Behavioral and brain oscillatory correlates of affective processing in subclinical depression.

Named among the most dangerous diseases of the modern era, depression is characterized primarily by distortions in the affective sphere. Despite extensive investigations of underlying the neural background, mechanisms of the distortion still remain unknown. The current study analyzed brain oscillatory dynamics in different frequencies during resting state and presentation of affective stimuli in nonclinical individuals with high Beck Depression Inventory-II (BDI-II) scores (HB) versus controls. Both behavioral and electrocortical "markers" of clinical depression were apparent at subclinical level. A resting-state electroencephalogram (EEG) of HB revealed increased power in low frequencies, predominantly in the frontal cortical areas, that is in accordance with a "spatio-temporal dysfunction" model of depression. Related to that, transition from an eyes-closed to eyes-open condition was associated with diminished alpha blockade in HB, suggesting difficulties with the relocation of attention focus from inner processes toward environmental stimuli. Subsequently, independently of a sign of emotion, five out of six discrete emotions were evaluated as less valenced and four out of six as less intense by HB than by controls, corroborating the view of emotion context insensitivity (ECI) associated with depression. Underlying brain oscillatory dynamics revealed that depression was associated with deficits in the early, implicit, processing stages of emotional stimuli. Later processing stages were characterized by prominent power surges in low and alpha frequencies, presumably indicating emotion upregulation processes and increased engagement of cognitive mechanisms in affective tasks. The study provides brain oscillatory-based mechanisms of emotion processing distortions associated with depression.