2011
DOI: 10.1159/000327245
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Deleterious Effect of Hyperoxia at Birth on White Matter Damage in the Newborn Rat

Abstract: White matter damage (WMD) remains the leading cause of cerebral palsy in children born prematurely. The release of an excessive amount of reactive oxygen species is recognized as a risk factor for WMD. We hypothesize that free radical injury during reoxygenation at birth may be harmful to the immature white matter and may underlie, at least in part, the pathogenesis of WMD. We tested this hypothesis in rat pups delivered from normoxic pregnant rats, and by investigating an animal model based on protracted ante… Show more

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Cited by 41 publications
(34 citation statements)
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“…Furthermore, rats at P3 and P6, but not at P10, showed hypomyelination upon exposure to 80% oxygen (15). In the study by Vottier et al (22), white matter myelin content and mature oligodendrocyte density at P10 were significantly reduced by postnatal hyperoxia for 7 d, but >2-fold increase in ED1-and TUNEL-positive cells at P3 tended to subside at P10, and significantly increased GFAP positive cells at P3 became normalized at P10. There were no significant differences in several neurotrophic factors, such as BDNF and VEGF, between the study groups.…”
Section: Y-axes: (A-e) Brain Weight (In Grams) X-axes: (A-d) Lung Inmentioning
confidence: 90%
“…Furthermore, rats at P3 and P6, but not at P10, showed hypomyelination upon exposure to 80% oxygen (15). In the study by Vottier et al (22), white matter myelin content and mature oligodendrocyte density at P10 were significantly reduced by postnatal hyperoxia for 7 d, but >2-fold increase in ED1-and TUNEL-positive cells at P3 tended to subside at P10, and significantly increased GFAP positive cells at P3 became normalized at P10. There were no significant differences in several neurotrophic factors, such as BDNF and VEGF, between the study groups.…”
Section: Y-axes: (A-e) Brain Weight (In Grams) X-axes: (A-d) Lung Inmentioning
confidence: 90%
“…It has been observed in experimental animals that hyperoxemia increases apoptotic cell death and white matter damage (14,15). The vulnerability to oxygen-induced cell death is age dependent and the maximal incidence is observed during the first week of life (16).…”
Section: Discussionmentioning
confidence: 99%
“…(Gerstner et al, 2008; Leviton et al, 2010; Vottier et al, 2011) Although the dysfunctions at age 10 years differ from those assessed at age 2 years, we continue to see the diversity and lack of cohesiveness of associated dysfunctions.…”
Section: Discussionmentioning
confidence: 99%
“…Although some observers want to emphasize hypoxia as a cause of brain injury in preterm newborns, (Salmaso et al, 2014; Volpe, 2009) other blood gas derangements, including hyperoxemia,(Gerstner et al, 2008; Leviton et al, 2010; Vottier et al, 2011) hypocapnia (hypocarbia),(Dammann et al, 2001; Fritz and Delivoria-Papadopoulos, 2006; Leviton et al, 2010) hypercapnia,(Fritz and Delivoria-Papadopoulos, 2006; Hagen et al, 2008; Leviton et al, 2010) and acidemia (acidosis)(Lavrijsen et al, 2005; Leviton et al, 2010) either are capable of contributing to brain damage in the immature brain, or are closely linked with related phenomena. We know of no study of the relationship between indicators of oxygenation or of carbon dioxide exchange shortly after birth among extremely preterm newborns and neurocognitive functions 10 years later.…”
Section: Introductionmentioning
confidence: 99%