发展性阅读障碍的听觉时间加工缺陷

doi:10.3724/SP.J.1042.2021.01231

摘要/Abstract

摘要：

发展性阅读障碍是指个体在智力正常并且不缺乏学校教育的情况下, 仍无法获得与年龄相匹配的阅读技能的一种学习障碍, 其缺陷的本质一直是研究者争论的焦点。大量研究显示, 阅读障碍者常表现出听觉时间加工损伤。在行为层面, 阅读障碍者难以辨别快速、连续呈现刺激的顺序以及刺激本身的动态时间特征。在神经层面, 阅读障碍者诱发的失匹配负波更弱且具有异常的神经同步加工。这些损伤同时存在于对言语和非言语刺激的加工中, 表明听觉时间加工缺陷非言语加工所特有。未来的研究还需阐明以下几个问题：1)阅读障碍的听觉时间加工缺陷发生在哪些时间窗口, 随年龄增长如何变化; 2)阅读障碍听觉时间加工缺陷在神经层面的时间进程是怎样的; 3)听觉时间加工缺陷是否为阅读障碍的核心缺陷。

关键词: 发展性阅读障碍, 听觉时间加工, 时间顺序, 动态时间特征, 失匹配, 神经同步

Abstract:

Developmental dyslexia is a neurological disorder characterized by a specific deficit in reading, despite adequate intelligence and socioeconomic opportunity. A large number of studies have revealed that dyslexics usually exhibit impaired auditory temporal processing. At the behavioral level, dyslexics struggle to discriminate the sequence of rapid and successive stimuli as well as dynamical temporal characteristics. At the neural level, dyslexics evoke weaker mismatch negativity (MMN) and have abnormal neural synchronization. These deficits have been found in the processing of both verbal and non-verbal stimuli, suggesting that such deficits are not specific to speech processing. However, the auditory temporal-order processing deficits of dyslexia are manifested in the processing of both rapidly and slowly presented auditory stimuli. Besides, dyslexic children have more abnormal neural synchronization in low-frequency temporal modulation, and dyslexic adults have more abnormal neural synchronization in high-frequency temporal modulation. Therefore, auditory temporal processing deficits of dyslexia seem to occur not only in a narrow temporal window, but also in a wider temporal window. The developmental characteristics of dyslexia may also imply that the temporal window of auditory temporal processing deficits will narrow with age. Moreover, only the neural mechanism of dyslexics while distinguishing deviant auditory temporal stimuli has been examined in previous studies, and there is still a lack of research, such as the neural mechanism of more general auditory temporal processing and the changing process of such a neural mechanism over time.

In summary, the following questions need to be elucidated in further studies. 1) The temporal windows in which auditory temporal processing deficits occur in dyslexia, and how will they change with age. It is generally known that different temporal windows (e.g., 40 ~ 4000 ms) correspond to different levels of language abstractions (e.g., phonetic feature, segment, syllable, word, metrical foot and prosodic phrase), and the cross-language phonological awareness is developed from larger-grained phonological units (such as stressed syllables) to smaller granular phonetic units (such as phonemes). Based on this, it can be inferred that the auditory temporal processing deficits of developmental dyslexia may only exist in temporal windows corresponding to language abstractions, which may gradually narrow with age. In the future, a cross-sectional and longitudinal study can be implemented to investigate this question. 2) What is the neural time course of auditory temporal processing deficits in dyslexia. N1, P2, CNV (contingent negative variation) and LPCt (late positive component of timing) correspond to selective attention, cognitive resource allocation, temporal encoding and temporal discrimination of the temporal processing, respectively. However, the current electrophysiological studies have only confirmed the existence of auditory temporal processing deficits among dyslexics through mismatch negativity waves, while the processing stage in which the auditory temporal deficits occur has not been ascertained. Aftertime, event-related potential (ERP) technology with a high temporal resolution can be used to explore this question. 3) Whether auditory temporal processing deficits are core causes of dyslexia. Previous studies have shown that dyslexics are also accompanied by deficits in attention and working memory, while the effects brought by differences in their attention and working memory were not excluded from tasks such as temporal order judgment (TOJ) used in previous studies. Control conditions can be set in future studies to explore whether auditory temporal processing deficits are the primary deficits that cause developmental dyslexia.

