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Part VI - Language Disorders, Interventions, and Instruction

Published online by Cambridge University Press:  08 July 2022

Edited by
John W. Schwieter  and
Zhisheng (Edward) Wen
John W. Schwieter
Affiliation:
Wilfrid Laurier University
Zhisheng (Edward) Wen
Affiliation:
Hong Kong Shue Yan University
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The Cambridge Handbook of Working Memory and Language , pp. 747 - 906
Publisher: Cambridge University Press
Print publication year: 2022

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References

References

Acheson, D. J., Hamidi, M., Binder, J. R., & Postle, B. R. (2011). A common neural substrate for language production and verbal working memory. Journal of Cognitive Neuroscience, 23 (6), 13581367. doi:10.1162/jocn.2010.21519Google Scholar
Ackerman, P. L., Beier, M., E., & Boyle, M. O. (2002). Individual differences in working memory within a nomological network of cognitive and perceptual speed abilities. Journal of Experimental Psychology: General, 131, 567589. doi: 10.1037/0096-3445.131.4.567CrossRefGoogle ScholarPubMed
Alloway, T. P., Gathercole, S. E., Willis, C., & Adams, A. (2004). A structural analysis of working memory and related cognitive skills in young children. Journal of Experimental Child Psychology, 87, 85106. doi:10.1016/j.jecp.2003.10.002CrossRefGoogle ScholarPubMed
American Psychiatric Association (2013). Diagnostic and statistical manual of mental disorders (5th ed). American Psychiatric Association.Google Scholar
Attout, L., & Majerus, S. (2015). Working memory deficits in developmental dyscalculia: The importance of serial order. Child Neuropsychology, 21(4), 432450. doi:10.1080/09297049.2014.922170CrossRefGoogle ScholarPubMed
Baddeley, A. D. (2012). Working memory: Theories, models, and controversies. Annual Review of Psychology, 63, 129. doi:10.1146/annurev-psych-120710-100422Google Scholar
Baddeley, A. D., Eldridge, M., Lewis, V., & Thomson, N. (1984). Attention and retrieval from long-term memory. Journal of Experimental Psychology: General, 113, 518540.CrossRefGoogle Scholar
Baddeley, A., Gathercole, S., & Papagno, C. (1998). The phonological loop as a language-learning device. Psychological Review, 105, 158173. doi:10.1037//0033-295X.105.1.158Google Scholar
Baddeley, A. D., & Logie, R. H. (1999). The multiple-component model. In Miyake, A. & Shah, P. (Eds.), Models of working memory: Mechanisms of active maintenance and executive control (pp. 2861). Cambridge University Press. doi:10.1017/CBO9781139174909.00CrossRefGoogle Scholar
Beneventi, H., Tønnessen, F. E., & Ersland, L. (2009). Dyslexic children show short-term memory deficits in phonological storage and serial rehearsal: An fMRI study. International Journal of Neuroscience, 119(11), 20172043. doi:10.1080/00207450903139671CrossRefGoogle ScholarPubMed
Beneventi, H., Tønnessen, F. E., Ersland, L., & Hugdahl, K. (2010). Executive working memory processes in dyslexia: Behavioral and fMRI evidence. Scandinavian Journal of Psychology, 51(3), 192202. doi:10.1111/j.1467-9450.2010.00808.xGoogle Scholar
Bledowski, C., Kaiser, J., & Rahm, B. (2010). Basic operations in working memory: Contributions from functional imaging studies. Behavioural Brain Research, 214(2), 172179. doi:10.1016/j.bbr.2010.05.041Google Scholar
Brandenburg, J., Klesczewski, J., Fischbach, A., Schuchardt, K., Büttner, G., & Hasselhorn, M. (2015). Working memory in children with learning disabilities in reading versus spelling: Searching for overlapping and specific cognitive factors. Journal of Learning Disabilities, 48(6), 622634. doi:10.1177/0022219414521665CrossRefGoogle ScholarPubMed
Chein, J. M., & Fiez, J. A. (2010). Evaluating models of working memory through the effects of concurrent irrelevant information. Journal of Experimental Psychology: General, 139(1), 117137. doi:10.1037/a0018200Google Scholar
Cohen, J. (1988). Statistical power analysis for the behavioral sciences (2nd ed.). L. Erlbaum Associates.Google Scholar
Cowan, N. (1997). The development of working memory. In Cowan, N. (Ed.), The development of working memory in childhood (pp. 163199). Psychology Press.Google Scholar
Cowan, N. (2014). Working memory underpins cognitive development, learning, and education. Educational Psychology Review, 26(2), 197223.CrossRefGoogle ScholarPubMed
Daneman, M., & Carpenter, P. A. (1980). Individual differences in working memory and reading. Journal of Verbal Learning and Verbal Behavior, 19(4), 450466. doi:10.1016/S0022-5371(80)90312-6Google Scholar
De Weerdt, F., Desoete, A., & Roeyers, H. (2013). Working memory in children with reading disabilities and/or mathematical disabilities. Journal of Learning Disabilities, 46(5), 461472.CrossRefGoogle ScholarPubMed
Engle, R. W., Tuholski, S. W., Laughlin, J. E., & Conway, A. R. (1999). Working memory, short-term memory, and general fluid intelligence: A latent variable approach. Journal of Experimental Psychology: General, 128, 309331.CrossRefGoogle ScholarPubMed
Evans, T. M., Flowers, D. L., Luetje, M. M., Napoliello, E., & Eden, G. F. (2016). Functional neuroanatomy of arithmetic and word reading and its relationship to age. NeuroImage, 143, 304315. doi:10.1016/j.neuroimage.2016.08.048Google Scholar
Fürst, A. J., & Hitch, G. J. (2000). Separate roles for executive and phonological components of working memory in mental arithmeticMemory & Cognition28(5), 774782.Google Scholar
Gathercole, S. E., Pickering, S. J., Ambridge, B., & Wearing, H. (2004). The structure of working memory from 4 to 15 years of age. Developmental Psychology, 40, 177190.Google Scholar
Geary, D. C. (2011). Cognitive predictors of achievement growth in mathematics: A 5-year longitudinal study. Developmental Psychology, 47(6), 15391552.CrossRefGoogle ScholarPubMed
Geary, D. C. (2013). Learning disabilities in mathematics: Recent advances. In Swanson, H. L., Harris, K., & Graham, S. (Eds.), Handbook of learning disabilities (2nd ed., pp. 239256). Guilford.Google Scholar
Geary, D. C., Hoard, M. K., Nugent, L., & Bailey, D. H. (2012). Mathematical cognition deficits in children with learning disabilities and persistent low achievement: A five-year prospective study. Journal of Educational Psychology, 104(1), 206223.Google Scholar
Gray, S., Green, S., Alt, M., Hogan, T., Kuo, T., Brinkley, S., & Cowan, N. (2017). The structure of working memory in young children and its relation to intelligence. Journal of Memory and Language, 92, 183201.CrossRefGoogle ScholarPubMed
Hecht, S. A., Torgesen, J. K., Wagner, R. K., & Rashotte, C. A. (2001). The relations between phonological processing abilities and emerging individual differences in mathematical computational skills: A longitudinal study from second to fifth grades. Journal of Experimental Child Psychology, 79(2), 192227.CrossRefGoogle ScholarPubMed
Hutton, U. M. Z., & Towse, J. N. (2001). Short-term memory and working memory as indices of children’s cognitive skills. Memory, 9(4–6), 383394.Google Scholar
Kaufmann, L., Wood, G., Rubinsten, O., & Henik, A. (2011). Meta-analyses of developmental fMRI studies investigating typical and atypical trajectories of number processing and calculation. Developmental Neuropsychology, 36(6), 763787.Google Scholar
Kudo, M. F., Lussier, C. M., & Swanson, H. L. (2015). Reading disabilities in children: A selective meta-analysis of the cognitive literature. Research in Developmental Disabilities, 40, 5162.Google Scholar
Kyllonen, P. C., & Christal, R. E. (1990). Reasoning ability is (little more than) working-memory capacity? Intelligence,14, 389433. doi:10.1016/S0160-2896(05)80012-1Google Scholar
Johnson, E. S., Humphrey, M., Mellard, D. F., Woods, K., & Swanson, H. L. (2010). Cognitive processing deficits and students with specific learning disabilities: A selective meta-analysis of the literature. Learning Disability Quarterly, 33(1), 318.Google Scholar
Lanfranchi, S., & Swanson, H. L. (2005). Short-term memory and working memory in children as a function of language-specific knowledge in English and Spanish. Learning and Individual Differences, 15(4), 299319.Google Scholar
Locascio, G., Mahone, E. M., Eason, S. H., & Cutting, L. E. (2010). Executive dysfunction among children with reading comprehension deficitsJournal of Learning Disabilities43(5), 441454.Google Scholar
Logie, R. H., Gilhooly, K. J., & Wynn, V. (1994). Counting on working memory in arithmetic problem solving. Memory & Cognition, 22(4), 395410.Google Scholar
Maguire, M. J., Schneider, J. M., Middleton, A. E., Ralph, Y., Lopez, M., Ackerman, R. A., & Abel, A. D. (2018). Vocabulary knowledge mediates the link between socioeconomic status and word learning in grade schoolJournal of Experimental Child Psychology166, 679695.Google Scholar
Mammarella, I. C., Caviola, S., Giofrè, D., & Szűcs, D. (2018). The underlying structure of visuospatial working memory in children with mathematical learning disability. British Journal of Developmental Psychology36(2), 220235.Google Scholar
McLean, J. F., & Hitch, G. J. (1999). Working memory impairments in children with specific arithmetic learning difficulties. Journal of Experimental Child Psychology, 74(3), 240260.CrossRefGoogle ScholarPubMed
Melby-Lervåg, M., & Hulme, C. (2013). Is working memory training effective? A meta-analytic review. Developmental Psychology, 49(2), 270291.CrossRefGoogle ScholarPubMed
Melby-Lervåg, M., Lyster, S. H., & Hulme, C. (2012). Phonological skills and their role in learning to read: A meta-analytic review. Psychological Bulletin, 138(2), 322352.Google Scholar
Miyake, A., Friedman, N. P., Emerson, M. J., Witzki, A. H., & Howerter, A. (2000). The unity and diversity of executive functions and their contributions to complex “frontal lobe” tasks: A latent variable analysis. Cognitive Psychology, 41, 49100.Google Scholar
National Assessment of Educational Progress (2017). The condition of education (update 2017). US Department of Education.Google Scholar
National Center for Education Statistics (2020) Common Core of Data (CCD): Local education agency universe surveyU.S. Department of Education.Google Scholar
Nee, D. E., Brown, J. W., Askren, M. K., Berman, M. G., Demiralp, E., Krawitz, A., & Jonides, J. (2013). A meta-analysis of executive components of working memory. Cerebral Cortex, 23(2), 264282.CrossRefGoogle ScholarPubMed
Passolunghi, M. C., & Siegel, L. S. (2004). Working memory and access to numerical information in children with disability in mathematics. Journal of Experimental Child Psychology, 88(4), 348367.Google Scholar
Peña, E. D., Bedore, L. M., & Kester, E. S. (2016). Assessment of language impairment in bilingual children using semantic tasks: Two languages classify better than one. International Journal of Language & Communication Disorders, 51(2), 192202.Google Scholar
Peng, P., Barnes, M., Wang, C., Wang, W., Li, S., Swanson, H. L., & Tao, S. (2018). A meta-analysis on the relation between reading and working memory. Psychological Bulletin144(1), 4876.Google Scholar
Peng, P., Congying, S., Beilei, L., & Sha, T. (2012). Phonological storage and executive function deficits in children with mathematics difficulties. Journal of Experimental Child Psychology, 112(4), 452466.CrossRefGoogle ScholarPubMed
Peng, P., & Fuchs, D. (2016). A meta-analysis of working memory deficits in children with learning difficulties: Is there a difference between verbal domain and numerical domain? Journal of Learning Disabilities, 49(1), 320. doi:10.1177/0022219414521667Google Scholar
Richlan, F. (2012). Developmental dyslexia: Dysfunction of a left hemisphere reading network. Frontiers in Human Neuroscience, 6 doi:10.3389/fnhum.2012.00120CrossRefGoogle Scholar
Richlan, F., Kronbichler, M., & Wimmer, H. (2011). Meta-analyzing brain dysfunctions in dyslexic children and adults. NeuroImage, 56(3), 17351742. doi:10.1016/j.neuroimage.2011.02.040Google Scholar
Rosselli, M., Ardila, A., Lalwani, L. N., & Vélez-Uribe, I. (2016). The effect of language proficiency on executive functions in balanced and unbalanced Spanish–English bilinguals. Bilingualism: Language and Cognition, 19(3), 489503.Google Scholar
Rosenberg-Lee, M., Lovett, M. C., & Anderson, J. R. (2009). Neural correlates of arithmetic calculation strategies. Cognitive, Affective & Behavioral Neuroscience, 9(3), 270285.Google Scholar
Scarborough, H. S. (1998). Early identification of children at risk for reading disabilities: Phonological awareness and some other promising predictors. In Shapiro, B, Accardo, P., & Capute, A (Eds.). Specific reading disability: A view of the spectrum (pp. 75119). York Press.Google Scholar
Schwaighofer, M., Fischer, F., Bühner, M. (2015). Does working memory training transfer? A meta-analysis including training conditions as moderators. Educational Psychologist, 50(2), 138166Google Scholar
Shipstead, Z., Redick, T. S., and Engle, R. W. (2010). Does working memory training generalize? Psychologica Belgica, 50(3&4), 245276Google Scholar
Siegel, L. S., & Ryan, E. B. (1989). The development of working memory in normally achieving and subtypes of learning disabled children. Child Development, 60(4), 973980.Google Scholar
Smith, E. E., & Jonides, J. (1997). Working memory: A view from neuroimaging. Cognitive Psychology, 33(1), 542.Google Scholar
Smith, E. E., & Jonides, J. (1999). Storage and executive processes in the frontal lobes. Science, 283(5408), 16571661.CrossRefGoogle ScholarPubMed
Swanson, H. (1981). Vigilance deficit in learning disabled children: A signal detection analysis. Child Psychology & Psychiatry & Allied Disciplines, 22(4), 393399.CrossRefGoogle ScholarPubMed
Swanson, H. (1983). A developmental study of vigilance in learning-disabled and nondisabled children. Journal of Abnormal Child Psychology, 11(3), 415429.Google Scholar
Swanson, H. (1988). Learning disabled children’s problem solving: Identifying mental processes underlying intelligent performance. Intelligence, 12(3), 261278.CrossRefGoogle Scholar
Swanson, H. (1989). The effects of central processing strategies on learning disabled, mildly retarded, average, and gifted children’s elaborative encoding abilities. Journal of Experimental Child Psychology, 47(3), 370397.Google Scholar
Swanson, H. (1992). Generality and modifiability of working memory among skilled and less skilled readers. Journal of Educational Psychology, 84(4), 473-488.Google Scholar
Swanson, H. (1993a). An information processing analysis of learning-disabled children’s problem solving. American Educational Research Journal, 30(4), 861893.Google Scholar
Swanson, H. (1993b). Executive processing in learning-disabled readers. Intelligence, 17(2), 117149.Google Scholar
Swanson, H. (1993c). Working memory in learning disability subgroups. Journal of Experimental Child Psychology, 56(1), 87114.Google Scholar
Swanson, H. (1995). S-Cognitive Processing Test (S-CPT): A dynamic assessment measure. PRO-ED.Google Scholar
Swanson, H. (1996). Individual and age-related differences in children’s working memory. Memory & Cognition, 24, 7082.CrossRefGoogle ScholarPubMed
Swanson, H. (1999). What develops in working memory? A life span perspective. Developmental Psychology, 35(4), 9861000.CrossRefGoogle ScholarPubMed
Swanson, H. (2000). Are working memory deficits in readers with learning disabilities hard to change? Journal of Learning Disabilities, 33(6), 551566.Google Scholar
Swanson, H. (2003). Age-related differences in learning disabled and skilled readers’ working memory. Journal of Experimental Child Psychology, 85(1), 131.Google Scholar
Swanson, H. (2004). Working memory and phonological processing as predictors of children’s mathematical problem solving at different ages. Memory & Cognition, 32(4), 648661.Google Scholar
Swanson, H. (2008). Working memory and intelligence in children: What develops? Journal of Educational Psychology, 100(3), 581602.Google Scholar
Swanson, H. (2011). The influence of working memory growth on reading and math performance in children with math and/or reading disabilities. In Barrouillet, P & Gaillard, V (Eds.), Cognitive development and working memory: A dialogue between neo-Piagetian theories and cognitive approaches (pp. 203231). Psychology Press.Google Scholar
Swanson, H. (2012). Intellectual growth in children as a function of domain specific and domain general working memory subgroups. Intelligence, 39, 481492.Google Scholar
Swanson, H. (2014). Does cognitive strategy training on word problems compensate for working memory capacity in children with math difficulties? Journal of Educational Psychology, 106(3), 831848.CrossRefGoogle Scholar
Swanson, H. (2016). Word problem solving, working memory and serious math difficulties: Do cognitive strategies really make a difference? Journal of Applied Research in Memory and Cognition, 5(4), 368383.Google Scholar
Swanson, H. (2017). Verbal and visual-spatial working memory: What develops over a life span? Developmental Psychology, 53(5), 971995.Google Scholar
Swanson, H (2020). Learning disabilities as a working memory deficit: A revised model. In Sperling, R., Martin, A., & Newton, K, Handbook of educational psychology & students with special needs (pp. 1951). Routledge.Google Scholar
Swanson, H., & Alexander, J. E. (1997). Cognitive processes as predictors of word recognition and reading comprehension in learning-disabled and skilled readers: Revisiting the specificity hypothesis. Journal of Educational Psychology, 89(1), 128158.Google Scholar
Swanson, H., & Alloway, T. P. (2012). Working memory, learning, and academic achievement. APA educational psychology handbook. Vol 1: Theories, constructs, and critical issues (pp. 327366). American Psychological Association.Google Scholar
Swanson, H., & Ashbaker, M. H. (2000). Working memory, short-term memory, speech rate, word recognition and reading comprehension in learning disabled readers: Does the executive system have a role? Intelligence, 28(1), 130.Google Scholar
Swanson, H., Ashbaker, M. H., & Lee, C. (1996). Learning-disabled readers’ working memory as a function of processing demands. Journal of Experimental Child Psychology, 61(3), 242275.Google Scholar
Swanson, H., & Beebe-Frankenberger, M. (2004). The relationship between working memory and mathematical problem solving in children at risk and not a risk for serious math difficulties. Journal of Educational Psychology, 96, 471491.Google Scholar
Swanson, H., & Berninger, V. (1995). The role of working memory in skilled and less skilled readers’ comprehension. Intelligence, 21(1), 83108.Google Scholar
Swanson, H., & Fung, W. (2016). Working memory components and problem-solving accuracy: Are there multiple pathways? Journal of Educational Psychology, 108(8), 11531177.Google Scholar
Swanson, H., Howard, C. B., & Sáez, L. (2006). Do different components of working memory underlie different subgroups of reading disabilities? Journal of Learning Disabilities, 39(3), 252269.Google Scholar
Swanson, H., & Jerman, O. (2006). Math disabilities: A selective meta-analysis of the literature. Review of Educational Research, 76(2), 249274.Google Scholar
Swanson, H., & Jerman, O. (2007). The influence of working memory on reading growth in subgroups of children with reading disabilities. Journal of Experimental Child Psychology, 96(4), 249283.Google Scholar
Swanson, H., Jerman, O., & Zheng, X. (2008). Growth in working memory and mathematical problem solving in children at risk and not at risk for serious math difficulties. Journal of Educational Psychology, 100(2), 343379.Google Scholar
Swanson, H., Jerman, O., & Zheng, X. (2009). Math disabilities and reading disabilities: Can they be separated? Journal of Psychoeducational Assessment, 27 (3), 175196.Google Scholar
Swanson, H., Kehler, P., & Jerman, O. (2010). Working memory, strategy knowledge, and strategy instruction in children with reading disabilities. Journal of Learning Disabilities, 43(1), 2447.Google Scholar
Swanson, L., & Kim, K. (2007). Working memory, short-term memory, and naming speed as predictors of children’s mathematical performance. Intelligence, 35(2), 151168.Google Scholar
Swanson, H., Kong, J., & Petcu, S. (2018). Math difficulties and working memory growth in English language learner children: Does bilingual proficiency play a significant role? Language, Speech, and Hearing Services in Schools49(3), 379394.Google Scholar
Swanson, H., Kong, J. E., & Petcu, S. D. (2019a). Individual differences in math problem solving and executive processing among emerging bilingual childrenJournal of Experimental Child Psychology187, 25.Google Scholar
Swanson, H., Kong, J., & Petcu, S. D. (2019b) Growth in math computation among monolingual and English language learners: Does the executive system have a role? Developmental Neuropsychology44(8), 566593.Google Scholar
Swanson, H., Kong, J, & Petcu, S. (2020) Emerging bilingual children at risk and not at risk for math difficultiesChild Neuropsychology26(4), 489517.Google Scholar
Swanson, H., Kudo, M., & Guzman-Orth, D. (2016). Cognition and literacy in English language learners at risk for reading disabilities: A latent transition analysis. Journal of Educational Psychology, 108(6), 830856.Google Scholar
Swanson, H., Kudo, M. F., & Van Horn, M. L. (2019c). Does the structure of working memory in EL children vary across age and two language systems? Memory27(2), 174191.Google Scholar
Swanson, H., Lussier, C. M., & Orosco, M. J. (2015). Cognitive strategies, working memory, and growth in word problem solving in children with math difficulties. Journal of Learning Disabilities, 48(4), 339358.Google Scholar
Swanson, H., Lussier, C. M., & Orosco, M. J. (2015). Cognitive strategies, working memory, and growth in word problem solving in children with math difficulties. Journal of Learning Disabilities, 48(4), 339358.Google Scholar
Swanson, H., & McMurran, M. (2018). The impact of working memory training on near and far transfer measures: Is it all about fluid intelligence? Child Neuropsychology24(3), 370395.Google Scholar
Swanson, H., Moran, A. S., Bocian, K., Lussier, C., & Zheng, X. (2013). Generative strategies, working memory, and word problem solving accuracy in children at risk for math disabilities. Learning Disability Quarterly, 36(4), 203214.Google Scholar
Swanson, H., Moran, A., Lussier, C., & Fung, W. (2014). The effect of explicit and direct generative strategy training and working memory on word problem-solving accuracy in children at risk for math difficulties. Learning Disability Quarterly, 37(2), 111122.Google Scholar
Swanson, H., Olide, A. F., & Kong, J. E. (2018). Latent class analysis of children with math difficulties and/or math learning disabilities: Are there cognitive differences? Journal of Educational Psychology, 110(7), 931951.Google Scholar
Swanson, H., Orosco, M. J., & Kudo, M. (2017). Does growth in the executive system of working memory underlie growth in literacy for bilingual children with and without reading disabilities? Journal of Learning Disabilities, 50(4), 386407.Google Scholar
Swanson, H., Orosco, M. J., & Lussier, C. M. (2012). Cognition and literacy in English language learners at risk for reading disabilities. Journal of Educational Psychology, 104(2), 302320.Google Scholar
Swanson, H., Orosco, M. J., & Lussier, C. M. (2015). Growth in literacy, cognition, and working memory in English language learners. Journal of Experimental Child Psychology, 132, 155188.CrossRefGoogle Scholar
Swanson, H., Orosco, M. J., Lussier, C. M., Gerber, M. M., & Guzman-Orth, D. (2011). The influence of working memory and phonological processing on English language learner children’s bilingual reading and language acquisition. Journal of Educational Psychology, 103(4), 838856.Google Scholar
Swanson, H., & Sachse-Lee, C. (2001a). A subgroup analysis of working memory in children with reading disabilities: Domain-general or domain-specific deficiency? Journal of Learning Disabilities, 34(3), 249263.Google Scholar
Swanson, H., & Sachse-Lee, C. (2001b). Mathematical problem solving and working memory in children with learning disabilities: Both executive and phonological processes are important. Journal of Experimental Child Psychology, 79(3), 294321.Google Scholar
Swanson, H., Sáez, L., Gerber, M., & Leafstedt, J. (2004). Literacy and cognitive functioning in bilingual and nonbilingual children at or not at risk for reading disabilitiesJournal of Educational Psychology96(1), 318.CrossRefGoogle Scholar
Swanson, H., & Siegel, L. (2001a). Elaborating on working memory and learning disabilities: A reply to commentators. Issues in Education: Contributions from Educational Psychology, 7, 107129.Google Scholar
Swanson, H., & Siegel, L. (2001b). Learning disabilities as a working memory deficit. Issues in Education: Contributions from Educational Psychology, 7, 148.Google Scholar
Swanson, H., & Zheng, X. (2013). Memory difficulties in children and adults with learning disabilities. In Swanson, H. L., Harris, K., & Graham, S. (Eds), Handbook of learning disabilities (2nd ed, pp. 214238). Guilford Press.Google Scholar
Swanson, H., Zheng, X., & Jerman, O. (2009). Working memory, short-term memory, and reading disabilities: A selective meta-analysis of the literature. Journal of Learning Disabilities, 42(3), 260287.Google Scholar
Uppal, H. K., & Swanson, H. L. (2016). Teachers’ ratings of working memory in English language learners: Do laboratory measures predict classroom analogues? Applied Cognitive Psychology, 30(6), 871884.Google Scholar
Unsworth, N., & Engle, R. W. (2007). On the division of short-term and working memory: An examination of simple and complex span and their relation to higher order abilities. Psychological Bulletin, 133(6), 10381066.Google Scholar
Wang, S., & Gathercole, S. E. (2013). Working memory deficits in children with reading difficulties: Memory span and dual task coordination. Journal of Experimental Child Psychology, 115(1), 188197.Google Scholar

