Animal models with complex cortical development are useful for improving our understanding of the wide spectrum of neurodevelopmental challenges facing human preterm infants. Magnetic resonance imaging (MRI) techniques can define both cerebral injury and alterations in cerebral development with translation between animal models and the human infant. We hypothesized that the immature ferret would display a similar sequence of brain development (both grey (GM) and white matter (WM)) to that of the preterm human infant. We describe postnatal ferret neurodevelopment with conventional and diffusion MRI. The ferret is born lissencephalic with a thin cortical plate and relatively large ventricles. Cortical folding and WM maturation take place during the first month of life. From the mid-second through the third week of postnatal life, the ferret brain undergoes a similar, though less complex, pattern of maturational changes to those observed in the human brain during the second half of gestation. GM anisotropy decreases rapidly in the first three weeks of life, followed by an upward surge of surface folding and WM anisotropy over the next two weeks.
WHAT'S KNOWN ON THIS SUBJECT: Computed tomography is commonly used for neuroimaging in newborn infants with neonatal encephalopathy despite concerns over potential harm from radiation exposure. Alternative neuroimaging options include MRI and cranial ultrasound.WHAT THIS STUDY ADDS: Using a very large, international, multicenter database, we demonstrate utilization rates and compare diagnostic findings of computed tomography, MRI, and cranial ultrasound in the evaluation of neonatal encephalopathy. abstract BACKGROUND AND OBJECTIVE: Computed tomography (CT) is still used for neuroimaging of infants with known or suspected neurologic disorders. Alternative neuroimaging options that do not expose the immature brain to radiation include MRI and cranial ultrasound. We aim to characterize and compare the use and findings of neuroimaging modalities, especially CT, in infants with neonatal encephalopathy. METHODS:The Vermont Oxford Network Neonatal Encephalopathy Registry enrolled 4171 infants ($36 weeks' gestation or treated with therapeutic hypothermia) between 2006 and 2010 who were diagnosed with encephalopathy in the first 3 days of life. Demographic, perinatal, and medical conditions were recorded, along with treatments, comorbidities, and outcomes. The modality, timing, and results of neuroimaging were also collected. RESULTS:CT scans were performed on 933 of 4107 (22.7%) infants, and 100 of 921 (10.9%) of those received multiple CT scans. Compared with MRI, CT provided less detailed evaluation of cerebral injury in areas of prognostic significance, but was more sensitive than cranial ultrasound for hemorrhage and deep brain structural abnormalities.CONCLUSIONS: CT is commonly used for neuroimaging in newborn infants with neonatal encephalopathy despite concerns over potential harm from radiation exposure. The diagnostic performance of CT is inferior to MRI in identifying neonatal brain injury. Our data suggest that using cranial ultrasound for screening, followed by MRI would be more appropriate than CT at any stage to evaluate infants with neonatal encephalopathy.
Increasing intake of sodium appears to be a modifiable risk factor for intraventricular hemorrhage in very low birth weight infants.
Articles Translational Investigation nature publishing group INTRODUCTION: chronic hypoxia in rodents induces white matter (WM) injury similar to that in human preterm infants. We used diffusion tensor imaging (DTI) and immunohistochemistry to study the impact of hypoxia in the immature ferret at two developmental time points relevant to the preterm and term brain. RESULTS: On ex vivo imaging, the apparent diffusion coefficient (aDc) was decreased throughout the WM after 10 days of hypoxia (hypoxia from postnatal day 10 (P10) to P20 and killed at P20 (early hypoxia P20)), corresponding to increased astrocytosis and decreased myelination. Diffusion values normalized after 10 days of normoxia (hypoxia from P10 to P20 and killed at P30 (early hypoxia P30)), but immunohistochemistry revealed significant astrocytosis and hypomyelination. In contrast, aDc and anisotropy were increased after 10 days of hypoxia at a later developmental time point (hypoxia from P20 to P30 and killed at P30 (late hypoxia P30)), with less astrocytosis and more prominent myelination. DISCUSSION: The patterns of alteration in imaging and histology varied in relation to the developmental time at which hypoxia occurred. Normalization of diffusion measures did not correspond to the normalization of underlying histopathology. METHODS: Ferrets were subjected to 10% hypoxia and divided into three groups: early hypoxia P20, early hypoxia P30, and late hypoxia P30.
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