Book contents
- The Cambridge Encyclopedia of Child Development
- Child Development
- Copyright page
- Dedication
- Contents
- Contributors
- Editorial preface
- Foreword
- Acknowledgments: External Reviewers
- Introduction Study of child development: an interdisciplinary enterprise
- Part I Theories of development
- Part II Methods in child development research
- Part III Prenatal development and the newborn
- Part IV Perceptual and cognitive development
- Part V Language and communication development
- Part VI Social and emotional development
- Part VII Motor and related development
- Part VIII Postnatal brain development
- Brain and behavioral development
- Cognitive neuroscience
- Educational neuroscience
- Social neuroscience
- Part IX Developmental pathology
- Part X Crossing the borders
- Part XI Speculations about future directions
- Book part
- Author Index
- Subject Index
- Plate Section (PDF Only)
- References
Brain and behavioral development
from Part VIII - Postnatal brain development
Published online by Cambridge University Press: 26 October 2017
Book contents
- The Cambridge Encyclopedia of Child Development
- Child Development
- Copyright page
- Dedication
- Contents
- Contributors
- Editorial preface
- Foreword
- Acknowledgments: External Reviewers
- Introduction Study of child development: an interdisciplinary enterprise
- Part I Theories of development
- Part II Methods in child development research
- Part III Prenatal development and the newborn
- Part IV Perceptual and cognitive development
- Part V Language and communication development
- Part VI Social and emotional development
- Part VII Motor and related development
- Part VIII Postnatal brain development
- Brain and behavioral development
- Cognitive neuroscience
- Educational neuroscience
- Social neuroscience
- Part IX Developmental pathology
- Part X Crossing the borders
- Part XI Speculations about future directions
- Book part
- Author Index
- Subject Index
- Plate Section (PDF Only)
- References
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- Information
- The Cambridge Encyclopedia of Child Development , pp. 565 - 575Publisher: Cambridge University PressPrint publication year: 2017
References
Further reading
Knudsen, E.I. (2004). Sensitive periods in the development of the brain and behavior. Journal of Cognitive Neuroscience, 16, 1412–1425.Google Scholar
Malter Cohen, M., Tottenham, N., & Casey, B.J. (2013). Translational developmental studies of stress on brain and behavior: Implications for adolescent mental health and illness? Neuroscience, 249, 53–62.Google Scholar
Paus, T., Keshavan, M., & Giedd, J.N. (2008). Why do many psychiatric disorders emerge during adolescence? Nature Reviews: Neuroscience, 9, 947–957.CrossRefGoogle ScholarPubMed
Tau, G.Z., & Peterson, B.S. (2009). Normal development of brain circuits. Neuropsychopharmacology, 35, 147–168.CrossRefGoogle Scholar
References
Andersen, S.L., & Teicher, M.H. (2008). Stress, sensitive periods and maturational events in adolescent depression. Trends in Neurosciences, 31, 183–191.Google Scholar
Brown, T.T., & Jernigan, T.L. (2012). Brain development during the preschool years. Neuropsychology Review, 22, 313–333.CrossRefGoogle ScholarPubMed
Chen, Z., Liu, M., Gross, D.W., & Beaulieu, C. (2013). Graph theoretical analysis of developmental patterns of the white matter network. Frontiers in Human Neuroscience, 7, 716.Google Scholar
Chugani, H.T. (1998). A critical period of brain development: Studies of cerebral glucose utilization with PET. Preventive Medicine, 27, 184–188.Google Scholar
DeMaster, D., Pathman, T., Lee, J.K., & Ghetti, S. (2014). Structural development of the hippocampus and episodic memory: Developmental differences along the anterior/posterior axis. Cerebral Cortex, 24, 3036–3045.Google Scholar
Dennis, E.L., & Thompson, P.M. (2013). Typical and atypical brain development: A review of neuroimaging studies. Dialogues in Clinical Neuroscience, 15, 359–384.Google Scholar
Dennis, E.L., Jahanshad, N., McMahon, K.L., de Zubicaray, G.I., Martin, N.G., Hickie, I.B.,… & Thompson, P.N. (2013). Development of brain structural connectivity between ages 12 and 30: A 4-Tesla diffusion imaging study in 439 adolescents and adults. NeuroImage, 64, 671–684.Google Scholar
Diamond, A. (2000). Close interrelation of motor development and cognitive development and of the cerebellum and prefrontal cortex. Child Development, 71, 44–56.Google Scholar
Dubois, J., Dehaene-Lambertz, G., Kulikova, S., Poupon, C., Hüppi, P.S., & Hertz-Pannier, L. (2014). The early development of brain white matter: A review of imaging studies in fetuses, newborns and infants. Neuroscience, 276, 48–71.CrossRefGoogle ScholarPubMed
Fair, D.A., Cohen, A.L., Power, J.D., Dosenbach, N.U.F., Church, J.A., Miezin, F.M.,… & Petersen, S.E. (2009). Functional brain networks develop from a “local to distributed” organization. PLoS Computational Biology, 5, e1000381.Google Scholar