Key words: developmental dyslexia, auditory temporal processing, temporal sequence, dynamic temporal feature, mismatch, neural synchronization

中图分类号:

B842

王润洲, 毕鸿燕. (2021). 发展性阅读障碍的听觉时间加工缺陷. 心理科学进展 , 29(7), 1231-1238.

WANG Runzhou, BI Hongyan. (2021). Auditory temporal processing deficits in developmental dyslexia. Advances in Psychological Science, 29(7), 1231-1238.

参考文献 50

[1]	张曼莉, 孟祥芝, 郑小蓓. (2018). 中文阅读障碍儿童的时间加工缺陷: 来自知觉学习干预研究的证据. 心理与行为研究, 16(5), 583-593.
[2]	Bhide, A., Power, A., & Goswami, U. (2013). A rhythmic musical intervention for poor readers: A comparison of efficacy with a letter-based intervention. Mind, Brain, and Education, 7(2), 113-123. doi: 10.1111/mbe.2013.7.issue-2 URL
[3]	Booth, J. R., Perfetti, C. A., MacWhinney, B., & Hunt, S. B. (2000). The association of rapid temporal perception with orthographic and phonological processing in reading impaired children and adults. Scientific Studies of Reading, 4, 101-132. doi: 10.1207/S1532799XSSR0402_02 URL
[4]	Casini, L., Pech-Georgel, C., & Ziegler, J. C. (2018). It’s about time: Revisiting temporal processing deficits in dyslexia. Developmental Science, 21(2), e12530. doi: 10.1111/desc.12530 URL
[5]	Cestnick, L., & Jerger, J. (2000). Auditory temporal processing and lexical/nonlexical reading in developmental dyslexics. Journal of the American Academy of Audiology, 11(9), 491-503.
[6]	Chung, K. K. H., McBride-Chang, C., Wong, S. W. L., Cheung, H., Penney, T. B., & Ho, C. S. H. (2008). The role of visual and auditory temporal processing for Chinese children with developmental dyslexia. Annals of Dyslexia, 58(1), 15-35. doi: 10.1007/s11881-008-0015-4 URL
[7]	Corbera, S., Escera, C., & Artigas, J. (2006). Impaired duration mismatch negativity in developmental dyslexia. Neuroreport, 17(10), 1051-1055. pmid: 16791102
[8]	Cutini, S., Szűcs, D., Mead, N., Huss, M., & Goswami, U. (2016). Atypical right hemisphere response to slow temporal modulations in children with developmental dyslexia. NeuroImage, 143, 40-49. doi: 10.1016/j.neuroimage.2016.08.012 URL
[9]	Flaugnacco, E., Lopez, L., Terribili, C., Montico, M., Zoia, S., & Schön, D. (2015). Music training increases phonological awareness and reading skills in developmental dyslexia: A randomized control trial. PLoS ONE, 10(9), e0138715. doi: 10.1371/journal.pone.0138715 URL
[10]	Fostick, L., Bar-El, S., & Ram-Tsur, R. (2012). Auditory temporal processing as a specific deficit among dyslexic readers. Psychology Research, 2, 77-88.
[11]	Fostick, L., Eshcoli, R., Shtibelman, H., Nechemya, R., & Levi, H. (2014). The efficacy of temporal processing training to improve phonological awareness among dyslexic students. Journal of Experimental Psychology: Human Perception and Performance, 40, 1799-1807.
[12]	Ghitza, O., & Greenberg, S. (2009). On the possible role of brain rhythms in speech perception: Intelligibility of time- compressed speech with periodic and aperiodic insertions of silence. Phonetica, 66, 113-126. doi: 10.1159/000208934 pmid: 19390234
[13]	Goswami, U. (2011). A temporal sampling framework for developmental dyslexia. Trends in Cognitive Sciences, 15(1), 3-10. doi: 10.1016/j.tics.2010.10.001 URL
[14]	Goswami, U. (2015). Sensory theories of developmental dyslexia: Three challenges for research. Nature Reviews Neuroscience, 16(1), 43-54. doi: 10.1038/nrn3836 URL
[15]	Goswami, U. (2018). A neural basis for phonological awareness? An oscillatory temporal-sampling perspective. Current Directions in Psychological Science, 27(1), 56-63. doi: 10.1177/0963721417727520 URL
[16]	Goswami, U. (2019). A neural oscillations perspective on phonological development and phonological processing in developmental dyslexia. Language and Linguistics Compass, 13(5), e12328. doi: 10.1111/lnc3.v13.5 URL
