Background and ObjectiveHigh bilirubin/albumin (B/A) ratios increase the risk of bilirubin neurotoxicity. The B/A ratio may be a valuable measure, in addition to the total serum bilirubin (TSB), in the management of hyperbilirubinemia. We aimed to assess whether the additional use of B/A ratios in the management of hyperbilirubinemia in preterm infants improved neurodevelopmental outcome.MethodsIn a prospective, randomized controlled trial, 615 preterm infants of 32 weeks' gestation or less were randomly assigned to treatment based on either B/A ratio and TSB thresholds (consensus-based), whichever threshold was crossed first, or on the TSB thresholds only. The primary outcome was neurodevelopment at 18 to 24 months' corrected age as assessed with the Bayley Scales of Infant Development III by investigators unaware of treatment allocation. Secondary outcomes included complications of preterm birth and death.ResultsComposite motor (100±13 vs. 101±12) and cognitive (101±12 vs. 101±11) scores did not differ between the B/A ratio and TSB groups. Demographic characteristics, maximal TSB levels, B/A ratios, and other secondary outcomes were similar. The rates of death and/or severe neurodevelopmental impairment for the B/A ratio versus TSB groups were 15.4% versus 15.5% (P = 1.0) and 2.8% versus 1.4% (P = 0.62) for birth weights ≤1000 g and 1.8% versus 5.8% (P = 0.03) and 4.1% versus 2.0% (P = 0.26) for birth weights of >1000 g.ConclusionsThe additional use of B/A ratio in the management of hyperbilirubinemia in preterm infants did not improve their neurodevelopmental outcome.Trial RegistrationControlled-Trials.com ISRCTN74465643
Purine and Pyrimidine Metabolism and Electrocortical Brain Activity during Hypoxemia in Near-Term Lambs
Insufficient cerebral O 2 supply leads to brain cell damage and loss of brain cell function. The relationship between the severity of hypoxemic brain cell damage and the loss of electrocortical brain activity (ECBA), as measure of brain cell function, is not yet fully elucidated in near-term newborns. We hypothesized that there is a strong relationship between cerebral purine and pyrimidine metabolism, as measures of brain cell damage, and brain cell function during hypoxemia. Nine near-term lambs (term, 147 d) were delivered at 131 (range, 120-141) d of gestation. After a stabilization period, prolonged hypoxemia (fraction of inspired oxygen, 0.10; duration, 2.5 h) was induced. Mean values of carotid artery blood flow, as a measure of cerebral blood flow, and ECBA were calculated over the last 3 min of hypoxemia. At the end of the hypoxemic period, cerebral arterial and venous blood gases were determined and CSF was obtained. CSF from 11 normoxemic siblings was used for baseline values. HPLC was used to determine purine and pyrimidine metabolites in CSF, as measures of brain cell damage. Concentrations of purine and pyrimidine metabolites were significantly higher in hypoxemic lambs than in their siblings, whereas ECBA was lower in hypoxemic lambs. Significant negative linear relationships were found between purine and pyrimidine metabolite concentrations and, respectively, cerebral O 2 supply, cerebral O 2 consumption, and ECBA. We conclude that brain cell function is related to concentrations of purine and pyrimidine metabolites in the CSF. Reduction of ECBA indeed reflects the measure of brain damage due to hypoxemia in near-term newborn lambs. Despite the increase in survival of preterm infants, long-term morbidity has not changed (1). Hypoxia-ischemia-related brain damage is an important contributor to perinatal mortality and long-term morbidity in survivors (2).The immature brain is very vulnerable to disturbances in cerebral oxygenation and hemodynamics. Cerebral O 2 supply depends on both CaO 2 and CBF. Cerebral hypoxia is defined as an insufficient O 2 supply to the brain, resulting from either hypoxemia (decreased CaO 2 ) or hypoperfusion (decreased CBF). During hypoxemia, the brain is considered to be protected adequately from injury by an increase in CBF to preserve cerebral O 2 supply and to stabilize brain metabolism, unless cerebral ischemia occurs from supervening systemic hypotension. With the neuronal oxygen and glucose debts arising from severe hypoxemia, oxidative metabolism shifts to anaerobic glycolysis, with its inefficient generation of highenergy phosphate reserves, necessary to maintain cellular ionic gradients and other metabolic processes. However, when hypoxemia progresses, cellular energy failure ultimately occurs, which, if not promptly reversed, results in decreased neuronal viability and death of the cell (3).During insufficient cerebral O 2 supply, an accumulation of purine metabolites, which are the degradation products from high-energy phosphate compounds (ATP, ADP, and AMP),...