Ganguly, K., & Poo, M.-M. (2013). Activity-dependent neural plasticity from bench to bedside. Neuron, 80, 729–741.Google Scholar
Giedd, J.N., Raznahan, A., Alexander-Bloch, A., Schmitt, E., Gogtay, N., & Rapoport, J.L. (2015). Child psychiatry branch of the National Institute of Mental Health longitudinal structural magnetic resonance imaging study of human brain development. Neuropsychopharmacology, 40, 43–49.Google Scholar
Gogtay, N., Nugent, T.F., Herman, D.H., Ordonez, A., Greenstein, D., Hayashi, K.M.,… & Thompson, P.M. (2006). Dynamic mapping of normal human hippocampal development. Hippocampus, 16, 664–672.Google Scholar
Hagmann, P., Sporns, O., Madan, N., Cammoun, L., Pienaar, R., Wedeen, V.J.,… & Grant, P.E. (2010). White matter maturation reshapes structural connectivity in the late developing human brain. Proceedings of the National Academy of Sciences, 107, 19067–19072.Google Scholar
Herholz, S.C., & Zatorre, R.J. (2012). Musical training as a framework for brain plasticity: Behavior, function, and structure. Neuron, 76, 485–502.Google Scholar
van den Heuvel, M.P., Kersbergen, K.J., de Reus, M.A., Keunen, K., Kahn, R.S., Groenendaal, F., … Benders, , M.J.N.L. (2015). The neonatal connectome during preterm brain development. Cerebral Cortex, 25, 3000–3013.Google Scholar
Hibi, M., & Shimizu, T. (2012). Development of the cerebellum and cerebellar neural circuits. Developmental Neurobiology, 72, 282–301.Google Scholar
Lupien, S.J., McEwen, B.S., Gunnar, M.R., & Heim, C. (2009). Effects of stress throughout the lifespan on the brain, behaviour and cognition. Nature Reviews: Neuroscience, 10, 434–445.Google Scholar
Panizzon, M., Fennema-Notestine, C., & Eyler, L. (2009). Distinct genetic influences on cortical surface area and cortical thickness. Cerebral Cortex, 19, 2728–2735.CrossRefGoogle ScholarPubMed
Peper, J.S., Hulshoff Pol, H.E., Crone, E.A., & van Honk, J. (2011). Sex steroids and brain structure in pubertal boys and girls: A mini-review of neuroimaging studies. Neuroscience, 191, 28–37.Google Scholar
Qin, S., Young, C.B., Supekar, K., Uddin, L.Q., & Menon, V. (2012). Immature integration and segregation of emotion-related brain circuitry in young children. Proceedings of the National Academy of Sciences, 109, 7941–7946.CrossRefGoogle ScholarPubMed
Raznahan, A., Shaw, P., Lalonde, F., Stockman, M., Wallace, G.L., Greenstein, D., … & Giedd, J. (2011). How does your cortex grow? Journal of Neuroscience, 31, 7174–7177.Google Scholar
Scherf, K.S., Smyth, J.M., & Delgado, M.R. (2013). The amygdala: An agent of change in adolescent neural networks. Hormones and Behavior, 64, 298–313.Google Scholar
Shaw, P., Greenstein, D., Lerch, J., Clasen, L., Lenroot, R., Gogtay, N., … & Giedd, J. (2006). Intellectual ability and cortical development in children and adolescents. Nature, 440, 676–679.Google Scholar
Sheridan, M.A., Sarsour, K., Jutte, D., D’Esposito, M., & Boyce, W.T. (2012). The impact of social disparity on prefrontal function in childhood. PLoS ONE, 7, e35744.Google Scholar
Somerville, L.H., & Casey, B.J. (2010). Developmental neurobiology of cognitive control and motivational systems. Current Opinion in Neurobiology, 20, 236–241.Google Scholar
Steele, C.J., Bailey, J.A., Zatorre, R.J., & Penhune, V.B. (2013). Early musical training and white-matter plasticity in the corpus callosum: Evidence for a sensitive period. Journal of Neuroscience, 33, 1282–1290.CrossRefGoogle ScholarPubMed
Thomas, K.M., King, S.W., Franzen, P.L., Welsh, T.F., Berkowitz, A.L., Noll, D.C., … & Casey, B.J. (1999). A developmental functional MRI study of spatial working memory. NeuroImage, 10, 327–338.Google Scholar
Tiemeier, H., Lenroot, R.K., Greenstein, D.K., Tran, L., Pierson, R., & Giedd, J.N. (2010). Cerebellum development during childhood and adolescence: A longitudinal morphometric MRI study. NeuroImage, 49, 63–70.Google Scholar
Tottenham, N., & Sheridan, M.A. (2009). A review of adversity, the amygdala and the hippocampus: A consideration of developmental timing. Frontiers in Human Neuroscience, 3, 68.Google Scholar
Uddin, L.Q., Supekar, K.S., Ryali, S., & Menon, V. (2011). Dynamic reconfiguration of structural and functional connectivity across core neurocognitive brain networks with development. Journal of Neuroscience, 31, 18578–18589.Google Scholar
Wierenga, L.M., Langen, M., Oranje, B., & Durston, S. (2014). Unique developmental trajectories of cortical thickness and surface area. NeuroImage, 87C, 120–126.Google Scholar
de Zeeuw, P., Zwart, F., Schrama, R., van Engeland, H., & Durston, S. (2012). Prenatal exposure to cigarette smoke or alcohol and cerebellum volume in attention-deficit/hyperactivity disorder and typical development. Translational Psychiatry, 2, e84.Google Scholar