| [1] | Rees S, Inder I (2005) Fetal and neonatal origins of altered brain development. Early Hum Dev 81: 753–761.
|
| [2] | Davis EP, Buss C, Muftuler T, Head K, Hasso A, et al.. (2011) Children's brain development benefits from longer gestation. Frontiers in Psychology 2 . doi: 10.3389/fpsyg.2011.00001.
|
| [3] | Wolke D (2011) Preterm and low birth weight children. In: P Howlin, T Charman, Ghaziuddin M, editors. The SAGE Handbook of Developmental Disorders. London, UK: Sage Publications 497–527.
|
| [4] | Peterson BS (2003) Brain imaging studies of the anatomical and functional consequences of preterm birth for human brain development. Ann N Y Acad Sci 1008: 219–237.
|
| [5] | Volpe JJ (2009) Brain injury in premature infants: a complex amalgam of destructive and developmental disturbances. Lancet Neurology 8: 110–124.
|
| [6] | Cheong JLY, Hunt RW, Anderson PJ, Howard K, Thompson DK, et al. (2008) Head growth in preterm infants: Correlation with magnetic resonance imaging and neurodevelopmental outcome. Pediatrics 121: e1534–1540.
|
| [7] | Toft PB, Leth H, Ring PB, Peitersen B, Lou HC, et al. (1995) Volumetric analysis of the normal infant brain and in intrauterine growth retardation. Early Hum Dev 43: 15–29.
|
| [8] | Dudink J, Kerr JL, Paterson K, Counsell SJ (2008) Connecting the developing preterm brain. Early Hum Dev 84: 777–782.
|
| [9] | Kapellou O, Counsell SJ, Kennea N, Dyet L, Saeed N, et al. (2006) Abnormal cortical development after premature birth shown by altered allometric scaling of brain growth. PLoS Med 3: e265.
|
| [10] | Ball G, Boardman JP, Rueckert D, Aljabar P, Arichi T, et al. (2012) The effect of preterm birth on thalamic and cortical development. Cereb Cortex 22: 1016–1024.
|
| [11] | Nagy Z, Westerberg H, Skare S, Andersson JL, Lilja A, et al. (2003) Preterm children have disturbances of white matter at 11 years of age as shown by diffusion tensor imaging. Pediatr Res 54: 672–679.
|
| [12] | Nosarti C, Murray RM, Hack ME (2010) Neurodevelopmental outcomes of preterm birth. Cambridge, UK: Cambridge University Press.
|
| [13] | Johnson S, Wolke D, Hennessy E, Marlow N (2011) Educational outcomes in extremely preterm children: Neuropsychological correlates and predictors of attainment. Dev Neuropsychol 36: 74–95.
|
| [14] | Taylor HG, Espy KA, Anderson PJ (2009) Mathematics deficiencies in children with very low birth weight or very preterm birth. Dev Dis Res Rev 15: 52–59.
|
| [15] | Quigley M, Poulsen G, Boyle M, Wolke D, Field D, et al.. (2012) Early term and late preterm birth is associated with poorer school performance at age 5 years: a cohort study. Arch Dis Child Fetal Neonatal Ed. doi: 10.1136/archdischild-2011-300888.
|
| [16] | van Baar AL, Vermaas J, Knots E, de Kleine MJK, Soons P (2009) Functioning at school age of moderately preterm children born at 32 to 36 weeks' gestational age. Pediatrics 124: 251–257.
|
| [17] | Boyle EM, Poulsen G, Field DJ, Kurinczuk JJ, Wolke D, et al.. (2012) Effects of gestational age at birth on health outcomes at 3 and 5 years of age: population based cohort study. BMJ 344 . doi: 10.1136/bmj.e896.
|
| [18] | Nutley SB, S?derqvist S, Bryde S, Humphreys K, Klingberg T (2010) Measuring working memory capacity with greater precision in the lower capacity ranges. Dev Neuropsychol 35: 81–95.
|
| [19] | Marlow N, Hennessy E, Bracewell M, Wolke D (2007) Motor and executive function at 6 years of age following extremely preterm birth. Pediatrics 120: 793–804.
|
| [20] | Wolke D, Meyer R (1999) Cognitive status, language attainment, and prereading skills of 6-year-old very preterm children and their peers: the Bavarian Longitudinal Study. Dev Med Child Neurol 41: 94–109.
