| scholarly article | Q13442814 |
| P2093 | author name string | E Sussman | |
| W Ritter | |||
| H G Vaughan | |||
| P433 | issue | 1 | |
| P304 | page(s) | 22-34 | |
| P577 | publication date | 1999-01-01 | |
| P1433 | published in | Psychophysiology | Q15716416 |
| P1476 | title | An investigation of the auditory streaming effect using event-related brain potentials | |
| P478 | volume | 36 |
| Q34224650 | "Primitive intelligence" in the auditory cortex |
| Q38533689 | A systematic review of the mismatch negativity as an index for auditory sensory memory: From basic research to clinical and developmental perspectives |
| Q49045055 | Activation of the auditory pre-attentive change detection system by tone repetitions with fast stimulation rate |
| Q30412928 | Analyzing the auditory scene: neurophysiologic evidence of a dissociation between detection of regularity and detection of change |
| Q38447278 | Are you listening? Brain activation associated with sustained nonspatial auditory attention in the presence and absence of stimulation |
| Q30483682 | Attention effects on auditory scene analysis in children |
| Q30466074 | Attention modifies sound level detection in young children |
| Q21129174 | Attention, awareness, and the perception of auditory scenes |
| Q47395503 | Attentional Resources Are Needed for Auditory Stream Segregation in Aging |
| Q51991803 | Attentional modulation of electrophysiological activity in auditory cortex for unattended sounds within multistream auditory environments. |
| Q47760043 | Auditory Scene Analysis: An Attention Perspective |
| Q35461195 | Auditory Stream Segregation Improves Infants' Selective Attention to Target Tones Amid Distractors |
| Q30466657 | Auditory grouping mechanisms reflect a sound's relative position in a sequence |
| Q35780073 | Auditory neglect: what and where in auditory space |
| Q30488906 | Auditory scene analysis: the interaction of stimulation rate and frequency separation on pre-attentive grouping |
| Q48972862 | Auditory stream segregation processes operate similarly in school-aged children and adults |
| Q30428691 | Auditory stream segregation using bandpass noises: evidence from event-related potentials |
| Q58808099 | Auditory streaming affects the processing of successive deviant and standard sounds |
| Q30351762 | Automatic encoding of polyphonic melodies in musicians and nonmusicians. |
| Q30388821 | Automaticity and primacy of auditory streaming: Concurrent subjective and objective measures. |
| Q38550520 | Behavioral and electrophysiological effects of task-irrelevant sound change: a new distraction paradigm |
| Q30419815 | Behavioral measures of auditory streaming in ferrets (Mustela putorius). |
| Q30475264 | Behind the scenes of auditory perception |
| Q30357847 | Brain potentials predict learning, transmission and modification of an artificial symbolic system |
| Q90443730 | Cognitive resources are distributed among the entire auditory landscape in auditory scene analysis |
| Q30328602 | Deficit in automatic sound-change detection may underlie some music perception deficits after acute hemispheric stroke. |
| Q42632330 | EEG signatures accompanying auditory figure-ground segregation |
| Q98771351 | Effect of Vowel Auditory Training on the Speech-In-Noise Perception among Older Adults with Normal Hearing |
| Q48685348 | Effects of attention on neuroelectric correlates of auditory stream segregation |
| Q30559106 | Effects of regularity on the processing of sound omission in a tone sequence in musicians and non-musicians. |
| Q30387448 | Effects of task-switching on neural representations of ambiguous sound input |
| Q48329957 | Effects of temporal encoding on auditory object formation: a mismatch negativity study |
| Q48853004 | Effects of vowel auditory training on concurrent speech segregation in hearing impaired children |
| Q30454150 | Electrophysiological evidence for age effects on sensory memory processing of tonal patterns |
| Q46688088 | Foreground-background discrimination indicated by event-related brain potentials in a new auditory multistability paradigm |
| Q30455623 | Functional brain networks underlying perceptual switching: auditory streaming and verbal transformations |
| Q30341172 | Grouping of sequential sounds--an event-related potential study comparing musicians and nonmusicians. |
| Q48153343 | Human auditory cortex tracks task-irrelevant sound sources |
| Q51971082 | Human cortical activity during streaming without spectral cues suggests a general neural substrate for auditory stream segregation. |
| Q30317930 | Influence of auditory object formation by multimodal interaction |
| Q30416267 | Interaction of streaming and attention in human auditory cortex |
| Q56963393 | Interpreting the Mismatch Negativity |
| Q48753888 | Investigating the neural basis of the auditory continuity illusion |
| Q48439323 | Involvement of the thalamocortical loop in the spontaneous switching of percepts in auditory streaming |
| Q52954379 | MMN and attention: competition for deviance detection. |
| Q58808089 | Mismatch Negativity |
| Q30407708 | Mismatch negativity (MMN) as an index of cognitive dysfunction |
