Print-Speech Convergence Predicts Future Reading Outcomes in Early Readers

Preston, Jonathan L.; Molfese, Peter J.; Frost, Stephen J.; Mencl, W. Einar; Fulbright, Robert K.; Hoeft, Fumiko; Landi, Nicole; Shankweiler, Donald; Pugh, Kenneth R.

doi:10.1177/0956797615611921

Cited by 67 publications

(87 citation statements)

References 38 publications

(115 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…We integrate these emerging lines of research to propose that excess neural noise (Box 1) within cortical regions implicated in reading may be a distal contributor to RD. We suggest that multifactorial sources of neural noise, for example arising from neural hyperexcitability related to RD risk genes, may disrupt two key processes important for reading— phonological awareness [44] (see glossary) and multisensory integration of visual symbols with their corresponding speech sounds [45,46]—through the impact of excess noise on neural synchrony and sensory representations (Figure 1). The neural noise hypothesis of RD synthesizes a range of neurobiological findings, providing a mechanistic framework for understanding the deficits observed in RD and identifying targets for systems-level intervention.…”

Section: Premise Of the Neural Noise Hypothesismentioning

confidence: 99%

Neural Noise Hypothesis of Developmental Dyslexia

Hancock

Pugh

Hoeft

2017

Trends in Cognitive Sciences

Self Cite

102

View full text Add to dashboard Cite

Developmental dyslexia (decoding-based reading disorder; RD) is a complex trait with multifactorial origins at the genetic, neural and cognitive levels. There is evidence that low-level sensory processing deficits precede and underlie phonological problems, which are one of the best-documented aspects of RD. RD is also associated with impairments in integrating visual symbols with their corresponding speech sounds. Although causal relationships between sensory processing, print-speech integration and fluent reading, and their neural bases are debated, these processes all require precise timing mechanisms across distributed brain networks. Neural excitability and neural noise are fundamental to these timing mechanisms. We propose that neural noise stemming from increased neural excitability in cortical networks implicated in reading is one key, distal contributor to RD.

show abstract

Section: Premise Of the Neural Noise Hypothesismentioning

confidence: 99%

Neural Noise Hypothesis of Developmental Dyslexia

Hancock

Pugh

Hoeft

2017

Trends in Cognitive Sciences

Self Cite

102

View full text Add to dashboard Cite

show abstract

“…For instance, in Scarborough's (1989) study, preschoolers' 247 phonological awareness, measured and analyzed as a continuous variable, uniquely explained the 248 wide variation in reading outcomes at second grade, ranging from reading disabled, to low-249 achieving, to normal. Also, functional neuroimaging research shows that the amount of overlap 250 between the neural substrates of speech processing and print processing varies continuously with 251 reading skill (Frost et al, 2009;Preston et al, 2016;Shankweiler et al, 2008), implying that 252 better readers tend to engage more phonological processing in reading and supporting the idea 253 that phonological ability may be an important locus on which individuals with different levels of 254 reading competence vary. 255…”

Section: A Community Sample For Investigating Individual Differencesmentioning

confidence: 98%

Individual Differences in Subphonemic Sensitivity and Phonological Skills

Li¹,

Braze²,

Kukona³

et al. 2017

Preprint

Self Cite

View full text Add to dashboard Cite

Many studies have established a link between phonological abilities (indexed by phonological awareness and phonological memory tasks) and typical and atypical reading development. Individuals who perform poorly on phonological assessments have been mostly assumed to have underspecified (or “fuzzy”) phonological re- presentations, with typical phonemic categories, but with greater category overlap due to imprecise encoding. An alternative posits that poor readers have overspecified phonological representations, with speech sounds perceived allophonically (phonetically distinct variants of a single phonemic category). On both accounts, mismatch between phonological categories and orthography leads to reading difficulty. Here, we consider the implications of these accounts for online speech processing. We used eye tracking and an individual differences approach to assess sensitivity to subphonemic detail in a community sample of young adults with a wide range of reading-related skills. Subphonemic sensitivity inversely correlated with meta-phonological task performance, consistent with overspecification.

show abstract

“…Learning Phoneme-Grapheme Mappings Reading relies on the ability to reorganize left hemisphere speech and/or language-sensitive networks to allow print-speech integration [46,[93][94][95], enabling phoneme-grapheme correspondences to be learned. The neural noise hypothesis predicts that multisensory integration, such as between print and speech, should be consistently impacted in RD.…”

