Computational Modeling of Threat Learning Reveals Links with Anxiety and Neuroanatomy in Humans

Overview

Journal Elife

Specialty Biology

Date 2022 Apr 27

PMID 35473766

Authors

Rany Abend

Diana Burk

Sonia G Ruiz

Andrea L Gold

Julia L Napoli

Jennifer C Britton

Kalina J Michalska

Tomer Shechner

Anderson M Winkler

Ellen Leibenluft

Daniel S Pine

Bruno B Averbeck

Affiliations

Soon will be listed here.

Abstract

Influential theories implicate variations in the mechanisms supporting threat learning in the severity of anxiety symptoms. We use computational models of associative learning in conjunction with structural imaging to explicate links among the mechanisms underlying threat learning, their neuroanatomical substrates, and anxiety severity in humans. We recorded skin-conductance data during a threat-learning task from individuals with and without anxiety disorders (N=251; 8-50 years; 116 females). Reinforcement-learning model variants quantified processes hypothesized to relate to anxiety: threat conditioning, threat generalization, safety learning, and threat extinction. We identified the best-fitting models for these processes and tested associations among latent learning parameters, whole-brain anatomy, and anxiety severity. Results indicate that greater anxiety severity related specifically to slower safety learning and slower extinction of response to safe stimuli. Nucleus accumbens gray-matter volume moderated learning-anxiety associations. Using a modeling approach, we identify computational mechanisms linking threat learning and anxiety severity and their neuroanatomical substrates.

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