噪声对内耳和外耳声电听觉整合的影响。

Effects of noise on integration of acoustic and electric hearing within and across ears.

机构信息

Department of Head and Neck Surgery, David Geffen School of Medicine, University of California Los Angeles, Los Angeles, California, United States of America.

Department of Experimental Psychology, University of Cambridge, Cambridge, United Kingdom.

出版信息

PLoS One. 2020 Oct 15;15(10):e0240752. doi: 10.1371/journal.pone.0240752. eCollection 2020.

DOI:10.1371/journal.pone.0240752

PMID:33057396

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7561114/

Abstract

In bimodal listening, cochlear implant (CI) users combine electric hearing (EH) in one ear and acoustic hearing (AH) in the other ear. In electric-acoustic stimulation (EAS), CI users combine EH and AH in the same ear. In quiet, integration of EH and AH has been shown to be better with EAS, but with greater sensitivity to tonotopic mismatch in EH. The goal of the present study was to evaluate how external noise might affect integration of AH and EH within or across ears. Recognition of monosyllabic words was measured for normal-hearing subjects listening to simulations of unimodal (AH or EH alone), EAS, and bimodal listening in quiet and in speech-shaped steady noise (10 dB, 0 dB signal-to-noise ratio). The input/output frequency range for AH was 0.1-0.6 kHz. EH was simulated using an 8-channel noise vocoder. The output frequency range was 1.2-8.0 kHz to simulate a shallow insertion depth. The input frequency range was either matched (1.2-8.0 kHz) or mismatched (0.6-8.0 kHz) to the output frequency range; the mismatched input range maximized the amount of speech information, while the matched input resulted in some speech information loss. In quiet, tonotopic mismatch differently affected EAS and bimodal performance. In noise, EAS and bimodal performance was similarly affected by tonotopic mismatch. The data suggest that tonotopic mismatch may differently affect integration of EH and AH in quiet and in noise.

摘要

在双模式听力中，人工耳蜗（CI）使用者在一只耳朵中结合电听觉（EH），在另一只耳朵中结合声学听觉（AH）。在电声刺激（EAS）中，CI 用户在同一只耳朵中结合 EH 和 AH。在安静环境中，已经证明 EAS 更有利于 EH 和 AH 的整合，但对 EH 的音调失配更敏感。本研究的目的是评估外部噪声如何影响 AH 和 EH 在同一耳或双耳内的整合。使用正常听力受试者的模拟，评估单模态（仅 AH 或 EH）、EAS 和双模态在安静和言语形状稳定噪声（10 dB，0 dB 信噪比）中的单音节词识别。AH 的输入/输出频率范围为 0.1-0.6 kHz。EH 采用 8 通道噪声声码器模拟。输出频率范围为 1.2-8.0 kHz，以模拟较浅的插入深度。输入频率范围与输出频率范围匹配（1.2-8.0 kHz）或不匹配（0.6-8.0 kHz）；不匹配的输入范围最大程度地增加了语音信息，而匹配的输入导致了一些语音信息的丢失。在安静环境中，音调失配对 EAS 和双模式性能的影响不同。在噪声中，EH 和双模式性能受到音调失配的影响相似。数据表明，音调失配对 EH 和 AH 在安静和噪声中的整合可能有不同的影响。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/7071/7561114/fdb8fb41af38/pone.0240752.g001.jpg

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噪声对内耳和外耳声电听觉整合的影响。

Effects of noise on integration of acoustic and electric hearing within and across ears.

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