References

Abbot-Smith, K., & Tomasello, M. (2006). Exemplar-learning and schematization in a usage-based account of syntactic acquisition. The Linguistic Review, 23, 275290.CrossRefGoogle Scholar
Adams, E., Nguyen, A., & Cowan, N. (2018). Theories of working memory: differences in definition, degree of modularity, role of attention and purpose. Language Speech and Hearing Services in Schools, 49, 340355.Google Scholar
Altmann, G., & Kamide, Y. (1999). Incremental interpretation at verbs: Restricting the domain of subsequent reference. Cognition, 73, 247264.Google Scholar
Andrews, G., Ogden, J., & Halford, G. (2017). Resolving conflicts between syntax and plausibility in sentence comprehension. Advances in Cognitive Psychology, 13, 1127.Google Scholar
Archibald, L., & Gathercole, S. (2007). The complexities of complex memory span: Storage and processing deficits in specific language impairment. Journal of Memory and Language, 57, 177194.Google Scholar
Arnon, I., & Christiansen, M. (2017). The role of multiword building blocks in explaining L1-L2 differences. Topics in Cognitive Science, 9, 621636.Google Scholar
Arnon, I., & Clark, E. (2011). Why brush your teeth is better than teeth: Children’s word production is facilitated in familiar sentence-frames. Language Learning and Development, 7, 107129.Google Scholar
Arnon, I., McCauley, S., & Christiansen, M. (2017). Digging up the building blocks of language: Age-of-acquisition effects for multiword phrases. Journal of Memory and Language, 92, 265280.Google Scholar
Arnon, I., & Snider, N. (2008). More than words: Frequency effects for multi-word phrases. Journal of Memory and Language, 62, 6782.Google Scholar
Baddeley, A. (2012). Working memory: Theories, models, and controversies. Annual Review of Psychology, 63, 129.Google Scholar
Bannard, C., & Lieven, E. (2012). Formulaic language in L1 acquisition. Annual Review of Applied Linguistics, 32, 316.Google Scholar
Bannard, C., & Matthews, D. (2008). Stored word sequences in language learning. Psychological Science, 19, 241248.Google Scholar
Barrouillet, P., & Camos, V. (2001). Developmental increase in working memory span: Resource sharing or temporal decay? Journal of Memory and Language, 45, 120.Google Scholar
Barrouillet, P., Gavens, N., Vergauwe, E., Gaillard, V., & Camos, V. (2009). Working memory span development: A time-based resource-sharing model account. Developmental Psychology, 45, 477490.Google Scholar
Borovsky, A., Elman, J., & Fernald, A. (2012). Knowing a lot for one’s age: Vocabulary skill and not age is associated with anticipatory incremental sentence interpretation in children and adults. Journal of Experimental Child Psychology, 112, 417436.Google Scholar
Burgess, G., Gray, J., Conway, A., & Braver, T. (2011). Neural mechanisms of interference control underlie the relationship between fluid intelligence and working memory span. Journal of Experimental Psychology: General, 140, 674692.Google Scholar
Chater, N., McCauley, S., & Christiansen, M. (2016). Language as skill: Intertwining comprehension and production. Journal of Memory and Language, 89, 244254.Google Scholar
Chein, J., Moore, A., & Conway, A. (2011). Domain-general mechanisms of complex working memory span. NeuroImage, 54, 550559.Google Scholar
Christiansen, M., & Arnon, I. (2017). More than words: The role of multiword sequences in language learning and use. Topics in Cognitive Science, 9, 542551.Google Scholar
Christiansen, M., & Chater, N. (2016). The now-or-never bottleneck: A fundamental constraint on language. Behavioral and Brain Sciences, 39, 119.Google Scholar
Christiansen, M., & MacDonald, M. (1999). Fractionated working memory: Even in pebbles, it’s still a soup stone. Behavioral and Brain Sciences, 22, 9798.Google Scholar
Conti-Ramsden, G., & Faragher, N. (2001). Psycholinguistic markers for Specific Language Impairment. Journal of Child Psychology and Psychiatry, 6, 741748.Google Scholar
Conti-Ramsden, G., Ullman, M., & Lum, J. (2015). The relation between receptive grammar and procedural, declarative, and working memory in specific language impairment. Frontiers in Psychology, 6, 111.Google Scholar
Cornish, H., Dale, R., Kirby, S., & Christiansen, M. (2017). Sequence memory constraints give rise to language-like structure through iterated learning. PLoS ONE, 12(1), Article e0168532. https://doi.org/10.1371/journal.pone.0168532.Google Scholar
Cowan, N., Rouder, J. Blume, C., & Saults, J. (2012). Models of verbal working memory capacity: What does it take to make them work? Psychological Review, 119, 480499.Google Scholar
Cowan, N., Saults, J., & Blume, C. (2014). Central and peripheral components of working memory storage. Journal of Experimental Psychology: General, 143, 18061836.CrossRefGoogle ScholarPubMed
Delage, H., & Frauenfelder, U. (2020). Relationship between working memory and complex syntax in children with developmental language disorder. Journal of Child Language, 47, 600632.Google Scholar
Dick, F., Wulfeck, B., Krupa-Kwiatkowski, M., & Bates, L. (2004). The development of complex sentence interpretation in typically developing children compared with children with specific language impairment or early unilateral focal lesions. Developmental Science, 7, 360377.CrossRefGoogle ScholarPubMed
Ellis Weismer, S., Evans, J., & Hesketh, L. (1999). An examination of verbal working memory capacity in children with specific language impairment. Journal of Speech, Language, and Hearing Research, 42, 12491260.Google Scholar
Engel de Abreu, P., Conway, A., & Gathercole, S. (2010). Working memory and fluid intelligence in young children. Intelligence, 38, 552561.Google Scholar
Engelhardt, P., Nigg, J., & Ferreira, F. (2017). Executive function and intelligence in the resolution of temporary syntactic ambiguity: An individual differences investigation. The Quarterly Journal of Experimental Psychology, 70, 12631281.Google Scholar
Engle, R. W. (2018). Working memory and executive attention: A revisit. Perspectives on Psychological Science, 13(2), 190193.Google Scholar
Engle, R., Tuholski, S., Laughlin, J., & Conway, A. (1999). Working memory, short-term memory, and general fluid intelligence: a latent-variable approach. Journal of experimental psychology: General, 128, 309331.Google Scholar
Evans, J., Saffran, J., & Robe-Torres, K. (2009). Statistical learning in children with specific language impairment. Journal of Speech, Language, and Hearing Research, 52, 321335.Google Scholar
Fernald, A., Perfors, A., & Marchman, V. (2006). Picking up speed in understanding: Speech processing efficiency and vocabulary growth across the 2nd year. Developmental Psychology, 42, 98116.Google Scholar
Ferreira, V., & Bock, K. (2006). The functions of structural priming. Language and Cognitive Processes, 21, 10111029.CrossRefGoogle ScholarPubMed
Ferretti, R., McRae, K., & Hatherell, A. (2001). Integrating verbs, situation schemas, and thematic role concepts. Journal of Memory and Language, 44, 516547.Google Scholar
Finney, M., Montgomery, J., Gillam, R., & Evans, J. (2014). Role of working memory storage and attention focus switching in children’s comprehension of spoken object relative sentences. Child Development Research, 54, 111.Google Scholar
Friedmann, N., & Novogrodsky, R. (2007). Is the movement deficit in syntactic SLI related to traces or to thematic role transfer? Brain and Language, 101, 5063.Google Scholar
Fukuda, K., Vogel, E., Mayr, U., & Awh, E. (2010). Quantity, not quality: The relationship between fluid intelligence and working memory capacity. Psychonomic Bulletin & Review, 17, 673679.Google Scholar
García-Madruga, J. A., Vila, J. O., Gómez-Veiga, I., Duque, G., & Elosúa, M. R. (2014). Executive processes, reading comprehension and academic achievement in 3rd grade primary students. Learning and Individual Differences, 35, 4148.Google Scholar
Garraffa, M., Coco, M., Branigan, H. (2018). Impaired implicit learning of syntactic structure in children with developmental language disorder: Evidence from syntactic priming. Autism & Developmental Language Impairments, 3, 115.Google Scholar
Gillam, R., Montgomery, J., Evans, J., & Gillam, S. (2019). Cognitive predictors of sentence comprehension in children with and without developmental language disorder: Implications for assessment and treatment. International Journal of Speech-Language Pathology, 21, 240251.Google Scholar
Gillam, R. & Pearson, N. (2004). Test of narrative language. Pro-Ed.Google Scholar
Gómez, R., & Gerken, L. (1999). Artificial grammar learning by 1-year-olds leads to specific and abstract knowledge. Cognition, 70, 109135.Google Scholar
Grunow, H., Spaulding, T., Gomez, R., & Plante, E. (2006). The effects of variation on learning word order rules by adults with and without language-based learning disabilities. Journal of Communication Disorders, 39, 158170.Google Scholar
Hamrick, P., Lum, J., & Ullman, M. (2018). Child first language and adult second language are both tied to general-purpose learning systems. Proceedings of the National Academy of Sciences of the United States of America, 7, 14871492.Google Scholar
Hardman, K., & Cowan, N. (2015). Reasoning and memory: People make varied use of the information available in working memory. Journal of Experimental Psychology: Learning, Memory, and Cognition, 42, 700722Google Scholar
Hedenius, M., Persson, J., Tremblay, A., Adi-Japha, E., Veríssimo, J., Dye, C., et al. (2011). Grammar predicts procedural learning and consolidation deficits in children with specific language impairment. Research in Developmental Disabilities, 32, 23622375.Google Scholar
Hsu, J., & Bishop, D. (2010). Grammatical difficulties in children with specific language impairment: Is learning deficient? Human Development, 53, 264277.Google Scholar
Joanisse, M., & McClelland, J. (2015). Connectionist perspectives on language learning, representation and processing. WIREs Cognitive Science, 6, 235247.Google Scholar
Kane, M., Hambrick, D., Tuholski, S., Wilhelm, O., Payne, T., & Engle, R. (2004). The generality of working memory capacity: A latent-variable approach to verbal and visuospatial memory span and reasoning. Journal of Experimental Psychology: General, 133, 189217.Google Scholar
Kidd, E. (2012). Implicit statistical learning is directly associated with the acquisition of syntax. Developmental Psychology, 48, 171184.Google Scholar
Kidd, E., & Arciuli, J. (2016). Individual differences in statistical learning predict children’s comprehension of syntax. Child Development, 87(1), 184193.Google Scholar
Leclercq, A., Majerus, S., Prigent, G., & Maillart, C. (2013). The impact of dual tasking on sentence comprehension in children with specific language impairment. Journal of Speech, Language and Hearing Research, 56, 265280.Google Scholar
Leonard, L. (2014). Children with specific language impairment (2nd ed.). MIT Press.CrossRefGoogle ScholarPubMed
Leonard, L., Deevy, P., Fey, M., & Bredin-Oja, S. (2013). Sentence comprehension in specific language impairment: A task designed to distinguish between cognitive capacity and syntactic complexity. Journal of Speech, Language and Hearing Research, 56, 577589.Google Scholar
Leonard, L., Eyer, J., Bedore, L., & Grela, B. (1997). Three accounts of the grammatical morpheme difficulties of English-speaking children with specific language impairment. Journal of Speech, Language, and Hearing Research, 40, 741753.Google Scholar
Lieven, E., Salomo, D., & Tomasello, M. (2009). Two-year-old children’s production of multiword utterances: A usage-based analysis. Cognitive Linguistics, 20, 481507.Google Scholar
Loaiza, V., & Camos, V. (2018). The role of semantic representations in verbal working memory. Journal of Experimental Psychology: Learning, Memory, and Cognition, 44, 863881.Google Scholar
Lum, J., & Conti-Ramsden, G. (2013). Long-term memory: A review and meta-analysis of studies of declarative and procedural memory in specific language impairment. Topics in Language Disorders, 33, 282297.Google Scholar
Lum, J., Conti-Ramsden, G., Morgan, A., & Ullman, M. (2014). Procedural learning deficits in specific language impairment (SLI): A meta-analysis of serial reaction time task performance. Cortex, 51, 110.Google Scholar
Lum, J., Youssef, G., & Clark, G. (2017). Using pupillometry to investigate sentence comprehension in children with and without specific language impairment. Journal of Speech, Language and Hearing Research, 60, 16481660.Google Scholar
MacDonald, M., & Christiansen, M. (2002). Reassessing working memory: Comment on Just and Carpenter (1992) and Waters and Caplan (1996). Psychological Review, 109, 3554.Google Scholar
Marshall, C., Marinis, T., & van der Lely, H. (2007). Passive verb morphology: The effect of phonotactics on passive comprehension in typically developing and Grammatical-SLI children. Lingua, 117, 302320.Google Scholar
Marshall, C., & van der Lely, H. (2006). A challenge to current models of past tense inflection: The impact of phonotactics. Cognition, 100, 302320.CrossRefGoogle ScholarPubMed
Marslen-Wilson, W., & Zwitserlood, P. (1989). Accessing spoken words: The importance of word onsets. Journal of Experimental Psychology: Human Perception and Performance, 15, 576585.Google Scholar
Marton, K., Campanelli, L., Eichorn, N., Scheuer, J., & Yoon, J. (2014). Information processing and proactive interference in children with and without specific language impairment. Journal of Speech, Language, and Hearing Research, 57, 106119.Google Scholar
McCauley, S., & Christiansen, M. (2013). Toward a unified account of comprehension and production in language development. Behavioral and Brain Sciences, 36, 3839.Google Scholar
McCauley, S., & Christiansen, M. (2014). Acquiring formulaic language: A computational model. The Mental Lexicon, 9, 419436.Google Scholar
McCauley, S., & Christiansen, M. (2015). Individual differences in chunking ability predict on-line sentence processing. Proceedings from The 37th Annual Conference of the Cognitive Science Society, 1553–1558.Google Scholar
McCauley, S., & Christiansen, M. (2017). Computational investigations of multiword chunks in language learning. Topics in Cognitive Science, 9, 637652.Google Scholar
McCauley, S., Isbilen, E., & Christiansen, M. (2017). Chunking ability shapes sentence processing at multiple levels of abstraction. In Gunzelmann, G., Howes, A., Tenbrink, T., & Davelaar, E. (Eds.), Proceedings of the 39th Annual Conference of the Cognitive Science Society (pp. 26812686). Cognitive Science Society.Google Scholar
Montgomery, J. (1995). Sentence comprehension in children with specific language impairment: The role of phonological working memory. Journal of Speech and Hearing Research, 38, 187199.Google Scholar
Montgomery, J. (2000). Relation of working memory to offline and real-time sentence processing in children with specific language impairment. Applied Psycholinguistics, 21, 117148.Google Scholar
Montgomery, J. (2008). Role of auditory attention in the real-time processing of simple grammar by children with specific language impairment: A preliminary investigation. International Journal of Language and Communication Disorders, 43, 499527.Google Scholar
Montgomery, J., & Evans, J. (2009). Complex sentence comprehension and working memory in children with specific language impairment. Journal of Speech, Language, and Hearing Research, 52, 269288.Google Scholar
Montgomery, J., Evans, J., Fargo, J., Schwartz, S., & Gillam, R. (2018). Structural relationship between cognitive processing and syntactic sentence comprehension in children with and without developmental language disorder. Journal of Speech, Language, and Hearing Research, 61, 29502976.Google Scholar
Montgomery, J., Evans, J., & Gillam, R. (2009). Relation of auditory attention and complex sentence comprehension in children with specific language impairment: A preliminary study. Applied Psycholinguistics, 30, 123151.Google Scholar
Montgomery, J., Evans, J., Gillam, R., Sergeev, A., & Finney, M. (2016). “Whatdunit?” Developmental changes in children’s syntactically based sentence comprehension abilities and sensitivity to word order. Applied Psycholinguistics, 37, 12811309.Google Scholar
Montgomery, J., Gillam, R., Evans, J., Fargo, J., & Schwartz, S. (2019). Comparison of the storage-only deficit and joint mechanism deficit hypotheses of the verbal working memory capacity limitation of children with developmental language disorder. Journal of Speech, Language, and Hearing Research, 62, 38083825.Google Scholar
Montgomery, J., Gillam, R., Evans, J., & Sergeev, A. (2017). Whatdunit? Sentence comprehension abilities of children with SLI: Sensitivity to word order in canonical and noncanonical sentences. Journal of Speech and Language Hearing Research, 60, 26032618.Google Scholar
Motallebzadeh, K., & Yazdi, M. (2016). The relationship between EFL learners’ reading comprehension ability and their fluid intelligence, crystallized intelligence, and processing speed. Cogent Education, 3, 18.Google Scholar
Moyle, M., Karasinski, C., Ellis Weismer, S., & Gorman, B. (2011). Grammatical morphology in school-age children with and without language impairment: A discriminant function analysis. Language, Speech, and Hearing Services in Schools, 42, 550560.Google Scholar
Nee, D., & Jonides, J. (2013). Trisecting representational states in short-term memory. Frontiers in Human Neuroscience, 7, 115.Google Scholar
Nippold, M. (2017). Reading comprehension deficits in adolescents: Addressing underlying language abilities. Language, Speech, and Hearing Services in Schools, 48, 125131.Google Scholar
Nippold, M., Hesketh, L., Duthie, J., & Mansfield, T. (2005). Conversational versus expository discourse: A study of syntactic development in children, adolescents, and adults. Journal of Speech, Language, and Hearing Research, 48, 10481064.Google Scholar
Nippold, M., Mansfield, T., Billow, J., & Tomblin, B. (2008). Expository discourse in adolescents with language impairments: Examining syntactic development. American Journal of Speech-Language Pathology, 17, 356366.Google Scholar
Nippold, M., Mansfield, T., Billow, J., & Tomblin, B. (2009). Syntactic development in adolescents with a history of language impairments: A follow-up investigation. American Journal of Speech-Language Pathology, 18, 241251.Google Scholar
Osaka, M., Osaka, N., Kondo, H., Morishita, M., Fukuyama, H., Aso, T., & Shibasaki, H. (2003). Neural basis of individual differences in working memory: An fMRI study. NeuroImage, 18, 789797.Google Scholar
Öztekin, I., & Cowan, N. (2015). Editorial: Representational states in memory: Where do we stand? Frontiers in Human Neuroscience, 9, 13.Google Scholar
Öztekin, I., Davachi, L., & McElree, B. (2010). Are representations in working memory distinct from representations in long-term memory? Neural evidence in support of a single store. Psychological Science, 21, 11231133.Google Scholar
Peterson, S., & Posner, M. (2012). The attention system of the human brain: 20 years after. Annual Review of Neuroscience, 35, 7389.Google Scholar
Plante, E., Patterson, D., Sandoval, M., Vance, C., & Asbjørnsen, A. (2017). An fMRI study of implicit language learning in developmental language impairment. NeuroImage: Clinical, 14, 277285.Google Scholar
Rice, M., Wexler, K., & Hershberger, S. (1998). Tense over time: The longitudinal course of tense acquisition in children with specific language impairment. Journal of Speech, Language, and Hearing Research, 41, 14121431.Google Scholar
Robertson, E., & Joanisse, M. (2010). Spoken sentence comprehension in children with dyslexia and language impairment: The roles of syntax and working memory. Applied Psycholinguistics, 31, 141165.Google Scholar
Roid, G., & Miller, L. (1997). Leiter International Performance Scale–Revised. Stoelting.Google Scholar
Savage, C., Lieven, E., Theakston, A., & Tomasello, M. (2003). Testing the abstractness of children’s linguistic representations: Lexical and structural priming of syntactic constructions in young children. Developmental Science, 6, 557567.Google Scholar
Shipstead, Z., Harrison, T., & Engle, R. (2016). Working memory capacity and fluid intelligence: Maintenance and disengagement. Perspectives on Psychological Science, 11, 771779.Google Scholar
Squire, L., Knowlton, B., & Musen, G. (1993). The structure and organization of memory. Annual Review in Psychology, 44, 453495.Google Scholar
The state of learning disabilities: Facts, trends and emerging issues (2014). National Center for Learning Disabilities (3rd Ed.).Google Scholar
Theakston, A., & Lieven, E. (2017). Multiunit sequences in first language acquisition. Topics in Cognitive Science, 9, 588603.Google Scholar
Thiessen, E. (2017). What’s statistical about learning? Insights from modelling statistical learning as a set of memory processes. Philosophical Transactions of the Royal Society B, 372, 20160056.Google Scholar
Ullman, M. (2016). The declarative/procedural model: A neurobiology model of language learning, knowledge, and use. In Hickok, G. & Small, S. (Eds.), Neurobiology of language (pp. 953968). Elsevier.Google Scholar
Ullman, M. (2004). Contributions of memory circuits to language: The declarative/procedural model. Cognition, 92, 231270.Google Scholar
Ullman, M., & Pierpont, E. (2005). Specific language impairment is not specific to language: The procedural deficit hypothesis. Cortex, 41, 399433.Google Scholar
Unsworth, N., & Engle, R. (2007). The nature of individual differences in working memory capacity: Active maintenance in primary memory and controlled search from secondary memory. Psychological Review, 114, 104132.Google Scholar
van der Lely, H., & Stollwerck, L. (1997). Binding theory and grammatical specific language impairment in children. Cognition, 62, 245290.Google Scholar
Victorino, K., & Schwartz, R. (2015). Control of auditory attention in children with specific language impairment. Journal of Speech, Language, and Hearing Research, 58, 12451257.Google Scholar
Weisleder, A., & Fernald, A. (2013). Talking to children matters: Early language experience strengthens processing and builds vocabulary. Psychological Science, 24, 21432152.Google Scholar
Wells, J., Christiansen, M., Race, D., Acheson, D., & MacDonald, M. (2009). Experience and sentence processing: Statistical learning and relative clause comprehension. Cognitive Psychology, 58, 250271.Google Scholar
Wilhelm, O., Hildebrandt, A., & Oberauer, K. (2013). What is working memory capacity, and how can we measure it? Frontiers in Psychology, 4, 122.Google Scholar
Zwitserlood, P. (1989). The locus of the effects of sentential-semantic context in spoken-word processing. Cognition, 32, 2564.Google Scholar

