将皮层下脑电图对连续语音的反应扩展到声场。

IF 2.6 2区 医学 Q1 AUDIOLOGY & SPEECH-LANGUAGE PATHOLOGY Trends in Hearing Pub Date : 2024-01-01 DOI:10.1177/23312165241246596
Florine L Bachmann, Joshua P Kulasingham, Kasper Eskelund, Martin Enqvist, Emina Alickovic, Hamish Innes-Brown
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引用次数: 0

摘要

听觉脑干反应(ABR)是一种用于客观听力评估的重要临床工具,传统的检测方法是将神经对数千个短刺激的反应平均化。除了这些非自然刺激之外,最近还利用线性时间反应函数(TRF)检测了脑干对耳机播放的连续语音的反应。在这里,我们通过测量皮层下对声场中连续语音的反应来扩展之前的研究,并评估估计脑干 TRF 所需的数据量。我们记录了 24 名听力正常的参与者在聆听通过耳机和扬声器播放的咔嗒声和故事时的脑电图(EEG)。在通过刺激整流或听觉神经模型对听觉外围进行非线性处理后,计算了皮层下 TRF。我们的研究结果表明,在声场中可以可靠地测量皮层下对连续语音的反应。使用听觉神经模型估算的TRF优于简单的整流,16分钟的数据足以让所有参与者的TRF在耳机和声场刺激下都显示出清晰的V波峰值。在耳机和声场条件下,皮层下连续语音 TRF 与点击 ABR 高度一致。然而,与耳机 TRF(12 分钟)相比,声场 TRF 需要稍多的数据(16 分钟)才能达到清晰的波 V 峰值,这可能是由于室内声学的影响。通过研究皮层下对声场言语刺激的反应,本研究为使客观听力评估更接近真实生活条件奠定了基础,这可能会改进听力评估和智能听力技术。
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Extending Subcortical EEG Responses to Continuous Speech to the Sound-Field.

The auditory brainstem response (ABR) is a valuable clinical tool for objective hearing assessment, which is conventionally detected by averaging neural responses to thousands of short stimuli. Progressing beyond these unnatural stimuli, brainstem responses to continuous speech presented via earphones have been recently detected using linear temporal response functions (TRFs). Here, we extend earlier studies by measuring subcortical responses to continuous speech presented in the sound-field, and assess the amount of data needed to estimate brainstem TRFs. Electroencephalography (EEG) was recorded from 24 normal hearing participants while they listened to clicks and stories presented via earphones and loudspeakers. Subcortical TRFs were computed after accounting for non-linear processing in the auditory periphery by either stimulus rectification or an auditory nerve model. Our results demonstrated that subcortical responses to continuous speech could be reliably measured in the sound-field. TRFs estimated using auditory nerve models outperformed simple rectification, and 16 minutes of data was sufficient for the TRFs of all participants to show clear wave V peaks for both earphones and sound-field stimuli. Subcortical TRFs to continuous speech were highly consistent in both earphone and sound-field conditions, and with click ABRs. However, sound-field TRFs required slightly more data (16 minutes) to achieve clear wave V peaks compared to earphone TRFs (12 minutes), possibly due to effects of room acoustics. By investigating subcortical responses to sound-field speech stimuli, this study lays the groundwork for bringing objective hearing assessment closer to real-life conditions, which may lead to improved hearing evaluations and smart hearing technologies.

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来源期刊
Trends in Hearing
Trends in Hearing AUDIOLOGY & SPEECH-LANGUAGE PATHOLOGYOTORH-OTORHINOLARYNGOLOGY
CiteScore
4.50
自引率
11.10%
发文量
44
审稿时长
12 weeks
期刊介绍: Trends in Hearing is an open access journal completely dedicated to publishing original research and reviews focusing on human hearing, hearing loss, hearing aids, auditory implants, and aural rehabilitation. Under its former name, Trends in Amplification, the journal established itself as a forum for concise explorations of all areas of translational hearing research by leaders in the field. Trends in Hearing has now expanded its focus to include original research articles, with the goal of becoming the premier venue for research related to human hearing and hearing loss.
期刊最新文献
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