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Cognitive Science

Neuroscience and education: prime time to build the bridge

Profile image of Marcela PenaMarcela Pena

2014, Nature Neuroscience

https://doi.org/10.1038/NN.3672
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6 pages

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The paper argues for a stronger integration between neuroscience and education, positing that the two fields should work together to better understand cognitive processes and improve educational practices. It highlights the importance of ethical considerations in educational experimentation, stressing that neuroscience should inform education while also being informed by educational needs and contexts. The paper outlines five key pillars for optimizing the dialogue between neuroscience and education, advocating for a closer relationship that can lead to transformative educational practices.

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References (79)

  1. Bruer, J.T. Education and the Brain: A bridge too far. Educ. Res. 26, 4-16 (1997).
  2. Arsalidou, M. & Taylor, M.J. Is 2+2=4? Meta-analyses of brain areas needed for numbers and calculations. Neuroimage 54, 2382-2393 (2011).
  3. Stokes, D.E. Pasteur's Quadrant: Basic Science and Technological Innovation (Brookings Institution Press, 1997).
  4. Korol, D.L. & Gold, P.E. Glucose, memory, and aging. Am. J. Clin. Nutr. 67, 764S-771S (1998).
  5. Hackman, D.A., Farah, M.J. & Meaney, M.J. Socioeconomic status and the brain: mechanistic insights from human and animal research. Nat. Rev. Neurosci. 11, 651-659 (2010).
  6. Valladolid-Acebes, I. et al. High-fat diets induce changes in hippocampal glutamate metabolism and neurotransmission. Am. J. Physiol. Endocrinol. Metab. 302, E396-E402 (2012).
  7. Grantham-McGregor, S. Can the provision of breakfast benefit school performance? Food Nutr. Bull. 26, S144-S158 (2005).
  8. Renfu, L. et al. Nutrition and educational performance in rural China's elementary schools: results of a randomized control trial in Shaanxi Province. Econ. Dev. Cult. Change 60, 735-772 (2012).
  9. Erickson, K.I. et al. Exercise training increases size of hippocampus and improves memory. Proc. Natl. Acad. Sci. USA 108, 3017-3022 (2011).
  10. Van der Borght, K. et al. Physical exercise leads to rapid adaptations in hippocampal vasculature: temporal dynamics and relationship to cell proliferation and neurogenesis. Hippocampus 19, 928-936 (2009).
  11. Perry, B.D. Childhood experience and the expression of genetic potential: What childhood neglect tells us about nature and nurture. Brain Mind 3, 79-100 (2002).
  12. Diekelmann, S. & Born, J. The memory function of sleep. Nat. Rev. Neurosci. 11, 114-126 (2010).
  13. Wilhelm, I., Diekelmann, S. & Born, J. Sleep in children improves memory performance on declarative but not procedural tasks. Learn. Mem. 15, 373-377 (2008).
  14. Stickgold, R., James, L. & Hobson, J.A. Visual discrimination learning requires sleep after training. Nat. Neurosci. 3, 1237-1238 (2000).
  15. Wagner, U., Gais, S., Haider, H., Verleger, R. & Born, J. Sleep inspires insight. Nature 427, 352-355 (2004).
  16. Wilhelm, I. et al. Sleep selectively enhances memory expected to be of future relevance. J. Neurosci. 31, 1563-1569 (2011).
  17. Huber, R., Ghilardi, M.F., Massimini, M. & Tononi, G. Local sleep and learning. Nature 430, 78-81 (2004).
  18. Kurdziel, L., Duclos, K. & Spencer, R.M.C. Sleep spindles in midday naps enhance learning in preschool children. Proc. Natl. Acad. Sci. USA 110, 17267-17272 (2013).
  19. Marshall, L., Helgadóttir, H., Mölle, M. & Born, J. Boosting slow oscillations during sleep potentiates memory. Nature 444, 610-613 (2006).
  20. Wilson, M. & McNaughton, B. Reactivation of hippocampal ensemble memories during sleep. Science 265, 676-679 (1994).
  21. Ribeiro, S. et al. Induction of hippocampal long-term potentiation during waking leads to increased extrahippocampal zif-268 expression during ensuing rapid-eye- movement sleep. J. Neurosci. 22, 10914-10923 (2002).
  22. Vecsey, C.G. et al. Sleep deprivation impairs cAMP signaling in the hippocampus. Nature 461, 1122-1125 (2009).
