The neurobiological basis of the awe experience in affective disorders: an exploratory EEG study
Elena Bondi, Flavia Carbone, Giandomenico Schiena, Yara Massalha, Mariapia Marra, Lorena di Consoli, Maddalena Mazzocut-mis, Andrea Gaggioli, Alice Chirico, Paolo Brambilla, Eleonora Maggioni
Frontiers in Systems Neuroscience June 4, 2026 Peer reviewed DOI: 10.3389/fnsys.2026.1805778 via OpenAlex
Summary
People with affective disorders (ADs) show emotional processing deficits involving disrupted brain network activity, especially in default mode and fronto-temporal circuits with abnormal theta and alpha oscillations. This exploratory study used virtual reality (VR) scenarios to induce awe—a self-transcendent emotion that may reduce rumination and boost positive affect—while recording EEG in ADs and healthy controls (HCs). HCs exhibited high awe responses with scenario-specific modulations in alpha and theta band activity and connectivity, indicating preserved cognitive flexibility.
Study at a glance
| Design | exploratory study |
|---|---|
| Population | individuals with affective disorders and healthy controls |
| Key finding | People with affective disorders showed reduced environmental differentiation in awe responses and elevated theta power in bilateral frontal and temporal regions compared to healthy controls, along with more pronounced VR-induced reductions in alpha-band global efficiency. |
Abstract
Introduction: Affective disorders (ADs) are characterized by profound emotional processing deficits involving disrupted neural network activity and connectivity, particularly within the default mode network and fronto-temporal circuits, with abnormalities in theta and alpha oscillatory patterns. While current treatments primarily target mood symptoms, emotional processing impairments often persist and predict relapses. Awe, a complex self-transcendent emotion, may counteract such deficits through its capacity to reduce rumination and enhance positive affect. However, the neural correlates of awe experiences in clinical populations remain unexplored. Objective: For the first time, this exploratory study investigated the electroencephalographic (EEG) correlates of awe induced by validated virtual reality (VR) scenarios in individuals with ADs compared to healthy controls (HCs). Methods: Participants were exposed to immersive VR scenarios designed to elicit different awe experiences (mountains, waterfall, Earth) and a reference (awe-neutral) scenario. EEG activity was recorded during VR exposure and at baseline, followed by emotional state questionnaires. Power spectral density and graph-theoretical connectivity indices - Nodal Positive Strength and Global Efficiency - were computed across theta, alpha, and beta bands. Results: Healthy controls showed high awe responses in awe-inducing scenarios with selective, scenario-specific modulations in alpha and theta band activity and connectivity, reflecting preserved cognitive flexibility. Conversely, ADs reported similar awe responses across all VR scenarios with reduced environmental differentiation. With respect to HCs, ADs showed elevated theta power in bilateral frontal and temporal regions, suggesting compensatory activity related to emotional processing alterations. Both groups exhibited VR-induced reductions in alpha-band global efficiency, more pronounced in ADs, suggesting compromised neural integration during complex emotional processing. Discussion: Taken together, the results suggest that the emotional processing deficits inherent to ADs may limit the capacity to engage differentially with emotionally complex stimuli such as awe, while nonetheless providing initial evidence that VR-based awe exposure combined with neurophysiological recording represents a valuable approach for discriminating differential cerebral emotional responses in clinical populations. This proof-of-concept work warrants further investigation in larger cohorts to evaluate the therapeutic potential of awe-based interventions for affective disorders.