Vann Chau

Procedural pain and brain development in premature newborns.

Preterm infants are exposed to multiple painful procedures in the neonatal intensive care unit (NICU) during a period of rapid brain development. Our aim was to examine relationships between procedural pain in the NICU and early brain development in very preterm infants.

Arrested preoligodendrocyte maturation contributes to myelination failure in premature infants.

The major form of magnetic resonance imaging–defined white matter injury (WMI) comprises diffuse lesions where the burden of small necrotic foci (microscopic necrosis) is poorly defined. We hypothesized that myelination failure associated with diffuse WMI involves an aberrant injury response linked to arrested preoligodendrocyte (preOL) maturation in reactive astrocyte‐rich lesions.

Effect of chorioamnionitis on brain development and injury in premature newborns

The association of chorioamnionitis and noncystic white matter injury, a common brain injury in premature newborns, remains controversial. Our objectives were to determine the association of chorioamnionitis and postnatal risk factors with white matter injury, and the effects of chorioamnionitis on early brain development, using advanced magnetic resonance imaging.

Slower Postnatal Growth Is Associated with Delayed Cerebral Cortical Maturation in Preterm Newborns

Impaired growth during neonatal intensive care is associated with delayed microstructural development of the cortical gray matter after accounting for prenatal growth, neonatal illness, and brain injury in infants born very preterm. Early Start for Better Brains Despite all of the recent advances in medical care for premature newborns, these infants still often experience complications. In particular, cognitive problems and developmental delays are common in this patient population and can be difficult to predict. Now, two sets of authors have obtained new data that approach this problem from different angles using diffusion tensor magnetic resonance imaging (MRI) in human infants and newborn lambs. Vinall and coauthors examined 95 premature newborn babies who were born at 24 to 32 weeks of gestation. The authors performed two sets of MRI scans on these infants: one scan was done about 2 months before their due dates and the other scan when they reached full term. The authors also tracked the infants’ growth parameters—weight, length, and head size—as well as data on other factors that could affect brain growth, including the presence of infections or other serious illnesses. A detailed analysis of the MRI scans showed that the development of normal brain structure correlated with postnatal growth (and presumably nutrition) even after accounting for any other illnesses the infants may have experienced early in life. Dean et al. took a different approach to studying premature brain development: they analyzed the brain structures of fetal lambs that had experienced ischemia in utero at a time that corresponded to about two-thirds of full gestation time. The lambs were analyzed both by MRI and by histological analysis of the brain at 1, 2, or 4 weeks after an in utero ischemic event, and these data were compared to those of age-matched animals that did not undergo ischemic episodes. Here, the authors also saw abnormalities in brain development by MRI and correlated them with histological and structural aberrations. The growth impairment seen in the animals’ brains by MRI corresponded to disturbances in the branching of neuronal dendrites and abnormal formation of synapse connections with other neurons. More studies are needed to understand how postnatal growth, nutrition, illness, and prenatal ischemia affect the developing brain to develop methods for preventing any resulting injury. In addition, long-term studies should help to determine how differences in brain anatomy and MRI data translate into developmental and cognitive outcomes. Slower postnatal growth is an important predictor of adverse neurodevelopmental outcomes in infants born preterm. However, the relationship between postnatal growth and cortical development remains largely unknown. Therefore, we examined the association between neonatal growth and diffusion tensor imaging measures of microstructural cortical development in infants born very preterm. Participants were 95 neonates born between 24 and 32 weeks gestational age studied twice with diffusion tensor imaging: scan 1 at a median of 32.1 weeks (interquartile range, 30.4 to 33.6) and scan 2 at a median of 40.3 weeks (interquartile range, 38.7 to 42.7). Fractional anisotropy and eigenvalues were recorded from 15 anatomically defined cortical regions. Weight, head circumference, and length were recorded at birth and at the time of each scan. Growth between scans was examined in relation to diffusion tensor imaging measures at scans 1 and 2, accounting for gestational age, birth weight, sex, postmenstrual age, known brain injury (white matter injury, intraventricular hemorrhage, and cerebellar hemorrhage), and neonatal illness (patent ductus arteriosus, days intubated, infection, and necrotizing enterocolitis). Impaired weight, length, and head growth were associated with delayed microstructural development of the cortical gray matter (fractional anisotropy: P < 0.001), but not white matter (fractional anisotropy: P = 0.529), after accounting for prenatal growth, neonatal illness, and brain injury. Avoiding growth impairment during neonatal care may allow cortical development to proceed optimally and, ultimately, may provide an opportunity to reduce neurological disabilities related to preterm birth.