References

Adams, A.-M., & Gathercole, S. E. (1995). Phonological working memory and speech production in preschool children. Journal of Speech & Hearing Research, 38(2), 403414. https://doi.org/10.1044/jshr.3802.403Google Scholar
Alloway, T. P., Gathercole, S. E., Adams, A. M., & Willis, C. (2005). Working memory abilities in children with special educational needs. Education and Child Psychology, 22.Google Scholar
Alloway, T. P., Gathercole, S. E., Adams, A. M., Willis, C., Eaglen, R., & Lamont, E. (2005). Working memory and other cognitive skills as predictors of progress towards early learning goals at school entry. British Journal of Developmental Psychology, 23, 417426.Google Scholar
Almomani, F., Al-Momani, M. O., Garadat, S., Alqudah, S., Kassab, M., Hamadneh, S., Rauterkus, G., & Gans, R. (2021). Cognitive functioning in deaf children using cochlear implants. BMC Pediatrics, 21(1), 71. https://doi.org/10.1186/s12887-021-02534-1Google Scholar
AuBuchon, A. M., Pisoni, D. B., & Kronenberger, W. G. (2015). Verbal processing speed and executive functioning in long-term cochlear implant users. Journal of Speech, Language, and Hearing Research, 58(1), 151162. https://doi.org/10.1044/2014_JSLHR-H-13-0259CrossRefGoogle ScholarPubMed
Baddeley, A. (2000). The episodic buffer: A new component of working memory? Trends in Cognitive Sciences, 4, 417423.Google Scholar
Baddeley, A. (2003). Working memory and language: An overview. Journal of Communication Disorders, 36, 189208.Google Scholar
Baddeley, A., Gathercole, S. E., & Papagno, C. (1998). The phonological loop as a language learning device. Psychological Review, 105,158173.Google Scholar
Baddeley, A., & Hitch, G. J. (1974). Working memory. In Bower, G. H. (Ed.), The psychology of learning and motivation (Vol. 8, pp. 742775). Academic Press.Google Scholar
Bavelier, D., Newman, A. J., Mukherjee, M., Hauser, P., Kemeny, S., Braun, A., & Boutla, M. (2008). Encoding, rehearsal, and recall in signers and speakers: Shared network but differential engagement. Cerebral Cortex, 18(10), 22632274. https://doi.org/10.1093/cercor/bhm248Google Scholar
Bebko, J., & Metcalfe-Haggert, A. (1997). Deafness, language skills, and rehearsal: A model for the development of a memory strategy. Journal of Deaf Studies and Deaf Education, 2(3), 131139. https://doi.org/10.1093/oxfordjournals.deafed.a014319Google Scholar
Brentari, D. 2019. Sign language phonology. Cambridge University Press.Google Scholar
Buchanan-Worster, E; MacSweeney, M; Pimperton, H; Kyle, F; Harris, M; Beedie, I; Ralph-Lewis, A., & Hulme, C. (2020) Speechreading ability is related to phonological awareness and single-word reading in both deaf and hearing children. Journal of Speech, Language, and Hearing Research, 63, 37753785Google Scholar
Campbell, R., & Dodd, B. (1980). Hearing by eye. Quarterly Journal of Experimental Psychology, 32, 8599.Google Scholar
Campbell, R., MacSweeney, M., & Woll, B. (2014). Cochlear implantation (CI) for prelingual deafness: The relevance of studies of brain organization and the role of first language acquisition in considering outcome success. Frontiers in Human Neuroscience, 8, 834.Google Scholar
Cleary, M., Pisoni, D. B., & Kirk, K. I. (2000). Working memory spans as predictors of spoken word recognition and receptive vocabulary in children with cochlear implants. The Volta Review, 102, 259280.Google Scholar
Conrad, R. (1970). Short-term memory processes in the deaf. British Journal of Psychology, 61(2), 179195.Google Scholar
Cowan, N. (2010). The magical mystery four: How is working memory capacity limited, and why? Current Directions in Psychological Science, 19(1), 5157.Google Scholar
Cowan, N., Li, Y., Glass, B., & Saults, J. S. (2017). Development of the ability to combine visual and acoustic information in working memory. Developmental Science, 21, e12635, 114.Google Scholar
Cowan, N., Rouder, J. N., Blume, C. L., & Saults, J. S. (2012). Models of verbal working memory capacity: What does it take to make them work? Psychological Review, 119, 480499.Google Scholar
D’Souza, D., D’Souza, H., Karmiloff-Smith, A. (2017). Precursors to language development in typically and atypically developing infants and toddlers: The importance of embracing complexity. Journal of Child Language, 44, 591627.Google Scholar
Davidson, K., Lillo-Martin, D., & Chen Pichler, D. (2014). Spoken English language development among native signing children with cochlear implants. Journal of Deaf Studies and Deaf Education, 19(2), 238250.Google Scholar
Desjardin, J. (2006). Family empowerment: Supporting language development in young children who are deaf or hard of hearing. Volta Review, 106, 275298.Google Scholar
Dillon, C. M., Cleary, M., Pisoni, D. B., & Carter, A. K. (2004). Imitation of nonwords by hearing-impaired children with cochlear implants: Segmental analyses. Clinical Linguistics & Phonetics, 18(1), 3955.Google Scholar
Dodd, B., Hobson, P., Brasher, J., & Campbell, R. (1983). Deaf children’s short-term memory for lip-read, graphic and signed stimuli. British Journal of Developmental Psychology, 1(4), 353364.Google Scholar
Doebel, S., & Zelazo, P. D. (2015). A meta-analysis of the Dimensional Change Card Sort: Implications for developmental theories and the measurement of executive function in children. Developmental Review, 38, 241268.Google Scholar
Elliott, R. (2003). Executive functions and their disorders. British Medical Bulletin, 65, 4959.Google Scholar
Emmorey, K., Giezen, M. R., Petrich, J. A. F., Spurgeon, E., & O’Grady Farnady, L. (2017). The relation between working memory and language comprehension in signers and speakers. Acta Psychologica, 177, 6977.Google Scholar
Fagan, M. K., Pisoni, D., Horn, D., & Dillon, C. (2007). Neuropsychological correlates of vocabulary, reading, and working memory in deaf children with cochlear implants. Journal of Deaf Studies and Deaf Education, 12, 461471Google Scholar
Fitzpatrick, E., Hamel, C., Stevens, A., Pratt, M., Moher, D., Doucet, S., … Na, E. (2016). Sign language and spoken language for children with hearing loss: A systematic review. Pediatrics, 137, e20151974Google Scholar
Gathercole, S. E. (1999). Cognitive approaches to the development of short-term memory. Trends in Cognitive Science, 3, 410418.Google Scholar
Gathercole, S. E., & Adams, A. M. (1993). Phonological working memory in very young children. Developmental Psychology, 29, 770778.Google Scholar
Gathercole, S. E., & Hitch, G. J. (1993). Developmental changes in short-term memory: A revised working memory perspective. In Collins, A. F., Gathercole, S. E., Conway, M. A., & Morris, P. E. (Eds.), Theories of memory (p. 189209). Lawrence Erlbaum Associates.Google Scholar
Gathercole, S. E., Tiffany, C., Briscoe, J., Thorn, A. S. C., & the ALSPAC Team (2005). Developmental consequences of phonological loop deficits during early childhood: A longitudinal study. Journal of Child Psychology and Psychiatry, 46, 598611.Google Scholar
Geers, A. E., & Sedey, A. L. (2011). Language and verbal reasoning skills in adolescents with 10 or more years of cochlear implant experience. Ear and Hearing, 32(1 Suppl), 39S48S.Google Scholar
Geers, A. E., Nicholas, J. G., Tobey, E., & Davidson, L. (2016). Persistent language delay versus late language emergence in children with early cochlear implantation. Journal of Speech, Language and Hearing Research, 59, 155170.Google Scholar
Gottardis, L., Nunes, T., & Lunt, I. (2011). A synthesis of research on deaf and hearing children’s mathematical achievement. Deafness & Education International, 13, 131150.Google Scholar
Hall, M. L., & Bavelier, D. (2010). Working memory, deafness, and sign language. In Marshark, M. & Spencer, P. E. (Eds.), The Oxford handbook of deaf studies, language, and education (Vol. 2, pp. 458472). Oxford University Press.Google Scholar
Hall, M. L., Hall, W. C., & Caselli, N. K. (2019). Deaf children need language, not (just) speech. First Language, 39(4), 367395.Google Scholar
Hanson, V. L. (1986). Access to spoken language and the acquisition of orthographic structure: Evidence from deaf readers. Quarterly Journal of Experimental Psychology, 38A, 193212.Google Scholar
Harlor, A. D. B., & Bower, C. (2009). Hearing assessment in infants and children: Recommendations beyond neonatal screening. Pediatrics, 124, 12521263.Google Scholar
Harris, M., & Moreno, C. (2004). Deaf children’s use of phonological coding: evidence from reading, spelling, and working memory. Journal of Deaf Studies & Deaf Education, 9(3), 253268.Google Scholar
Harris, M. S., Kronenberger, W. G., Gao, S., Hoen, H. M., Miyamoto, R. T., & Pisoni, D. B. (2013). Verbal short-term memory development and spoken language outcomes in deaf children with cochlear implants. Ear and Hearing, 34(2), 179192.Google Scholar
Henry, L. A, Messer, D. J., & Nash, G. (2012). Executive functioning in children with specific language impairment. Journal of Child Psychology and Psychiatry, 53, 3745Google Scholar
Jones, A., Atkinson, J., Marshall, C. R., Botting, N., St Clair, M., & Morgan, G. (2020). Expressive vocabulary predicts non-verbal executive function: A 2-year longitudinal study of deaf and hearing children. Child Development, 91,e400–14.63.Google Scholar
Just, M. A., & Carpenter, P. A. (1992). A capacity theory of comprehension: Individual differences in working memory. Psychological Review, 99(1), 122149.Google Scholar
Kapa, L. L., & Colombo, J. (2013). Attentional control in early and later bilingual children. Cognitive Development, 28(3), 233246.Google Scholar
Kapa, L. L., & Erikson, J. A. (2019). Variability of executive function performance in pre-schoolers with developmental language disorder. Seminars in Speech and Language, 40(4), 243255.Google Scholar
Keehner, M., & Atkinson, J. (2006). Working memory and deafness: Implications for cognitive development and functioning. In Pickering, Susan J. (Ed.), Working memory and education. Academic Press.Google Scholar
Koo, D., Crain, K., LaSasso, C., & Eden, G. (2008). Phonological awareness and short-term memory in hearing and deaf individuals of different communication backgrounds. Annals of the New York Academy of Sciences, 1145, pp. 8399.Google Scholar
Kronenberger, W. G., Pisoni, D. B., Henning, S. C., & Colson, B. G. (2013). Executive functioning skills in long-term users of cochlear implants: A case control study. Journal of Pediatric Psychology, 38, 902914.Google Scholar
Lauro, L. J. R., Crespi, M., Papagno, C., & Cecchetto, C. (2014). Making sense of an unexpected detrimental effect of sign language use in a visual task. Journal of Deaf Studies and Deaf Education, 19 (3), 358365.Google Scholar
Lina-Granade, G., Comte-Gervais, I., Gippon, L., Nappez, G., Morin, E., & Truy, E. (2010). Correlation between cognitive abilities and language level in cochlear implanted children. Cochlear Implants International, 11(Suppl. 1), 328331.Google Scholar
López-Crespo, G., Daza, M. T., & Méndez-López, M. (2012). Visual working memory in deaf children with diverse communication modes: Improvement by differential outcomes. Research in Developmental Disabilities, 33(2), 362368.Google Scholar
Lu, J., Jones, A., & Morgan, G. (2016). The impact of input quality on early sign development in native and non-native language learners. Journal of Child Language, 43, 537552Google Scholar
MacSweeney, M., Campbell, R., & Donlan, C. (1996). Varieties of short-term memory coding in deaf teenagers. Journal of Deaf Studies and Deaf Education, 1(4), 249262.Google Scholar
Marschark, M., Rhoten, C., & Fabich, M. (2007). Effects of cochlear implants on children’s reading and academic achievement. Journal of Deaf Studies and Deaf Education, 12, 269282.Google Scholar
Marshall, C., Jones, A., Denmark, T., Mason, K., Atkinson, J., Botting, N., & Morgan, G. (2015). Deaf children’s non-verbal working memory is impacted by their language experience. Frontiers in Psychology, 6, 527.Google Scholar
Miller, P. (2001). Communication mode and the information processing capacity of Hebrew readers with prelingually acquired deafness. Journal of Developmental and Physical Disabilities, 13(2001), 8396Google Scholar
Mitchell, R. E., & Karchmer, M. A. (2004). Chasing the mythical ten percent: parental hearing status of deaf and hard of hearing students in the United States. Sign Language Studies, 4(2), 138163.Google Scholar
National Institute for Health and Clinical Excellence (NICE). (2019). Cochlear implants for children and adults with severe to profound deafness. NICE technology appraisal guidance 566. [online]. https://www.nice.org.uk/guidance/ta566Google Scholar
Nittrouer, S., Sansom, E., Low, K., Rice, C., & Caldwell-Tarr, A. (2014). Language structures used by kindergartners with cochlear implants: Relationship to phonological awareness, lexical knowledge and hearing loss. Ear and Hearing, 35(5), 506518.Google Scholar
Nittrouer, S., Caldwell, A., Lowenstein, J.H., Tarr, E., & Holloman, C. (2012). Emergent literacy in kindergartners with cochlear implants, Ear Hear, 33(6) 683697.Google Scholar
Nittrouer, S., Caldwell-Tarr, A., & Lowenstein, J. H. (2013). Working memory in children with cochlear implants: Problems are in storage, not processing. International Journal of Pediatric Otorhinolaryngology, 77(11), 18861898.Google Scholar
Nouwens, S., Groen, M. A., & Verhoeven, L. (2017). How working memory relates to children’s reading comprehension: The importance of domain-specificity in storage and processing. Reading and Writing, 30(1), 105120.Google Scholar
O’Connor, N., & Hermelin, B. (1972). Seeing and hearing and time and space. Perception and Psychophysics, 11, 4648.Google Scholar
Pierce, L., Genesee, F., Delcenserie, A., & Morgan, G. (2017). Variations in phonological working memory: Linking early language experiences and language learning outcomes. Applied Psycholinguistics, 38, 12651300.Google Scholar
Pisoni, D. B., & Cleary, M. (2003). Measures of working memory span and verbal rehearsal speed in deaf children after cochlear implantation. Ear and Hearing, 24(1 Suppl), 106S120S.Google Scholar
Pisoni, D. B., Kronenberger, W. G., Roman, A. S., & Geers, A. E. ( 2011). Measures of digit span and verbal rehearsal speed in deaf children after more than 10 years of cochlear implantation. Ear and Hearing, 32, 60S74S.Google Scholar
Power, D. (2005). Models of deafness: Cochlear implants in the Australian daily press. The Journal of Deaf Studies and Deaf Education, 10, 451459.Google Scholar
Soleymani, Z., Amidfar, M., Dadgar, H., & Jalaei, S. (2014). Working memory in Farsi-speaking children with normal development and cochlear implant. International Journal of Pediatric Otorhinolaryngology, 78.Google Scholar
Stiles, D. J., McGregor, K. K., & Bentler, R. A. (2012). Vocabulary and working memory in children fit with hearing aids. Journal of Speech, Language, and Hearing Research, 55, 154167.Google Scholar
Torkildsen, J. V., Arciuli, J., Haukedal, C. L., & Wie, O. B. (2018). Does a lack of auditory experience affect sequential learning? Cognition, 170, 123129.Google Scholar
Vugs, B., Knoors, H., Cuperus, J., Hendriks, M., & Verhoeven, L. (2017). Executive function training in children with SLI: A pilot study. Child Language Teaching and Therapy, 33(1), 4766.Google Scholar
Vygotsky, L. (1962). Studies in communication, thought and language. In Hanfmann, E. & Vakar, G. (Eds.), MIT Press.Google Scholar
Wilson, M., & Emmorey, K. (1997). A visuospatial “phonological loop” in working memory: Evidence from American Sign Language. Memory & Cognition, 25(3), 313320.Google Scholar
Wingfield, A., Tun, P. A., & McCoy, S. L. (2005). Hearing loss in older adulthood: What it is and how it interacts with cognitive performance. Current Directions in Psycholological Science, 14, 144148.Google Scholar
Wolfe, C. D., & Bell, M. A. (2004). Working memory and inhibitory control in early childhood: Contributions from physiology, temperament, and language. Developmental Psychobiology, 44(1), 6883.Google Scholar

