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Mapping human pitch representation in a distributed system using depth-electrode recordings and modelingHemispheric asymmetry for spectral and temporal processing in the human antero-lateral auditory belt cortexHeschl's gyrus, posterior superior temporal gyrus, and mid-ventrolateral prefrontal cortex have different roles in the detection of acoustic changesFrequency Selectivity of Voxel-by-Voxel Functional Connectivity in Human Auditory CortexActivation in the Right Inferior Parietal Lobule Reflects the Representation of Musical Structure beyond Simple Pitch Discrimination.Individual Differences in the Frequency-Following Response: Relation to Pitch PerceptionTracing the neural basis of auditory entrainment.Parcellation of Human and Monkey Core Auditory Cortex with fMRI Pattern Classification and Objective Detection of Tonotopic Gradient ReversalsSelective attention modulates human auditory brainstem responses: relative contributions of frequency and spatial cues.Spectro-temporal modulation transfer function of single voxels in the human auditory cortex measured with high-resolution fMRI.Depth electrode recordings show double dissociation between pitch processing in lateral Heschl's gyrus and sound onset processing in medial Heschl's gyrus.Cortical brain states and corticospinal synchronization influence TMS-evoked motor potentials.Sensation of agency and perception of temporal order.Loudness modulation after transient and permanent hearing loss: implications for tinnitus and hyperacusis.Adaptation to shifted interaural time differences changes encoding of sound location in human auditory cortex.Sensory suppression of brain responses to self-generated sounds is observed with and without the perception of agency.Enhanced brainstem and cortical encoding of sound during synchronized movement.Fast and persistent adaptation to new spectral cues for sound localization suggests a many-to-one mapping mechanism.Enhanced visual adaptation in cochlear implant users revealed by concurrent EEG-fNIRS.Hierarchical processing of sound location and motion in the human brainstem and planum temporale.Blindsight mediated by an S-cone-independent collicular pathway: an fMRI study in hemispherectomized subjects.Motor intention determines sensory attenuation of brain responses to self-initiated sounds.Neural bases of rhythmic entrainment in humans: critical transformation between cortical and lower-level representations of auditory rhythm.Cortical response to auditory motion suggests an asymmetry in the reliance on inter-hemispheric connections between the left and right auditory cortices.Vowel processing evokes a large sustained response anterior to primary auditory cortex.Is it tonotopy after all?Spectral and temporal processing in the human auditory cortex--revisited.Hemispheric asymmetry for auditory processing in the human auditory brain stem, thalamus, and cortex.Cortical Speech and Music Processes Revealed by Functional NeuroimagingTowards an objective test of chronic tinnitus: Properties of auditory cortical potentials evoked by silent gaps in tinnitus-like soundsRepresentation of Interaural Temporal Information from Left and Right Auditory Space in the Human Planum Temporale and Inferior Parietal LobeThe Encoding of Sound Source Elevation in the Human Auditory Cortex
P50
Q26850718-C2DC6753-1D4E-4A5B-9516-A5D012216302Q28274501-6EC37868-7901-4C18-95E8-0A89FA581B41Q28279973-FC66F2BE-4DD0-478D-A2BF-6DB927C39BA6Q30366660-D1890DCB-FE16-4A2F-9CDA-87B6C927DECFQ30381862-1D25ECE7-B316-4041-A476-41EF0B6BA412Q30386647-0C537BBE-F111-448F-8CB3-B80E419992F4Q30393371-CE882670-B4F3-4DD5-A2D5-674B587CB8E6Q30402260-C7BEEACE-D958-44D6-BFA5-DCA2658B86B9Q30444253-920DB143-47EA-4017-A95D-8A0A06CEAC3AQ30483109-8546EFF1-8414-4164-8581-C737BCDD1AB6Q30543599-208F7349-D2F4-4C57-8FBE-24AABB7D5D11Q30559921-B7C74FC3-7E04-46E7-BC2F-55D4B0CDA2D2Q30560295-63EB875D-27F0-464D-915A-2252BEA94DFBQ30563000-5FA0E386-DFD0-4E07-BA0A-66F6DA282D5EQ30567914-D808BFEA-FBE9-426D-8FAE-2B3B3147B74AQ30571006-F5004FC1-35DF-49CE-84F4-D762511138D0Q30571386-50B435C6-73C7-4666-AFDE-7F593A00979DQ30571563-C598CC9B-CD84-4DE4-9BFF-4579D2BFA1DBQ30571598-36AEFEEB-9B7F-4414-A363-405ACA89E33CQ45227508-1A5F6C58-4527-40DF-845E-8BF5E1B4B78CQ46077308-F4502105-4601-4323-B99E-2133E23E73A8Q47813267-F3368437-3652-4C6F-80A2-7CC45CE06E52Q47847988-A9F474A7-130F-4F1D-AEF8-BB4F693D7504Q48368984-5ADF724C-3066-4B12-B8A6-FBABC2D1D5D2Q48372111-F894DF91-560A-49F6-AFF0-894BF78160D9Q48454901-7191A6AF-0BB5-4869-9516-E8585C093EB4Q48592229-70121D31-7001-40DF-B995-ED6E9ECC3D38Q48604677-2AE3101A-B411-4BC6-A015-02F8EAA29632Q56239964-AACBB728-D218-4F23-9926-DBDD747AC1FBQ56378885-45daa438-4890-f3d9-fd08-5bb174a49501Q57514825-F64E88C9-74A7-4CE1-9D7E-DC56C258E6BBQ61789095-7452D209-2D96-42F2-A39B-291DF279FD86
P50
description
onderzoeker
@nl
professeur et chercheur en neurosciences
@fr
professor and researcher in neuroscience
@en
professore e ricercatore nelle neuroscienze
@it
name
Marc Schönwiesner
@ast
Marc Schönwiesner
@en
Marc Schönwiesner
@es
Marc Schönwiesner
@fr
Marc Schönwiesner
@it
Marc Schönwiesner
@nl
Marc Schönwiesner
@sl
type
label
Marc Schönwiesner
@ast
Marc Schönwiesner
@en
Marc Schönwiesner
@es
Marc Schönwiesner
@fr
Marc Schönwiesner
@it
Marc Schönwiesner
@nl
Marc Schönwiesner
@sl
altLabel
Marc Schoenwiesner
@en
prefLabel
Marc Schönwiesner
@ast
Marc Schönwiesner
@en
Marc Schönwiesner
@es
Marc Schönwiesner
@fr
Marc Schönwiesner
@it
Marc Schönwiesner
@nl
Marc Schönwiesner
@sl
P106
P1153
15758073100
P21
P2798
P31
P496
0000-0002-2023-1207