  23. Hagenauer, M.H., Perryman, J.I., Lee, T.M. & Carskadon, M.a. Adolescent changes in the homeostatic and circadian regulation of sleep. Dev. Neurosci. 31, 276-284 (2009).
  24. Hansen, M., Janssen, I., Schiff, A., Zee, P.C. & Dubocovich, M.L. The impact of school daily schedule on adolescent sleep. Pediatrics 115, 1555-1561 (2005).
  25. Owens, J.A., Belon, K. & Moss, P. Impact of delaying school start time on adolescent sleep, mood, and behavior. Arch. Pediatr. Adolesc. Med. 164, 608-614 (2010).
  26. Mednick, S., Nakayama, K. & Stickgold, R. Sleep-dependent learning: a nap is as good as a night. Nat. Neurosci. 6, 697-698 (2003).
  27. Melhuish, E.C., Sylva, K. & Sammons, P. Preschool influences on mathematics achievement. Science 321, 1161-1162 (2008).
  28. Farah, M.J. et al. Environmental stimulation, parental nurturance and cognitive development in humans. Dev. Sci. 11, 793-801 (2008).
  29. Fisher, K., Hirsh-pasek, K., Golinkoff, R.M., Singer, D.G. & Berk, L. Playing around in school: implications for learning and educational policy in Oxford Handb. Dev. Play (Pellegrini, A.) 341-362 (Oxford University Press, 2011).
  30. Rothbart, M.K. & Jones, L.B. Temperament, self-regulation and education. School Psych. Rev. 27, 479-491 (1998).
  31. Korver, A.M.H. et al. Newborn hearing screening vs later hearing screening and developmental outcomes in children with permanent childhood hearing impairment. J. Am. Med. Assoc. 304, 1701-1708 (2010).
  32. Mehl, A.L. & Thomson, V. Newborn hearing screening: the great omission. Pediatrics 101, e4 (1998).
  33. Francis, H.W. & Niparko, J.K. Cochlear implantation update. Pediatr. Clin. North Am. 50, 341-361 (2003).
  34. Semenov, Y.R., Martinez-Monedero, R. & Niparko, J.K. Cochlear implants: clinical and societal outcomes. Otolaryngol. Clin. North Am. 45, 959-981 (2012).
  35. Connor, C.M., Craig, H.K., Raudenbush, S.W., Heavner, K. & Zwolan, T.A. The age at which young deaf children receive cochlear implants and their vocabulary and speech-production growth: is there an added value for early implantation? Ear Hear. 27, 628-644 (2006).
  36. Connor, C.M. & Zwolan, T.A. Examining multiple sources of influence on the reading comprehension skills of children who use cochlear implants. J. Speech Lang. Hear. Res. 47, 509-526 (2004).
  37. Carey, S. The Origin of Concepts (Oxford University Press, 2009).
  38. Evers, K. & Sigman, M. Possibilities and limits of mind-reading: a neurophilosophical perspective. Conscious. Cogn. 22, 887-897 (2013).
  39. Peña, M. et al. Sounds and silence: an optical topography study of language recognition at birth. Proc. Natl. Acad. Sci. USA 100, 11702-11705 (2003).
  40. Dehaene-Lambertz, G. et al. Functional organization of perisylvian activation during presentation of sentences in preverbal infants. Proc. Natl. Acad. Sci. USA 103, 14240-14245 (2006).
  41. Petersen, S.E. & Posner, M.I. The attention system of the human brain: 20 years after. Annu. Rev. Neurosci. 35, 73-89 (2012).
  42. Davidson, M.C., Amso, D., Anderson, L.C. & Diamond, A. Development of cognitive control and executive functions from 4 to 13 years: evidence from manipulations of memory, inhibition and task switching. Neuropsychologia 44, 2037-2078 (2006).
  43. Atance, C.M. & O'Neill, D.K. Episodic future thinking. Trends Cogn. Sci. 5, 533-539 (2001).
  44. Medin, D., Bennis, W. & Chandler, M. Culture and the home-field disadvantage. Perspect. Psychol. Sci. 5, 708-713 (2010).
  45. Akhtar, N. & Menjivar, J.A. Cognitive and linguistic correlates of early exposure to more than one language. Adv. Child Dev. Behav. 42, 41-78 (2012).
  46. UNESCO. Education in a multilingual world. <http://unesdoc.unesco.org/images/ 0012/001297/129728e.pdf>. (2003).
  47. Bialystok, E. Bilingualism: The good, the bad, and the indifferent. Biling. Lang. Cogn. 12, 3-11 (2009).
  48. Werker, J.F. & Byers-Heinlein, K. Bilingualism in infancy: first steps in perception and comprehension. Trends Cogn. Sci. 12, 144-151 (2008).
  49. Kovács, A.M. & Mehler, J. Cognitive gains in 7-month-old bilingual infants. Proc. Natl. Acad. Sci. USA 106, 6556-6560 (2009).
  50. Bialystok, E., Luk, G., Peets, K.F. & Yang, S. Receptive vocabulary differences in monolingual and bilingual children. Lang. Cogn. 13, 525-531 (2010).