References

Alloway, T. P. (2010). Improving working memory: Supporting students’ learning. Sage.Google Scholar
Alloway, T. P. (2012). Can interactive working memory training improve learning? Journal of Interactive Learning Research, 23(3), 197207.Google Scholar
Alloway, T. P., & Alloway, R. G. (2010). Investigating the predictive roles of working memory and IQ in academic attainment. Journal of Experimental Child Psychology, 106(1), 2029.Google Scholar
Alloway, T. P., Alloway, R. G., & Wootan, S. (2014). Home sweet home: Does where you live matter to working memory and other cognitive skills? Journal of Experimental Child Psychology, 124, 124131Google Scholar
Alloway, T. P., Bibile, V., & Lau, G. (2013). Computerized working memory training: Can it lead to gains in cognitive skills in students? Computers & Human Behavior, 29(3), 632638.Google Scholar
Alloway, T. P., & Copello, E. (2013). Working memory: The what, the why, and the how. The Australian Educational and Developmental Psychologist, 30(2), 105118.Google Scholar
Alloway, T. P., Gathercole, S. E., Adams, A. M., Willis, C., Eaglen, R., & Lamont, E. (2005). Working memory and other cognitive skills as predictors of progress towards early learning goals at school entry. British Journal of Developmental Psychology, 23, 417426.Google Scholar
Alloway, T. P., Gathercole, S. E., & Kirkwood, H. (2008). Working memory rating scale. Pearson.Google Scholar
Alloway, T. P., Gathercole, S. E., Kirkwood, H., & Elliott, J. (2009). The cognitive and behavioral characteristics of children with low working memory. Child Development, 80(2), 606621.Google Scholar
Alloway, T. P., & Gregory, D. (2013). The predictive ability of IQ and working memory scores in literacy in an adult population. International Journal of Educational Research, 57, 5156 (2013).Google Scholar
Alloway, T. P., & Passolunghi, M. C. (2011). The relationship between working memory, IQ, and mathematical skills in children. Learning and Individual Differences, 21(1), 133137.Google Scholar
Aksayli, N. D., Sala, G., & Gobet, F. (2019). The cognitive and academic benefits of Cogmed: A meta-analysis. Educational Research Review, 27, 229243.Google Scholar
Anderson, P. J., Lee, K. J., Roberts, G., Spencer-Smith, M. M., Thompson, D. K., Seal, M. L., … & Pascoe, L. (2018). Long-term academic functioning following Cogmed working memory training for children born extremely preterm: A randomized controlled trial. The Journal of Pediatrics, 202, 9297.Google Scholar
Baddeley, A. (2010). Working memory. Current Biology, 20(4), R136R140.Google Scholar
Bigorra, A., Garolera, M., Guijarro, S., & Hervás, A. (2016). Long-term far-transfer effects of working memory training in children with ADHD: A randomized controlled trial. European Child & Adolescent Psychiatry, 25(8), 853867.Google Scholar
Cain, K., Oakhill, J., & Bryant, P. (2004). Children’s reading comprehension ability: concurrent prediction by working memory, verbal ability and component skills. Journal of Educational Psychology, 96, 3142.Google Scholar
Chen, X., Ye, M., Chang, L., Chen, W., & Zhou, R. (2018). Effect of working memory updating training on retrieving symptoms of children with learning disabilities. Journal of Learning Disabilities, 51(5), 507519.Google Scholar
Colmar, S., Double, K., Davis, N., Sheldon, L., Phillips, N., Cheng, M., & Briddon, S. (2020). Memory mates: An evaluation of a classroom-based, student-focused working memory intervention. Journal of Psychologists and Counsellors in Schools, 30(2), 159171.Google Scholar
Cornoldi, C., Carretti, B., Drusi, S., & Tencati, C. (2015) Improving problem solving in primary school students: The effect of a training programme focusing on metacognition and working memory. British Journal of Educational Psychology, 85(3), 424439. doi: 10.1111/bjep.12083Google Scholar
Dahlin, E., Nyberg, L., Bäckman, L., & Neely, A. S. (2008). Plasticity of executive functioning in young and older adults: Immediate training gains, transfer, and long-term maintenance. Psychology and Aging, 23(4), 720730. doi: 10.1037/a0014296Google Scholar
D’Amico, A., & Guarnera, M. (2005). Exploring working memory in children with low arithmetical achievement. Learning and Individual Differences, 15, 189202.Google Scholar
De Weerdt, F., Desoete, A., & Roeyers, H. (2013). Working memory in children with reading disabilities and/or mathematical disabilities. Journal of Learning Disabilities, 46(5), 461472.Google Scholar
Dentz, A., Guay, M. C., Parent, V., & Romo, L. (2020). Working memory training for adults with ADHD. Journal of Attention Disorders, 24(6), 918927.Google Scholar
Dietrichson, J., Bøg, M., Filges, T., & Klint Jørgensen, A. M. (2017). Academic interventions for elementary and middle school students with low socioeconomic status: A systematic review and meta-analysis. Review of Educational Research, 87(2), 243282.Google Scholar
Fitzpatrick, C., Archambault, I., Janosz, M., & Pagani, L. S. (2015). Early childhood working memory forecasts high school dropout risk. Intelligence, 53, 160165.Google Scholar
Friso-Van den Bos, I., Van der Ven, S. H., Kroesbergen, E. H., & Van Luit, J. E. (2013). Working memory and mathematics in primary school children: A meta-analysis. Educational Research Review, 10, 2944.Google Scholar
Gathercole, S., & Alloway, T. P. (2008). Working memory and learning: A practical guide for teachers. Sage.Google Scholar
Gathercole, S. E., Alloway, T. P., Willis, C., & Adams, A. M. (2006). Working memory in children with reading disabilities. Journal of Experimental Child Psychology, 93, 265−281.Google Scholar
Green, C. T., Long, D. L., Green, D., Iosif, A. M., Dixon, J. F., Miller, M. R., et al. (2012). Will working memory training generalize to improve off-task behavior in children with attention-deficit/hyperactivity disorder? Neurotherapeutics, 9, 639648.Google Scholar
Giofrè, D., Borella, E., & Mammarella, I. C. (2017). The relationship between intelligence, working memory, academic self-esteem, and academic achievement. Journal of Cognitive Psychology, 29(6), 731747.Google Scholar
Hannon, B., & McNaughton‐Cassill, M. (2011). SAT performance: Understanding the contributions of cognitive/learning and social/personality factors. Applied Cognitive Psychology, 25(4), 528535.Google Scholar
Hardy, J. L., Nelson, R. A., Thomason, M. E., Sternberg, D. A., Katovich, K., Farzin, F., & Scanlon, M. (2015). Enhancing cognitive abilities with comprehensive training: A large, online, randomized, active-controlled trial. PLoS ONE, 10(9), e0134467.Google Scholar
Hawes, Z., & Ansari, D. (2020). What explains the relationship between spatial and mathematical skills? A review of evidence from brain and behavior. Psychonomic Bulletin & Review, 1–18.Google Scholar
Holmes, J., & Gathercole, S. E. (2014). Taking working memory from the laboratory into schools. Educational Psychologist 34(4), 440450.Google Scholar
Holmes, J., Gathercole, S. E., & Dunning, D. L. (2009). Adaptive training leads to sustained enhancement of poor working memory in children. Developmental Science, 12(4), F9F15 (2009).Google Scholar
Kerns, K. A., Macoun, S., MacSween, J., Pei, J., & Hutchison, M. (2017). Attention and working memory training: A feasibility study in children with neurodevelopmental disorders. Applied Neuropsychology: Child, 6(2), 120137.Google Scholar
Kirk, H. E., Gray, K., Riby, D., & Cornish, K. M. (2015). Cognitive training as a resolution for early executive function difficulties in children with intellectual disabilities. Research in Developmental Disabilities, 38, 145160.Google Scholar
Klingberg, T., Fernell, E., Olesen, P. J., Johneson, M., Gustafsson, P., Dahlström, K., & Westerberg, H. (2005). Computerized training of working memory in children with ADHD: A randomized, controlled trial. Child and Adolescent Psychiatry, 44(2), 177186.Google Scholar
Lee, K., Lee, M. P., Ang, S. Y., & Stankov, L. (2009). Do measures of working memory predict academic proficiency better than measures of intelligence? Psychology Science.Google Scholar
Lin, X., Peng, P., & Luo, H. (2021). The deficit profile of elementary students with computational difficulties versus word problem-solving difficulties. Learning Disability Quarterly, 44(2), 110122.Google Scholar
Linares, R., Borella, E., Lechuga, M. T., Carretti, B., & Pelegrina, S. (2019). Nearest transfer effects of working memory training: A comparison of two programs focused on working memory updating. PLoS ONE, 14(2), e0211321.Google Scholar
Loosli, S. V., Buschkuehl, M., Perrig, W. J., & Jaeggi, S. M. (2012 ). Working-memory training improves reading processes in typically developing children. Child Neuropsychology, 18(1), 6278.Google Scholar
Melby-Lervåg, M., Redick, T. S., & Hulme, C. (2016). Working memory training does not improve performance on measures of intelligence or other measures of “far transfer” evidence from a meta-analytic review. Perspectives on Psychological Science, 11(4), 512534.Google Scholar
Mezzacappa, E., & Buckner, J. C. (2010). Working memory training for children with attention problems or hyperactivity : A school-based pilot study. School Mental Health, 2(4), 202208.Google Scholar
Nguyen, T., & Duncan, G. J. (2019). Kindergarten components of executive function and third grade achievement: A national study. Early Childhood Research Quarterly, 46, 4961.Google Scholar
Phakey, N., Sharma, S., Garg, D., Mukherjee, S. B., Sapra, S., Wadhawan, A. N., & Shukla, G. (2021). Development and evaluation of a working memory intervention kit in children with epilepsy in low-resource settings. The Indian Journal of Pediatrics, 1–4.Google Scholar
Redick, T. S., & Lindsey, D. R. (2013). Complex span and n-back measures of working memory: A meta-analysis. Psychonomic Bulletin & Review, 20(6), 11021113.Google Scholar
Rey-Mermet, A., Gade, M., Souza, A. S., Von Bastian, C. C., & Oberauer, K. (2019). Is executive control related to working memory capacity and fluid intelligence? Journal of Experimental Psychology: General, 148(8), 1335.Google Scholar
Rode, C., Robson, R., Purviance, A., Geary, D., & Mayr, U. (2014). Is working memory training effective? A study in a school setting. PLoS ONE, 9(8), 18.Google Scholar
Roberts, G., Quach, J., Spencer-Smith, M., Anderson, P. J., Gathercole, S., Gold, L., … & Wake, M. (2016). Academic outcomes 2 years after working memory training for children with low working memory: A randomized clinical trial. JAMA Pediatrics, 170(5), e154568e154568.Google Scholar
Ruan, Y., Georgiou, G. K., Song, S., Li, Y., & Shu, H. (2018). Does writing system influence the associations between phonological awareness, morphological awareness, and reading? A meta-analysis. Journal of Educational Psychology, 110(2), 180.Google Scholar
Sala, G., & Gobet, F. (2017). Working memory training in typically developing children: A meta-analysis of the available evidence. Developmental Psychology, 53(4), 671.Google Scholar
Schwaighofer, M., Fischer, F., & Buhner, M. (2015). Does working memory training transfer? A meta-analysis including training conditions as moderators. Educational Psychologist, 50(2), 138166.Google Scholar
Siquara, G. M., dos Santos Lima, C., & Abreu, N. (2018). Working memory and intelligence quotient: Which best predicts on school achievement? Psico, 49(4), 365374.Google Scholar
Söderqvist, S., & Bergman Nutley, S. (2015). Working memory training is associated with long term attainments in math and reading. Frontiers in Psychology, 6, 1711.Google Scholar
Swanson, H. L., & McMurran, M. (2018). The impact of working memory training on near and far transfer measures: Is it all about fluid intelligence? Child Neuropsychology, 24(3), 370395.Google Scholar
Swanson, H. L., & Saez, L. (2003). Memory difficulties in children and adults with learning disabilities. In Swanson, H. L., Graham, S., & Harris, K. R. (Eds.), Handbook of learning disabilities (pp. 182198). Guildford Press.Google Scholar
Thevenot, C., & Oakhill, J. (2005). The strategic use of alternative representations in arithmetic word problem solving. The Quarterly Journal of Experimental Psychology, 58A, 13111323.Google Scholar
Titz, C., & Karbach, J. (2014). Working memory and executive functions: Effects of training on academic achievement. Psychological Research, 78(6), 852868 (2014).Google Scholar
Träff, U., Olsson, L., Östergren, R., & Skagerlund, K. (2020). Development of early domain-specific and domain-general cognitive precursors of high and low math achievers in grade 6. Child Neuropsychology, 26(8), 10651090.Google Scholar
Van der Molen, M., Van Luit, J., Van der Molen, M., Klugkist, I., & Jongmans, M. (2010). Effectiveness of a computerised working memory training in adolescents with mild to borderline intellectual disabilities. Journal of Intellectual Disability Research, 54(5), 433447.Google Scholar
Wu, Y. (2020). Does Cogmed working memory training improve school-age ADHD children’s academic achievement? Cambridge Educational Research e-Journal 7, 141167.Google Scholar

