Cross-Frequency Brain Network Dynamics Support Pitch Change Detection.

Bijblijven (Amsterdam, Netherlands) Pub Date : 2022-05-04 Epub Date: 2022-03-29 DOI:10.1523/JNEUROSCI.0630-21.2022
Soheila Samiee, Dominique Vuvan, Esther Florin, Philippe Albouy, Isabelle Peretz, Sylvain Baillet
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Abstract

Processing auditory sequences involves multiple brain networks and is crucial to complex perception associated with music appreciation and speech comprehension. We used time-resolved cortical imaging in a pitch change detection task to detail the underlying nature of human brain network activity, at the rapid time scales of neurophysiology. In response to tone sequence presentation to the participants, we observed slow inter-regional signaling at the pace of tone presentations (2-4 Hz) that was directed from auditory cortex toward both inferior frontal and motor cortices. Symmetrically, motor cortex manifested directed influence onto auditory and inferior frontal cortices via bursts of faster (15-35 Hz) activity. These bursts occurred precisely at the expected latencies of each tone in a sequence. This expression of interdependency between slow/fast neurophysiological activity yielded a form of local cross-frequency phase-amplitude coupling in auditory cortex, which strength varied dynamically and peaked when pitch changes were anticipated. We clarified the mechanistic relevance of these observations in relation to behavior by including a group of individuals afflicted by congenital amusia, as a model of altered function in processing sound sequences. In amusia, we found a depression of inter-regional slow signaling toward motor and inferior frontal cortices, and a chronic overexpression of slow/fast phase-amplitude coupling in auditory cortex. These observations are compatible with a misalignment between the respective neurophysiological mechanisms of stimulus encoding and internal predictive signaling, which was absent in controls. In summary, our study provides a functional and mechanistic account of neurophysiological activity for predictive, sequential timing of auditory inputs.SIGNIFICANCE STATEMENT Auditory sequences are processed by extensive brain networks, involving multiple systems. In particular, fronto-temporal brain connections participate in the encoding of sequential auditory events, but so far, their study was limited to static depictions. This study details the nature of oscillatory brain activity involved in these inter-regional interactions in human participants. It demonstrates how directed, polyrhythmic oscillatory interactions between auditory and motor cortical regions provide a functional account for predictive timing of incoming items in an auditory sequence. In addition, we show the functional relevance of these observations in relation to behavior, with data from both normal hearing participants and a rare cohort of individuals afflicted by congenital amusia, which we considered here as a model of altered function in processing sound sequences.

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跨频率脑网络动力学支持音高变化检测
听觉序列的处理涉及多个大脑网络,对于与音乐欣赏和语音理解相关的复杂感知至关重要。我们在一项音调变化检测任务中使用了时间分辨皮层成像技术,以神经生理学的快速时间尺度详细了解人类大脑网络活动的基本性质。在向参与者呈现音调序列时,我们观察到音调呈现速度(2-4 Hz)缓慢的区域间信号传导,这些信号从听觉皮层传向下额叶和运动皮层。与此对应的是,运动皮层通过速度更快(15-35 Hz)的突发性活动对听觉皮层和下额叶皮层产生定向影响。这些爆发恰好发生在序列中每个音调的预期潜伏期。这种慢/快神经生理活动之间相互依存的表现形式在听觉皮层中产生了一种局部跨频率相位-振幅耦合,其强度动态变化,并在预期音高变化时达到峰值。我们将一组患有先天性失聪症的人作为声音序列处理功能改变的模型,从而阐明了这些观察结果与行为的机理相关性。在失聪症患者中,我们发现向运动皮层和下额叶皮层的区域间慢信号传导受到抑制,而听觉皮层的慢/快相位-振幅耦合长期过度表达。这些观察结果与刺激编码和内部预测信号之间各自的神经生理机制之间的错位是一致的,而对照组中不存在这种错位。总之,我们的研究为听觉输入的预测性顺序计时的神经生理活动提供了功能和机制上的解释。尤其是大脑前颞连接参与了顺序听觉事件的编码,但迄今为止,对它们的研究仅限于静态描述。本研究详细介绍了人类参与者参与这些区域间互动的大脑振荡活动的性质。它展示了听觉和运动皮层区域之间的定向、多节律振荡相互作用如何为预测听觉序列中进入项目的时间提供功能性解释。此外,我们还展示了这些观察结果与行为的功能相关性,数据来自听力正常的参与者和罕见的先天性失神症患者。
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