Department of Psychiatry, University of Wisconsin-Madison, Madison, USA.
Division of Cerebral Integration, Department of System Neuroscience, National Institute for Physiological Sciences (NIPS), Aichi, Japan; Department of Physiological Sciences, School of Life Sciences, SOKENDAI (The Graduate University for Advanced Studies), Kanagawa, Japan.
Neuroimage. 2021 Jan 1;224:117375. doi: 10.1016/j.neuroimage.2020.117375. Epub 2020 Sep 17.
How coherent neural oscillations are involved in task execution is a fundamental question in neuroscience. Although several electrophysiological studies have tackled this issue, the brain-wide task modulation of neural coherence remains uncharacterized. Here, with a fast fMRI technique, we studied shifts of brain-wide neural coherence across different task states in the ultraslow frequency range (0.01-0.7 Hz). First, we examined whether the shifts of the brain-wide neural coherence occur in a frequency-dependent manner. We quantified the shift of a region's average neural coherence by the inter-state variance of the mean coherence between the region and the rest of the brain. A clustering analysis based on the variance's spatial correlation between frequency components revealed four frequency bands (0.01-0.15 Hz, 0.15-0.37 Hz, 0.37-0.53 Hz, and 0.53-0.7 Hz) showing band-specific shifts of the brain-wide neural coherence. Next, we investigated the similarity of the inter-state variance's spectra between all pairs of regions. We found that regions showing similar spectra correspond to those forming functional modules of the brain network. Then, we investigated the relationship between identified frequency bands and modules' inter-state variances. We found that modules showing the highest variance are those made up of parieto-occipital regions at 0.01-0.15 Hz, while it is replaced with another consisting of frontal regions above 0.15 Hz. Furthermore, these modules showed specific shifting patterns of the mean coherence across states at 0.01-0.15 Hz and above 0.15 Hz, suggesting that identified frequency bands differentially contribute to neural interactions during task execution. Our results highlight that usage of the fast fMRI enables brain-wide investigation of neural coherence up to 0.7 Hz, which opens a promising track for assessment of the large-scale neural interactions in the ultraslow frequency range.
神经振荡的同步性如何参与任务执行是神经科学中的一个基本问题。尽管已有几项电生理研究探讨了这个问题,但大脑整体的任务调制的神经同步性仍未被描述。在这里,我们使用快速 fMRI 技术研究了在超慢频率范围(0.01-0.7 Hz)中不同任务状态下大脑整体神经同步性的变化。首先,我们检验了大脑整体神经同步性的变化是否以频率依赖的方式发生。我们通过区域与大脑其余部分之间的平均相干性的状态间方差来量化区域平均神经同步性的变化。基于频率分量之间方差的空间相关性的聚类分析揭示了四个具有特定频率带的同步性变化:0.01-0.15 Hz、0.15-0.37 Hz、0.37-0.53 Hz 和 0.53-0.7 Hz。其次,我们研究了所有区域对之间的状态间方差谱的相似性。我们发现,表现出相似谱的区域对应于形成大脑网络功能模块的区域。然后,我们研究了已识别的频率带与模块的状态间方差之间的关系。我们发现,表现出最高方差的模块是由 0.01-0.15 Hz 频段的顶枕叶区域组成的模块,而在高于 0.15 Hz 的频段则由额区区域组成的模块代替。此外,这些模块在 0.01-0.15 Hz 和高于 0.15 Hz 的频段之间表现出特定的平均相干性变化模式,这表明已识别的频率带在任务执行过程中对神经相互作用有不同的贡献。我们的结果强调了快速 fMRI 的使用可以对 0.7 Hz 以下的大脑整体神经同步性进行研究,这为评估超慢频率范围内的大规模神经相互作用开辟了一条有前途的途径。