References

Allen, R. J., Hitch, G. J., Mate, J., & Baddeley, A. D. (2012). Feature binding and attention in working memory: A resolution of previous contradictory findings. The Quarterly Journal of Experimental Psychology, 65(12), 23692383.Google Scholar
Allen, R. J., & Waterman, A. H. (2015). How does enactment affect the ability to follow instructions in working memory? Memory & Cognition, 43(3), 555561.Google Scholar
Astle, D. E., & Fletcher-Watson, S. (2020). Beyond the core-deficit hypothesis in developmental disorders. Current Directions in Psychological Science, 29(5), 431437.Google Scholar
Au, J., Katz, B., Buschkuehl, M., Bunarjo, K., Senger, T., Zabel, C., Jaeggi, S. M., & Jonides, J. (2016). Enhancing working memory training with transcranial direct current stimulation. Journal of Cognitive Neuroscience, 28(9), 14191432.Google Scholar
Au, J., Sheehan, E., Tsai, N., Duncan, G. J., Buschkuehl, M., & Jaeggi, S. M. (2015). Improving fluid intelligence with training on working memory. Psychonomic Bulletin & Review, 22(2), 112.Google Scholar
Baddeley, A. D. (1986). Working memory. Oxford University Press.Google Scholar
Baddeley, A. (2010). Working memory. Current Biology, 20(4), R136R140.Google Scholar
Baddeley, A. (2012). Working memory: Theories, models, and controversies. Annual Review of Psychology, 63, 129.Google Scholar
Baddeley, A. D., & Hitch, G. (1974). Working memory. In Psychology of learning and motivation (Vol. 8, pp. 4789). Elsevier.Google Scholar
Baddeley, A. D., & Scott, D. (1971). Short term forgetting in the absence of proactive interference. The Quarterly Journal of Experimental Psychology, 23(3), 275283.Google Scholar
Berryhill, M. E., Peterson, D. J., Jones, K. T., & Stephens, J. A. (2014). Hits and misses: Leveraging tDCS to advance cognitive research. Frontiers in Psychology, 5, 112.Google Scholar
Bishop, D. V. M., & Snowling, M. J. (2004). Developmental dyslexia and specific language impairment: Same or different? Psychological Bulletin, 130(6), 858886.Google Scholar
Booth, J. N., Boyle, J. M. E., & Kelly, S. W. (2010). Do tasks make a difference? Accounting for heterogeneity of performance of children with reading difficulties on tasks of executive function: Findings from a meta‐analysis. British Journal of Developmental Psychology, 28(1), 133176.Google Scholar
Brener, R. (1940). An experimental investigation of memory span. Journal of Experimental Psychology, 26(5), 467482.Google Scholar
Bull, R., & Johnston, R. S. (1997). Children’s arithmetical difficulties: Contributions from processing speed, item identification, and short-term memory. Journal of Experimental Child Psychology, 65(1), 124.Google Scholar
Bull, R., & Scerif, G. (2001). Executive functioning as a predictor of children’s mathematics ability: Inhibition, switching, and working memory. Developmental Neuropsychology, 19(3), 273293.Google Scholar
Byrne, E. M., Ewbank, M. P., Gathercole, S. E., & Holmes, J. (2020). The effects of transcranial direct current stimulation on within- and cross-paradigm transfer following multi-session backward recall training. Brain and Cognition, 141, 105552.Google Scholar
Byrne, E. M., Nord, C. L., & Holmes, J. (2021). Cognitive plasticity and transcranial electrical stimulation. In Cognitive Training (pp. 85105). Springer International Publishing.Google Scholar
Cain, K., Oakhill, J., & Bryant, P. (2004). Children’s reading comprehension ability: Concurrent prediction by working memory, verbal ability, and component skills. Journal of Educational Psychology, 96(1), 3142.Google Scholar
Cain, K., Oakhill, J., & Lemmon, K. (2004). Individual differences in the inference of word meanings from context: The influence of reading comprehension, vocabulary knowledge, and memory capacity. Journal of Educational Psychology, 96(4), 671681.Google Scholar
Camos, V., Lagner, P., & Barrouillet, P. (2009). Two maintenance mechanisms of verbal information in working memory. Journal of Memory and Language, 61(11), 457469.Google Scholar
Cantor, J., & Engle, R. W. (1993). Working-memory capacity as long-term memory activation: An individual-differences approach. Journal of Experimental Psychology: Learning, Memory, and Cognition, 19(5), 11011114.Google Scholar
Carretti, B., Borella, E., Cornoldi, C., & De Beni, R. (2009). Role of working memory in explaining the performance of individuals with specific reading comprehension difficulties: A meta-analysis. Learning and Individual Differences, 19(2), 246251.Google Scholar
Castles, A., & Friedmann, N. (2014). Developmental dyslexia and the phonological deficit hypothesis. Mind and Language, 29(3), 270285.Google Scholar
Catts, H. W., Fey, M. E., Tomblin, J. B., & Zhang, X. (2002). A longitudinal investigation of reading outcomes in children with language impairments. Journal of Speech, Language, and Hearing Research, 45(6), 11421157.Google Scholar
Chandler, P,. & Sweller, J. (1991). Cognitive Load Theory and the format of instruction. Cognition and Instruction, 8(4), 293332.Google Scholar
Charlesworth, L. A., Allen, R. J., Morson, S., Burn, W. K., & Souchay, C. (2014). Working memory and the enactment effect in early Alzheimer’s disease. ISRN Neurology, eCollection 2014.Google Scholar
Child, A. E., Cirino, P. T., Fletcher, J. M., Willcutt, E. G., & Fuchs, L. S. (2019). A cognitive dimensional approach to understanding shared and unique contributions to reading, math, and attention skills. Journal of Learning Disabilities, 52(1), 1530.Google Scholar
Cirino, P. T., Child, A. E., & Macdonald, K. T. (2018). Longitudinal predictors of the overlap between reading and math skills. Contemporary Educational Psychology, 54, 99111.Google Scholar
Coffman, B. A., Clark, V. P., & Parasuraman, R. (2014). Battery powered thought: Enhancement of attention, learning, and memory in healthy adults using transcranial direct current stimulation. NeuroImage, 85, 895908.Google Scholar
Cohen Kadosh, R., Levy, N., O’Shea, J., Shea, N., & Savulescu, J. (2012). The neuroethics of non-invasive brain stimulation. Current Biology, 22(4), R108–R111.Google Scholar
Cornoldi, C., Carretti, B., Drusi, S., & Tencati, C. (2015). Improving problem solving in primary school students: The effect of a training programme focusing on metacognition and working memory. The British Journal of Educational Psychology, 85(3), 424439.Google Scholar
Cortese, S., Ferrin, M., Brandeis, D., Buitelaar, J., Daley, D., Dittmann, R. W., Holtmann, M., Santosh, P., Stevenson, J., Stringaris, A., Zuddas, A., & Sonuga-Barke, E. J. S. (2015). Cognitive training for attention-deficit/hyperactivity disorder: Meta-analysis of clinical and neuropsychological outcomes from randomized controlled trials. Journal of the American Academy of Child and Adolescent Psychiatry, 54(3), 164174.Google Scholar
Costanzo, F., Rossi, S., Varuzza, C., Varvara, P., Vicari, S., & Menghini, D. (2019). Long-lasting improvement following tDCS treatment combined with a training for reading in children and adolescents with dyslexia. Neuropsychologia, 130, 3843.Google Scholar
Costanzo, F., Varuzza, C., Rossi, S., Sdoia, S., Varvara, P., Oliveri, M., Giacomo, K., Vicari, S., & Menghini, D. (2016). Evidence for reading improvement following tDCS treatment in children and adolescents with dyslexia. Restorative Neurology and Neuroscience, 34(2), 215226.Google Scholar
Cowan, N. (2008). What are the differences between long-term, short-term, and working memory? Progress in Brain Research, 169, 323338.Google Scholar
Cowan, N. (2017). The many faces of working memory and short-term storage. Psychonomic Bulletin & Review, 24(4), 11581170.Google Scholar
Cowan, N., Saults, J. S., & Nugent, L. D. (1997). The role of absolute and relative amounts of time in forgetting within immediate memory: The case of tone-pitch comparisons. Psychonomic Bulletin & Review, 4(3), 393397.Google Scholar
Dahlin, E., Neely, A. S., Larsson, A., Bäckman, L., & Nyberg, L. (2008). Transfer of learning after updating training mediated by the striatum. Science, 320(5882), 15101512Google Scholar
Davis, N. J., Oberman, L. M., & Earp, B. D. (2014). Transcranial stimulation of the developing brain: A plea for extreme caution. Frontiers in Human Neuroscience, 8, 600.Google Scholar
De Smedt, B., Swillen, A., Verschaffel, L., & Ghesquière, P. (2009). Mathematical learning disabilities in children with 22q11.2 deletion syndrome: A review. Developmental Disabilities Research Reviews, 15(1), 410.Google Scholar
Duncan, J., & Owen, A. M. (2000). Common regions of the human frontal lobe recruited by diverse cognitive demands. Trends in Neurosciences, 23(10), 475483.Google Scholar
Dunning, D. L., & Holmes, J. (2014). Does working memory training promote the use of strategies on untrained working memory tasks? Memory & Cognition, 42(6), 854862.Google Scholar
Dunning, D. L., Holmes, J., & Gathercole, S. E. (2013). Does working memory training lead to generalized improvements in children with low working memory? A randomized controlled trial. Developmental Science, 16, 915925.Google Scholar
Dwan, K., Gamble, C., Williamson, P. R., & Kirkham, J. J. (2013). Systematic review of the empirical evidence of study publication bias and outcome reporting bias: An updated review. PLoS ONE, 8, e66844.Google Scholar
Elliott, J. G., Gathercole, S. E., Alloway, T. P., Holmes, J., & Kirkwood, H. (2010). An evaluation of a classroom-based intervention to help overcome working memory difficulties and improve long-term academic achievement. Journal of Cognitive Education and Psychology, 9, 227251.Google Scholar
Elmasry, J., Loo, C., & Martin, D. M. (2015). A systematic review of transcranial electrical stimulation combined with cognitive training. Restorative Neurology and Neuroscience, 33(3), 263278.Google Scholar
Engle, R. W., Carullo, J. J., & Collins, K. W. (1991). Individual differences in working memory for comprehension and following directions. Journal of Educational Research, 84(5), 253262.Google Scholar
Follmer, D. J. (2018). Executive function and reading comprehension: A meta-analytic review. Educational Psychologist, 53(1), 4260.Google Scholar
Gathercole, S. E., & Alloway, T. P. (2008). Working memory and learning: A practical guide for teachers. Sage.Google Scholar
Gathercole, S. E., Brown, L., & Pickering, S. J. (2003). Working memory assessments at school entry as longitudinal predictors of National Curriculum attainment levels. Educational and Child Psychology, 20(3), 109122.Google Scholar
Gathercole, S. E., Dunning, D. L., Holmes, J., & Norris, D. (2019). Working memory training involves learning new skills. Journal of Memory and Language, 105, 1942.Google Scholar
Gathercole, S. E., Durling, E., Evans, M., Jeffcock, S., & Stone, S. (2008). Working memory abilities and children’s performance in laboratory analogues of classroom activities. Applied Cognitive Psychology, 22(8), 10191037.Google Scholar
Gathercole, S. E., & Holmes, J. (2014). Developmental impairments of working memory: Profiles and interventions. Perspectives on Language and Literacy, 40, 3639.Google Scholar
Gathercole, S. E., Lamont, E., & Alloway, T. P. (2006). Working memory in the classroom. In Pickering, S. (Ed.), Working memory and education. Academic.Google Scholar
Geary, D. C. (1993). Mathematical disabilities: Cognitive, neuropsychological, and genetic components. Psychological Bulletin, 114(2), 345362.Google Scholar
Geary, D. C. (2003). Learning disabilities in arithmetic: Problem-solving differences and cognitive deficits. In Swanson, H. L., Harris, K. R., & Graham, S. (Eds.), Handbook of learning disabilities (pp. 199212). The Guilford Press.Google Scholar
Henry, L. A., Messer, D. J., & Nash, G. (2014). Testing for near and far transfer effects with a short, face-to-face adaptive working memory training intervention in typical children. Infant and Child Development, 23(1), 84103.Google Scholar
Hill, A. T., Fitzgerald, P. B., & Hoy, K. E. (2016). Effects of anodal transcranial direct current stimulation on working memory: A systematic review and meta-analysis of findings from healthy and neuropsychiatric populations. Brain Stimulation, 9(2), 197208.Google Scholar
Hitch, G. J., & McAuley, E. (1991). Working memory in children with specific arithmetical learning difficulties. British Journal of Psychology, 82(3), 375386.Google Scholar
Holmes, J., Adams, J. W., & Hamilton, C. J. (2008). The relationship between visuospatial sketchpad capacity and children’s mathematical skills. European Journal of Cognitive Psychology, 20(2), 272289.Google Scholar
Holmes, J., Byrne, E. M., Gathercole, S. E., & Ewbank, M. P. (2016). Transcranial random noise stimulation does not enhance the effects of working memory training. Journal of Cognitive Neuroscience, 28(10), 113.Google Scholar
Holmes, J., Gathercole, S. E., & Dunning, D. L. (2009). Adaptive training leads to sustained enhancement of poor working memory in children. Developmental Science, 12(4), 17.Google Scholar
Holmes, J., Guy, J., Kievit, R. A., Bryant, A., Mareva, S., Gathercole, S. E., & CALM Team. (2020). Cognitive dimensions of learning in children with problems in attention, learning, and memory. Journal of Educational Psychology. Advance online publication.Google Scholar
Holmes, J., Woolgar, F., Hampshire, A., & Gathercole, S. E. (2019). Are working memory training effects paradigm-specific? Frontiers in Psychology, 10(May), 1103.Google Scholar
Jaeggi, S. M., Buschkuehl, M., Jonides, J., & Perrig, W. J. (2008). Improving fluid intelligence with training on working memory. Proceedings of the National Academy of Sciences of the United States of America, 105(19), 68296833.Google Scholar
Jaeggi, S. M., Studer-Luethi, B., Buschkuehl, M., Su, Y.-F., Jonides, J., & Perrig, W. J. (2010). The relationship between n-back performance and matrix reasoning: Implications for training and transfer. Intelligence, 38(6), 625635.Google Scholar
Jaroslawska, A. J., Gathercole, S. E., Allen, R. J., & Holmes, J. (2016). Following instructions from working memory: Why does action at encoding and recall help? Memory & Cognition, 44(8), 11831191.Google Scholar
Jaroslawska, A. J., Gathercole, S. E., & Holmes, J. (2018). Following instructions in a dual-task paradigm: Evidence for a temporary motor store in working memory. Quarterly Journal of Experimental Psychology, 71(11), 24392449.Google Scholar
Jaroslawska, A. J., Gathercole, S. E., Logie, M. R., & Holmes, J. (2016). Following instructions in a virtual school: Does working memory play a role? Memory & Cognition, 44(4), 580589.Google Scholar
Jeffries, S., & Everatt, J. (2004). Working memory: Its role in dyslexia and other specific learning difficulties. Dyslexia, 10(3), 196214. https://doi.org/10.1002/dys.278Google Scholar
Kaplan, C. H., & White, M. A. (1980). Children’s direction-following behavior in grades K-S. The Journal of Educational Research, 74(1), 4348.Google Scholar
Karbach, J., & Verhaeghen, P. (2014). Making working memory work: A meta-analysis of executive-control and working memory training in older adults. Psychological Science, 25(11), 20272037.Google Scholar
Kievit, R. A., Hofman, A. D., & Nation, K. (2019). Mutualistic coupling between vocabulary and reasoning in young children: A replication and extension of the study by Kievit et al. (2017). Psychological Science, 30(8), 12451252.Google Scholar
Klingberg, T., Fernell, E., Olesen, P. J., Johnson, M., Gustafsson, P., Dahlström, K., Gillberg, C. G., Forssberg, H., & Westerberg, H. (2005). Computerized training of working memory in children with ADHD: A randomized, controlled trial. Journal of the American Academy of Child and Adolescent Psychiatry, 44(2), 177186.Google Scholar
Koriat, A., Ben-Zur, H., & Nussbaum, A. (1990). Encoding information for future action: Memory for to-be-performed tasks versus memory for to-be-recalled tasks. Memory & Cognition, 18(6), 568578.Google Scholar
Kudo, M. F., Lussier, C. M., & Swanson, H. L. (2015). Reading disabilities in children: A selective meta-analysis of the cognitive literature. Research in Developmental Disabilities, 40, 5162.Google Scholar
Kuo, M.-F., & Nitsche, M. A. (2012). Effects of transcranial electrical stimulation on cognition. Clinical EEG and Neuroscience, 43(3), 192199.Google Scholar
Küper, K., & Karbach, J. (2016). Increased training complexity reduces the effectiveness of brief working memory training: Evidence from short-term single and dual n-back training interventions. Journal of Cognitive Psychology, 28(2), 199208.Google Scholar
Landerl, K., & Kölle, C. (2009). Typical and atypical development of basic numerical skills in elementary school. Journal of Experimental Child Psychology, 103(4), 546565.Google Scholar
Li, S.-C., Schmiedek, F., Huxhold, O., Röcke, C., Smith, J., & Lindenberger, U. (2008). Working memory plasticity in old age: Practice gain, transfer, and maintenance. Psychology and Aging, 23(4), 731742.Google Scholar
Li, Y., & Geary, D. C. (2013). Developmental gains in visuospatial memory predict gains in mathematics achievement. PLoS ONE, 8(7), e70160–e70160.Google Scholar
