The Journal of neuroscience : the official journal of the Society for Neuroscience
November 8, 2023
Lindsay P Cameron, Joseph Benetatos, Vern Lewis et al.
88 citations
Serotonergic psychedelics like psilocybin and LSD activate serotonin 5-HT2A receptors in cortical brain regions, altering perception, cognition, and emotions. Their ability to promote neuroplasticity—forming new neural connections and rewiring networks—is thought to underlie therapeutic potential for depression, anxiety, and substance use disorders. These compounds also interact with other serotonin receptor subtypes (5-HT1A, 5-HT2C) and neurotrophin receptors, adding complexity to their effects. Research is exploring nonhallucinogenic derivatives that retain therapeutic benefits without intense psychedelic experiences, potentially reducing adverse reactions. The review also discusses psychedelics as substrates for post-translational protein modification as part of their mechanism.
The Journal of neuroscience : the official journal of the Society for Neuroscience
June 26, 2024
Fynn-Mathis Trautwein, Yoav Schweitzer, Yair Dor-Ziderman et al.
27 citations
Long-term meditators can intentionally reduce the sense of being an embodied self, and this change is linked to decreased high-beta brain activity in the posterior medial cortex. In a study of 46 experienced meditators (19 female, 27 male) who underwent magnetoencephalographic monitoring, those who reported radical disruptions of embodied self-experience—such as loss of agency and a localized first-person perspective—showed the strongest neural reductions. These neural changes correlated with lifetime meditation experience and interview-based reports of experiential shifts, but not with standard self-report questionnaires. The findings suggest that posterior medial cortex oscillations are central to supporting the embodied sense of self.
The Journal of neuroscience : the official journal of the Society for Neuroscience
October 25, 2023
Leila Azizi, Ignacio Polti, Virginie Van Wassenhove
15 citations
The relative duration of alpha brain rhythm bursts (7-14 Hz) during quiet rest predicts how long people retrospectively estimate the rest period lasted, but only when they are not instructed to attend to time. In a magnetoencephalography (MEG) experiment, participants who were unaware they would be asked about time showed that longer alpha burst durations corresponded to longer retrospective time estimates. Alpha burst duration was a better predictor than alpha power or burst amplitude, and no other brain rhythms predicted retrospective duration. When participants timed prospectively, alpha bursts did not predict their estimates. A control experiment showed the relation persists even during a visual counting task. Alpha bursts may embody discrete states of awareness that constitute episodic timing.
The Journal of neuroscience : the official journal of the Society for Neuroscience
May 14, 2025
Çağatay Demirel, Jarrod Gott, Kristoffer Appel et al.
8 citations
Lucid dreaming, where a person becomes aware they are dreaming, is linked to REM sleep. To overcome previous research limitations, a new preprocessing pipeline was applied to pooled EEG data from multiple labs. Sensor-level differences between lucid and nonlucid REM sleep were minimal, but source-level analysis revealed reduced beta power (12-30 Hz) in right central and parietal areas, including the temporoparietal junction, during lucid dreaming. Alpha-band (8-12 Hz) connectivity increased compared to nonlucid REM sleep. During eye signaling of lucidity, gamma1 power (30-36 Hz) increased in right temporo-occipital regions, including the precuneus, and interhemispheric gamma1 connectivity rose. These patterns suggest shifts in network communication underlying changes in perception, self-awareness, and cognitive control.
The Journal of neuroscience : the official journal of the Society for Neuroscience
February 21, 2024
Yunkai Zhu, Charlotte Li, Camille Hendry et al.
8 citations
A left-lateralized, near-vertex negativity in EEG, occurring 200–300 ms after stimulus onset, distinguishes sine-wave speech tokens perceived as speech from those perceived as noise, even when task-irrelevant. This response, interpreted as a phonological perceptual awareness negativity, was absent for frequency-flipped control tokens never perceived as speech. The P3b component was enhanced only for tokens both perceived as speech and task-relevant. The findings suggest that neural correlates of conscious perception, across different types of conscious content, are most likely midlatency negative-going brain responses in content-specific sensory areas.
The Journal of neuroscience : the official journal of the Society for Neuroscience
May 14, 2025
Diego G Dávila, Andrew McKinstry-Wu, Max B Kelz et al.
