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Rhythmicity of neuronal oscillations delineates their cortical and spectral architecture.

Vladislav MyrovFelix SiebenhühnerJoonas J JuvonenGabriele ArnulfoJ Matias PalvaJ Matias Palva
Published in: Communications biology (2024)
Neuronal oscillations are commonly analyzed with power spectral methods that quantify signal amplitude, but not rhythmicity or 'oscillatoriness' per se. Here we introduce a new approach, the phase-autocorrelation function (pACF), for the direct quantification of rhythmicity. We applied pACF to human intracerebral stereoelectroencephalography (SEEG) and magnetoencephalography (MEG) data and uncovered a spectrally and anatomically fine-grained cortical architecture in the rhythmicity of single- and multi-frequency neuronal oscillations. Evidencing the functional significance of rhythmicity, we found it to be a prerequisite for long-range synchronization in resting-state networks and to be dynamically modulated during event-related processing. We also extended the pACF approach to measure 'burstiness' of oscillatory processes and characterized regions with stable and bursty oscillations. These findings show that rhythmicity is double-dissociable from amplitude and constitutes a functionally relevant and dynamic characteristic of neuronal oscillations.
Keyphrases
  • resting state
  • functional connectivity
  • working memory
  • cerebral ischemia
  • endothelial cells
  • air pollution
  • high frequency
  • magnetic resonance
  • big data
  • brain injury
  • data analysis
  • machine learning
  • dual energy