RationaleBronchopulmonary dysplasia is one of the most serious complications observed in premature infants. Thanks to microarray technique, expression of nearly all human genes can be reliably evaluated.ObjectiveTo compare whole genome expression in the first month of life in groups of infants with and without bronchopulmonary dysplasia.Methods111 newborns were included in the study. The mean birth weight was 1029g (SD:290), and the mean gestational age was 27.8 weeks (SD:2.5). Blood samples were drawn from the study participants on the 5th, 14th and 28th day of life. The mRNA samples were evaluated for gene expression with the use of GeneChip® Human Gene 1.0 ST microarrays. The infants were divided into two groups: bronchopulmonary dysplasia (n=68) and control (n=43).ResultsOverall 2086 genes were differentially expressed on the day 5, only 324 on the day 14 and 3498 on the day 28. Based on pathway enrichment analysis we found that the cell cycle pathway was up-regulated in the bronchopulmonary dysplasia group. The activation of this pathway does not seem to be related with the maturity of the infant. Four pathways related to inflammatory response were continuously on the 5th, 14th and 28th day of life down-regulated in the bronchopulmonary dysplasia group. However, the expression of genes depended on both factors: immaturity and disease severity. The most significantly down-regulated pathway was the T cell receptor signaling pathway.ConclusionThe results of the whole genome expression study revealed alteration of the expression of nearly 10% of the genome in bronchopulmonary dysplasia patients.
In this review oxygenation and hyperoxic injury of newborn infants are described through molecular and genetic levels. Protection and repair mechanisms that may be important for a new understanding of oxidative stress in the newborn are discussed. The research summarized in this article represents a basis for the reduced oxygen supplementation and oxidative load of newborn babies, especially since the turn of the century. The mechanisms discussed may also contribute to an understanding of why hyperoxic resuscitation of the newborn may damage DNA and affect its repair, thus increasing the risk that it may be carcinogenic. Today, term babies should be resuscitated with air rather than 100% oxygen and very and extremely low birth weight infants in need of stabilization or resuscitation at birth should be administered initially 21–30% oxygen and the level should be titrated according to the response, preferably measured by pulse oximetry. In the postnatal period the oxygen saturation should be targeted low <95%; however, saturations between 85 and 89% seem to increase mortality. The optimal oxygen saturation target for these infants postnatally is still unknown.
Background: Hyperoxic reoxygenation following hypoxia increases the expression of inflammatory genes in the neonatal mouse brain. We have therefore compared the temporal profile of 44 a priori selected genes after hypoxia and hyperoxic or normoxic reoxygenation. Methods: Postnatal day 7 mice were subjected to 2 h of hypoxia (8% O 2 ) and 30 min reoxygenation with 60% or 21% O 2 . After 0 to 72 h observation, mRNA and protein were examined in the hippocampus and striatum. results: There were significantly higher gene expression changes in six genes after hyperoxic compared to normoxic reoxygenation. Three genes had a generally higher expression throughout the observation period: the inflammatory genes Hmox1 (mean difference: 0.52, 95% confidence interval (CI): 0.15-1.01) and Tgfb1 (mean difference: 0.099, CI: 0.003-0.194), and the transcription factor Nfkb1 (mean difference: 0.049, CI: 0.011-0.087). The inflammatory genes Cxcl10 and Il1b, and the DNA repair gene Neil3, had a higher gene expression change after hyperoxic reoxygenation at one time point only. Nineteen genes involved in inflammation, transcription regulation, apoptosis, angiogenesis, and glucose transport had significantly different gene expression changes with time in all intervention animals. conclusion: We confirm that hyperoxic reoxygenation induces a stronger inflammatory gene response than reoxygenation with air.
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