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Implicit, Explicit, and Predictive Perceptual Processing in Dyslexia
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| 2 |
A Tale of Two Lexica Testing Computational Hypotheses with Deep Convolutional Neural Networks ...
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| 3 |
Behavioral and Neurodynamic Effects of Word Learning on Phonotactic Repair
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In: Front Psychol (2021)
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Tracking reorganization of large-scale effective connectivity in aphasia following right hemisphere stroke
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There is a Missing-Phoneme Effect in Aural Prose Comprehension
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Sentential influences on acoustic-phonetic processing: a Granger causality analysis of multimodal imaging data ...
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Sentential influences on acoustic-phonetic processing: a Granger causality analysis of multimodal imaging data ...
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Sentential influences on acoustic-phonetic processing: a Granger causality analysis of multimodal imaging data ...
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| 9 |
Sentential influences on acoustic-phonetic processing: a Granger causality analysis of multimodal imaging data ...
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| 10 |
Sentential influences on acoustic-phonetic processing: A Granger causality analysis of multimodal imaging data
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| 11 |
Lexical mediation of phonotactic frequency effects on spoken word recognition: A Granger causality analysis of MRI-constrained MEG/EEG data
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| 12 |
Rules from Words: A Dynamic Neural Basis for a Lawful Linguistic Process
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| 13 |
Rules from Words: A Dynamic Neural Basis for a Lawful Linguistic Process
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| 16 |
New levels of language processing complexity and organization revealed by Granger causation
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In: Frontiers Research Foundation (2012)
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Abstract:
Granger causation analysis of high spatiotemporal resolution reconstructions of brain activation offers a new window on the dynamic interactions between brain areas that support language processing. Premised on the observation that causes both precede and uniquely predict their effects, this approach provides an intuitive, model-free means of identifying directed causal interactions in the brain. It requires the analysis of all non-redundant potentially interacting signals, and has shown that even “early” processes such as speech perception involve interactions of many areas in a strikingly large network that extends well beyond traditional left hemisphere perisylvian cortex that play out over hundreds of milliseconds. In this paper we describe this technique and review several general findings that reframe the way we think about language processing and brain function in general. These include the extent and complexity of language processing networks, the central role of interactive processing dynamics, the role of processing hubs where the input from many distinct brain regions are integrated, and the degree to which task requirements and stimulus properties influence processing dynamics and inform our understanding of “language-specific” localized processes. ; National Institute on Deafness and Other Communication Disorders (U.S.) (R01DC003108)
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URL: http://hdl.handle.net/1721.1/77578
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| 17 |
New Levels of Language Processing Complexity and Organization Revealed by Granger Causation
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| 18 |
New Levels of Language Processing Complexity and Organization Revealed by Granger Causation
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| 19 |
The cortical organization of lexical knowledge: A dual lexicon model of spoken language processing
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