  51. Ivanova, I. & Costa, A. Does bilingualism hamper lexical access in speech production? Acta Psychol. (Amst.) 127, 277-288 (2008).
  52. Garbin, G. et al. Bridging language and attention: brain basis of the impact of bilingualism on cognitive control. Neuroimage 53, 1272-1278 (2010).
  53. Abutalebi, J. et al. Bilingualism tunes the anterior cingulate cortex for conflict monitoring. Cereb. Cortex 22, 2076-2086 (2012).
  54. Posner, M.I., Rothbart, M.K., Sheese, B.E. & Tang, Y. The anterior cingulate gyrus and the mechanism of self-regulation. Cogn. Affect. Behav. Neurosci. 7, 391-395 (2007).
  55. Bialystok, E., Craik, F.I.M. & Freedman, M. Bilingualism as a protection against the onset of symptoms of dementia. Neuropsychologia 45, 459-464 (2007).
  56. Luk, G., Bialystok, E., Craik, F.I.M. & Grady, C.L. Lifelong bilingualism maintains white matter integrity in older adults. J. Neurosci. 31, 16808-16813 (2011).
  57. Mischel, W. et al. "Willpower" over the life span: decomposing self-regulation. Soc. Cogn. Affect. Neurosci. 6, 252-256 (2011).
  58. Hoff, E. Interpreting the early language trajectories of children from low-SES and language minority homes: Implications for closing achievement gaps. Dev. Psychol. 49, 4-14 (2013).
  59. Dehaene, S. & Cohen, L. Cultural recycling of cortical maps. Neuron 56, 384-398 (2007).
  60. Jay Gould, S. & Vrba, E. Exaptation-a missing term in the science of form. Paleobiology 8, 4-15 (1982).
  61. Wiesel, T.N. & Hubel, D.H. Extent of recovery from the effects of visual deprivation in kittens. J. Neurophysiol. 28, 1060-1072 (1965).
  62. Gilbert, C.D., Sigman, M. & Crist, R.E. The neural basis of perceptual learning. Neuron 31, 681-697 (2001).
  63. Carreiras, M. et al. An anatomical signature for literacy. Nature 461, 983-986 (2009).
  64. Dehaene, S., Cohen, L., Sigman, M. & Vinckier, F. The neural code for written words: a proposal. Trends Cogn. Sci. 9, 335-341 (2005).
  65. Rayner, K. Eye movements in reading and information processing: 20 years of research. Psychol. Bull. 124, 372-422 (1998).
  66. Biemiller, A. Relationships between oral reading rates for letters, words, and simple text in the development of reading achievement. Read. Res. Q. 13, 223-253 (1977).
  67. Reicher, G.M. Perceptual recognition as a function of meaninfulness of stimulus material. J. Exp. Psychol. 81, 275-280 (1969).
  68. Dehaene, S. Reading in the Brain: the New Science of How We Read (Penguin books, 2009).
  69. Ullman, S. Object recognition and segmentation by a fragment-based hierarchy. Trends Cogn. Sci. 11, 58-64 (2007).
  70. Vinckier, F. et al. Hierarchical coding of letter strings in the ventral stream: dissecting the inner organization of the visual word-form system. Neuron 55, 143-156 (2007).
  71. Zorzi, M. et al. Extra-large letter spacing improves reading in dyslexia. Proc. Natl. Acad. Sci. USA 109, 11455-11459 (2012).
  72. Martelli, M. & Di Filippo, G. Crowding, reading, and developmental dyslexia. J. Vis. 9, 1-18 (2009).
  73. Goswami, U. The development of reading across languages. Ann. NY Acad. Sci. 1145, 1-12 (2008).
  74. Temple, E. et al. Neural deficits in children with dyslexia ameliorated by behavioral remediation: evidence from functional MRI. Proc. Natl. Acad. Sci. USA 100, 2860-2865 (2003).
  75. Gabrieli, J.D.E. Dyslexia: a new synergy between education and cognitive neuroscience. Science 325, 280-283 (2009).
  76. Guttorm, T.K., Leppanen, P.H.T., Richardson, U. & Lyytinen, H. Event-related potentials and consonant differentiation in newborns with familial risk for dyslexia. J. Learn. Disabil. 34, 534-544 (2001).
  77. Guttorm, T.K., Leppänen, P.H.T., Hämäläinen, J.A., Eklund, K.M. & Lyytinen, H.J. Newborn event-related potentials predict poorer pre-reading skills in children at risk for dyslexia. J. Learn. Disabil. 43, 391-401 (2010).
  78. Leppänen, P.H. et al. Newborn brain event-related potentials revealing atypical processing of sound frequency and the subsequent association with later literacy skills in children with familial dyslexia. Cortex 46, 1362-1376 (2010).
  79. Molfese, D.L. Predicting dyslexia at 8 years of age using neonatal brain responses. Brain Lang. 72, 238-245 (2000).

