Cortical structural differences following repeated ayahuasca use hold molecular signatures

Frontiers in Neuroscience  – October 05, 2023

Source: OpenAlex

Summary

Repeated use of the serotonergic psychedelic Ayahuasca profoundly remodels brain networks. Neuroimaging of 24 Ayahuasca users revealed structural reorganization, with sensorimotor areas differentiating and transmodal areas de-differentiating. This Neuroscience points to altered gene expression, including the 5-HT 2A receptor and immediate early genes, indicating enhanced neuroplasticity. Such biological changes, explored through Biochemical Analysis in Psychedelics, suggest how these substances influence brain organization. This macroscale effect, linked to Neurotransmitter Receptor Influence, offers insight into the Psychology and behavioral differences observed in experienced users.

Abstract

Introduction Serotonergic psychedelics such as ayahuasca are reported to promote both structural and functional neural plasticity via partial 5-HT 2A agonism. However, little is known about how these molecular mechanisms may extend to repeated psychedelic administration in humans, let alone neuroanatomy. While early evidence suggests localised changes to cortical thickness in long-term ayahuasca users, it is unknown how such findings may be reflected by large-scale anatomical brain networks comprising cytoarchitecturally complex regions. Methods Here, we examined the relationship between cortical gene expression markers of psychedelic action and brain morphometric change following repeated ayahuasca usage, using high-field 7 Tesla neuroimaging data derived from 24 members of an ayahuasca-using church (Santo Daime) and case-matched controls. Results Using a morphometric similarity network (MSN) analysis, repeated ayahuasca use was associated with a spatially distributed cortical patterning of both structural differentiation in sensorimotor areas and de-differentiation in transmodal areas. Cortical MSN remodelling was found to be spatially correlated with dysregulation of 5-HT 2A gene expression as well as a broader set of genes encoding target receptors pertinent to ayahuasca’s effects. Furthermore, these associations were similarly interrelated with altered gene expression of specific transcriptional factors and immediate early genes previously identified in preclinical assays as relevant to psychedelic-induced neuroplasticity. Conclusion Taken together, these findings provide preliminary evidence that the molecular mechanisms of psychedelic action may scale up to a macroscale level of brain organisation in vivo . Closer attention to the role of cortical transcriptomics in structural-functional coupling may help account for the behavioural differences observed in experienced psychedelic users.

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