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Frontiers in Systems Neuroscience

7 papers in the library · 83 citations · publishing 2016-2026

Papers

Neural Correlates of Non-ordinary States of Consciousness in Pranayama Practitioners: The Role of Slow Nasal Breathing

Frontiers in Systems Neuroscience March 21, 2022 32 citations

Slow nasal breathing at 2.5 breaths per minute, as practiced in Pranayama, alters brain activity and induces a non-ordinary state of consciousness, primarily through mechanical stimulation of the olfactory epithelium rather than through vagal nerve stimulation. In 12 experienced meditators, slow nasal breathing produced slowing of EEG delta and theta activity in prefrontal regions, widespread increases in theta and high-beta connectivity, increased phase-amplitude coupling between these bands in prefrontal and posterior Default Mode Network regions, and increased small-worldness of high-beta networks. Participants reported a higher perception of being in a non-ordinary state of consciousness compared to mouth breathing at the same rate or resting state.

A scoping review for building a criticality-based conceptual framework of altered states of consciousness

Frontiers in Systems Neuroscience May 25, 2023 Charles Gervais, Louis-Philippe Boucher, Guillermo Martinez Villar et al. 25 citations

The healthy conscious brain is thought to operate near a critical state, balancing order and chaos for optimal information processing. This scoping review of 49 studies across seven altered states of consciousness (ASC)—including disorders of consciousness, sleep, anesthesia, epilepsy, psychedelics, delirium, and meditation—found that each category showed a deviation from this critical state. Most studies could identify a deviation but not its direction; however, a preliminary consensus indicates non-REM sleep reflects a subcritical state, epileptic seizures a supercritical state, and psychedelics are closer to criticality than normal waking consciousness. The evidence is limited and methodologically varied, but criticality may become an objective way to characterize ASC and guide treatments, such as using anesthesia or psychedelics to restore criticality in pathological brain states.

On the character of consciousness

Frontiers in Systems Neuroscience July 1, 2016 Arto eAnnila 18 citations

The brain, as an open thermodynamic system, consumes free energy in the least time across all its processes, from cellular metabolism to cognition and consciousness. This principle, derived from statistical mechanics, treats cognitive operations as identical in organizational principle to other natural processes, emerging along path-dependent, non-determinate trajectories. Consciousness integrates neural networks for coherent free-energy consumption—meaningful action—and the entire hierarchy of systems can be summed up as thermodynamic entropy. The theory also acknowledges awareness in other systems at different levels of nature's hierarchy.

Neurobiology of psilocybin: a comprehensive overview and comparative analysis of experimental models

Frontiers in Systems Neuroscience August 5, 2025 Dotun Adeleye Adeyinka, Donelson R. Forsyth, Suzanne Currie et al. 7 citations

Psilocybin, from Psilocybe mushrooms, shows promise for treating neurodegenerative and psychiatric disorders like major depressive disorder by promoting neuroprotection, neurogenesis, and neuroplasticity. It may help combat mild neurodegeneration by increasing synaptic density and supporting neuronal growth, with low addiction risk and few adverse effects. Animal models, including Drosophila and fish, have provided insights into its mechanisms, aiding high-throughput screening of neural development, behavior, and genetic pathways. While mammalian models are needed for pharmacokinetics and complex nervous system interactions, small non-mammalian models help identify early targets. This complementary approach suggests psilocybin could potentially halt or reverse neurodegenerative processes.

De-anthropomorphizing the mind: life as a cognitive spectrum in a unified framework for biological minds

Frontiers in Systems Neuroscience January 22, 2026 Gordana Dodig-Crnković 1 citation

Cognition is not limited to organisms with nervous systems but is an organizational property of all living systems, from single cells to complex animals. Living systems engage in learning, memory, and goal-directed behavior by transforming information embodied in their physical structures and interactions with the environment. This info-computational (ICON) framework views these processes as present from the start of life, becoming more integrated and temporally extended with increasing biological complexity. It explains how complex cognition, awareness, and mind arise from basic life-regulatory dynamics and generates testable implications for basal cognition, developmental biology, and embodied artificial systems.

Autonomic-salience stability as a candidate Gate for awake low-dose ketamine: a systems neuroscience framework with a clinical anchor

Frontiers in Systems Neuroscience July 1, 2026 Kei Torii, Maho Jinno

Ketamine's effects vary across patients and sessions, so dose alone does not explain them. A Gate-Amplifier-Reintegration framework proposes that awake low-dose ketamine amplifies transient network flexibility, while autonomic-salience stability acts as a Gate that may steer this flexibility toward reintegration or dysphoric dissociation. The three-step sequence involves Gate (candidate autonomic-salience stability), Amplifier (ketamine under conditions preserving vigilance), and Reintegration (organizing flexibility into language, attention, and action). Heart-rate variability serves as a peripheral state-verification proxy. The framework is informed by nonrandomized clinical observations from a single-center outpatient chronic pain care pathway, which provide clinical provenance but not comparative efficacy evidence. Falsifiable predictions include prospective Gate manipulation altering pre-dose autonomic state and randomized designs testing mediation of tolerability and clinical change.

The neurobiological basis of the awe experience in affective disorders: an exploratory EEG study

Frontiers in Systems Neuroscience June 4, 2026 Elena Bondi, Flavia Carbone, Giandomenico Schiena et al.

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.