|
| [21] | Schermann L, Sedin G (2004) Cognitive function at 10 years of age in children who have required neonatal intensive care. Acta Paediatr 93: 1619–1629.
|
| [22] | Oberauer K, Sü? HM, Schulze R, Wilhelm O, Wittmann WW (2000) Working memory capacity – facets of a cognitive ability construct. Personality and Individual Differences 29: 1017–1045.
|
| [23] | Kline RB, Guilmette S, Snyder J, Castellanos M (1992) Relative cognitive complexity of the Kaufman Assessment Battery for Children (K-ABC) and the WISC-R. Journal of Psychoeducational Assessment 10: 141–152.
|
| [24] | Just MA, Varma S (2007) The organization of thinking: What functional brain imaging reveals about the neuroarchitecture of complex cognition. Cognitive, Affective, & Behavioral Neuroscience 7: 153–191.
|
| [25] | Niendam TA, Laird AR, Ray KL, Dean YM, Glahn DC, et al. (2012) Meta-analytic evidence for a superordinate cognitive control network subserving diverse executive functions. Cognitive, Affective, & Behavioral Neuroscience 12: 241–268.
|
| [26] | Volpe JJ, Kinney HC, Jensen FE, Rosenberg PA (2011) The developing oligodendrocyte: key cellular target in brain injury in the premature infant. Int J Dev Neurosci 29: 423–440.
|
| [27] | MacKay DF, Smith GCS, Dobbie R, Pell JP (2010) Gestational age at delivery and special educational need: retrospective cohort study of 407,503 schoolchildren. PLoS Med 7: e1000289.
|
| [28] | Schneider W, Wolke D, Schlagmüller M, Meyer R (2004) Pathways to school achievement in very preterm and full term children. Eur J Psychol Edu 19: 385–406.
|
| [29] | Gutbrod B, Wolke D, S?hne B, Ohrt B, Riegel K (2000) The effects of gestation and birthweight on the growth and development of very low birthweight small for gestational age infants: A matched group comparison. Arch Dis Child 82: F208–F214.
|
| [30] | Dubowitz LM, Dubowitz V, Goldberg D (1970) Clinical assessment of gestational age in the newborn infant. J Pediatr 77: 1–10.
|
| [31] | Schmid G, Schreier A, Meyer R, Wolke D (2011) Predictors of crying, feeding and sleeping problems: a prospective study. Child Care Health Dev. doi: 10.1111/j.1365-2214.2010.01201.x.
|
| [32] | Bauer A (1988) Ein Verfahren zur Messung des für das Bildungsverhalten relevanten Sozial Status (BRSS) - überarbeitete Fassung. Frankfurt: Deutsches Institut für Internationale P?dagogische Forschung.
|
| [33] | Kaufman AS, Kaufman N (1983) Kaufman Assessment Battery for Children. Circle Pines, MN: American Guidance Service.
|
| [34] | Melchers P, Preuss U (1991) K-ABC: Kaufman Battery for Children: Deutschsprachige Fassung. Frankfurt am Main: Swets & Zeitlinger.
|
| [35] | Wolke D, Leon-Villagra J (1993) Mathematiktest für Grundschulkinder. Munich: Bavarian Longitudinal Study.
|
| [36] | Simms V, Gilmore CK, Cragg L, Marlow N, Wolke D, et al.. (2012) Mathematics difficulties in extremely preterm children: Evidence of a specific deficit in basic mathematics processing. Pediatr Res. doi: 10.1038/pr.2012.157.
|
| [37] | Stigler JW, Lee S-Y, Stevenson HW (1990) Mathematical knowledge of Japanese, Chinese, and American elementary school children. Reston, VA: National Council of Teachers of Mathematics.
|
| [38] | Kaufman AS, Kamphaus RW (1984) Factor analysis of the Kaufman Assessment Battery for Children (K-ABC) for ages 2? through 12? years. J Edu Psychol 76: 623–637.
|
| [39] | Clark CAC, Woodward LJ (2010) Neonatal cerebral abnormalities and later verbal and visuospatial working memory abilities of children born very preterm. Dev Neuropsychol 35: 622–642.
|
| [40] | Johnson S, Hennessy E, Smith R, Trikic R, Wolke D, et al. (2009) Academic attainment and special educational needs in extremely preterm children at 11 years of age: the EPICure study. Arch Dis Child Fetal Neonatal Ed 94: F283–F289.
|
| [41] | Baddeley AD (2002) Is working memory still working? European Psychologist 7: 85–97.