Looi, C. Y., Lim, J., Sella, F., Lolliot, S., Duta, M., Avramenko, A. A., & Cohen Kadosh, R. (2017). Transcranial random noise stimulation and cognitive training to improve learning and cognition of the atypically developing brain: A pilot study. Scientific Reports, 7(1), 4633.Google Scholar
Loosli, S. V., Buschkuehl, M., Perrig, W. J., & Jaeggi, S. M. (2012). Working memory training improves reading processes in typically developing children. Child Neuropsychology, 18(1), 6278.Google Scholar
Mancuso, L. E., Ilieva, I. P., Hamilton, R. H., & Farah, M. J. (2016). Does transcranial direct current stimulation improve healthy working memory? A meta-analytic review. Journal of Cognitive Neuroscience, 28(8), 10631089.Google Scholar
Mareva, S., The CALM Team, & Holmes, J. (2021). Cognitive and academic skills in two developmental cohorts of different ability level: A mutualistic network perspective, Journal of Applied Research in Memory and Cognition.Google Scholar
Martin, D. M., Liu, R., Alonzo, A., Green, M., Player, M. J., Sachdev, P., & Loo, C. K. (2013). Can transcranial direct current stimulation enhance outcomes from cognitive training? A randomized controlled trial in healthy participants. The International Journal of Neuropsychopharmacology, 16(9), 19271936.Google Scholar
McLean, J. F., & Hitch, G. J. (1999). Working memory impairments in children with specific arithmetic learning difficulties. Journal of Experimental Child Psychology, 74(3), 240260.Google Scholar
Melby-Lervåg, M., & Hulme, C. (2013). Is working memory training effective? A meta-analytic review. Developmental Psychology, 49(2), 270291.Google Scholar
Melby-Lervåg, M., Lervåg, A., Lyster, S.-A. H., Klem, M., Hagtvet, B., & Hulme, C. (2012). Nonword-repetition ability does not appear to be a causal influence on children’s vocabulary development. Psychological Science, 23(10), 10921098.Google Scholar
Melby-Lervåg, M., Lyster, S. A. H., & Hulme, C. (2012). Phonological skills and their role in learning to read: A meta-analytic review. Psychological Bulletin, 138(2), 322352.Google Scholar
Melby-Lervåg, M., Redick, T. S., & Hulme, C. (2016). Working memory training does not improve performance on measures of intelligence or other measures of “far transfer”: Evidence from a meta-analytic review. Perspectives on Psychological Science, 11(4), 512534.Google Scholar
Meyer, M. L., Salimpoor, V. N., Wu, S. S., Geary, D. C., & Menon, V. (2010). Differential contribution of specific working memory components to mathematics achievement in 2nd and 3rd graders. Learning and Individual Differences, 20(2), 101109.Google Scholar
Minear, M., Brasher, F., Guerrero, C. B., Brasher, M., Moore, A., & Sukeena, J. (2016). A simultaneous examination of two forms of working memory training: Evidence for near transfer only. Memory & Cognition, 44, 10101037.Google Scholar
Morrison, A. B., & Chein, J. M. (2011). Does working memory training work? The promise and challenges of enhancing cognition by training working memory. Psychonomic Bulletin & Review, 18, 4660.Google Scholar
Nation, K. (1999). Reading skills in hyperlexia: A developmental perspective. Psychological Bulletin, 125(3), 338355.Google Scholar
Nilsson, J., Lebedev, A. V., Rydström, A., & Lövdén, M. (2017). Direct-current stimulation does little to improve the outcome of working memory training in older adults. Psychological Science, 28(7), 907920.Google Scholar
Nitsche, M. A., & Paulus, W. (2000). Excitability changes induced in the human motor cortex by weak transcranial direct current stimulation. The Journal of Physiology, 527(3), 633639.Google Scholar
Osterberg, L., & Blaschke, T. (2005). Adherence to medication. New England Journal of Medicine, 353, 487497.Google Scholar
Paas, F. G. W. C., Renkl, A., & Sweller, J. (2003). Cognitive load theory and instructional design: Recent developments. Educational Psychologist, 38(1), 14.Google Scholar
Paas, F. G. W. C., Renkl, A., & Sweller, J. (2004). Cognitive Load Theory: Instructional implications of the interaction between information structures and cognitive architecture, Instructional Science, 32, 18.Google Scholar
Paas, F., & Sweller, J. (2012). An evolutionary upgrade of cognitive load theory: Using the human motor system and collaboration to support the learning of complex cognitive tasks. Educational Psychology Review, 24(1), 2745.Google Scholar
Passolunghi, M. C., & Costa, H. M. (2016). Working memory and early numeracy training in preschool children. Child Neuropsychology, 22(1), 8198.Google Scholar
Passolunghi, M. C., Mammarella, I. C., & Altoè, G. (2008). Cognitive abilities as precursors of the early acquisition of mathematical skills during first through second grades. Developmental Neuropsychology, 33(3), 229250.Google Scholar
Passolunghi, M. C., & Siegel, L. S. (2001). Short-term memory, working memory, and inhibitory control in children with difficulties in arithmetic problem solving. Journal of Experimental Child Psychology, 80(1), 4457.Google Scholar
Pause, B. M., Zlomuzica, A., Kinugawa, K., Mariani, J., Pietrowsky, R., & Dere, E. (2013). Perspectives on episodic-like and episodic memory. Frontiers in Behavioral Neuroscience, 7, 112.Google Scholar
Peijnenborgh, J. C. A., Hurks, P. M., Aldenkamp, A. P., Vles, J. S. H., & Hendriksen, J. G. M. (2016). Efficacy of working memory training in children and adolescents with learning disabilities: A review study and meta-analysis. Neuropsychological Rehabilitation, 26(5–6), 645672.Google Scholar
Peng, P., & Fuchs, D. (2015). A randomized control trial of working memory training with and without strategy instruction: Effects on young children’s working memory and comprehension. Journal of Learning Disabilities, 50(1), 6280.Google Scholar
Peng, P., & Fuchs, D. (2016). A meta-analysis of working memory deficits in children with learning difficulties: Is there a difference between verbal domain and numerical domain? Journal of Learning Disabilities, 49(1), 320.Google Scholar
Peng, P., & Kievit, R. A. (2020). The development of academic achievement and cognitive abilities: A bidirectional perspective. Child Development Perspectives, 14(1), 1520.Google Scholar
Peng, P., Namkung, J., Barnes, M., & Sun, C. (2016). A meta-analysis of mathematics and working memory: Moderating effects of working memory domain, type of mathematics skill, and sample characteristics. Journal of Educational Psychology, 108(4), 455473.Google Scholar
Peng, P., Wang, C., & Namkung, J. (2018). Understanding the cognition related to mathematics difficulties: A meta-analysis on the cognitive deficit profiles and the bottleneck theory. Review of Educational Research, 88(3), 434476.Google Scholar
Pimperton, H., & Nation, K. (2010). Suppressing irrelevant information from working memory: Evidence for domain-specific deficits in poor comprehenders. Journal of Memory and Language, 62(4), 380391.Google Scholar
Preßler, A.-L., Könen, T., Hasselhorn, M., & Krajewski, K. (2014). Cognitive preconditions of early reading and spelling: A latent-variable approach with longitudinal data. Reading and Writing, 27(2), 383406.Google Scholar
Rapport, M. D., Orban, S. A., Kofler, M. J., & Friedman, L. M. (2013). Do programs designed to train working memory, other executive functions, and attention benefit children with ADHD? A meta-analytic review of cognitive, academic, and behavioral outcomes. Clinical Psychology Review, 33(8), 12371252.Google Scholar
Redick, T. S., Shipstead, Z., Harrison, T. L., Hicks, K. L., Fried, D. E., Hambrick, D. Z., Kane, M. J., & Engle, R. W. (2013). No evidence of intelligence improvement after working memory training: A randomized, placebo-controlled study. Journal of Experimental Psychology: General, 142(2), 359379.Google Scholar
Redick, T. S., Shipstead, Z., Wiemers, E. A., Melby-Lervåg, M., & Hulme, C. (2015). What’s working in working memory training? An Educational Perspective, 27(4), 617633.Google Scholar
Richmond, L. L., Wolk, D., Chein, J. M., & Olson, I. R. (2014). Transcranial direct current stimulation enhances verbal working memory training performance over time and near-transfer outcomes. Journal of Cognitive Neuroscience, 26(11), 24432454.Google Scholar
Rotzer, S., Loenneker, T., Kucian, K., Martin, E., Klaver, P., & von Aster, M. (2009). Dysfunctional neural network of spatial working memory contributes to developmental dyscalculia. Neuropsychologia, 47(13), 28592865.Google Scholar
Rowe, A., Titterington, J., Holmes, J., Henry, L., & Taggart, L. (2019). Interventions targeting working memory in 4–11 year olds within their everyday contexts: A systematic review. Developmental Review, 52, 123.Google Scholar
Ruf, S. P., Fallgatter, A. J., & Plewnia, C. (2017). Augmentation of working memory training by transcranial direct current stimulation (tDCS). Scientific Reports, 7(1), 876.Google Scholar
Sala, G., Deniz Aksayli, N., Semir Tatlidil, K., Tatsumi, T., Gondo, Y., & Gobet, F. (2019). Near and far transfer in cognitive training: A second-order meta-analysis. Collabra: Psychology, 5(1), 18.Google Scholar
Sala, G., & Gobet, F. (2017). Does far transfer exist? Negative evidence from chess, music, and working memory training. Current Directions in Psychological Science, 26(6), 515520.Google Scholar
Schwaighofer, M., Fischer, F., & Bühner, M. (2015). Does working memory training transfer? A meta-analysis including training conditions as moderators. Educational Psychologist, 50(2), 138166.Google Scholar
Shapiro, L. (2007). The embodied cognition research programme. Philosophy Compass, 2(2), 338346.Google Scholar
Shipstead, Z., Hicks, K. L., & Engle, R. W. (2012). Cogmed working memory training: Does the evidence support the claims? Journal of Applied Research in Memory and Cognition, 1(3), 185193.Google Scholar
Shipstead, Z., Redick, T. S., & Engle, R. W. (2012). Is working memory training effective? Psychological Bulletin, 138(4), 628654.CrossRefGoogle ScholarPubMed
Simons, D. J., Boot, W. R., Charness, N., Gathercole, S. E., Chabris, C. F., Hambrick, D. Z., & Stine-Morrow, E. A. L. (2016). Do “brain-training” programs work? Psychological Science in the Public Interest, 17(3), 103186.Google Scholar
Smyth, M. M., & Pendleton, L. R. (1989). Working memory for movements. The Quarterly Journal of Experimental Psychology, 41(2), 235250.Google Scholar
Smyth, M. M., & Pendleton, L. R. (1990). Space and movement in working memory. The Quarterly Journal of Experimental Psychology, 42(2), 291304.CrossRefGoogle ScholarPubMed
Sonuga-Barke, E. J. S., Brandeis, D., Cortese, S., Daley, D., Ferrin, M., Holtmann, M., Stevenson, J., Danckaerts, M., Van Der Oord, S., Döpfner, M., Dittmann, R. W., Simonoff, E., Zuddas, A., Banaschewski, T., Buitelaar, J., Coghill, D., Hollis, C., Konofal, E., Lecendreux, M.,…Zuddas, A. (2013). Nonpharmacological interventions for ADHD: Systematic review and meta-analyses of randomized controlled trials of dietary and psychological treatments. American Journal of Psychiatry, 170(3), 275289.Google Scholar
Soveri, A., Antfolk, J., Karlsson, L., Salo, B., & Laine, M. (2017). Working memory training revisited: A multi-level meta-analysis of n-back training studies. Psychonomic Bulletin & Review, 24(4), 10771096.Google Scholar
Spencer-Smith, M., & Klingberg, T. (2015). Benefits of a working memory training program for inattention in daily life: A systematic review and meta-analysis. PLoS ONE, 10(3), 118.CrossRefGoogle ScholarPubMed
Sprenger, A. M., Atkins, S. M., Bolger, D. J., Harbison, J. I., Novick, J. M., Chrabaszcz, J. S., Weems, S. A., Smith, V., Bobb, S., Bunting, M. F., & Dougherty, M. R. (2013). Training working memory: Limits of transfer. Intelligence, 41 (5), 638663.Google Scholar
St. Clair-Thompson, H. L., & Holmes, J. (2008) Improving short term and working memory: Methods of memory training. In Johansen, N.B. (Ed.), New research in short term memory (pp. 125–54). Novascience.Google Scholar
Swanson, H. L., & Ashbaker, M. H. (2000). Working memory, short-term memory, speech rate, word recognition and reading comprehension in learning disabled readers: Does the executive system have a role? Intelligence, 28(1), 130.Google Scholar
Swanson, H. L., & Beebe-Frankenberger, M. (2004). The relationship between working memory and mathematical problem solving in children at risk and not at risk for serious math difficulties. Journal of Educational Psychology, 96(3), 471491.Google Scholar
Swanson, H. L., & Jerman, O. (2006). Math disabilities: A selective meta-analysis of the literature. Review of Educational Research, 76(2), 249274.Google Scholar
Swanson, H. L., Zheng, X., & Jerman, O. (2009). Working memory, short-term memory, and reading disabilities: A selective meta-analysis of the literature. Journal of Learning Disabilities, 42(3), 260287.Google Scholar
Sweller, J. (2011). Cognitive load theory. In Psychology of learning and motivation (Vol. 55, pp. 3776). Academic Press.Google Scholar
Sweller, J. (2016). Working memory, long-term memory, and instructional design. Journal of Applied Research in Memory and Cognition, 5(4), 360367.Google Scholar
Szucs, D., Devine, A., Soltesz, F., Nobes, A., & Gabriel, F. (2013). Developmental dyscalculia is related to visuo-spatial memory and inhibition impairment. Cortex, 49(10), 26742688.Google Scholar
Thompson, T. W., Waskom, M. L., Garel, K. L. a, Cardenas-Iniguez, C., Reynolds, G. O., Winter, R., Chang, P., Pollard, K., Lala, N., Alvarez, G. a., & Gabrieli, J. D. E. (2013). Failure of working memory training to enhance cognition or intelligence. PLoS ONE, 8(5).Google Scholar
Tremblay, S., Lepage, J.-F. F., Latulipe-Loiselle, A., Fregni, F., Pascual-Leone, A., & Théoret, H. (2014). The uncertain outcome of prefrontal tDCS. Brain Stimulation, 7(6), 773783.Google Scholar
Tulving, E. (2002). Episodic memory: From mind to brain. Annual Review of Psychology, 53, 125.Google Scholar
Van Der Maas, H. L. J., Dolan, C. V., Grasman, R. P. P. P., Wicherts, J. M., Huizenga, H. M., & Raijmakers, M. E. J. (2006). A dynamical model of general intelligence: The positive manifold of intelligence by mutualism. Psychological Review, 113(4), 842861.Google Scholar
Van de Weijer-Bergsma, E., Kroesbergen, E. H., & Van Luit, J. E. (2015). Verbal and visual-spatial working memory and mathematical ability in different domains throughout primary school. Memory & Cognition, 43(3), 367378.CrossRefGoogle ScholarPubMed
von Bastian, C. C., & Oberauer, K. (2013). Distinct transfer effects of training different facets of working memory capacity. Journal of Memory and Language, 69(1), 3658.Google Scholar
Wang, S., & Gathercole, S. E. (2013). Working memory deficits in children with reading difficulties: Memory span and dual task coordination. Journal of Experimental Child Psychology, 115(1), 188197.Google Scholar
Waterman, A. H., Atkinson, A. L., Aslam, S. S., Holmes, J., Jaroslawska, A. J., & Allen, R. J. (2017). Do actions speak louder than words? Examining children’s ability to follow instructions. Memory & Cognition, 45(6), 877890.Google Scholar
Wickens, C. M., Toplak, M. E., & Wiesenthal, D. L. (2008). Cognitive failures as predictors of driving errors, lapses, and violations. Accident Analysis & Prevention, 40(3), 12231233.Google Scholar
Willcutt, E. G., Petrill, S. A., Wu, S., Boada, R., DeFries, J. C., Olson, R. K., & Pennington, B. F. (2013). Comorbidity between reading disability and math disability: Concurrent psychopathology, functional impairment, and neuropsychological functioning. Journal of Learning Disabilities, 46(6), 500516.Google Scholar
Witt, M. U. (2011). School based working memory training: Preliminary finding of improvement in children’s mathematical performance. Advances in Cognitive Psychology, 7, 715.Google Scholar
Wojcik, D., Allen, R., Brown, C., & Souchay, C. (2011). Memory for actions in autism spectrum disorder. Memory, 19(6), 549558.Google Scholar
Wolpert, D. M., & Ghahramani, Z. (2000). Computational principles of movement neuroscience. Nature Neuroscience, 3(11), 12121217.Google Scholar
Yang, T., Allen, R. J., & Gathercole, S. E. (2016). Examining the role of working memory resources in following spoken instructions. Journal of Cognitive Psychology, 28(2), 186198.Google Scholar
Yang, T., Allen, R. J., Holmes, J., & Chan, R. C. (2017). Impaired memory for instructions in children with attention-deficit hyperactivity disorder is improved by action at presentation and recall. Frontiers in Psychology, 8, 39.Google Scholar
Yang, T., Gathercole, S. E., & Allen, R. J. (2014). Benefit of enactment over oral repetition of verbal instruction does not require additional working memory during encoding. Psychonomic Bulletin & Review, 21(1), 186192.Google Scholar
Yeniad, N., Malda, M., Mesman, J., van IJzendoorn, M. H., & Pieper, S. (2013). Shifting ability predicts math and reading performance in children: A meta-analytical study. Learning and Individual Differences, 23, 19.Google Scholar

