Musical neurodynamics

IF 26.7 1区医学 Q1 NEUROSCIENCES

Nature Reviews Neuroscience Pub Date : 2025-03-18 DOI:10.1038/s41583-025-00915-4

Eleanor E. Harding, Ji Chul Kim, Alexander P. Demos, Iran R. Roman, Parker Tichko, Caroline Palmer, Edward W. Large

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Abstract

A great deal of research in the neuroscience of music suggests that neural oscillations synchronize with musical stimuli. Although neural synchronization is a well-studied mechanism underpinning expectation, it has even more far-reaching implications for music. In this Perspective, we survey the literature on the neuroscience of music, including pitch, harmony, melody, tonality, rhythm, metre, groove and affect. We describe how fundamental dynamical principles based on known neural mechanisms can explain basic aspects of music perception and performance, as summarized in neural resonance theory. Building on principles such as resonance, stability, attunement and strong anticipation, we propose that people anticipate musical events not through predictive neural models, but because brain–body dynamics physically embody musical structure. The interaction of certain kinds of sounds with ongoing pattern-forming dynamics results in patterns of perception, action and coordination that we collectively experience as music. Statistically universal structures may have arisen in music because they correspond to stable states of complex, pattern-forming dynamical systems. This analysis of empirical findings from the perspective of neurodynamic principles sheds new light on the neuroscience of music and what makes music powerful. In this Perspective article, Edward Large and colleagues examine the neuroscience of music, placing their focus on neural resonance theory, which summarizes how the dynamics of fundamental neural mechanisms can explain various aspects of music perception and performance.

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音乐神经动力学

大量关于音乐的神经科学研究表明，神经振荡与音乐刺激同步。尽管神经同步是一种被充分研究的支持期望的机制，但它对音乐的影响更为深远。在这个视角中，我们调查了音乐神经科学方面的文献，包括音高、和声、旋律、调性、节奏、韵律、凹槽和情感。我们描述了基于已知神经机制的基本动力学原理如何解释音乐感知和表演的基本方面，如神经共振理论所总结的那样。基于共振、稳定性、调音和强预期等原理，我们提出人们不是通过预测性神经模型来预测音乐事件，而是因为脑-体动力学在物理上体现了音乐结构。某些种类的声音与持续的模式形成动力学的相互作用产生了我们共同体验的音乐的感知、行动和协调模式。统计上普遍的结构可能在音乐中出现，因为它们对应于复杂的、形成模式的动力系统的稳定状态。从神经动力学原理的角度对经验发现进行分析，为音乐的神经科学以及音乐的力量提供了新的视角。

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来源期刊

Nature Reviews Neuroscience NEUROSCIENCES-

自引率

0.60%

发文量

104

期刊介绍： Nature Reviews Neuroscience is a multidisciplinary journal that covers various fields within neuroscience, aiming to offer a comprehensive understanding of the structure and function of the central nervous system. Advances in molecular, developmental, and cognitive neuroscience, facilitated by powerful experimental techniques and theoretical approaches, have made enduring neurobiological questions more accessible. Nature Reviews Neuroscience serves as a reliable and accessible resource, addressing the breadth and depth of modern neuroscience. It acts as an authoritative and engaging reference for scientists interested in all aspects of neuroscience.