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Neural representation of interaural correlation in human auditory brainstem: Comparisons between temporal-fine structure and envelope.

Authors :
Wang, Qian
Lu, Hao
Wu, Zhemeng
Li, Liang
Source :
Hearing Research. Aug2018, Vol. 365, p165-173. 9p.
Publication Year :
2018

Abstract

Central processing of interaural correlation (IAC), which depends on the precise representation of acoustic signals from the two ears, is essential for both localization and recognition of auditory objects. A complex soundwave is initially filtered by the peripheral auditory system into multiple narrowband waves, which are further decomposed into two functionally distinctive components: the quickly-varying temporal-fine structure (TFS) and the slowly-varying envelope. In rats, a narrowband noise can evoke auditory-midbrain frequency-following responses (FFRs) that contain both the TFS component (FFR TFS ) and the envelope component (FFR Env ), which represent the TFS and envelope of the narrowband noise, respectively. These two components are different in sensitivity to the interaural time disparity. In human listeners, the present study investigated whether the FFR TFS and FFR Env components of brainstem FFRs to a narrowband noise are different in sensitivity to IAC and whether there are potential brainstem mechanisms underlying the integration of the two components. The results showed that although both the amplitude of FFR TFS and that of FFR Env were significantly affected by shifts of IAC between 1 and 0, the stimulus-to-response correlation for FFR TFS , but not that for FFR Env , was sensitive to the IAC shifts. Moreover, in addition to the correlation between the binaurally evoked FFR TFS and FFR Env , the correlation between the IAC-shift-induced change of FFR TFS and that of FFR Env was significant. Thus, the TFS information is more precisely represented in the human auditory brainstem than the envelope information, and the correlation between FFR TFS and FFR Env for the same narrowband noise suggest a brainstem binding mechanism underlying the perceptual integration of the TFS and envelope signals. [ABSTRACT FROM AUTHOR]

Details

Language :
English
ISSN :
03785955
Volume :
365
Database :
Academic Search Index
Journal :
Hearing Research
Publication Type :
Academic Journal
Accession number :
130357827
Full Text :
https://doi.org/10.1016/j.heares.2018.05.015