| Q55195397 | Mismatch negativity (MMN) elicited by abstract regularity violations in two concurrent auditory streams. |
| Q30378963 | Multitasking: Effects of processing multiple auditory feature patterns. |
| Q30474666 | Neural adaptation to tone sequences in the songbird forebrain: patterns, determinants, and relation to the build-up of auditory streaming |
| Q30401894 | Neural correlates of auditory stream segregation: an analysis of onset- and change-related responses. |
| Q50026053 | Neural decoding of bistable sounds reveals an effect of intention on perceptual organization. |
| Q30491041 | Neural representations of auditory input accommodate to the context in a dynamically changing acoustic environment |
| Q30492930 | Neural substrate of concurrent sound perception: direct electrophysiological recordings from human auditory cortex |
| Q30500002 | Neuromagnetic correlates of streaming in human auditory cortex |
| Q30482477 | Neurophysiological evidence for context-dependent encoding of sensory input in human auditory cortex |
| Q50470810 | Neurophysiological indexes of speech processing deficits in children with specific language impairment. |
| Q30501574 | Newborn infants can organize the auditory world |
| Q30472581 | Objective and subjective psychophysical measures of auditory stream integration and segregation. |
| Q48931043 | Organizing sound sequences in the human brain: the interplay of auditory streaming and temporal integration |
| Q30445724 | Perceptual organization of auditory streaming-task relies on neural entrainment of the stimulus-presentation rate: MEG evidence |
| Q45700099 | Preattentive auditory context effects |
| Q30439991 | Predictability effects in auditory scene analysis: a review |
| Q52105333 | Preserved use of spatial cues for sound segregation in a case of spatial deafness. |
| Q50480611 | Primitive auditory stream segregation: a neurophysiological study in the songbird forebrain. |
| Q48500125 | Reduced suppression or labile memory? Mechanisms of inefficient filtering of irrelevant information in older adults |
| Q30467014 | Regularity extraction from non-adjacent sounds |
| Q48214591 | Representation of the standard: stimulus context effects on the process generating the mismatch negativity component of event-related brain potentials |
| Q43922673 | Schema-based processing in auditory scene analysis |
| Q48173728 | Selective entrainment of brain oscillations drives auditory perceptual organization |
| Q30462171 | Sequential grouping modulates the effect of non-simultaneous masking on auditory intensity resolution |
| Q52018253 | Simultaneously active pre-attentive representations of local and global rules for sound sequences in the human brain. |
| Q48276919 | Sound presentation rate is represented logarithmically in human cortex. |
| Q30444838 | Spatial stream segregation by auditory cortical neurons |
| Q47440689 | Spectrotemporal window of integration of auditory information in the human brain |
| Q48135800 | Statistical Learning of Melodic Patterns Influences the Brain's Response to Wrong Notes |
| Q30445388 | Stimulus phase locking of cortical oscillation for auditory stream segregation in rats |
| Q30470150 | Temporal coherence and attention in auditory scene analysis. |
| Q48216243 | Temporal integration of auditory stimulus deviance as reflected by the mismatch negativity |
| Q48433910 | Temporal integration: intentional sound discrimination does not modulate stimulus-driven processes in auditory event synthesis |
| Q30461480 | The Build-up of Auditory Stream Segregation: A Different Perspective. |
| Q29036131 | The Intraparietal Sulcus and Perceptual Organization |
| Q38178363 | The auditory novelty system: an attempt to integrate human and animal research |
| Q48315162 | The electrophysiological net response (‘F-complex’) to spatial fusion of speech elements forming an auditory object |
| Q30407711 | The five myths of MMN: redefining how to use MMN in basic and clinical research |
| Q50458546 | The listening in spatialized noise-sentences test (LISN-S): test-retest reliability study |
| Q45924379 | The role of attention in the formation of auditory streams. |
| Q30494054 | The role of auditory cortex in the formation of auditory streams. |
| Q48971086 | The role of large-scale memory organization in the mismatch negativity event-related brain potential |
| Q30392251 | The role of temporal structure in the investigation of sensory memory, auditory scene analysis, and speech perception: a healthy-aging perspective |
| Q52028773 | Time course of auditory cortex activation during speech processing. |
| Q48648494 | Top-down effects can modify the initially stimulus-driven auditory organization |
| Q30498656 | Visual cues can modulate integration and segregation of objects in auditory scene analysis |
| Q48614207 | Visual object representations can be formed outside the focus of voluntary attention: evidence from event-related brain potentials |
| Q30474414 | Widespread Brain Areas Engaged during a Classical Auditory Streaming Task Revealed by Intracranial EEG. |
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