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Josephine Cruzat

Latin American Brain Health Institute (BrainLat), Universidad Adolfo Ibanez, Santiago, Chile.

4 papers in the library · 540 citations · publishing 2020-2022

Papers

Dynamic coupling of whole-brain neuronal and neurotransmitter systems

Proceedings of the National Academy of Sciences April 13, 2020 Morten L. Kringelbach, Josephine Cruzat, Joana Cabral et al. 326 citations

By combining multimodal neuroimaging data, a framework was developed that demonstrates the fundamental principles of bidirectional coupling between neuronal and neurotransmitter dynamical systems. The work causally explains the functional effects of stimulating specific serotoninergic receptors (5-HT2AR) with psilocybin in healthy humans. This could lead to a better understanding of why psilocybin shows promise as a therapeutic intervention for neuropsychiatric disorders such as depression, anxiety, and addiction.

Receptor-informed network control theory links LSD and psilocybin to a flattening of the brain's control energy landscape.

Nature communications October 3, 2022 S Parker Singleton, Andrea I Luppi, Robin L Carhart-Harris et al. 156 citations

Psychedelics like LSD and psilocybin temporarily alter subjective experience by acting on serotonin 2a (5-HT2a) receptors, increasing the diversity (entropy) of brain activity. This increase may arise from a flattening of the brain's control energy landscape. Using fMRI data, the authors show that these compounds reduce the control energy needed for transitions between brain states compared to placebo. Across individuals, lower control energy correlates with more frequent state transitions and higher entropy. Incorporating PET data on 5-HT2a receptor distribution under non-drug conditions, the analysis links these receptors to reduced control energy. The findings demonstrate that receptor-informed network control theory can model how neuropharmacological manipulation affects brain dynamics.

LSD and psilocybin flatten the brain’s energy landscape: insights from receptor-informed network control theory

bioRxiv (Cold Spring Harbor Laboratory) May 17, 2021 S. Parker Singleton, Andrea I. Luppi, Robin L. Carhart-Harris et al. 30 citations preprint

LSD and psilocybin reduce the amount of energy the brain needs to transition between different activity states, as measured by functional MRI. This flattening of the brain's control energy landscape allows for more frequent state transitions and more diverse (entropic) brain activity. The effects are linked to the spatial distribution of serotonin 2a receptors, the main target of these psychedelics. The findings suggest that these compounds make brain state transitions more facile and temporally diverse, offering a mechanistic explanation for the altered subjective experience induced by psychedelics.

Effects of classic psychedelic drugs on turbulent signatures in brain dynamics

Network Neuroscience January 1, 2022 Josephine Cruzat, Yonatan Sanz Perl, Anira Escrichs et al. 28 citations

Psychedelic drugs like LSD and psilocybin may treat neuropsychiatric disorders by dose-dependently altering the brain's functional hierarchy—the organization of neural activity across regions. Using a turbulence framework that measures local synchronization (vorticity) in both space and time, researchers found that both drugs produce consistent and distinct effects, particularly compressing the default mode network, a higher-level network. These findings support the hypothesis that psychedelics modulate the functional hierarchy and provide a quantitative comparison of how LSD and psilocybin change brain dynamics, with implications for therapeutic use.