Differential effects of intraventricular hemorrhage and white matter injury on preterm cerebellar growth

OBJECTIVE To hypothesize that detailed examination of early cerebellar volumes in time would distinguish differences in cerebellar growth associated with intraventricular hemorrhage (IVH) and white matter injury in preterm infants. STUDY DESIGN Preterm newborns at the University of California San Francisco (n = 57) and the University of British Columbia (n = 115) were studied with serial magnetic resonance imaging scans near birth and again at near term-equivalent age. Interactive semi-automated tools were used to determine volumes of the cerebellar hemispheres. RESULTS Adjusting for supratentorial brain injury, cerebellar hemorrhage, and study site, cerebellar volume increased 1.7 cm(3)/week postmenstrual age (95% CI, 1.6-1.7; P < .001). More severe supratentorial IVH was associated with slower growth of cerebellar volumes (P < .001). Volumes by 40 weeks were 1.4 cm(3) lower in premature infants with grade 1 to 2 IVH and 5.4 cm(3) lower in infants with grade 3 to 4 IVH. The same magnitude of decrease was found between ipsilateral and contralateral IVH. No association was found with severity of white matter injury (P = .3). CONCLUSIONS Early effects of decreased cerebellar volume associated with supratentorial IVH in either hemisphere may be a result of concurrent cerebellar injury or direct effects of subarachnoid blood on cerebellar development.

Clinically silent preoperative brain injuries do not worsen with surgery in neonates with congenital heart disease.

OBJECTIVE Preoperative brain injury, particularly stroke and white matter injury, is common in neonates with congenital heart disease. The objective of this study was to determine the risk of hemorrhage or extension of preoperative brain injury with cardiac surgery. METHODS This dual-center prospective cohort study recruited 92 term neonates, 62 with transposition of the great arteries and 30 with single ventricle physiology, from 2 tertiary referral centers. Neonates underwent brain magnetic resonance imaging scans before and after cardiac surgery. RESULTS Brain injury was identified in 40 (43%) neonates on the preoperative magnetic resonance imaging scan (median 5 days after birth): stroke in 23, white matter injury in 21, and intraventricular hemorrhage in 7. None of the brain lesions presented clinically with overt signs or seizures. Preoperative brain injury was associated with balloon atrial septostomy (P = .003) and lowest arterial oxygen saturation (P = .007); in a multivariable model, only the effect of balloon atrial septostomy remained significant when adjusting for lowest arterial oxygen saturation. On postoperative magnetic resonance imaging in 78 neonates (median 21 days after birth), none of the preoperative lesions showed evidence of extension or hemorrhagic transformation (0/40 [95% confidence interval: 0%-7%]). The presence of preoperative brain injury was not a significant risk factor for acquiring new injury on postoperative magnetic resonance imaging (P = .8). CONCLUSIONS Clinically silent brain injuries identified preoperatively in neonates with congenital heart disease, including stroke, have a low risk of progression with surgery and cardiopulmonary bypass and should therefore not delay clinically indicated cardiac surgery. In this multicenter cohort, balloon atrial septostomy remains an important risk factor for preoperative brain injury, particularly stroke.

Brain injury and development in newborns with critical congenital heart disease.

Objective: To determine the relationship between radiologically identifiable brain injuries and delayed brain development as reflected by brain metabolic and microstructural integrity. Methods: Term newborns with congenital heart disease (CHD) (120 preoperatively and 104 postoperatively) were studied with MRI to determine brain injury severity (BIS), microstructure reflected by fractional anisotropy (FA) and average diffusivity (Dav), and metabolism reflected by N-acetylaspartate (NAA)/choline (Cho) and lactate/Cho. Brain development is characterized by increasing NAA/Cho and white matter FA, and by decreasing Dav and lactate/Cho. Results: Newly acquired brain injury was common (41% preoperative, 30% postoperative). Lower white matter FA (p = 0.005) and lower NAA/Cho (p = 0.01) were associated with increasing preoperative BIS. Higher neonatal illness severity scores (p = 0.03), lower preoperative oxygen saturation (p = 0.002), hypotension (p < 0.001), and septostomy (p = 0.002) were also predictive of higher preoperative BIS. Preoperative FA, Dav, and NAA/Cho did not predict new postoperative BIS. Increasing preoperative BIS predicted higher postoperative Dav (p = 0.002) and lactate/Cho (p = 0.008). Within the postoperative scan, new brain injuries were associated with lower white matter FA (p = 0.04). Postoperative BIS (new lesions) was associated with lower postoperative systolic (p = 0.03) and mean (p = 0.05) blood pressures. Conclusions: Brain injuries in newborns with CHD are strongly related to abnormalities of brain microstructural and metabolic brain development, especially preoperatively. Both newly acquired preoperative and postoperative brain injuries are related to potentially modifiable clinical risk factors.

