| scholarly article | Q13442814 |
| P50 | author | Sophie Scott | Q17278767 |
| Carolyn McGettigan | Q59282535 | ||
| P2093 | author name string | Carolyn McGettigan | |
| P2860 | cites work | Neural Oscillations Carry Speech Rhythm through to Comprehension. | Q21558371 |
| Progressive associative phonagnosia: a neuropsychological analysis | Q24632592 | ||
| The θ-γ neural code | Q26853056 | ||
| Hemispheric asymmetries in speech perception: sense, nonsense and modulations | Q27320741 | ||
| Dorsal and ventral streams: a framework for understanding aspects of the functional anatomy of language | Q28252051 | ||
| Hemispheric asymmetry for spectral and temporal processing in the human antero-lateral auditory belt cortex | Q28274501 | ||
| The cortical organization of speech processing | Q28297888 | ||
| Cerebral dominance and the perception of verbal stimuli. | Q29029173 | ||
| Central auditory pathologies | Q29036173 | ||
| Maps and streams in the auditory cortex: nonhuman primates illuminate human speech processing | Q29619526 | ||
| Structure and function of auditory cortex: music and speech. | Q30329717 | ||
| Bilateral speech comprehension reflects differential sensitivity to spectral and temporal features. | Q30371245 | ||
| Suppressed alpha oscillations predict intelligibility of speech and its acoustic details | Q30394161 | ||
| Neural correlates of strategy use during auditory working memory in musicians and non-musicians | Q30396200 | ||
| Cortical oscillations and speech processing: emerging computational principles and operations | Q30409666 | ||
| Cortical asymmetries in speech perception: what's wrong, what's right and what's left? | Q30435341 | ||
| Speech comprehension aided by multiple modalities: behavioural and neural interactions | Q30436966 | ||
| Encoding of spectral correlation over time in auditory cortex | Q30445788 | ||
| Phase-locked responses to speech in human auditory cortex are enhanced during comprehension. | Q30454854 | ||
| The theta-syllable: a unit of speech information defined by cortical function | Q30456142 | ||
| Neuronal oscillations and speech perception: critical-band temporal envelopes are the essence | Q30459170 | ||
| Phonological grammar shapes the auditory cortex: a functional magnetic resonance imaging study. | Q48164971 | ||
| Lateralization of speech and auditory temporal processing. | Q48407535 | ||
| Neural correlates of intelligibility in speech investigated with noise vocoded speech--a positron emission tomography study | Q48434611 | ||
| Hemispheric specialization for processing auditory nonspeech stimuli | Q48701210 | ||
| Left-hemisphere specialization for the processing of acoustic transients | Q48708128 | ||
| The neural processing of masked speech: evidence for different mechanisms in the left and right temporal lobes | Q48710474 | ||
| Right anterior superior temporal activation predicts auditory sentence comprehension following aphasic stroke | Q48724913 | ||
| Spectral and temporal processing in human auditory cortex | Q48798226 | ||
| Neural substrates of phonemic perception | Q49064873 | ||
| The functional neuroanatomy of prelexical processing in speech perception. | Q50480655 | ||
| Speech recognition with primarily temporal cues. | Q50517986 | ||
| Identification of consonants and vowels presented to left and right ears. | Q50668268 | ||
| The aprosodias. Functional-anatomic organization of the affective components of language in the right hemisphere. | Q51254480 | ||
| TEMPORAL PERCEPTION, APHASIA AND D'EJ'A VU | Q51284022 | ||
| Speech acoustic-cue discrimination abilities of normally developing and language-impaired children. | Q52294582 | ||
| Developmental aphasia: Rate of auditory processing and selective impairment of consonant perception | Q52319002 | ||
| Multisensory prior entry. | Q52936326 | ||
| Endogenous cortical rhythms determine cerebral specialization for speech perception and production | Q57700184 | ||
| Auditory processing in dyslexia and specific language impairment: is there a deficit? What is its nature? Does it explain anything? | Q59292579 | ||
| PET Studies of Auditory and Phonological Processing: Effects of Stimulus Characteristics and Task Demands | Q60149208 | ||
| Rate of acoustic change may underlie hemispheric specialization for speech perception | Q71134995 | ||
| Hemispheric specialization for language processes | Q71492711 | ||
| Functional asymmetries in the representation of noise-vocoded speech | Q85195242 | ||
| The hemispheric lateralization of speech processing depends on what "speech" is: a hierarchical perspective. | Q30460802 | ||
| Oscillators and syllables: a cautionary note | Q30462578 | ||
| Neural Oscillations in Speech: Don't be Enslaved by the Envelope | Q30463710 | ||
| Asymmetric function of theta and gamma activity in syllable processing: an intra-cortical study | Q30465519 | ||
| On the role of theta-driven syllabic parsing in decoding speech: intelligibility of speech with a manipulated modulation spectrum | Q30465626 | ||
| An application of univariate and multivariate approaches in FMRI to quantifying the hemispheric lateralization of acoustic and linguistic processes | Q30466549 | ||