[17]	Goswami, U., Gerson, D., & Astruc, L. (2010). Amplitude envelope perception, phonology and prosodic sensitivity in children with developmental dyslexia. Reading and Writing, 23(8), 995- 1019.
[18]	Goswami, U., & Leong, V. (2013). Speech rhythm and temporal structure: Converging perspectives. Laboratory Phonology, 4(1), 67-92.
[19]	Goswami, U., Mead, N., Fosker, T., Huss, M., Barnes, L., & Leong, V. (2013). Impaired perception of syllable stress in children with dyslexia: A longitudinal study. Journal of Memory and Language, 69(1), 1-17. doi: 10.1016/j.jml.2013.03.001 URL
[20]	Goswami, U., Wang, H.-L. S., Cruz, A., Fosker, T., Mead, N., & Huss, M. (2011). Language-universal sensory deficits in developmental dyslexia: English, Spanish, and Chinese. Journal of Cognitive Neuroscience, 23(2), 325-337. doi: 10.1162/jocn.2010.21453 URL
[21]	Grondin, S. (2010). Timing and time perception: A review of recent behavioral and neuroscience findings and theoretical directions. Attention, Perception, and Psychophysics, 72(3), 561-582.
[22]	Gross, J., Hoogenboom, N., Thut, G., Schyns, P., Panzeri, S., Belin, P., & Garrod, S. (2013). Speech rhythms and multiplexed oscillatory sensory coding in the human brain. PLoS Biology, 11(12), e1001752. doi: 10.1371/journal.pbio.1001752 URL
[23]	Hämäläinen, J. A., Rupp, A., Soltész, F., Szücs, D., & Goswami, U. (2012). Reduced phase locking to slow amplitude modulation in adults with dyslexia: An MEG study. NeuroImage, 59(3), 2952-2961. doi: 10.1016/j.neuroimage.2011.09.075 pmid: 22001790
[24]	Kalashnikova, M., Goswami, U., & Burnham, D. (2018). Mothers speak differently to infants at‐risk for dyslexia. Developmental Science, 21(1), e12487.
[25]	Kalashnikova, M., Goswami, U., & Burnham, D. (2019). Sensitivity to amplitude envelope rise time in infancy and vocabulary development at 3 years: A significant relationship. Developmental Science, e12836.
[26]	Kotz, S. A., & Schwartze, M. (2010). Cortical speech processing unplugged: A timely subcortico-cortical framework. Trends in Cognitive Sciences, 14(9), 392-399. doi: 10.1016/j.tics.2010.06.005 URL
[27]	Law, J. M., Wouters, J., & Ghesquière, P. (2017). The influences and outcomes of phonological awareness: A study of MA, PA and auditory processing in pre-readers with a family risk of dyslexia. Developmental Science, 20(5), e12453. doi: 10.1111/desc.2017.20.issue-5 URL
[28]	Lehongre, K., Morillon, B., Giraud, A.-L., & Ramus, F. (2013). Impaired auditory sampling in dyslexia: Further evidence from combined fMRI and EEG. Frontiers in Human Neuroscience, 7, 454.
[29]	Liu, S., Wang, L. C., & Liu, D. (2019). Auditory, visual, and cross-modal temporal processing skills among Chinese children with developmental dyslexia. Journal of Learning Disabilities, 52(6), 431-441. doi: 10.1177/0022219419863766 URL
[30]	Lovegrove, W. J., Bowling, A., Badcock, D., & Blackwood, M. (1980). Specific reading disability: Differences in contrast sensitivity as a function of spatial frequency. Science, 210(4468), 439-440. doi: 10.1126/science.7433985 URL
[31]	Meng, X. Z., Sai, X. G., Wang, C. X., Wang, J., Sha, S. Y., & Zhou, X. L. (2005). Auditory and speech processing and reading development in Chinese school children: Behavioural and ERP evidence. Dyslexia, 11(4), 292-310. doi: 10.1002/(ISSN)1099-0909 URL
[32]	Nittrouer, S. (1999). Do temporal processing deficits cause phonological processing problems? Journal of Speech, Language, and Hearing Research, 42(4), 925-942. doi: 10.1044/jslhr.4204.925 URL
[33]	Power, A. J., Colling, L. J., Mead, N., Barnes, L., & Goswami, U. (2016). Neural encoding of the speech envelope by children with developmental dyslexia. Brain and Language, 160, 1-10. doi: 10.1016/j.bandl.2016.06.006 pmid: 27433986
