Centre for Systematic Musicology, University of Graz, Graz A-8010, Austria
Department of Neurology, Section of Biomagnetism, University of Heidelberg Medical School, Heidelberg D-69120, Germany.
J Neurosci. 2023 Sep 13;43(37):6430-6446. doi: 10.1523/JNEUROSCI.0274-23.2023. Epub 2023 Aug 21.
Auditory perception is fundamental to human development and communication. However, no long-term studies have been performed on the plasticity of the auditory system as a function of musical training from childhood to adulthood. The long-term interplay between developmental and training-induced neuroplasticity of auditory processing is still unknown. We present results from AMseL (Audio and Neuroplasticity of Musical Learning), the first longitudinal study on the development of the human auditory system from primary school age until late adolescence. This 12-year project combined neurologic and behavioral methods including structural magnetic resonance imaging (MRI), magnetoencephalography (MEG), and auditory tests. A cohort of 112 typically developing participants (51 male, 61 female), classified as "musicians" ( = 66) and "nonmusicians" ( = 46), was tested at five measurement timepoints. We found substantial, stable differences in the morphology of auditory cortex (AC) between musicians and nonmusicians even at the earliest ages, suggesting that musical aptitude is manifested in macroscopic neuroanatomical characteristics. Maturational plasticity led to a continuous increase in white matter myelination and systematic changes of the auditory evoked P1-N1-P2 complex (decreasing latencies, synchronization effects between hemispheres, and amplitude changes) regardless of musical expertise. Musicians showed substantial training-related changes at the neurofunctional level, in particular more synchronized P1 responses and bilaterally larger P2 amplitudes. Musical training had a positive influence on elementary auditory perception (frequency, tone duration, onset ramp) and pattern recognition (rhythm, subjective pitch). The observed interplay between "nature" (stable biological dispositions and natural maturation) and "nurture" (learning-induced plasticity) is integrated into a novel neurodevelopmental model of the human auditory system. We present results from AMseL (Audio and Neuroplasticity of Musical Learning), a 12-year longitudinal study on the development of the human auditory system from childhood to adulthood that combined structural magnetic resonance imaging (MRI), magnetoencephalography (MEG), and auditory discrimination and pattern recognition tests. A total of 66 musicians and 46 nonmusicians were tested at five timepoints. Substantial, stable differences in the morphology of auditory cortex (AC) were found between the two groups even at the earliest ages, suggesting that musical aptitude is manifested in macroscopic neuroanatomical characteristics. We also observed neuroplastic and perceptual changes with age and musical practice. This interplay between "nature" (stable biological dispositions and natural maturation) and "nurture" (learning-induced plasticity) is integrated into a novel neurodevelopmental model of the human auditory system.
听觉感知是人类发展和交流的基础。然而,目前还没有研究从儿童期到成年期的音乐训练对听觉系统可塑性的长期影响。发育和训练诱导的听觉处理神经可塑性之间的长期相互作用仍然未知。我们展示了 AMseL(音乐学习的听觉和神经可塑性)的研究结果,这是第一项关于人类听觉系统从小学年龄到青春期后期发展的纵向研究。该 12 年项目结合了神经科学和行为学方法,包括结构磁共振成像(MRI)、脑磁图(MEG)和听觉测试。一个由 112 名典型发展的参与者(51 名男性,61 名女性)组成的队列,分为“音乐家”( = 66)和“非音乐家”( = 46),在五个测量时间点进行了测试。我们发现,即使在最早的年龄,音乐家和非音乐家之间的听觉皮层(AC)形态也存在显著且稳定的差异,这表明音乐才能表现在宏观神经解剖学特征上。成熟可塑性导致白质髓鞘形成的持续增加和听觉诱发 P1-N1-P2 复合波的系统变化(潜伏期缩短、半球间的同步效应以及幅度变化),而与音乐专业知识无关。音乐家在神经功能水平上表现出与训练相关的显著变化,特别是更同步的 P1 反应和双侧更大的 P2 幅度。音乐训练对基本听觉感知(频率、音长、起始斜坡)和模式识别(节奏、主观音高)有积极影响。观察到的“天性”(稳定的生物倾向和自然成熟)和“教养”(学习诱导的可塑性)之间的相互作用被整合到一个新的人类听觉系统神经发育模型中。我们展示了 AMseL(音乐学习的听觉和神经可塑性)的研究结果,这是一项 12 年的纵向研究,研究了从儿童期到成年期人类听觉系统的发展,该研究结合了结构磁共振成像(MRI)、脑磁图(MEG)以及听觉辨别和模式识别测试。共有 66 名音乐家和 46 名非音乐家在五个时间点进行了测试。即使在最早的年龄,两组之间的听觉皮层(AC)形态也存在显著且稳定的差异,这表明音乐才能表现在宏观神经解剖学特征上。我们还观察到了随着年龄和音乐实践的神经可塑性和感知变化。这种“天性”(稳定的生物倾向和自然成熟)和“教养”(学习诱导的可塑性)之间的相互作用被整合到一个新的人类听觉系统神经发育模型中。