| Discriminating between auditory and motor cortical responses to speech and nonspeech mouth sounds | Q30467122 | ||
| Amplitude onsets and spectral energy in perceptual experience | Q30468833 | ||
| Discrimination of speech stimuli based on neuronal response phase patterns depends on acoustics but not comprehension | Q30473333 | ||
| Linking speech perception and neurophysiology: speech decoding guided by cascaded oscillators locked to the input rhythm | Q30474865 | ||
| Inferior frontal gyrus activation predicts individual differences in perceptual learning of cochlear-implant simulations | Q30478568 | ||
| Bihemispheric foundations for human speech comprehension | Q30479124 | ||
| Temporal envelope of time-compressed speech represented in the human auditory cortex | Q30481123 | ||
| Expertise with artificial nonspeech sounds recruits speech-sensitive cortical regions. | Q30485875 | ||
| Right-hemisphere auditory cortex is dominant for coding syllable patterns in speech | Q30488159 | ||
| Phase patterns of neuronal responses reliably discriminate speech in human auditory cortex | Q30488506 | ||
| Neural specializations for speech and pitch: moving beyond the dichotomies | Q30490731 | ||
| Speech comprehension is correlated with temporal response patterns recorded from auditory cortex | Q30531116 | ||
| Hierarchical and asymmetric temporal sensitivity in human auditory cortices | Q33340905 | ||
| Towards a functional neuroanatomy of speech perception | Q33877224 | ||
| Neural resources for processing language and environmental sounds: evidence from aphasia | Q33964688 | ||
| The neuroanatomical and functional organization of speech perception | Q34171595 | ||
| Predictive coding under the free-energy principle | Q37520162 | ||
| Auditory temporal perception deficits in the reading-impaired: A critical review of the evidence | Q38160807 | ||
| Distribution of cortical neural networks involved in word comprehension and word retrieval | Q38475908 | ||
| Brain oscillations during spoken sentence processing | Q38483262 | ||
| Defects of non-verbal auditory perception in children with developmental aphasia | Q38588494 | ||
| Functional specificity in the right human auditory cortex for perceiving pitch direction | Q39433944 | ||
| Word deafness and auditory cortical function. A case history and hypothesis | Q41189560 | ||
| Identification of a pathway for intelligible speech in the left temporal lobe | Q42275641 | ||
| Evidence for rapid auditory perception as the foundation of speech processing: a sparse temporal sampling fMRI study. | Q42639643 | ||
| Vocal pitch discrimination in the motor system | Q43794339 | ||
| A temporal sampling framework for developmental dyslexia. | Q43834590 | ||
| Speech dominance is a better predictor of functional brain asymmetry than handedness: a combined fMRI word generation and behavioral dichotic listening study. | Q45988846 | ||
| Defining a left-lateralized response specific to intelligible speech using fMRI. | Q48146171 | ||
| Functional neuroimaging of speech perception in six normal and two aphasic subjects | Q48153062 | ||
| P433 | issue | 1 | |
| P407 | language of work or name | English | Q1860 |
| P304 | page(s) | 36-45 | |
| P577 | publication date | 2013-10-01 | |
| P1433 | published in | Brain and Language | Q2474530 |
| P1476 | title | Do temporal processes underlie left hemisphere dominance in speech perception? | |
| P478 | volume | 127 |
| Q91286930 | 'Normal' hearing thresholds and fundamental auditory grouping processes predict difficulties with speech-in-noise perception |
| Q89972126 | Asymmetric sampling in human auditory cortex reveals spectral processing hierarchy |
| Q30572227 | Cortical Correlates of the Auditory Frequency-Following and Onset Responses: EEG and fMRI Evidence. |
| Q96171748 | Differential contributions of the two cerebral hemispheres to temporal and spectral speech feedback control |
| Q90658833 | From speech and talkers to the social world: The neural processing of human spoken language |
| Q41109427 | Modulation of pre-attentive spectro-temporal feature processing in the human auditory system by HD-tDCS. |
| Q48515961 | Phonetic detail and lateralization of reading-related inner speech and of auditory and somatosensory feedback processing during overt reading. |
| Q93012564 | Spectrotemporal modulation provides a unifying framework for auditory cortical asymmetries |
| Q98568537 | Speech-in-noise detection is related to auditory working memory precision for frequency |
| Q33875608 | The Functional Genetics of Handedness and Language Lateralization: Insights from Gene Ontology, Pathway and Disease Association Analyses. |
| Q28066012 | The Language, Tone and Prosody of Emotions: Neural Substrates and Dynamics of Spoken-Word Emotion Perception |
| Q30401775 | The neuroanatomic and neurophysiological infrastructure for speech and language |
| Q38542281 | Transcranial direct current stimulation as a tool in the study of sensory-perceptual processing |
| Q28075522 | Vowels and Consonants in the Brain: Evidence from Magnetoencephalographic Studies on the N1m in Normal-Hearing Listeners. |
Search more.