Beta-band activity in auditory pathways reflects speech localization and recognition in bilateral cochlear implant users

Daniel Senkowski; Ulrich Pomper; Inga Fitzner; Andreas Karl Engel; Andrej Kral

doi:10.1002/hbm.22388

Beta-band activity in auditory pathways reflects speech localization and recognition in bilateral cochlear implant users

Standard

Beta-band activity in auditory pathways reflects speech localization and recognition in bilateral cochlear implant users. / Senkowski, Daniel; Pomper, Ulrich; Fitzner, Inga; Engel, Andreas Karl; Kral, Andrej.

In: HUM BRAIN MAPP, 07.10.2013.

Research output: SCORING: Contribution to journal › SCORING: Journal article › Research › peer-review

Harvard

Senkowski, D, Pomper, U, Fitzner, I, Engel, AK & Kral, A 2013, 'Beta-band activity in auditory pathways reflects speech localization and recognition in bilateral cochlear implant users', HUM BRAIN MAPP. https://doi.org/10.1002/hbm.22388

APA

Senkowski, D., Pomper, U., Fitzner, I., Engel, A. K., & Kral, A. (2013). Beta-band activity in auditory pathways reflects speech localization and recognition in bilateral cochlear implant users. HUM BRAIN MAPP. https://doi.org/10.1002/hbm.22388

Vancouver

Senkowski D, Pomper U, Fitzner I, Engel AK, Kral A. Beta-band activity in auditory pathways reflects speech localization and recognition in bilateral cochlear implant users. HUM BRAIN MAPP. 2013 Oct 7. https://doi.org/10.1002/hbm.22388

Bibtex

@article{969e5c074dca462e83d6bb309eee08a8,

title = "Beta-band activity in auditory pathways reflects speech localization and recognition in bilateral cochlear implant users",

abstract = "In normal-hearing listeners, localization of auditory speech involves stimulus processing in the postero-dorsal pathway of the auditory system. In quiet environments, bilateral cochlear implant (CI) users show high speech recognition performance, but localization of auditory speech is poor, especially when discriminating stimuli from the same hemifield. Whether this difficulty relates to the inability of the auditory system to translate binaural electrical cues into neural signals, or to a functional reorganization of auditory cortical pathways following long periods of binaural deprivation is unknown. In this electroencephalography study, we examined the processing of auditory syllables in postlingually deaf adults with bilateral CIs and in normal-hearing adults. Participants were instructed to either recognize ({"}recognition{"} task) or localize ({"}localization{"} task) the syllables. The analysis focused on event-related potentials and oscillatory brain responses. N1 amplitudes in CI users were larger in the localization compared with recognition task, suggesting an enhanced stimulus processing effort in the localization task. Linear beamforming of oscillatory activity in CI users revealed stronger suppression of beta-band activity after 200 ms in the postero-dorsal auditory pathway for the localization compared with the recognition task. In normal-hearing adults, effects for longer latency event-related potentials were found, but no effects were observed for N1 amplitudes or beta-band responses. Our study suggests that difficulties in speech localization in bilateral CI users are not reflected in a functional reorganization of cortical auditory pathways. New signal processing strategies of cochlear devices preserving unambiguous binaural cues may improve auditory localization performance in bilateral CI users. Hum Brain Mapp, 2013. {\textcopyright} 2013 Wiley Periodicals, Inc.",

author = "Daniel Senkowski and Ulrich Pomper and Inga Fitzner and Engel, {Andreas Karl} and Andrej Kral",

note = "Copyright {\textcopyright} 2013 Wiley Periodicals, Inc.",

year = "2013",

month = oct,

day = "7",

doi = "10.1002/hbm.22388",

language = "English",

journal = "HUM BRAIN MAPP",

issn = "1065-9471",

publisher = "Wiley-Liss Inc.",

}

RIS

TY - JOUR

T1 - Beta-band activity in auditory pathways reflects speech localization and recognition in bilateral cochlear implant users

AU - Senkowski, Daniel

AU - Pomper, Ulrich

AU - Fitzner, Inga

AU - Engel, Andreas Karl

AU - Kral, Andrej

PY - 2013/10/7

Y1 - 2013/10/7

N2 - In normal-hearing listeners, localization of auditory speech involves stimulus processing in the postero-dorsal pathway of the auditory system. In quiet environments, bilateral cochlear implant (CI) users show high speech recognition performance, but localization of auditory speech is poor, especially when discriminating stimuli from the same hemifield. Whether this difficulty relates to the inability of the auditory system to translate binaural electrical cues into neural signals, or to a functional reorganization of auditory cortical pathways following long periods of binaural deprivation is unknown. In this electroencephalography study, we examined the processing of auditory syllables in postlingually deaf adults with bilateral CIs and in normal-hearing adults. Participants were instructed to either recognize ("recognition" task) or localize ("localization" task) the syllables. The analysis focused on event-related potentials and oscillatory brain responses. N1 amplitudes in CI users were larger in the localization compared with recognition task, suggesting an enhanced stimulus processing effort in the localization task. Linear beamforming of oscillatory activity in CI users revealed stronger suppression of beta-band activity after 200 ms in the postero-dorsal auditory pathway for the localization compared with the recognition task. In normal-hearing adults, effects for longer latency event-related potentials were found, but no effects were observed for N1 amplitudes or beta-band responses. Our study suggests that difficulties in speech localization in bilateral CI users are not reflected in a functional reorganization of cortical auditory pathways. New signal processing strategies of cochlear devices preserving unambiguous binaural cues may improve auditory localization performance in bilateral CI users. Hum Brain Mapp, 2013. © 2013 Wiley Periodicals, Inc.

AB - In normal-hearing listeners, localization of auditory speech involves stimulus processing in the postero-dorsal pathway of the auditory system. In quiet environments, bilateral cochlear implant (CI) users show high speech recognition performance, but localization of auditory speech is poor, especially when discriminating stimuli from the same hemifield. Whether this difficulty relates to the inability of the auditory system to translate binaural electrical cues into neural signals, or to a functional reorganization of auditory cortical pathways following long periods of binaural deprivation is unknown. In this electroencephalography study, we examined the processing of auditory syllables in postlingually deaf adults with bilateral CIs and in normal-hearing adults. Participants were instructed to either recognize ("recognition" task) or localize ("localization" task) the syllables. The analysis focused on event-related potentials and oscillatory brain responses. N1 amplitudes in CI users were larger in the localization compared with recognition task, suggesting an enhanced stimulus processing effort in the localization task. Linear beamforming of oscillatory activity in CI users revealed stronger suppression of beta-band activity after 200 ms in the postero-dorsal auditory pathway for the localization compared with the recognition task. In normal-hearing adults, effects for longer latency event-related potentials were found, but no effects were observed for N1 amplitudes or beta-band responses. Our study suggests that difficulties in speech localization in bilateral CI users are not reflected in a functional reorganization of cortical auditory pathways. New signal processing strategies of cochlear devices preserving unambiguous binaural cues may improve auditory localization performance in bilateral CI users. Hum Brain Mapp, 2013. © 2013 Wiley Periodicals, Inc.

U2 - 10.1002/hbm.22388

DO - 10.1002/hbm.22388

M3 - SCORING: Journal article

C2 - 24123535

JO - HUM BRAIN MAPP

JF - HUM BRAIN MAPP

SN - 1065-9471

ER -