Frequency domain connectivity identification: An application of partial directed coherence in fMRI

João R. Sato, Daniel Y. Takahashi, Silvia M. Arcuri, Koichi Sameshima, Pedro A. Morettin, Luiz A. Baccalá
2007 Human Brain Mapping  
Functional magnetic resonance imaging (fMRI) has become an important tool in Neuroscience due to its noninvasive and high spatial resolution properties compared to other methods like PET or EEG. Characterization of the neural connectivity has been the aim of several cognitive researches, as the interactions among cortical areas lie at the heart of many brain dysfunctions and mental disorders. Several methods like correlation analysis, structural equation modeling, and dynamic causal models have
more » ... been proposed to quantify connectivity strength. An important concept related to connectivity modeling is Granger causality, which is one of the most popular definitions for the measure of directional dependence between time series. In this article, we propose the application of the partial directed coherence (PDC) for the connectivity analysis of multisubject fMRI data using multivariate bootstrap. PDC is a frequency domain counterpart of Granger causality and has become a very prominent tool in EEG studies. The achieved frequency decomposition of connectivity is useful in separating interactions from neural modules from those originating in scanner noise, breath, and heart beating. Real fMRI dataset of six subjects executing a language processing protocol was used for the analysis of connectivity. Hum Brain Mapp 00:000-000, 2007. V V C 2007 Wiley-Liss, Inc. Figure 5. ROIs' multisubject median partial directed coherence. The dotted line shows the 95% confidence upper bound under the hypothesis of no connectivity between the nodes. r Frequency Domain Connectivity Identification AQ1 r r 7 r
doi:10.1002/hbm.20513 pmid:18064582 fatcat:johtfjk4arfi7egqfsnsprns7u