A Linear Superposition Model of Envelope and Frequency Following Responses May Help Identify Generators Based on Latency.

IF 3.6 Q1 LINGUISTICS
Tobias Teichert, G Nike Gnanateja, Srivatsun Sadagopan, Bharath Chandrasekaran
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引用次数: 3

Abstract

Envelope and frequency-following responses (FFRENV and FFRTFS) are scalp-recorded electrophysiological potentials that closely follow the periodicity of complex sounds such as speech. These signals have been established as important biomarkers in speech and learning disorders. However, despite important advances, it has remained challenging to map altered FFRENV and FFRTFS to altered processing in specific brain regions. Here we explore the utility of a deconvolution approach based on the assumption that FFRENV and FFRTFS reflect the linear superposition of responses that are triggered by the glottal pulse in each cycle of the fundamental frequency (F0 responses). We tested the deconvolution method by applying it to FFRENV and FFRTFS of rhesus monkeys to human speech and click trains with time-varying pitch patterns. Our analyses show that F0ENV responses could be measured with high signal-to-noise ratio and featured several spectro-temporally and topographically distinct components that likely reflect the activation of brainstem (<5 ms; 200-1000 Hz), midbrain (5-15 ms; 100-250 Hz), and cortex (15-35 ms; ~90 Hz). In contrast, F0TFS responses contained only one spectro-temporal component that likely reflected activity in the midbrain. In summary, our results support the notion that the latency of F0 components map meaningfully onto successive processing stages. This opens the possibility that pathologically altered FFRENV or FFRTFS may be linked to altered F0ENV or F0TFS and from there to specific processing stages and ultimately spatially targeted interventions.

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包络和频率跟随响应的线性叠加模型可以帮助识别基于延迟的发生器。
包络和频率跟随响应(FFRENV和FFRTFS)是头皮记录的电生理电位,密切关注复杂声音(如语音)的周期性。这些信号已被确定为言语和学习障碍的重要生物标志物。然而,尽管取得了重要进展,但将改变的FFRENV和FFRTFS映射到特定大脑区域改变的加工过程仍然具有挑战性。在这里,我们基于假设FFRENV和FFRTFS反映了由声门脉冲在基频的每个周期(F0响应)触发的响应的线性叠加,探讨了反卷积方法的效用。我们将反卷积方法应用于恒河猴的FFRENV和FFRTFS对人类语音和具有时变音高模式的点击训练进行测试。我们的分析表明,F0ENV反应可以用高信噪比测量,并且具有几个可能反映脑干激活的光谱时间和地形不同的成分(TFS反应只包含一个可能反映中脑活动的光谱时间成分)。总之,我们的研究结果支持这样的观点,即F0组件的延迟有意义地映射到连续的处理阶段。这开启了一种可能性,即病理性改变的FFRENV或FFRTFS可能与改变的F0ENV或F0TFS有关,并由此进入特定的加工阶段,最终实现空间靶向干预。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Neurobiology of Language
Neurobiology of Language Social Sciences-Linguistics and Language
CiteScore
5.90
自引率
6.20%
发文量
32
审稿时长
17 weeks
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