听觉外围可解释大脑皮层对隐约信号源的反应

IF 3.2 2区 心理学 Q1 BEHAVIORAL SCIENCES
Sarah Benghanem , Rudradeep Guha , Estelle Pruvost-Robieux , Julie Lévi-Strauss , Coralie Joucla , Alain Cariou , Martine Gavaret , Jean-Julien Aucouturier
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引用次数: 0

摘要

大量行为学证据表明,与渐行渐远的声音相比,强度越来越大的声音(即似乎正向听者逼近的声音)在处理时会耗费更多的注意力和生理资源。然而,导致这种认知放大的神经生理学机制仍然难以捉摸。在这里,我们证明了大脑皮层对逼近声音和后退声音的反应之间的巨大差异实际上几乎完全可以用听觉外围水平的非线性编码来解释。我们在一个奇特的范例中收集了脑电图(EEG)数据,以诱发错配负性(MMN)和其他事件相关电位(EPRs),从而对同一参与者中与标准有动态(隐现和后退)和恒定水平(平缓)差异的偏差刺激做出反应。然后,我们将听觉外周的计算模型与脑电图生成方法(时间反应函数,TRFs)相结合,建立了单个参与者对平坦偏差的ERPs反应模型,并用它们来预测同一机制对隐现和后退刺激的影响。平面模型解释了 45% 的隐现反应方差和 33% 的后退反应方差。这提供了惊人的证据,证明对 "逼近 "和 "后退 "声音的差异波反应是由相同的大脑皮层机制产生的,这种机制也产生了对恒定水平偏差的反应:所有这些差异都是它们的特殊物理形态被外周听觉机制放大和整合的唯一结果。因此,在大脑皮层看到的所有效应并非都来自高层次决策变量自上而下的调节,而是可以通过前馈式外围机制早期有效地实现。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Cortical responses to looming sources are explained away by the auditory periphery

A wealth of behavioral evidence indicate that sounds with increasing intensity (i.e. appear to be looming towards the listener) are processed with increased attentional and physiological resources compared to receding sounds. However, the neurophysiological mechanism responsible for such cognitive amplification remains elusive. Here, we show that the large differences seen between cortical responses to looming and receding sounds are in fact almost entirely explained away by nonlinear encoding at the level of the auditory periphery. We collected electroencephalography (EEG) data during an oddball paradigm to elicit mismatch negativity (MMN) and others Event Related Potentials (EPRs), in response to deviant stimuli with both dynamic (looming and receding) and constant level (flat) differences to the standard in the same participants. We then combined a computational model of the auditory periphery with generative EEG methods (temporal response functions, TRFs) to model the single-participant ERPs responses to flat deviants, and used them to predict the effect of the same mechanism on looming and receding stimuli. The flat model explained 45% variance of the looming response, and 33% of the receding response. This provide striking evidence that difference wave responses to looming and receding sounds result from the same cortical mechanism that generate responses to constant-level deviants: all such differences are the sole consequence of their particular physical morphology getting amplified and integrated by peripheral auditory mechanisms. Thus, not all effects seen cortically proceed from top-down modulations by high-level decision variables, but can rather be performed early and efficiently by feed-forward peripheral mechanisms that evolved precisely to sparing subsequent networks with the necessity to implement such mechanisms.

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来源期刊
Cortex
Cortex 医学-行为科学
CiteScore
7.00
自引率
5.60%
发文量
250
审稿时长
74 days
期刊介绍: CORTEX is an international journal devoted to the study of cognition and of the relationship between the nervous system and mental processes, particularly as these are reflected in the behaviour of patients with acquired brain lesions, normal volunteers, children with typical and atypical development, and in the activation of brain regions and systems as recorded by functional neuroimaging techniques. It was founded in 1964 by Ennio De Renzi.
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