Communications Biology (May 2024)

The neurocomputational link between defensive cardiac states and approach-avoidance arbitration under threat

  • Felix H. Klaassen,
  • Lycia D. de Voogd,
  • Anneloes M. Hulsman,
  • Jill X. O’Reilly,
  • Floris Klumpers,
  • Bernd Figner,
  • Karin Roelofs

DOI
https://doi.org/10.1038/s42003-024-06267-6
Journal volume & issue
Vol. 7, no. 1
pp. 1 – 15

Abstract

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Abstract Avoidance, a hallmark of anxiety-related psychopathology, often comes at a cost; avoiding threat may forgo the possibility of a reward. Theories predict that optimal approach-avoidance arbitration depends on threat-induced psychophysiological states, like freezing-related bradycardia. Here we used model-based fMRI analyses to investigate whether and how bradycardia states are linked to the neurocomputational underpinnings of approach-avoidance arbitration under varying reward and threat magnitudes. We show that bradycardia states are associated with increased threat-induced avoidance and more pronounced reward-threat value comparison (i.e., a stronger tendency to approach vs. avoid when expected reward outweighs threat). An amygdala-striatal-prefrontal circuit supports approach-avoidance arbitration under threat, with specific involvement of the amygdala and dorsal anterior cingulate (dACC) in integrating reward-threat value and bradycardia states. These findings highlight the role of human freezing states in value-based decision making, relevant for optimal threat coping. They point to a specific role for amygdala/dACC in state-value integration under threat.