5 citations
During wakefulness, people respond to external stimuli, while in dreams or drug-induced dissociated states, vivid internal experiences occur with reduced perception of the outside world. The brain's activity near a critical point between damped and exploding oscillations is linked to conscious experience, and this signature appears in both normal wakefulness and dissociative states but not in dreamless sleep or anesthesia. Using high-density EEG in human male volunteers given escalating ketamine doses, activity became progressively more stable, especially at higher frequencies, as dissociative symptoms increased. This stabilization correlated with reduced ability to perceive external stimuli, not with conscious experience itself. Combining statistical and dynamical measures of criticality may help distinguish wakefulness, dissociation, and unconsciousness.
The Journal of neuroscience : the official journal of the Society for Neuroscience
June 26, 2024
Mahan Hosseini, Alon Zivony, Martin Eimer et al.
5 citations
The N2pc and P3 brain signals, which index selective attention and conscious awareness respectively, are temporally linked. In an experiment with 23 participants monitoring rapid letter and digit streams, dynamic time warping analysis showed that the latencies of these two signals correlated in time, both when participants correctly reported a target digit and when they mistakenly reported a nearby distractor. The link was weaker on distractor intrusion trials. The findings clarify the relationship between attention and access consciousness, and the novel method offers a general approach for assessing temporal links between any two time-series processes.
The Journal of neuroscience : the official journal of the Society for Neuroscience
April 9, 2025
Audrey Dureux, Alessandro Zanini, Azadeh Jafari et al.
3 citations
Ketamine, a drug that blocks NMDA receptors, broadly suppresses brain activity in auditory regions of awake marmoset monkeys, especially when they hear other marmosets' calls. Using ultra-high field fMRI at 9.4 T, the study compared brain responses to vocalizations, scrambled versions, and nonvocal sounds after a subanesthetic dose of ketamine versus saline. Ketamine caused widespread reduction of activations across auditory areas and produced distinct changes in the mediodorsal thalamus and anterior cingulate cortex during vocalization processing. These effects overlap with neural disruptions seen in schizophrenia, suggesting ketamine can model auditory processing deficits in this disorder.
The Journal of neuroscience : the official journal of the Society for Neuroscience
December 11, 2024
Liya Ma, Nupur Katyare, Kevin Johnston et al.
1 citation
Ketamine, an NMDAR antagonist, impairs cognitive control by disrupting frontoparietal dynamics. In macaques performing an antisaccade task, ketamine altered excitation/inhibition balance in the lateral prefrontal and posterior parietal cortices, reduced rule coding in neural oscillations, and lowered frontoparietal coherence in a frequency- and rule-dependent manner. It also decreased bidirectional connectivity between these areas. Greater reductions in connectivity during the delay period of antisaccade trials preceded larger delays in saccade onset under a rule-memorized condition and greater performance deficits under a rule-visible condition. Ketamine also compromised rule coding in prefrontal neurons under both conditions and in parietal neurons only under the rule-visible condition. These results demonstrate how acute NMDAR blockade can reveal mechanisms by which frontoparietal dynamics support cognitive control.
The Journal of neuroscience : the official journal of the Society for Neuroscience
February 3, 2026
Kyle A Brown, Patrick J Morris, Craig J Thomas et al.
The antidepressant effects of ketamine arise from its metabolite (2R,6R)-hydroxynorketamine (2R6R), not from ketamine itself. In mouse hippocampal slices, 2R6R rapidly strengthens synapses and induces long-lasting metaplasticity—a form of plasticity that primes synapses for future change—whereas ketamine alone does not. This rapid and sustained plasticity requires mTOR signaling and can be mimicked by activating mTOR. The sustained phase also depends on IP3 receptors, L-type calcium channels, and delayed BDNF/TrkB signaling, but not on new protein synthesis. The findings outline a sequence of molecular events underlying 2R6R's synaptic actions, with implications for developing rapid-acting antidepressants and understanding activity-dependent plasticity.
The Journal of neuroscience : the official journal of the Society for Neuroscience
November 24, 2025
Mona Irrmischer, Marco Aqil, Lisa Luan et al.
A psychedelic substance (DMT) shifts brain oscillations away from criticality—a state of balanced, complex activity—toward a quieter subcritical regime, particularly in alpha and adjacent frequency bands. This shift increases entropy while reducing complexity. The magnitude of the criticality shift in alpha and theta bands correlates with the intensity of self-dissolution, a core feature of the psychedelic experience. These findings suggest that altered proximity to critical dynamics underlies both the neurological and experiential effects of psychedelics, with implications for understanding altered states of consciousness.