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听觉诱发电位中潜伏期和脑桥晚期成分的偏侧化及双耳相互作用

Lateralization and Binaural Interaction of Middle-Latency and Late-Brainstem Components of the Auditory Evoked Response.

作者信息

Dykstra Andrew R, Burchard Daniel, Starzynski Christian, Riedel Helmut, Rupp Andre, Gutschalk Alexander

机构信息

Department of Neurology, Ruprecht-Karls-Universität Heidelberg, Heidelberg, Germany.

Department of Human Neurobiology, Center for Cognitive Science, Universität Bremen, Bremen, Germany.

出版信息

J Assoc Res Otolaryngol. 2016 Aug;17(4):357-70. doi: 10.1007/s10162-016-0572-x. Epub 2016 May 19.

DOI:10.1007/s10162-016-0572-x
PMID:27197812
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4940292/
Abstract

We used magnetoencephalography to examine lateralization and binaural interaction of the middle-latency and late-brainstem components of the auditory evoked response (the MLR and SN10, respectively). Click stimuli were presented either monaurally, or binaurally with left- or right-leading interaural time differences (ITDs). While early MLR components, including the N19 and P30, were larger for monaural stimuli presented contralaterally (by approximately 30 and 36 % in the left and right hemispheres, respectively), later components, including the N40 and P50, were larger ipsilaterally. In contrast, MLRs elicited by binaural clicks with left- or right-leading ITDs did not differ. Depending on filter settings, weak binaural interaction could be observed as early as the P13 but was clearly much larger for later components, beginning at the P30, indicating some degree of binaural linearity up to early stages of cortical processing. The SN10, an obscure late-brainstem component, was observed consistently in individuals and showed linear binaural additivity. The results indicate that while the MLR is lateralized in response to monaural stimuli-and not ITDs-this lateralization reverses from primarily contralateral to primarily ipsilateral as early as 40 ms post stimulus and is never as large as that seen with fMRI.

摘要

我们使用脑磁图来检测听觉诱发反应的中潜伏期和脑干晚期成分(分别为中潜伏期反应和SN10)的偏侧化和双耳相互作用。短声刺激以单耳方式呈现,或以左耳或右耳领先的双耳间时间差(ITD)双耳呈现。虽然包括N19和P30在内的早期中潜伏期反应成分在对侧呈现单耳刺激时更大(分别在左半球和右半球大约大30%和36%),但包括N40和P50在内的后期成分在同侧更大。相比之下,由左耳或右耳领先的ITD双耳短声诱发的中潜伏期反应没有差异。根据滤波设置,早在P13时就能观察到微弱的双耳相互作用,但从P30开始,后期成分的双耳相互作用明显大得多,这表明在皮质处理的早期阶段存在一定程度的双耳线性。SN10是一个不明确的脑干晚期成分,在个体中一直能观察到,并表现出双耳线性叠加。结果表明,虽然中潜伏期反应在对单耳刺激而非ITD的反应中发生偏侧化,但这种偏侧化在刺激后40毫秒时就从主要对侧反转至主要同侧,且从未像功能磁共振成像所见的那样大。

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