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Tone language experience-dependent advantage in pitch representation in brainstem and auditory cortex is maintained under reverberation
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In: Hear Res (2019)
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| 2 |
Language experience-dependent advantage in pitch representation in the auditory cortex is limited to favorable signal-to-noise ratios
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Changes in pitch height elicit both language universal and language dependent changes in neural representation of pitch in the brainstem and auditory cortex
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Language-dependent changes in pitch-relevant neural activity in the auditory cortex reflect differential weighting of temporal attributes of pitch contours
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Pitch processing of dynamic lexical tones in the auditory cortex is influenced by sensory and extrasensory processes
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| 6 |
Language experience enhances early cortical pitch-dependent responses
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| 8 |
Cortical pitch response components show differential sensitivity to native and nonnative pitch contours
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LANGUAGE EXPERIENCE SHAPES PROCESSING OF PITCH RELEVANT INFORMATION IN THE HUMAN BRAINSTEM AND AUDITORY CORTEX: ELECTROPHYSIOLOGICAL EVIDENCE
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| 12 |
A functional deficit in the sensorimotor interface component as revealed by oral reading in Thai conduction aphasia
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Abstract:
The contemporary view is that a disruption in phonological encoding underlies the speech production deficit in conduction aphasia. We therefore expect to observe a commonality in phonological errors regardless of task – speaking, reading, or writing. A case report is presented of an oral reading task performed by a Thai conduction aphasic with evidence of localized damage in the left temporoparietal zone. He was instructed to read aloud selections from elementary school materials printed in Thai script at his own pace. A phonological analysis of substitution errors revealed that syllable-initial consonants were more vulnerable to disruption than vowels or tones. Tonal errors were seen to be a secondary consequence of a substitution error involving the syllable-initial consonant. His impaired performance is interpreted as evidence in support of a sensorimotor interface system that converts phonological representations derived from visual orthographic input into articulatory motor representations for speech output.
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URL: http://www.ncbi.nlm.nih.gov/pmc/articles/PMC3633224
http://www.ncbi.nlm.nih.gov/pubmed/23626404
https://doi.org/10.1016/j.jneuroling.2012.10.005
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| 13 |
Experience-dependent plasticity in pitch encoding: from brainstem to auditory cortex
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Neural correlates of musical and linguistic pitch as revealed in the auditory brainstem
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In: Theses and Dissertations Available from ProQuest (2011)
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Musicians and tone-language speakers share enhanced brainstem encoding but not perceptual benefits for musical pitch
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Musicians demonstrate experience-dependent brainstem enhancement of musical scale features within continuously gliding pitch
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| 19 |
Functional ear (a)symmetry in brainstem neural activity relevant to encoding of voice pitch: A precursor for hemispheric specialization?
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Linguistic status of timbre influences pitch encoding in the brainstem
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