Paper detail

Cortical Xi-Alpha model for resting state electric neuronal activity

Power spectra of awake resting state EEG recordings in humans typically have an Alpha peak at around 10 Hz riding a decreasing background "Xi process". Normal and pathological variations may have more than one peak or none. The single channel Xi-Alpha model (Pascual-Marqui et al 1988, https://doi.org/10.3109/00207458808985730) separated these two processes, providing a low-dimensional parametric description of EEG spectra. Currently lacking is a generative whole cortex model for activity spectra and intracortical functional connectivity. Here we introduce the "cortical Xi-Alpha model". The cross-spectral density matrices are modeled as additive components, each one consisting of a scalar spectrum that multiplies a frequency invariant Hermitian covariance matrix. This simple "separation of variables" form offers a very rich repertoire of spatio-spectral properties, as well as diverse whole cortex functional connectivity patterns. The scalp EEG model conserves the same form, allowing simple estimation from scalp to cortex. Two independent open-access, resting state eyes open and closed EEG data sets (203 participants with 61 electrodes, and 47 participants with 26 electrodes) were used to demonstrate, test, and validate the model. Results summary: - The average dimension of cross-spectra lies between 1.7 and 2.6, indicating two processes. - Non-negative matrix factorization of population power spectra sampled at 6239 cortical voxels with only two components (identified as Xi and Alpha) explains 99% of the variance. - The median value of explained variance was 95% for the "cortical Xi-Alpha model" across all datasets and conditions. - Alpha process generators more occipital, Xi more frontal. - Xi cortical lagged connectivities are isotropic with interdistance. - Laminar recordings suggest layers 2/3 pyramidal neurons generate Xi; layers 5/6 pyramidal neurons generate Alpha.