Cerebral electrometabolic coupling in disordered and normal states of consciousness

We assess cerebral integrity with cortical and subcortical FDG-PET and cortical electroencephalography (EEG) within the mesocircuit model framework in patients with disorders of consciousness (DoCs). The mesocircuit hypothesis proposes that subcortical activation facilitates cortical function. We find that the metabolic balance of subcortical mesocircuit areas is informative for diagnosis and is associated with four EEG-based power spectral density patterns, cortical metabolism, and a power in healthy controls and patients with a DoC. Last, regional electrometabolic coupling at the cortical level can be identified in the q and a ranges, showing positive and negative relations with glucose uptake, respectively. This relation is inverted in patients with a DoC, potentially related to altered orchestration of neural activity, and may underlie suboptimal excitability states in patients with a DoC. By understanding the neurobiological basis of the pathophysiology underlying DoCs, we foresee translational value for diagnosis and treatment of patients with a DoC.

Automated summary

We use FDG-PET and EEG to assess cerebral integrity in patients with DoCs within the mesocircuit model framework. Subcortical activation facilitates cortical function according to the mesocircuit hypothesis. The metabolic balance of subcortical mesocircuit areas is informative for diagnosis and is associated with EEG patterns, cortical metabolism, and excitability states in both healthy controls and patients with DoCs. Understanding the pathophysiology of DoCs has translational value for diagnosis and treatment.