One of the benefits musicians derive from their training is an increased ability to detect small differences between sounds. Here, we asked whether musicians’ experience discriminating sounds on the basis of small acoustic differences confers advantages in the subcortical differentiation of closely related speech sounds (e.g., /ba/ and /ga/), distinguishable only by their harmonic spectra (i.e., their second formant trajectories). Although the second formant is particularly important for distinguishing stop consonants, auditory brainstem neurons do not phase-lock to its frequency range (above 1000 Hz). Instead, brainstem neurons convert this high-frequency content into neural response timing differences. As such, speech tokens with higher formant frequencies elicit earlier brainstem responses than those with lower formant frequencies. By measuring the degree to which subcortical response timing differs to the speech syllables /ba/, /da/, and /ga/ in adult musicians and nonmusicians, we reveal that musicians demonstrate enhanced subcortical discrimination of closely related speech sounds. Furthermore, the extent of subcortical consonant discrimination correlates with speech-in-noise perception. Taken together, these findings show a musician enhancement for the neural processing of speech and reveal a biological mechanism contributing to musicians’ enhanced speech perception in noise.
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机译:音乐家从他们的培训中获得的好处之一是增强了检测声音之间细微差异的能力。在这里,我们问到音乐家基于小声学差异来区分声音的经验是否在紧密相关的语音(例如,/ ba /和/ ga /)的皮层下区分方面具有优势,这些区别只能通过其谐波频谱(即第二共振峰轨迹)。尽管第二共振峰对于区分终止辅音特别重要,但听觉脑干神经元并未锁相至其频率范围(高于1000 Hz)。取而代之的是,脑干神经元将这种高频成分转换为神经反应时间差异。这样,共振峰频率较高的语音令牌比共振峰频率较低的语音令牌引起的脑干反应更早。通过测量成年音乐家和非音乐家的皮层下响应时间与语音音节/ ba /,/ da /和/ ga /的差异程度,我们发现音乐家表现出对密切相关的语音的皮层下分辨力的增强。此外,皮层下辅音辨别的程度与语音中的语音感知相关。综上所述,这些发现显示出音乐家对语音神经处理的增强,并揭示了一种生物学机制,有助于音乐家增强对噪声的语音感知能力。
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