文章基本信息

标题：Functional asymmetry and effective connectivity of the auditory system during speech perception is modulated by the place of articulation of the consonant- A 7T fMRI study
本地全文：下载
作者：Specht, Karsten ; Baumgartner, Florian ; Stadler, Jörg 等
期刊名称：Frontiers in Psychology
电子版ISSN：1664-1078
出版年度：2014
卷号：5
页码：1-10
DOI：10.3389/fpsyg.2014.00549
出版社：Frontiers Media
摘要：To differentiate between stop-consonants, the auditory system has to detect subtle place of articulation (PoA) and voice onset time (VOT) differences between stop-consonants. How this differential processing is represented on the cortical level remains unclear. The present functional magnetic resonance (fMRI) study takes advantage of the superior spatial resolution and high sensitivity of ultra high field 7T MRI. Subjects were attentively listening to consonant-vowel syllables with an alveolar or bilabial stop-consonant and either a short or long voice-onset time. The results showed an overall bilateral activation pattern in the posterior temporal lobe during the processing of the consonant-vowel syllables. This was however modulated strongest by place of articulation such that syllables with an alveolar stop-consonant showed stronger left lateralized activation. In addition, analysis of underlying functional and effective connectivity revealed an inhibitory effect of the left planum temporale onto the right auditory cortex during the processing of alveolar consonant-vowel syllables. Further, the connectivity result indicated also a directed information flow from the right to the left auditory cortex, and further to the left planum temporale for all syllables. These results indicate that auditory speech perception relies on an interplay between the left and right auditory cortex, with the left planum temporale as modulator. Furthermore, the degree of functional asymmetry is determined by the acoustic properties of the consonant-vowel syllables.
关键词：functional magnetic resonance imaging; Auditory Cortex; place of articulation; voice onset time; dynamic causal modelling; ultra-high field