Neonatal pain in relation to postnatal growth in infants born very preterm

TOC summary Repetitive procedural pain in preterm infants appears to impact early body growth and head circumference, after accounting for multiple medical confounders. ABSTRACT Procedural pain is associated with poorer neurodevelopment in infants born very preterm (⩽32 weeks gestational age), however, the etiology is unclear. Animal studies have demonstrated that early environmental stress leads to slower postnatal growth; however, it is unknown whether neonatal pain‐related stress affects postnatal growth in infants born very preterm. The aim of this study was to examine whether greater neonatal pain (number of skin‐breaking procedures adjusted for medical confounders) is related to decreased postnatal growth (weight and head circumference [HC] percentiles) early in life and at term‐equivalent age in infants born very preterm. Participants were n = 78 preterm infants born ⩽32 weeks gestational age, followed prospectively since birth. Infants were weighed and HC measured at birth, early in life (median: 32 weeks [interquartile range 30.7–33.6]) and at term‐equivalent age (40 weeks [interquartile range 38.6–42.6]). Weight and HC percentiles were computed from sex‐specific British Columbia population‐based data. Greater neonatal pain predicted lower body weight (Wald χ2 = 7.36, P = 0.01) and HC (Wald χ2 = 4.36, P = 0.04) percentiles at 32 weeks postconceptional age, after adjusting for birth weight percentile and postnatal risk factors of illness severity, duration of mechanical ventilation, infection, and morphine and corticosteroid exposure. However, later neonatal infection predicted lower weight percentile at term (Wald χ2 = 5.09, P = 0.02). Infants born very preterm undergo repetitive procedural pain during a period of physiological immaturity that appears to impact postnatal growth, and may activate a downstream cascade of stress signaling that affects later growth in the neonatal intensive care unit.

Extreme premature birth is not associated with impaired development of brain microstructure.

OBJECTIVE To assess whether birth at <26 weeks gestation is an important predictor of brain microstructure maturation as determined by using diffusion tensor imaging. STUDY DESIGN We performed serial magnetic resonance imaging and diffusion tensor imaging in 176 infants born at <33 weeks gestation. Diffusion parameters were calculated for white and gray matter regions. Linear regression for repeated measures was used to assess the effect of extremely premature birth on brain maturation. RESULTS In white matter, fractional anisotropy increased by 0.008 per week (95% CI, 0.007-0.009; P < .0001) and mean diffusivity decreased by 0.021 mm(2)/sec per week, (95% CI, -0.24-0.018; P < .0001). Birth at <26 weeks was associated with lower white matter fractional anisotropy (-0.01; 95% CI, -0.018-0.003; P = .008), but this effect was eliminated when co-morbid conditions were added to the model. Moderate-severe brain injury was associated with decreased mean white matter fractional anisotropy (-0.012; 95% CI, -0.02-0.004; P = .002). CONCLUSION Brain microstructure maturation as measured serially in premature infants is independent of extremely premature birth. Brain injury and co-morbid conditions may be the important determinants of microstructure maturation.

Tractography-Based Quantitation of Corticospinal Tract Development in Premature Newborns

OBJECTIVE To evaluate the impact of early brain injury and neonatal illness on corticospinal tract (CST) development in premature newborns serially studied with diffusion tensor tractography. STUDY DESIGN Fifty-five premature newborns (median 27.6 weeks postmenstrual age) were scanned with magnetic resonance imaging (MRI) early in life and at term-equivalent age. Moderate-severe brain abnormalities (abnormal-MRI) were characterized by moderate-severe white matter injury or ventriculomegaly. Diffusion tensor tractography was used to measure CST diffusion parameters which reflect microstructural development: fractional anisotropy (FA) and average diffusivity (D(av)). The effect of abnormal-MRI and neonatal illness on FA and D(av) were assessed with multivariate regression for repeated measures adjusting for age at scan. RESULTS Twenty-one newborns (38%) had abnormal-MRI on either scan. FA increased with age significantly slower in newborns with abnormal-MRI (0.008/week) relative to newborns without these MRI abnormalities (0.011/wk) (interaction term P = .05). D(av) was higher in newborns with abnormal-MRI (1.5 x 10(-5) mm(2)/sec; P < .001) for any given age at scan. In the 23 newborns (42%) with postnatal infection, FA increased more slowly (interaction term P = .04), even when adjusting for the presence of abnormal-MRI. CONCLUSIONS CST microstructural development is significantly impaired in premature newborns with abnormal-MRI or postnatal infection, with a pattern of diffusion changes suggesting impaired glial cell development.