References

Bandura, A. (1986). Social foundations of thought and action: A social cognitive theory. Prentice Hall.Google Scholar
Bartlett, F. C. (1932). Remembering: A study in experimental and social psychology. Macmillan.Google Scholar
Bruner, J. (1978). The role of dialogue in language acquisition. In Sinclair, A., Jarvella, R., & Levelt, W. (Eds.), The child’s conception of language (pp. 241256). Springer-Verlag.Google Scholar
Bruton, A. (2013). CLIL: Some of the reasons why…and why not. System, 41, 587597.Google Scholar
Cenoz, J., Genesee, F., & Gorter, D. (2013). Critical analysis of CLIL: Taking stock and looking forward. Applied Linguistics, 35, 243262. https://doi.org/10.1093/applin/amt011Google Scholar
Chase, W. G., & Simon, H. A. (1973). Perception in chess. Cognitive Psychology, 4, 5581.Google Scholar
Chen, O., Kalyuga, S., & Sweller, J. (2017). The expertise reversal effect is a variant of the more general element interactivity effect. Educational Psychology Review, 29, 393405.Google Scholar
Cowan, N. (2001). The magical number 4 in short-term memory: A reconsideration of mental storage capacity. Behavioral and Brain Sciences, 24, 87114.Google Scholar
Dallinger, S., Jonkmann, K., Hollm, J., & Fiege, C. (2016). The effect of content and language integrated learning on students’ English and history competences: Killing two birds with one stone? Learning and Instruction, 41, 2331.Google Scholar
Dalton-Puffer, C. (2007). Discourse in content and language integrated (CLIL) classrooms. John Benjamins.Google Scholar
Dalton-Puffer, C., Llinares, A., Lorenzo, F., & Nikula, T. (2014). “You can stand under my umbrella”: Immersion, CLIL and bilingual education. A response to Cenoz, Genesee, & Gorter (2013). Applied Linguistics, 35, 213218.Google Scholar
Dearden, J. (2015). English as a medium of instruction: A growing global phenomenon. British Council.Google Scholar
De Groot, A. (1946/1965). Thought and choice in chess. Mouton.Google Scholar
De Groot, A., & Gobet, F. (1996). Perception and memory in chess: Heuristics of the professional eye. Van Gorcum.Google Scholar
Diao, Y., Chandler, P., & Sweller, J. (2007). The effect of written text on learning to comprehend spoken English as a foreign language. American Journal of Psychology, 120, 237261.CrossRefGoogle Scholar
Diao, Y., & Sweller, J. (2007). Redundancy in foreign language reading instruction: Concurrent written and spoken presentations. Learning and Instruction, 17, 7888.Google Scholar
Egan, D. E., & Schwartz, B. J. (1979). Chunking in recall of symbolic drawings. Memory & Cognition, 7, 149158.Google Scholar
Ericsson, K. A., & Charness, N. (1994). Expert performance; Its structure and acquisition. American Psychologist, 49, 725747.Google Scholar
Ericsson, K. A., & Kintsch, W. (1995). Long-term working memory. Psychological Review, 102, 211245.Google Scholar
Ericsson, K. A., Krampe, R., & Tesch-Romer, C. (1993). The role of deliberate practice in the acquisition of expert performance. Psychological Review, 100, 363406.Google Scholar
Fischer, F., Chinn, C. A., Engelmann, K., & Osborne, J. (Eds.). (2018). Scientific reasoning and argumentation: The roles of domain-specific and domain-general knowledge. Routledge.Google Scholar
Gablasova, D. (2014a). Issues in the assessment of bilingually educated students: Expressing subject knowledge through L1 and L2. The Language Learning Journal, 42(2), 151164.CrossRefGoogle Scholar
Gablasova, D. (2014b). Learning and retaining specialized vocabulary from textbook reading: Comparison of learning outcomes through L1 and L2. The Modern Language Journal, 98(4), 976991.Google Scholar
Gass, S., & Mackey, A. (2007). Input, interaction, and output in second language acquisition. In VanPatten, B., & Williams, J. (Eds.), Theories in second language acquisition (pp. 175199). Erlbaum.Google Scholar
Geary, D. (2008). An evolutionarily informed education science. Educational Psychologist, 43, 179195.Google Scholar
Geary, D. (2012). Evolutionary educational psychology. In Harris, K., Graham, S., & Urdan, T. (Eds.), APA educational psychology handbook (Vol. 1, pp. 597621). American Psychological Association.Google Scholar
Geary, D., & Berch, D. (2016). Evolution and children’s cognitive and academic development. In Geary, D. & Berch, D. (Eds.), Evolutionary perspectives on child development and education (pp. 217249). Springer.Google Scholar
Hüttner, J., & Smit, U. (2014). CLIL (Content and Language Integrated Learning): The bigger picture. A response to: A. Bruton (2013). CLIL: Some of the reasons why…and why not. System, 41, 587–597. System, 44, 160167.Google Scholar
Jeffries, R., Turner, A., Polson, P., & Atwood, M. (1981). Processes involved in designing software. In Anderson, J. R. (Ed.), Cognitive skills and their acquisition (pp. 255283). Erlbaum.Google Scholar
Jiang, D., Kalyuga, S., & Sweller, J. (2018). The curious case of improving foreign language listening skills by reading rather than listening: An expertise reversal effect. Educational Psychology Review, 30, 11391165.Google Scholar
Kalyuga, S., Chandler, P., & Sweller, J. (2004). When redundant on-screen text in multimedia technical instruction can interfere with learning. Human Factors, 46, 567581.Google Scholar
Kirschner, P., Sweller, J., & Clark, R. (2006). Why minimal guidance during instruction does not work: An analysis of the failure of constructivist, discovery, problem-based, experiential and inquiry-based teaching. Educational Psychologist, 41, 7586.Google Scholar
Krashen, S. D. (1985). The input hypothesis: Issues and implications. Longman.Google Scholar
Krashen, S. D., & Terrell, T. D. (2000). The natural approach: Language acquisition in the classroom (2nd ed.). Prentice Hall.Google Scholar
Kyun, S., Kalyuga, S., & Sweller, J. (2013). The effect of worked examples when learning to write essays in English literature. Journal of Experimental Education, 81, 385408.Google Scholar
Long, M. (1991). Focus on form: A design feature in language teaching methodology. In de Bot, K., Ginsberg, R., & Kramsch, C. (Eds.), Foreign language research in cross-cultural perspective (p. 3952). John Benjamins.Google Scholar
Lu, J., Kalyuga, S., & Sweller, J. (2020). Altering element interactivity and variability in example-practice sequences to enhance learning to write Chinese characters. Applied Cognitive Psychology, 34, 837843.Google Scholar
Macaro, E., Curle, S., Pun, J., An, J., & Dearden, J. (2018). A systematic review of English medium instruction in higher education. Language Teaching, 51, 3676.Google Scholar
Miller, G. A. (1956). The magical number seven, plus or minus two: Some limits on our capacity for processing information. Psychological Review, 63, 8197.Google Scholar
Moussa-Inaty, J., Ayres, P., & Sweller, J. (2012). Improving listening skills in English as a foreign language by reading rather than listening: A cognitive load perspective. Applied Cognitive Psychology, 26, 391402.Google Scholar
Nikula, T., Dalton-Puffer, C., & Llinares, A. (2013). CLIL classroom discourse: Research from Europe, Journal of Immersion and Content-Based Language Education, 1, 70100.Google Scholar
Paas, F., & Sweller, J. (2012). An evolutionary upgrade of cognitive load theory: Using the human motor system and collaboration to support the learning of complex cognitive tasks. Educational Psychology Review, 24, 2745.CrossRefGoogle Scholar
Peterson, L., & Peterson, M. J. (1959). Short-term retention of individual verbal items. Journal of Experimental Psychology, 58, 193198.Google Scholar
Piaget, J. (1928). Judgement and reasoning in the child. Harcourt.Google Scholar
Robinson, P. (2003). Attention and memory during SLA. In Doughty, C., & Long, M. (Eds.), Handbook of second language acquisition (pp. 631662). Blackwell.Google Scholar
Roussel, S., Joulia, D., Tricot, A., & Sweller, J. (2017). Learning subject content through a foreign language should not ignore human cognitive architecture: A cognitive load theory approach. Learning and Instruction, 52, 6979.Google Scholar
Roussel, S., Tricot, A., & Sweller, J. (in press). The advantages of listening to academic content in a second language may be outweighed by disadvantages: A cognitive load theory approach. British Journal of Educational Psychology.Google Scholar
Roussel, S. (2019). Comprendre un contenu disciplinaire en allemand L2: quels ajustements pédagogiques? Études en didactique des langues (EDL), 32, 89100Google Scholar
Rumlich, D. (2016). Evaluating bilingual education In Germany. Clil students’ general English proficiency, Efl self-concept and interest. Peter Lang.Google Scholar
Schmidt, R. (2001). Attention. In Robinson, P. (Ed.), Cognition and second language instruction (p. 332). Cambridge University Press.Google Scholar
Spilich, G., Vesonder, G., Chiesi, H., & Voss, J. (1979). Text processing of domain-related information for individuals with high and low domain knowledge. Journal of Verbal Learning and Verbal Behavior, 18, 275290.Google Scholar
Sweller, J. (2010). Element interactivity and intrinsic, extraneous and germane cognitive load. Educational Psychology Review, 22, 123138.Google Scholar
Sweller, J. (2015). In academe, what is learned and how is it learned? Current Directions in Psychological Science, 24, 190194.Google Scholar
Sweller, J. (2016). Working memory, long-term memory and instructional design. Journal of Applied Research in Memory and Cognition, 5, 360367.Google Scholar
Sweller, J., Ayres, P., & Kalyuga, S. (2011). Cognitive load theory. Springer.Google Scholar
Sweller, J., & Chandler, P. (1994). Why some material is difficult to learn. Cognition and Instruction, 12, 185233.Google Scholar
Sweller, J., & Cooper, G. (1985). The use of worked examples as a substitute for problem solving in learning algebra. Cognition & Instruction, 2, 5989.Google Scholar
Sweller, J., Kirschner, P., & Clark, R. E. (2007). Why minimally guided teaching techniques do not work: A reply to commentaries. Educational Psychologist, 42, 115121.Google Scholar
Sweller, J., & Sweller, S. (2006). Natural information processing systems. Evolutionary Psychology, 4, 434458.Google Scholar
Sweller, J., van Merriënboer, J., & Paas, F. (1998). Cognitive architecture and instructional design. Educational Psychology Review, 10, 251296.CrossRefGoogle Scholar
Sweller, J., van Merriënboer, J., & Paas, F. (2019). Cognitive architecture and instructional design: 20 years later. Educational Psychology Review, 31, 261292.Google Scholar
Thornton, A., & Raihani, N. (2008). The evolution of teaching. Animal Behaviour, 75, 18231836.Google Scholar
Tindall-Ford, S., Agostinho, S., & Sweller, J. (Eds.). (2020). Advances in cognitive load theory: Rethinking teaching. Routledge.Google Scholar
Tomasello, M. (2009). Why we cooperate. MIT press.Google Scholar
Tricot, A., & Sweller, J. (2014). Domain-specific knowledge and why teaching generic skills does not work. Educational Psychology Review, 26, 265283.Google Scholar
Vygotsky, L. S. (1978), Mind in society, The development of higher psychological processes. Harvard University Press.Google Scholar
Yeung, A. S., Jin, P., & Sweller, J. (1998). Cognitive load and learner expertise: Split-attention and redundancy effects in reading with explanatory notes. Contemporary Educational Psychology, 23, 121.Google Scholar

