Cognition requires the coordinated interaction of structurally and functionally diverse brain areas. Neuronal oscillations have been linked to a multitude of cognitive processes, are disturbed in neuropsychiatric diseases and have been recently revealed, through non-invasive magnetoencephalography (MEG) recordings, to be unique to each area. However, the detailed spatio-temporal organization of these “spectral fingerprints”, their potential co-variation with structural properties of the brain, as well as their subject-specificity and individual differences have not been characterized. For that reason, I propose, first, to characterize these properties using a large existing MEG data set of a healthy population provided by the Human Connectome Project. Together, spectral, temporal, spatial and structural information, as well as their variation in healthy individuals, will provide an extensive characterization of area-specific neural processing and is a crucial step for establishing spectral fingerprints as biomarkers to be compared, in future work, with a diseased population. Moreover, spectral fingerprints will inform and improve computational whole-brain models. Specifically, established models, spatially resolved at the level of cortical areas, possess unrealistic power spectra. I therefore propose, second, to develop a new generation of whole-brain models with more realistic power spectra and to infer the underlying neural circuitry parameters by constraining these models with each area’s spectral fingerprint. Computational modeling in combination with non-invasively obtainable biomarkers can reveal disturbances in neural circuit parameters in diseased individuals and can thereby hint at neural circuit mechanisms of neuropsychiatric diseases which remain poorly understood.

DFG Programme Research Fellowships

International Connection USA

Host Professor John D. Murray, Ph.D.