Abstract
Co-existing infection/inflammation and birth asphyxia potentiate the risk of developing neonatal encephalopathy (NE) and adverse outcome. In a newborn piglet model we assessed the effect of E. coli lipopolysaccharide (LPS) infusion started 4 h prior to and continued for 48 h after hypoxia on brain cell death and systemic haematological changes compared to LPS and hypoxia alone. LPS sensitized hypoxia resulted in an increase in mortality and in brain cell death (TUNEL positive cells) throughout the whole brain, and in the internal capsule, periventricular white matter and sensorimotor cortex. LPS alone did not increase brain cell death at 48 h, despite evidence of neuroinflammation, including the greatest increases in microglial proliferation, reactive astrocytosis and cleavage of caspase-3. LPS exposure caused splenic hypertrophy and platelet count suppression. The combination of LPS and hypoxia resulted in the highest and most sustained systemic white cell count increase. These findings highlight the significant contribution of acute inflammation sensitization prior to an asphyxial insult on NE illness severity.
Highlights
Intrapartum-related neonatal encephalopathy (NE) is estimated to affect 1.16 million babies per year, causing 287,000 deaths and resulting in 50.2 million disability adjusted life years[1]
We hypothesized that the combination of LPS and hypoxia would exacerbate brain injury measured by overall transferase dUTP nick end labelling (TUNEL) positive (TUNEL+) cells compared to either intervention alone
Bacterial LPS commenced 4 h prior to hypoxia and continued for 48 h in the newborn piglet resulted in an increase in mortality and an exacerbation of brain cell death compared to hypoxia alone
Summary
Intrapartum-related neonatal encephalopathy (NE) is estimated to affect 1.16 million babies per year, causing 287,000 deaths and resulting in 50.2 million disability adjusted life years[1]. The overall aim of the study was to compare LPS, Hypoxia and LPS + Hypoxia groups over 52 h for: (i) physiological changes; (ii) morbidity and mortality; (iii) amplitude integrated EEG (aEEG) background activity recovery over 48 h, which is a predictor of outcome in babies with NE29; (iv) histological assessment of TUNEL+ cell death in 8 brain regions at 48 h after hypoxia; and (v) systemic haematological changes. We used an established piglet model that replicates neonatal intensive care monitoring and control of physiological and metabolic parameters. This model has strong similarities to newborn infants with NE in terms of the timing of the evolution of injury after HI, pattern of injury and neuropathology[30,31]
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