Identification of oscillatory brain networks with Hidden Gaussian Graphical Spectral models of EEG/MEG
- Resource Type
- Working Paper
- Authors
- Paz-Linares, Deirel; Gonzalez-Moreira, Eduardo; Areces-Gonzalez, Ariosky; Wang, Ying; Li, Min; Martinez-Montes, Eduardo; Bosch-Bayard, Jorge; Bringas-Vega, Maria L.; Valdes-Sosa, Mitchel J.; Valdes-Sosa, Pedro A.
- Source
- Subject
- Statistics - Methodology
Quantitative Biology - Neurons and Cognition
- Language
Identifying the functional networks underpinning indirectly observed processes poses an inverse problem for neurosciences or other fields. A solution of such inverse problems estimates as a first step the activity emerging within functional networks from EEG or MEG data. These EEG or MEG estimates are a direct reflect functional brain network activity with a temporal resolution that no other in vivo neuroimage may provide. A second step estimating functional connectivity from such activity pseudodata unveil the oscillatory brain networks that strongly correlate with all cognition and behavior. Simulations of such MEG or EEG inverse problem also reveal estimation errors of the functional connectivity determined by any of the state-of-the-art inverse solutions. We disclose a significant cause of estimation errors originating from misspecification of the functional network model incorporated into either inverse solution steps. We introduce the Bayesian identification of a Hidden Gaussian Graphical Spectral (HIGGS) model specifying such oscillatory brain networks model. In human EEG alpha rhythm simulations estimation errors measured as ROC performance do not surpass 2% in our HIGGS inverse solution and reach 20% in state-of-the-art methods. Macaque simultaneous EEG/ECoG recordings provide experimental confirmation for our inverse-solution with 1/3 more congruence according to Riemannian distances than state-of-the-art methods.