Correction to: Investigation of brain structure in the 1-month infant.

The authors regret that, in this article, there was an error in the analyses comparing infant male and female regional brain volume differences.

Investigation of brain structure in the 1-month infant.

The developing brain undergoes systematic changes that occur at successive stages of maturation. Deviations from the typical neurodevelopmental trajectory are hypothesized to underlie many early childhood disorders; thus, characterizing the earliest patterns of normative brain development is essential. Recent neuroimaging research provides insight into brain structure during late childhood and adolescence; however, few studies have examined the infant brain, particularly in infants under 3 months of age. Using high-resolution structural MRI, we measured subcortical gray and white matter brain volumes in a cohort (N = 143) of 1-month infants and examined characteristics of these volumetric measures throughout this early period of neurodevelopment. We show that brain volumes undergo age-related changes during the first month of life, with the corresponding patterns of regional asymmetry and sexual dimorphism. Specifically, males have larger total brain volume and volumes differ by sex in regionally specific brain regions, after correcting for total brain volume. Consistent with findings from studies of later childhood and adolescence, subcortical regions appear more rightward asymmetric. Neither sex differences nor regional asymmetries changed with gestation-corrected age. Our results complement a growing body of work investigating the earliest neurobiological changes associated with development and suggest that asymmetry and sexual dimorphism are present at birth.

Mapping White Matter Microstructure in the One Month Human Brain.

White matter microstructure, essential for efficient and coordinated transmission of neural communications, undergoes pronounced development during the first years of life, while deviations to this neurodevelopmental trajectory likely result in alterations of brain connectivity relevant to behavior. Hence, systematic evaluation of white matter microstructure in the normative brain is critical for a neuroscientific approach to both typical and atypical early behavioral development. However, few studies have examined the infant brain in detail, particularly in infants under 3 months of age. Here, we utilize quantitative techniques of diffusion tensor imaging and neurite orientation dispersion and density imaging to investigate neonatal white matter microstructure in 104 infants. An optimized multiple b-value diffusion protocol was developed to allow for successful acquisition during non-sedated sleep. Associations between white matter microstructure measures and gestation corrected age, regional asymmetries, infant sex, as well as newborn growth measures were assessed. Results highlight changes of white matter microstructure during the earliest periods of development and demonstrate differential timing of developing regions and regional asymmetries. Our results contribute to a growing body of research investigating the neurobiological changes associated with neurodevelopment and suggest that characteristics of white matter microstructure are already underway in the weeks immediately following birth.

Hydrogen peroxide-induced potentiation of contractile responses in isolated rat airways.

We hypothesized that metabolites of O2 may play a role in the development of airway hyperreactivity and undertook this study to examine the effects of one of these metabolites, hydrogen peroxide (H2O2), on electrical field stimulation-induced contractile responses of isolated rat intrapulmonary bronchi. Exposure to H2O2 (1 mM) elicited a transient contractile response with a peak response equivalent to 18.1 +/- 2.0% of the reference contraction obtained to electrical stimulation. The H2O2-induced contraction was attenuated by pretreatment of tissues with indomethacin and superoxide dismutase, but abolished by catalase and mianserin. Subsequent to H2O2 exposure, electrical field stimulation-induced contractile responses were potentiated (P less than 0.0001), whereas acetylcholine-induced contractions were not. The potentiating effects of H2O2 were inhibited by catalase and mianserin. Addition of 5-hydroxytryptamine (5-HT) to the bath similarly potentiated contractions to electrical stimulation (P less than 0.0001). Together, these results are consistent with a role for 5-HT in H2O2-induced contraction and the subsequent potentiation of airway smooth muscle contraction elicited by cholinergic nerve activation. Thus endogenous metabolites of O2 may be important in modulating airway smooth muscle tone.