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    Dispelling the Myth: Training in Education or Neuroscience Decreases but Does Not Eliminate Beliefs in Neuromyths
    Alida Anderson

    Frontiers in psychology, 2017

    Neuromyths are misconceptions about brain research and its application to education and learning. Previous research has shown that these myths may be quite pervasive among educators, but less is known about how these rates compare to the general public or to individuals who have more exposure to neuroscience. This study is the first to use a large sample from the United States to compare the prevalence and predictors of neuromyths among educators, the general public, and individuals with high neuroscience exposure. Neuromyth survey responses and demographics were gathered via an online survey hosted at TestMyBrain.org. We compared performance among the three groups of interest: educators (N = 598), high neuroscience exposure (N = 234), and the general public (N = 3,045) and analyzed predictors of individual differences in neuromyths performance. In an exploratory factor analysis, we found that a core group of 7 &quot;classic&quot; neuromyths factored together (items related to learn...

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    Reviews of research funded by U.S. Institute of Educational Sciences: A case of reading development and instruction
    Sungyoon Lee

    Cogent Education

    Empirical research is a critical in the field of education, however, research funding sources are often hard to identify. In this study, we examined how National Center for Education Research (NCER), a branch of the federal Institute of Education Science (IES), has supported research on various areas of reading development and instruction. Our goal was to identify the major trends and issues in NCER reading research projects over the past 13 years by examining the general characteristics, participants, and research foci of the studies. To do so, we reviewed and coded 158 research projects based on existing content analyses about reading research. Findings indicate that the NCER has allocated approximately $397 million to 158 reading research projects from 2004 to 2016. Research projects under the Reading and Writing program were the most frequently funded, particularly studies focusing on comprehension and including participants in grades K-3. Recommendations are made for reading researchers seeking funding based on the major trends and issues identified in NCER studies.

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