[34]	Power, A. J., Mead, N., Barnes, L., & Goswami, U. (2012). Neural entrainment to rhythmically presented auditory, visual, and audio-visual speech in children. Frontiers in Psychology, 3, 216.
[35]	Power, A. J., Mead, N., Barnes, L., & Goswami, U. (2013). Neural entrainment to rhythmic speech in children with developmental dyslexia. Frontiers in Human Neuroscience, 7, 777.
[36]	Rey, V., de Martino, S., Espesser, R., & Habib, M. (2002). Temporal processing and phonological impairment in dyslexia: Effect of phoneme lengthening on order judgement of two consonants. Brain and Language, 80, 576-591. doi: 10.1006/brln.2001.2618 URL
[37]	Rufener, K. S., Krauel, K., Meyer, M., Heinze, H. J., & Zaehle, T. (2019). Transcranial electrical stimulation improves phoneme processing in developmental dyslexia. Brain Stimulation, 12(4), 930-937. doi: 10.1016/j.brs.2019.02.007 URL
[38]	Schulte-Körne, G., Deimel, W., Bartling, J., & Remschmidt, H. (1999). Pre-attentive processing of auditory patterns in dyslexic human subjects. Neuroscience Letters, 276(1), 41-44. doi: 10.1016/S0304-3940(99)00785-5 URL
[39]	Share, D. L., Jorm, A. F., Maclean, R. O. D., & Matthews, R. (2002). Temporal processing and reading disability. Reading and Writing, 15(1-2),151-178. doi: 10.1023/A:1013876606178 URL
[40]	Snowling, M. J. (2001). From language to reading and dyslexia. Dyslexia, 7(1), 37-46. pmid: 11305230
[41]	Stein, J. (2018). What is developmental dyslexia. Brain Sciences, 8, 26.
[42]	Studdert-Kennedy, M., & Mody, M. (1995). Auditory temporal perception deficits in the reading-impaired: A critical review of the evidence. Psychonomic Bulletin and Review, 2(4), 508-514. doi: 10.3758/BF03210986 URL
[43]	Tallal, P. (1980). Auditory temporal perception, phonics, and reading disabilities in children. Brain and Language, 9(2), 182-198. pmid: 7363063
[44]	van Hirtum, T., Ghesquière, P., & Wouters, J. (2019). Atypical neural processing of rise time by adults with dyslexia. Cortex, 113, 128-140. doi: S0010-9452(18)30416-7 pmid: 30640141
[45]	van Zuijen, T. L., Plakas, A., Maassen, B. A., Been, P., Maurits, N. M., Krikhaar, E., ... van der Leij, A. (2012). Temporal auditory processing at 17 months of age is associated with preliterate language comprehension and later word reading fluency: An ERP study. Neuroscience Letters, 528(1), 31-35. doi: 10.1016/j.neulet.2012.08.058 URL
[46]	Wang, L.-C., Liu, D., & Xu, Z. (2019). Distinct effects of visual and auditory temporal processing training on reading and reading-related abilities in Chinese children with dyslexia. Annals of Dyslexia, 69(2), 166-185. doi: 10.1007/s11881-019-00176-8 pmid: 30671864
[47]	Wang, L.-C., & Yang, H.-M. (2018). Temporal processing development in Chinese primary school-aged children with dyslexia. Journal of Learning Disabilities, 51(3), 302-312. doi: 10.1177/0022219416680798 URL
[48]	Witton, C., Talcott, J. B., Hansen, P. C., Richardson, A. J., Griffiths, T. D., Rees, A., ... Green, G. G. R. (1998). Sensitivity to dynamic auditory and visual stimuli predicts nonword reading ability in both dyslexic and normal readers. Current Biology, 8(14), 791-797. pmid: 9663387
[49]	Zhang, M., Xie, W., Xu, Y., & Meng, X. (2018). Auditory temporal perceptual learning and transfer in Chinese- speaking children with developmental dyslexia. Research in Developmental Disabilities, 74, 146-159. doi: 10.1016/j.ridd.2018.01.005 URL
[50]	Ziegler, J. C., & Goswami, U. (2005). Reading acquisition, developmental dyslexia, and skilled reading across languages: A psycholinguistic grain size theory. Psychological Bulletin, 131(1), 3-29. doi: 10.1037/0033-2909.131.1.3 URL