A Computational Account of the Development and Evolution of Psychotic Symptoms

Overview

Journal Biol Psychiatry

Publisher Elsevier

Specialty Psychiatry

Date 2024 Sep 11

PMID 39260466

Authors

Albert Powers

Phillip A Angelos

Alexandria Bond

Emily Farina

Carolyn Fredericks

Jay Gandhi

Maximillian Greenwald

Gabriela Hernandez-Busot

Gabriel Hosein

Megan Kelley

Catalina Mourgues

William Palmer

Julia Rodriguez-Sanchez

Rashina Seabury

Silmilly Toribio

Raina Vin

Jeremy Weleff

Scott Woods

David Benrimoh

Affiliations

Soon will be listed here.

Abstract

The mechanisms of psychotic symptoms such as hallucinations and delusions are often investigated in fully formed illness, well after symptoms emerge. These investigations have yielded key insights but are not well positioned to reveal the dynamic forces underlying symptom formation itself. Understanding symptom development over time would allow us to identify steps in the pathophysiological process leading to psychosis, shifting the focus of psychiatric intervention from symptom alleviation to prevention. We propose a model for understanding the emergence of psychotic symptoms within the context of an adaptive, developing neural system. We make the case for a pathophysiological process that begins with cortical hyperexcitability and bottom-up noise transmission, which engenders inappropriate belief formation via aberrant prediction error signaling. We argue that this bottom-up noise drives learning about the (im)precision of new incoming sensory information because of diminished signal-to-noise ratio, causing a compensatory relative overreliance on prior beliefs. This overreliance on priors predisposes to hallucinations and covaries with hallucination severity. An overreliance on priors may also lead to increased conviction in the beliefs generated by bottom-up noise and drive movement toward conversion to psychosis. We identify predictions of our model at each stage, examine evidence to support or refute those predictions, and propose experiments that could falsify or help select between alternative elements of the overall model. Nesting computational abnormalities within longitudinal development allows us to account for hidden dynamics among the mechanisms driving symptom formation and to view established symptoms as a point of equilibrium among competing biological forces.

Citing Articles

Editorial: Tales from across the psychosis spectrum: understanding differences and similarities in mechanisms and experiences.

Palmer-Cooper E, Ellett L, Benrimoh D Front Psychiatry. 2024; 15:1513000.

PMID: 39634082 PMC: 11615062. DOI: 10.3389/fpsyt.2024.1513000.

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