References

Ackermann, S., Halfon, O., Fornari, E., Urben, S., & Bader, M. (2018). Cognitive Working Memory Training (CWMT) in adolescents suffering from Attention-Deficit/Hyperactivity Disorder (ADHD): A controlled trial taking into account concomitant medication effects. Psychiatry Research, 269, 7985.Google Scholar
Aksayli, N. D., Sala, G., & Gobet, F. (2019). The cognitive and academic benefits of Cogmed: A meta-analysis. Educational Research Review, 27, 229243.Google Scholar
Antshel, K. M., Zhang-James, Y., & Faraone, S. V. (2013). The comorbidity of ADHD and Autism Spectrum Disorder. Expert Review of Neurotherapeutics, 13(10), 11171128.Google Scholar
Au, J., Gibson, B. C., Bunarjo, K., Buschkuehl, M., & Jaeggi, S. M. (2020). Quantifying the difference between active and passive control groups in cognitive interventions using two meta-analytical approaches. Journal of Cognitive Enhancement, 4(2), 192210.Google Scholar
Au, J., Sheehan, E., Tsai, N., Duncan, G. J., Buschkuehl, M., & Jaeggi, S. M. (2014). Improving fluid intelligence with training on working memory: A meta-analysis. Psychonomic Bulletin & Review, 22(2), 366377.Google Scholar
Bailey, D., Duncan, G. J., Odgers, C. L., & Yu, W. (2017). Persistence and fadeout in the impacts of child and adolescent interventions. Journal of Research on Educational Effectiveness, 10(1), 739.Google Scholar
Barnett, S. M., & Ceci, S. J. (2002). When and where do we apply what we learn? A taxonomy for far transfer. Psychological Bulletin, 128(4), 612637.Google Scholar
Barriga, A. Q., Doran, J. W., Newell, S. B., Morrison, E. M., Barbetti, V., & Robbins, B. D. (2002). Relationships between problem behaviors and academic achievement in adolescents: The unique role of attention problems. Journal of Emotional and Behavioral Disorders, 10(4), 233240.Google Scholar
Bavelier, D., Bediou, B., & Green, C. S. (2018). Expertise and generalization: Lessons from action video games. Current Opinion in Behavioral Sciences, 20, 169173.Google Scholar
Biederman, J., Monuteaux, M. C., Spencer, T., Wilens, T. E., Macpherson, H. A., & Faraone, S. V. (2008). Stimulant therapy and risk for subsequent substance use disorders in male adults with ADHD: A naturalistic controlled 10-year follow-up study. The American Journal of Psychiatry, 165(5), 597603.Google Scholar
Cantwell, D. P., & Baker, L. (1991). Association between Attention Deficit-Hyperactivity Disorder and Learning Disorders. Journal of Learning Disabilities, 24(2), 8895.CrossRefGoogle ScholarPubMed
Cao, Y., Huang, T., Huang, J., Xie, X., & Wang, Y. (2020). Effects and moderators of computer-based training on children’s executive functions: A systematic review and meta-analysis. Frontiers in Psychology, 11.Google Scholar
Cepeda, N. J., Pashler, H., Vul, E., Wixted, J. T., & Rohrer, D. (2006). Distributed practice in verbal recall tasks: A review and quantitative synthesis. Psychological Bulletin, 132(3), 354380.Google Scholar
Chacko, A., Bedard, A.-C. V., Marks, D., Gopalan, G., Feirsen, N., Uderman, J., Chimiklis, A., Heber, E., Cornwell, M., Anderson, L., Zwilling, A., & Ramon, M. (2018). Sequenced neurocognitive and behavioral parent training for the treatment of ADHD in school-age children. Child Neuropsychology, 24(4), 427450.Google Scholar
Chacko, A., Feirsen, N., Bedard, A.-C., Marks, D., Uderman, J. Z., & Chimiklis, A. (2013). Cogmed working memory training for youth with ADHD: A closer examination of efficacy utilizing evidence-based criteria. Journal of Clinical Child & Adolescent Psychology, 42(6), 769783.Google Scholar
Cicerone, K. D., Langenbahn, D. M., Braden, C., Malec, J. F., Kalmar, K., Fraas, M., Felicetti, T., Laatsch, L., Harley, J. P., Bergquist, T., Azulay, J., Cantor, J., & Ashman, T. (2011). Evidence-based cognitive rehabilitation: Updated review of the literature from 2003 through 2008. Archives of Physical Medicine and Rehabilitation, 92(4), 519530.Google Scholar
Coghill, D. (2019). Debate: Are stimulant medications for Attention-Deficit/Hyperactivity Disorder effective in the long term? (For). Journal of the American Academy of Child and Adolescent Psychiatry, 58(10), 938939.Google Scholar
Commissioner, O. of the. (2020, June 17). FDA Permits Marketing of First Game-Based Digital Therapeutic to Improve Attention Function in Children with ADHD. FDA. www.fda.gov/news-events/press-announcements/fda-permits-marketing-first-game-based-digital-therapeutic-improve-attention-function-children-adhdGoogle Scholar
Conway, A. R. A., Kane, M. J., & Engle, R. W. (2003). Working memory capacity and its relation to general intelligence. Trends in Cognitive Sciences, 7(12), 547552.Google Scholar
Cornoldi, C., Carretti, B., Drusi, S., & Tencati, C. (2015). Improving problem solving in primary school students: The effect of a training programme focusing on metacognition and working memory. British Journal of Educational Psychology, 85(3), 424439.Google Scholar
Cortese, S., Ferrin, M., Brandeis, D., Buitelaar, J., Daley, D., Dittmann, R. W., Holtmann, M., Santosh, P., Stevenson, J., Stringaris, A., Zuddas, A., & Sonuga-Barke, E. J. S. (2015). Cognitive training for attention-deficit/hyperactivity disorder: Meta-analysis of clinical and neuropsychological outcomes from randomized controlled trials. Journal of the American Academy of Child & Adolescent Psychiatry, 54(3), 164174.Google Scholar
Cowan, N., Elliott, E. M., Scott Saults, J., Morey, C. C., Mattox, S., Hismjatullina, A., & Conway, A. R. A. (2005). On the capacity of attention: Its estimation and its role in working memory and cognitive aptitudes. Cognitive Psychology, 51(1), 42100.Google Scholar
Danielson, M. L., Bitsko, R. H., Ghandour, R. M., Holbrook, J. R., Kogan, M. D., & Blumberg, S. J. (2018). Prevalence of parent-reported ADHD diagnosis and associated treatment among U.S. children and adolescents, 2016. Journal of Clinical Child & Adolescent Psychology, 47(2), 199212.Google Scholar
Danielsson, H., Zottarel, V., Palmqvist, L., & Lanfranchi, S. (2015). The effectiveness of working memory training with individuals with intellectual disabilities: A meta-analytic review. Frontiers in Psychology, 6, 1230.Google Scholar
Davis, N. O., Bower, J., & Kollins, S. H. (2018). Proof-of-concept study of an at-home, engaging, digital intervention for pediatric ADHD. PLoS ONE, 13(1), e0189749.Google Scholar
de Vries, M., Prins, P. J. M., Schmand, B. A., & Geurts, H. M. (2015). Working memory and cognitive flexibility-training for children with an autism spectrum disorder: A randomized controlled trial. Journal of Child Psychology and Psychiatry, 56(5), 566576.Google Scholar
Deveau, J., Jaeggi, S. M., Zordan, V., Phung, C., & Seitz, A. R. (2015). How to build better memory training games. Frontiers in Systems Neuroscience, 8.Google Scholar
Diamond, A. (2013). Executive functions. Annual Review of Psychology, 64(1), 135168.Google Scholar
DuPaul, G. J., Gormley, M. J., & Laracy, S. D. (2013). Comorbidity of LD and ADHD: Implications of DSM-5 for assessment and treatment. Journal of Learning Disabilities, 46(1), 4351.Google Scholar
Engle, R. W., Kane, M. J., & Tuholski, S. W. (1999). Individual differences in working memory capacity and what they tell us about controlled attention, general fluid intelligence, and functions of the prefrontal cortex. In Miyake, A. & Shah, P. (Eds.), Models of working memory: Mechanisms of active maintenance and executive control. Cambridge University Press.Google Scholar
Fabiano, G. A., Pelham, W. E. Jr., Coles, E. K., Gnagy, E. M., Chronis-Tuscano, A., & O’Connor, B. C. (2009). A meta-analysis of behavioral treatments for attention-deficit/hyperactivity disorder. Clinical Psychology Review, 29(2), 129140.Google Scholar
Farcas, S., & Szamosközi, I. (2016). The effects of working memory trainings with game elements for children with ADHD. A meta-analytic review. Transylvanian Journal of Psychology, 1.Google Scholar
Forster, S., Robertson, D. J., Jennings, A., Asherson, P., & Lavie, N. (2014). Plugging the attention deficit: Perceptual load counters increased distraction in ADHD. Neuropsychology, 28(1), 91.Google Scholar
Fuchs, L., Fuchs, D., Seethaler, P. M., & Barnes, M. A. (2020). Addressing the role of working memory in mathematical word-problem solving when designing intervention for struggling learners. ZDM, 52(1), 8796.Google Scholar
Gathercole, S. E., Dunning, D. L., Holmes, J., & Norris, D. (2019). Working memory training involves learning new skills. Journal of Memory and Language, 105, 1942.Google Scholar
Gau, S. S.-F., Chen, S.-J., Chou, W.-J., Cheng, H., Tang, C.-S., Chang, H.-L., Tzang, R.-F., Wu, Y.-Y., Huang, Y.-F., Chou, M.-C., Liang, H.-Y., Hsu, Y.-C., Lu, H.-H., & Huang, Y.-S. (2008). National survey of adherence, efficacy, and side effects of methylphenidate in children with attention-deficit/hyperactivity disorder in Taiwan. The Journal of Clinical Psychiatry, 69(1), 131140.Google Scholar
Gibson, B. S., Gondoli, D. M., Johnson, A. C., Steeger, C. M., & Morrissey, R. A. (2012). The future promise of Cogmed working memory training. Journal of Applied Research in Memory and Cognition, 1(3), 214216.Google Scholar
Green, C. S., Bavelier, D., Kramer, A. F., Vinogradov, S., Ansorge, U., Ball, K. K., Bingel, U., Chein, J. M., Colzato, L. S., Edwards, J. D., Facoetti, A., Gazzaley, A., Gathercole, S. E., Ghisletta, P., Gori, S., Granic, I., Hillman, C. H., Hommel, B., Jaeggi, S. M.,…Witt, C. M. (2019). Improving methodological standards in behavioral interventions for cognitive enhancement. Journal of Cognitive Enhancement, 3(1), 229.Google Scholar
Hartshorne, J. K., & Germine, L. T. (2015). When does cognitive functioning peak? The asynchronous rise and fall of different cognitive abilities across the life span. Psychological Science, 26(4), 433443.Google Scholar
Hou, J., Jiang, T., Fu, J., Su, B., Wu, H., Sun, R., & Zhang, T. (2020). The long-term efficacy of working memory training in healthy older adults: A systematic review and meta-analysis of 22 randomized controlled trials. The Journals of Gerontology: Series B, 75(8), e174e188.Google Scholar
Jaeggi, S. M., Buschkuehl, M., Jonides, J., & Perrig, W. J. (2008). Improving fluid intelligence with training on working memory. Proceedings of the National Academy of Sciences, 105(19), 68296833.Google Scholar
Jaeggi, S. M., Buschkuehl, M., Jonides, J., & Shah, P. (2011). Short- and long-term benefits of cognitive training. Proceedings of the National Academy of Sciences, 108(25), 1008110086.Google Scholar
Jaeggi, S. M., Buschkuehl, M., Parlett-Pelleriti, C. M., Moon, S. M., Evans, M., Kritzmacher, A., Reuter-Lorenz, P. A., Shah, P., & Jonides, J. (2020). Investigating the effects of spacing on working memory training outcome: A randomized controlled multi-site trial in older adults. The Journals of Gerontology: Series B, 75(6).Google Scholar
Jaeggi, S. M., Buschkuehl, M., Shah, P., & Jonides, J. (2014). The role of individual differences in cognitive training and transfer. Memory & Cognition, 42(3), 464480.Google Scholar
Jaeggi, S. M., Pahor, A., & Seitz, A. R. (2020, Sept. 24). Does “Brain Training” actually work? Scientific American. www.scientificamerican.com/article/does-brain-training-actually-work.Google Scholar
Jensen, P. S., Hinshaw, S. P., Swanson, J. M., Greenhill, L. L., Conners, C. K., Arnold, L. E., Abikoff, H. B., Elliott, G., Hechtman, L., Hoza, B., March, J. S., Newcorn, J. H., Severe, J. B., Vitiello, B., Wells, K., & Wigal, T. (2001). Findings from the NIMH Multimodal Treatment Study of ADHD (MTA): Implications and applications for primary care providers. Journal of Developmental & Behavioral Pediatrics, 22(1), 6073.Google Scholar
Jones, M. R., Katz, B., Buschkuehl, M., Jaeggi, S. M., & Shah, P. (2020). Exploring n-back cognitive training for children with ADHD. Journal of Attention Disorders, 24(5), doi: 10.1177/1087054718779230.Google Scholar
Kambeitz-Ilankovic, L., Betz, L. T., Dominke, C., Haas, S. S., Subramaniam, K., Fisher, M., Vinogradov, S., Koutsouleris, N., & Kambeitz, J. (2019). Multi-outcome meta-analysis (MOMA) of cognitive remediation in schizophrenia: Revisiting the relevance of human coaching and elucidating interplay between multiple outcomes. Neuroscience & Biobehavioral Reviews, 107, 828845.Google Scholar
Kane, M. J., Brown, L. H., McVay, J. C., Silvia, P. J., Myin-Germeys, I., & Kwapil, T. R. (2007). For whom the mind wanders, and when: An experience-sampling study of working memory and executive control in daily life. Psychological Science, 18(7), 614621.Google Scholar
Kane, M. J., Hambrick, D. Z., Tuholski, S. W., Wilhelm, O., Payne, T. W., & Engle, R. W. (2004). The generality of working memory capacity: A latent-variable approach to verbal and visuospatial memory span and reasoning. Journal of Experimental Psychology: General, 133(2), 189217.Google Scholar
Karbach, J., Könen, T., & Spengler, M. (2017). Who benefits the most? Individual differences in the transfer of executive control training across the lifespan. Journal of Cognitive Enhancement, 1(4), 394405.Google Scholar
Karbach, J., & Verhaeghen, P. (2014). Making working memory work: A meta-analysis of executive-control and working memory training in older adults. Psychological Science, 25(11), 20272037.Google Scholar
Kassai, R., Futo, J., Demetrovics, Z., & Takacs, Z. K. (2019). A meta-analysis of the experimental evidence on the near- and far-transfer effects among children’s executive function skills. Psychological Bulletin, 145(2), 165188.Google Scholar
Katz, B., Jaeggi, S., Buschkuehl, M., Stegman, A., & Shah, P. (2014). Differential effect of motivational features on training improvements in school-based cognitive training. Frontiers in Human Neuroscience, 8.Google Scholar
Katz, B., Jaeggi, S. M., Buschkuehl, M., Shah, P., & Jonides, J. (2018). The effect of monetary compensation on cognitive training outcomes. Learning and Motivation, 63, 7790.Google Scholar
Katz, B., Jones, M. R., Shah, P., Buschkuehl, M., & Jaeggi, S. M. (2016). Individual differences and motivational effects. In Cognitive training: An overview of features and applications (pp. 157166). Springer International Publishing.Google Scholar
Kenworthy, L., Yerys, B. E., Anthony, L. G., & Wallace, G. L. (2008). Understanding executive control in Autism Spectrum Disorders in the lab and in the real world. Neuropsychology Review, 18(4), 320338.Google Scholar
Kerns, K. A., Macoun, S., MacSween, J., Pei, J., & Hutchison, M. (2017). Attention and working memory training: A feasibility study in children with neurodevelopmental disorders. Applied Neuropsychology: Child, 6(2), 120137.Google Scholar
Klingberg, T. (2010). Training and plasticity of working memory. Trends in Cognitive Sciences, 14(7), 317324.Google Scholar
Knight, L. A., Rooney, M., & Chronis-Tuscano, A. (2008). Psychosocial treatments for Attention-Deficit/Hyperactivity Disorder. Current Psychiatry Reports, 10(5), 412418.Google Scholar
Kofler, M. J., Sarver, D. E., Austin, K. E., Schaefer, H. S., Holland, E., Aduen, P. A., Wells, E. L., Soto, E. F., Irwin, L. N., Schatschneider, C., & Lonigan, C. J. (2018). Can working memory training work for ADHD? Development of central executive training and comparison with behavioral parent training. Journal of Consulting and Clinical Psychology, 86(12), 964979.Google Scholar
Kollins, S. H., DeLoss, D. J., Cañadas, E., Lutz, J., Findling, R. L., Keefe, R. S. E., Epstein, J. N., Cutler, A. J., & Faraone, S. V. (2020). A novel digital intervention for actively reducing severity of paediatric ADHD (STARS-ADHD): A randomised controlled trial. The Lancet Digital Health, 2(4), e168e178.Google Scholar
Kraft, M. A. (2020). Interpreting effect sizes of education interventions. Educational Researcher, 49(4), 241253.Google Scholar
Lambez, B., Harwood-Gross, A., Golumbic, E. Z., & Rassovsky, Y. (2020). Non-pharmacological interventions for cognitive difficulties in ADHD: A systematic review and meta-analysis. Journal of Psychiatric Research, 120, 4055.Google Scholar
Loosli, S. V., Buschkuehl, M., Perrig, W. J., & Jaeggi, S. M. (2012). Working memory training improves reading processes in typically developing children. Child Neuropsychology, 18(1), 6278.Google Scholar
Melby-Lervåg, M., & Hulme, C. (2013). Is working memory training effective? A meta-analytic review. Developmental Psychology, 49(2), 270291.Google Scholar
Melby-Lervåg, M., & Hulme, C. (2015). There is no convincing evidence that working memory training is effective: A reply to Au et al. (2014) and Karbach and Verhaeghen (2014). Psychonomic Bulletin & Review, 23(1), 324330.Google Scholar
Melby-Lervåg, M., Redick, T. S., & Hulme, C. (2016). Working memory training does not improve performance on measures of intelligence or other measures of “far transfer”: Evidence from a meta-analytic review. Perspectives on Psychological Science: A Journal of the Association for Psychological Science, 11(4), 512534.Google Scholar
Mohammed, S., Flores, L., Deveau, J., Hoffing, R. C., Phung, C., Parlett, C. M., Sheehan, E., Lee, D., Au, J., Buschkuehl, M., Zordan, V., Jaeggi, S. M., & Seitz, A. R. (2017). The benefits and challenges of implementing motivational features to boost cognitive training outcome. Journal of Cognitive Enhancement: Towards the Integration of Theory and Practice, 1(4), 491507.Google Scholar
Molina, B. S. G., Hinshaw, S. P., Eugene Arnold, L., Swanson, J. M., Pelham, W. E., Hechtman, L., Hoza, B., Epstein, J. N., Wigal, T., Abikoff, H. B., Greenhill, L. L., Jensen, P. S., Wells, K. C., Vitiello, B., Gibbons, R. D., Howard, A., Houck, P. R., Hur, K., Lu, B.,…MTA Cooperative Group. (2013). Adolescent substance use in the multimodal treatment study of attention-deficit/hyperactivity disorder (ADHD) (MTA) as a function of childhood ADHD, random assignment to childhood treatments, and subsequent medication. Journal of the American Academy of Child and Adolescent Psychiatry, 52(3), 250263.Google Scholar
Nemmi, F., Helander, E., Helenius, O., Almeida, R., Hassler, M., Räsänen, P., & Klingberg, T. (2016). Behavior and neuroimaging at baseline predict individual response to combined mathematical and working memory training in children. Developmental Cognitive Neuroscience, 20, 4351.Google Scholar
Passolunghi, M. C., Marzocchi, G. M., & Fiorillo, F. (2005). Selective effect of inhibition of literal or numerical irrelevant information in children with Attention Deficit Hyperactivity Disorder (ADHD) or Arithmetic Learning Disorder (ALD). Developmental Neuropsychology, 28(3), 731753.Google Scholar
Peijnenborgh, J. C., Hurks, P. M., Aldenkamp, A. P., Vles, J. S., & Hendriksen, J. G. (2016). Efficacy of working memory training in children and adolescents with learning disabilities: A review study and meta-analysis. Neuropsychological Rehabilitation, 26(5–6), 645672.Google Scholar
Peng, P., & Miller, A. C. (2016). Doesattention training work? A selective meta-analysis to explore the effects of attention training and moderators. Learning and Individual Differences, 45, 7787.Google Scholar
Peng, P., Namkung, J., Barnes, M., & Sun, C. (2016). A meta-analysis of mathematics and working memory: Moderating effects of working memory domain, type of mathematics skill, and sample characteristics. Journal of Educational Psychology, 108(4), 455.Google Scholar
Pergher, V., Shalchy, M. A., Pahor, A., Van Hulle, M. M., Jaeggi, S. M., & Seitz, A. R. (2019). Divergent research methods limit understanding of working memory training. Journal of Cognitive Enhancement, 1–21.Google Scholar
Randall, L., & Tyldesley, K. (2016). Evaluating the impact of working memory training programmes on children: A systematic review. Educational and Child Psychology, 33(1), 3450.Google Scholar
Rapport, M. D., Orban, S. A., Kofler, M. J., & Friedman, L. M. (2013). Do programs designed to train working memory, other executive functions, and attention benefit children with ADHD? A meta-analytic review of cognitive, academic, and behavioral outcomes. Clinical Psychology Review, 33(8), 12371252.Google Scholar
Rebok, G. W., Langbaum, J. B. S., Jones, R. N., Gross, A. L., Parisi, J. M., Spira, A. P., Kueider, A. M., Petras, H., & Brandt, J. (2013). Memory training in the ACTIVE study: How much is needed and who benefits? Journal of Aging and Health, 25(8 suppl.), 21S42S.Google Scholar
Reser, M. P., Slikboer, R., & Rossell, S. L. (2019). A systematic review of factors that influence the efficacy of cognitive remediation therapy in schizophrenia. Australian & New Zealand Journal of Psychiatry, 53(7), 624641.Google Scholar
Robert, P., Manera, V., Derreumaux, A., Montesino, M. F. Y., Leone, E., Fabre, R., & Bourgeois, J. (2020). Efficacy of a web app for cognitive training (MeMo) regarding cognitive and behavioral performance in people with neurocognitive disorders: Randomized controlled trial. Journal of Medical Internet Research, 22(3), e17167. https://doi.org/10.2196/17167Google Scholar
Sala, G., Aksayli, N. D., Tatlidil, K. S., Tatsumi, T., Gondo, Y., & Gobet, F. (2019). Near and far transfer in cognitive training: A second-order meta-analysis. Collabra: Psychology, 5(18). https://doi.org/10.1525/collabra.203Google Scholar
Sala, G., & Gobet, F. (2017). Working memory training in typically developing children: A meta-analysis of the available evidence. Developmental Psychology, 53(4), 671.Google Scholar
Salmi, J., Soveri, A., Salmela, V., Alho, K., Leppämäki, S., Tani, P., Koski, A., Jaeggi, S. M., & Laine, M. (2020). Working memory training restores aberrant brain activity in adult attention-deficit hyperactivity disorder. Human Brain Mapping, 41(17), 48764891.Google Scholar
Sandeep, S., Shelton, C. R., Pahor, A., Jaeggi, S. M., & Seitz, A. R. (2020). Application of machine learning models for tracking participant skills in cognitive training. Frontiers in Psychology, 11.Google Scholar
Saxena, S., Thornicroft, G., Knapp, M., & Whiteford, H. (2007). Resources for mental health: Scarcity, inequity, and inefficiency. Lancet, 370(9590), 878889.Google Scholar
Schwaighofer, M., Fischer, F., & Bühner, M. (2015). Does working memory training transfer? A meta-analysis including training conditions as moderators. Educational Psychologist, 50(2), 138166.Google Scholar
Scionti, N., Cavallero, M., Zogmaister, C., & Marzocchi, G. M. (2020). Is cognitive training effective for improving executive functions in preschoolers? A systematic review and meta-analysis. Frontiers in Psychology, 10.Google Scholar
Shah, P., Buschkuehl, M., Jaeggi, S., & Jonides, J. (2012). Cognitive training for ADHD: The importance of individual differences. Journal of Applied Research in Memory and Cognition, 1(3), 204205.Google Scholar
Shah, P., & Miyake, A. (1999). Models of working memory: An introduction. In Miyake, A. & Shah, P. (Eds.), Models of working memory: Mechanism of active maintenance and executive control (pp. 126). Cambridge University Press.Google Scholar
Shipstead, Z., Hicks, K. L., & Engle, R. W. (2012). Cogmed working memory training: Does the evidence support the claims? Journal of Applied Research in Memory and Cognition, 1(3), 185193.Google Scholar
Shipstead, Z., Redick, T. S., & Engle, R. W. (2010). Does working memory training generalize? Psychologica Belgica, 50(3–4), 245.Google Scholar
Shipstead, Z., Redick, T. S., & Engle, R. W. (2012). Is working memory training effective? Psychological Bulletin, 138(4), 628654.Google Scholar
Simons, D. J., Boot, W. R., Charness, N., Gathercole, S. E., Chabris, C. F., Hambrick, D. Z., & Stine-Morrow, E. A. L. (2016). Do “Brain-Training” programs work? Psychological Science in the Public Interest, 17(3), 103186.Google Scholar
Söderqvist, S., Nutley, S. B., Ottersen, J., Grill, K. M., & Klingberg, T. (2012). Computerized training of non-verbal reasoning and working memory in children with intellectual disability. Frontiers in Human Neuroscience, 6, 271.Google Scholar
Sonuga-Barke, E. J. S. (2002). Psychological heterogeneity in AD/HD: A dual pathway model of behaviour and cognition. Behavioural Brain Research, 130(1), 2936.Google Scholar
Sonuga-Barke, E. J. S., Brandeis, D., Cortese, S., Daley, D., Ferrin, M., Holtmann, M., Stevenson, J., Danckaerts, M., van der Oord, S., Döpfner, M., Dittmann, R. W., Simonoff, E., Zuddas, A., Banaschewski, T., Buitelaar, J., Coghill, D., Hollis, C., Konofal, E., Lecendreux, M.,…Sergeant, J. (2013). Nonpharmacological interventions for ADHD: Systematic review and meta-analyses of randomized controlled trials of dietary and psychological treatments. American Journal of Psychiatry, 170(3), 275289.Google Scholar
Sonuga-Barke, E. J. S., Brandeis, D., Holtmann, M., & Cortese, S. (2014). Computer-based cognitive training for ADHD: A review of current evidence. Child and Adolescent Psychiatric Clinics of North America, 23(4), 807824.Google Scholar
Soveri, A., Antfolk, J., Karlsson, L., Salo, B., & Laine, M. (2017). Working memory training revisited: A multi-level meta-analysis of n-back training studies. Psychonomic Bulletin & Review, 24(4), 10771096.Google Scholar
Spencer-Smith, M., & Klingberg, T. (2015). Benefits of a working memory training program for inattention in daily life: A systematic review and meta-analysis. PLoS ONE, 10(3).Google Scholar
Stepankova, H., Lukavsky, J., Buschkuehl, M., Kopecek, M., Ripova, D., & Jaeggi, S. M. (2014). Dose-response relationship of working memory training and improvements in fluid intelligence: A randomized controlled study in old adults. Developmental Psychology, 50, 10491059.Google Scholar
Swanson, J. M. (2019). Debate: Are stimulant medications for Attention-Deficit/Hyperactivity Disorder effective in the long term? (Against). Journal of the American Academy of Child & Adolescent Psychiatry, 58(10), 936938.Google Scholar
Takacs, Z. K., & Kassai, R. (2019). The efficacy of different interventions to foster children’s executive function skills: A series of meta-analyses. Psychological Bulletin, 145(7), 653697.Google Scholar
Tsai, N., Buschkuehl, M., Kamarsu, S., Shah, P., Jonides, J., & Jaeggi, S. M. (2018). (Un)Great expectations: The role of placebo effects in cognitive training. Journal of Applied Research in Memory and Cognition, 7(4), 564573.Google Scholar
Tullo, D., Faubert, J., & Bertone, A. (2018). The characterization of attention resource capacity and its relationship with fluid reasoning intelligence: A multiple object tracking study. Intelligence, 69, 158168.Google Scholar
Tullo, D., Guy, J., Faubert, J., & Bertone, A. (2018). Training with a three-dimensional multiple object-tracking (3D-MOT) paradigm improves attention in students with a neurodevelopmental condition: A randomized controlled trial. Developmental Science, 21(6), e12670.Google Scholar
von Bastian, C. C., & Oberauer, K. (2014). Effects and mechanisms of working memory training: A review. Psychological Research, 78(6), 803820.Google Scholar
Wang, C., Jaeggi, S. M., Yang, L., Zhang, T., He, X., Buschkuehl, M., & Zhang, Q. (2019). Narrowing the achievement gap in low-achieving children by targeted executive function training. Journal of Applied Developmental Psychology, 63, 8795.Google Scholar
Wang, Z., Zhou, R., & Shah, P. (2014). Spaced cognitive training promotes training transfer. Frontiers in Human Neuroscience, 8.Google Scholar
Wass, S. V., Scerif, G., & Johnson, M. H. (2012). Training attentional control and working memory: Is younger, better? Developmental Review, 32(4), 360387.Google Scholar
Webb, S. L., Loh, V., Lampit, A., Bateman, J. E., & Birney, D. P. (2018). Meta-analysis of the effects of computerized cognitive training on executive functions: A cross-disciplinary taxonomy for classifying outcome cognitive factors. Neuropsychology Review, 28(2), 232250.Google Scholar
Weicker, J., Villringer, A., & Thöne-Otto, A. (2016). Can impaired working memory functioning be improved by training? A meta-analysis with a special focus on brain injured patients. Neuropsychology, 30(2), 190.Google Scholar
Zhang, Q., Wang, C., Zhao, Q., Yang, L., Buschkuehl, M., & Jaeggi, S. M. (2019). The malleability of executive function in early childhood: Effects of schooling and targeted training. Developmental Science, 22(2), e12748.Google Scholar

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