimental BPD.

Bronchopulmonary dysplasia in a double-hit mouse model induced by intrauterine hypoxia and postnatal hyperoxia: closer to clinical features?

Despite increased survival of very preterm newborns, bronchopulmonary dysplasia (BPD) remains a major threat, as it affects long-term pulmonary function and neurodevelopmental outcome. Recent research focused on mechanisms of lung repair. Animal models of BPD in term rodents use postnatal hyperoxia in order to mimic features observed in very preterm human neonates: reduced alveolarization and impaired septal architecture without profound inflammatory changes. In contrast, BPD in very preterm human neonates involves prenatal hits e.g. infections and growth restriction plus postnatal ventilation. BPD induced in rodents by postnatal hyperoxia also exhibits reduced alveolarization however without septal pathology but with marked inflammation. We therefore aimed to establish an animal model combining prenatal growth restriction (FiO2 0.1 for 4 days) with postnatal hyperoxia (FiO2 0.7 for 2 weeks). In double-hit mice the development was retarded: body weight and length, lung and brain weight were significantly reduced by day P14 compared with normoxic controls. Histomorphometric analysis revealed reduced alveolarization and increased septal thickness without pronounced inflammatory lesions. A down-regulation of SftpB and SftpC genes was observed in double-hit animals compared with controls. Thus, we established a new model of BPD using pre- and postnatal hits.