Adequate cerebral perfusion is necessary to preserve cerebral O(2) supply in order to maintain brain cell function. Our aim was to assess the influence of gestational age on the response of cerebral hemodynamics to hypoxemia and to determine thresholds of cerebral O(2) supply for preservation of brain cell function in preterm born lambs. Lambs were delivered by hysterotomy at 141 (n=5), 134 (n=5) or 127 (n=7) days of gestation. Decreases in arterial oxygen content (CaO(2)) were induced by stepwise reduction of the fraction of O(2) in inspired air (FiO(2)). Mean arterial blood pressure (MABP), carotid artery blood flow (Qcar), and electrocortical brain activity as a measure of brain cell function, were continuously recorded. Cerebral arterial blood gases were analyzed at the end of each hypoxemic level to calculate CaO(2) and cerebral O(2) supply. In contrast to 141-day lambs, MABP could not be maintained in 134-day and 127-day lambs at levels of severe hypoxemia. Increases in Qcar were observed at levels of moderate hypoxemia in all gestational age-groups. Albeit Qcar increased further at levels of severe hypoxemia in the 141-day lambs, Qcar declined under these conditions in the 134-day and 127-day lambs. The threshold of cerebral O(2) supply for the preservation of brain cell function was however similar in all gestational age-groups (1.7 ml/min). It is concluded that the ability to maintain cerebral function during hypoxemia depends upon the ability to preserve cerebral O(2) supply by means of cerebral hemodynamic compensatory mechanisms, which are not fully matured until 96% of gestation.
We observed an increase in methicillin-susceptible Staphylococcus aureus (MSSA) infections at a Dutch neonatal intensive care unit. Weekly neonatal MSSA carriage surveillance and cross-sectional screenings of health care workers (HCWs) were available for outbreak tracing. Traditional clustering of MSSA isolates by spa typing and Multiple-Locus Variable number tandem repeat Analysis (MLVA) suggested that nosocomial transmission had contributed to the infections. We investigated whether whole-genome sequencing (WGS) of MSSA surveillance would provide additional evidence for transmission. MSSA isolates from neonatal infections, carriage surveillance, and HCWs were subjected to WGS and bioinformatic analysis for identification and localization of high-quality single nucleotide polymorphisms, and in-depth analysis of subsets of isolates. By measuring the genetic diversity in background surveillance, we defined transmission-level relatedness and identified isolates that had been unjustly assigned to clusters based on MLVA, while spa typing was concordant but of insufficient resolution. Detailing particular subsets of isolates provided evidence that HCWs were involved in multiple outbreaks, yet it alleviated concerns about one particular HCW. The improved resolution and accuracy of genomic outbreak analyses substantially altered the view on outbreaks, along with apposite measures. Therefore, inclusion of the circulating background population has the potential to overcome current issues in genomic outbreak inference. In the third level neonatal intensive care unit (NICU) of our hospital, we observed a rise in methicillin-susceptible S. aureus (MSSA) infections in two consecutive years. Traditional MSSA typing methods brought the suspicion of health care workers (HCWs) being repeatedly involved in the outbreak transmission chains. However, as these traditional typing methods fell short in providing definitive answers, we set out to improve the resolution of our outbreak analysis by bacterial whole-genome sequencing (WGS). Neonates have an immature immune system and are susceptible to opportunistic bacterial infections, especially in case of premature birth. Important bacteria involved in outbreaks at NICUs causing neonatal infections are Enterobacteriaceae and S. aureus. Although many studies have emphasized transmission of MRSA (methicillin-resistant S. aureus), its susceptible variant MSSA is, depending on local epidemiology, generally a more frequent cause of neonatal infections 1-3. Neonatal bacterial infections are preceded by bacterial spread which involves both direct transmission by close interaction with visiting parents and HCWs and indirect
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