Lithari Chrysa, Moratti Stephan, Weisz Nathan
Center for Mind/Brain Sciences, CIMeC, University of Trento, Italy.
Departamento De Psicología Básica I, Universidad Complutense De Madrid, Spain.
Hum Brain Mapp. 2015 Nov;36(11):4592-603. doi: 10.1002/hbm.22940. Epub 2015 Aug 19.
Despite a strong focus on the role of the amygdala in fear conditioning, recent works point to a more distributed network supporting fear conditioning. We aimed to elucidate interactions between subcortical and cortical regions in fear conditioning in humans. To do this, we used two fearful faces as conditioned stimuli (CS) and an electrical stimulation at the left hand, paired with one of the CS, as unconditioned stimulus (US). The luminance of the CS was rhythmically modulated leading to "entrainment" of brain oscillations at a predefined modulation frequency. Steady-state responses (SSR) were recorded by MEG. In addition to occipital regions, spectral analysis of SSR revealed increased power during fear conditioning particularly for thalamus and cerebellum contralateral to the upcoming US. Using thalamus and amygdala as seed-regions, directed functional connectivity was calculated to capture the modulation of interactions that underlie fear conditioning. Importantly, this analysis showed that the thalamus drives the fusiform area during fear conditioning, while amygdala captures the more general effect of fearful faces perception. This study confirms ideas from the animal literature, and demonstrates for the first time the central role of the thalamus in fear conditioning in humans.
尽管人们强烈关注杏仁核在恐惧条件反射中的作用,但最近的研究指出,存在一个更广泛分布的网络支持恐惧条件反射。我们旨在阐明人类恐惧条件反射中皮层下和皮层区域之间的相互作用。为此,我们使用两张恐惧面孔作为条件刺激(CS),并在左手进行电刺激,将其与其中一个CS配对,作为非条件刺激(US)。CS的亮度有节奏地调制,导致大脑振荡在预定义的调制频率下“同步化”。通过脑磁图(MEG)记录稳态反应(SSR)。除枕叶区域外,SSR的频谱分析显示,在恐惧条件反射期间功率增加,特别是在即将到来的US对侧的丘脑和小脑中。以丘脑和杏仁核作为种子区域,计算定向功能连接以捕捉恐惧条件反射背后的相互作用调制。重要的是,该分析表明,在恐惧条件反射期间丘脑驱动梭状回区域,而杏仁核捕捉恐惧面孔感知的更普遍效应。这项研究证实了动物文献中的观点,并首次证明了丘脑在人类恐惧条件反射中的核心作用。