|
| [42] | Miyake A, Friedman NP (2012) The nature and organization of individual differences in executive functions: four general conclusions. Current Directions in Psychological Science 21: 8–14.
|
| [43] | Bornstein MH, Hahn C-S, Wolke D (2012) Systems and cascades in cognitive development and academic achievement. Child Dev. doi: 10.1111/j.1467-8624.2012.01849.x.
|
| [44] | Garon N, Bryson SE, Smith IM (2008) Executive function in preschoolers: A review using an integrative framework. Psychol Bull 134: 31–60.
|
| [45] | Breslau N, Dickens WT, Flynn JR, Peterson EL, Lucia VC (2006) Low birthweight and social disadvantage: Tracking their relationship with children's IQ during the period of school attendance. Intelligence 34: 351–362.
|
| [46] | Jaekel J, Wolke D, Chernova J (2012) Mother and child behaviour in very preterm and fullterm dyads at 6;3 and 8;5 years. Dev Med Child Neurol 54: 716–723.
|
| [47] | Sameroff A, Chandler M (1975) Reproductive risk and the continuum of caretaking casualty. In: Horowitz F, Hetherington J, Scarr-Salapatek S, Siegel G, editors. Review of child development research. Chigaco: University of Chicago Press 187–243.
|
| [48] | Panigrahy A, Wisnowski JL, Furtado A, Lepore N, Paquette L, et al. (2012) Neuroimaging biomarkers of preterm brain injury: toward developing the preterm connectome. Pediatr Radiol 42: 33–61.
|
| [49] | Fox MD, Raichle ME (2007) Spontaneous fluctuations in brain activity observed with functional magnetic resonance imaging. Nature Reviews Neuroscience 8: 700–711.
|
| [50] | Esposito F, Bertolino A, Scarabino T, Latoffe V, Blasi G, et al. (2006) Independent component model of the default-mode brain function: Assessing the impact of active thinking. Brain Res Bull 70: 263–269.
|
| [51] | Holmes J, Gathercole SE, Dunning DL (2009) Adaptive training leads to sustained enhancement of poor working memory in children. Dev Sci 12: F9–F15.
|
| [52] | Klingberg T, Fernell E, Olesen PJ, Johnson M, Gustafsson P, et al. (2005) Computerized training of working memory in children with ADHD-A randomized, controlled trial. J Am Acad Child Adolesc Psychiatry 44: 177–186.
|
| [53] | Lohaugen GCC, Antonsen I, Haberg A, Gramstad A, Vik T, et al. (2011) Computerized working memory training improves function in adolescents born at extremely low birth weight. J Pediatr 158: 555–U556.
|
| [54] | Zatorre RJ, Fields RD, Johansen-Berg H (2012) Plasticity in gray and white: neuroimaging changes in brain structure during learning. Nature Neurosci 15: 528–536.
|
| [55] | Takeuchi H, Sekiguchi A, Taki Y, Yokoyama S, Yomogida Y, et al. (2010) Training of working memory impacts structural connectivity. J Neurosci 30: 3297–3303.
|
| [56] | Olesen PJ, Westerberg H, Klingberg T (2004) Increased prefrontal and parietal activity after training of working memory. Nature Neurosci 7: 75–79.
|
| [57] | Westerberg H, Klingberg T (2007) Changes in cortical activity after training of working memory - a single-subject analysis. Physiol Behav 92: 186–192.
|
| [58] | Klingberg T (2010) Training and plasticity of working memory. Trends in Cognitive Science 14: 317–324.
|
| [59] | Mulder H, Pitchford NJ, Marlow N (2010) Processing speed and working memory underlie academic attainment in very preterm children. Arch Dis Child Fetal Neonatal Ed 95: F267–F272.
|
| [60] | Jolles D, Crone EA (2012) Training the developing brain: a neurocognitive perspective. Frontiers in Human Neuroscience 6 . doi: 10.3389/fnhum.2012.00076.
|
| [61] | Melby-Lerv?g M, Hulme C (2012) Is Working Memory Training Effective? A Meta-Analytic Review. Dev Sci: doi: 10.1037/a0028228.
|
| [62] | Moore T, Hennessy EM, Myles J, Johnson S, Draper ES, et al.. (2012) Neurological and developmental outcome in extremely preterm children born in England in 1995 and 2006: the EPICure studies. BMJ 345. doi: 10.1136/bmj.e7961.
|