Section: Phonological Awarenessmentioning

confidence: 99%

“…Several studies have found that individuals with RD have reduced sensitivity to rhythmic patterns in the speech envelope, particularly at the syllabic rate [90,91], which some studies have attributed to impaired neural entrainment to the speech signal at low frequencies relevant to stress and syllabic segmentation [34]. There is also evidence for deficient phase-locking to both the fine structure of speech [92] and speech envelope in RD [81], consistent with the hyperexcitability-related spike timing variability observed in animal models [5,56].Learning Phoneme-Grapheme Mappings Reading relies on the ability to reorganize left hemisphere speech and/or language-sensitive networks to allow print-speech integration [46,[93][94][95], enabling phoneme-grapheme correspondences to be learned. The neural noise hypothesis predicts that multisensory integration, such as between print and speech, should be consistently impacted in RD.…”

mentioning

confidence: 98%

“…We integrate these emerging lines of research to propose that excess neural noise (Box 1) within cortical regions implicated in reading may be a distal contributor to RD. We suggest that multifactorial sources of neural noise, for example arising from neural hyperexcitability related to RD risk genes, disrupt two key processes important for reading [phonological awareness [44] (see Glossary) and multisensory integration of visual symbols with their corresponding speech sounds [45,46]] through the impact of excess noise on neural synchrony and sensory representations (Figure 1). The neural noise hypothesis of RD synthesizes a range of neurobiological findings, providing a mechanistic framework for understanding the deficits observed in RD and identifying targets for systems-level intervention.…”

mentioning

confidence: 99%

See 1 more Smart Citation

Neural Noise Hypothesis of Developmental Dyslexia

Hancock¹,

Pugh²,

Hoeft³

2017

Trends in Cognitive Sciences

Self Cite

View full text Add to dashboard Cite

Developmental dyslexia (decoding-based reading disorder; RD) is a complex trait with multifactorial origins at the genetic, neural, and cognitive levels. There is evidence that low-level sensory-processing deficits precede and underlie phonological problems, which are one of the best-documented aspects of RD. RD is also associated with impairments in integrating visual symbols with their corresponding speech sounds. Although causal relationships between sensory processing, print-speech integration, and fluent reading, and their neural bases are debated, these processes all require precise timing mechanisms across distributed brain networks. Neural excitability and neural noise are fundamental to these timing mechanisms. Here, we propose that neural noise stemming from increased neural excitability in cortical networks implicated in reading is one key distal contributor to RD. Premise of the Neural Noise HypothesisDevelopmental dyslexia (specific reading disabilities/disorders, or decoding-based RD) is a neurodevelopmental disorder contributed to by multiple genetic, neural, and cognitive factors [1], yet neurobiological models that account for the diversity of RD phenotypes remain elusive. An increasing number of studies have investigated the function of RD risk genes in animal models [2][3][4][5][6][7][8][9][10][11][12][13], and the neurobiological and behavioral consequences of genetic RD risk variants in humans [14][15][16][17][18][19][20][21][22][23][24][25][26][27][28][29][30][31], motivating the need for a synthesis of these findings, especially because they relate to emerging avenues of human research on the role of neurochemistry [32] and neural oscillations [33][34][35][36] in RD. Here, we present a timely integration of diverse lines of current research linking some of the key neural and behavioral deficits associated with RD to basic neural processes.A variety of neurobiological contributors to RD have been proposed, ranging from disrupted structural and functional connectivity [37,38] to atypical neural migration [39]. Recent work has investigated the neural dynamics that support language and sensory processing [40][41][42] and how these dynamics may be altered in RD [36,43]. We integrate these emerging lines of research to propose that excess neural noise (Box 1) within cortical regions implicated in reading may be a distal contributor to RD. We suggest that multifactorial sources of neural noise, for example arising from neural hyperexcitability related to RD risk genes, disrupt two key processes important for reading [phonological awareness [44] (see Glossary) and multisensory integration of visual symbols with their corresponding speech sounds [45,46]] through the impact of excess noise on neural synchrony and sensory representations (Figure 1). The neural noise hypothesis of RD synthesizes a range of neurobiological findings, providing a mechanistic framework for understanding the deficits observed in RD and identifying targets for systems-level intervention. While the potential for noisy proce...

show abstract

Print-Speech Convergence Predicts Future Reading Outcomes in Early Readers

Cited by 67 publications

References 38 publications

Neural Noise Hypothesis of Developmental Dyslexia

Neural Noise Hypothesis of Developmental Dyslexia

Individual Differences in Subphonemic Sensitivity and Phonological Skills

Neural Noise Hypothesis of Developmental Dyslexia

Contact Info

Product

Resources

About