University College London Speech, Hearing and Phonetic Sciences, University College London Division of Psychology and Language Sciences, London, United Kingdom.
PLoS One. 2011;6(9):e24672. doi: 10.1371/journal.pone.0024672. Epub 2011 Sep 30.
The well-established left hemisphere specialisation for language processing has long been claimed to be based on a low-level auditory specialization for specific acoustic features in speech, particularly regarding 'rapid temporal processing'.
A novel analysis/synthesis technique was used to construct a variety of sounds based on simple sentences which could be manipulated in spectro-temporal complexity, and whether they were intelligible or not. All sounds consisted of two noise-excited spectral prominences (based on the lower two formants in the original speech) which could be static or varying in frequency and/or amplitude independently. Dynamically varying both acoustic features based on the same sentence led to intelligible speech but when either or both acoustic features were static, the stimuli were not intelligible. Using the frequency dynamics from one sentence with the amplitude dynamics of another led to unintelligible sounds of comparable spectro-temporal complexity to the intelligible ones. Positron emission tomography (PET) was used to compare which brain regions were active when participants listened to the different sounds.
Neural activity to spectral and amplitude modulations sufficient to support speech intelligibility (without actually being intelligible) was seen bilaterally, with a right temporal lobe dominance. A left dominant response was seen only to intelligible sounds. It thus appears that the left hemisphere specialisation for speech is based on the linguistic properties of utterances, not on particular acoustic features.
长期以来,人们一直认为语言处理的左半球专门化是基于语音特定声学特征的低级听觉专门化,特别是关于“快速时间处理”。
使用一种新的分析/合成技术,根据可以在频谱时间复杂度上进行操作的简单句子构建各种声音,以及它们是否可理解。所有声音都由两个噪声激发的频谱突出(基于原始语音中的较低两个共振峰)组成,它们可以是静态的或频率和/或幅度独立变化的。基于相同句子动态变化这两个声学特征会导致可理解的语音,但当任何一个或两个声学特征为静态时,刺激就不可理解。使用一个句子的频率动态和另一个句子的幅度动态导致具有可比频谱时间复杂度的不可理解的声音。正电子发射断层扫描 (PET) 用于比较参与者在听不同声音时哪些大脑区域活跃。
足以支持语音可理解性(而实际上不可理解)的频谱和幅度调制的神经活动在双侧出现,右颞叶占主导地位。仅对可理解的声音出现左侧主导反应。因此,言语的左半球专门化似乎是基于话语的语言属性,而不是特定的声学特征。
