Induction and Relief of Curiosity Elicit Parietal and Frontal Activity

Overview

Journal J Neurosci

Specialty Neurology

Date 2018 Feb 14

PMID 29439166

Citations 40

Authors

Lieke L F van Lieshout

Annelinde R E Vandenbroucke

Nils C J Muller

Roshan Cools

Floris P de Lange

Affiliations

Soon will be listed here.

Abstract

Curiosity is a basic biological drive, but little is known about its behavioral and neural mechanisms. We can be curious about several types of information. On the one hand, curiosity is a function of the expected value of information, serving primarily to help us maximize reward. On the other hand, curiosity can be a function of the uncertainty of information, helping us to update what we know. In the current studies, we aimed to disentangle the contribution of information uncertainty and expected value of rewards to curiosity in humans. To this end, we designed a lottery task in which uncertainty and expected value of trial outcomes were manipulated independently and examined how neural activity and behavioral measures of curiosity were modulated by these factors. Curiosity increased linearly with increased outcome uncertainty, both when curiosity was explicitly probed as well as when it was implicitly tested by people's willingness to wait. Increased expected value, however, did not strongly relate to these curiosity measures. Neuroimaging results showed greater BOLD response with increasing outcome uncertainty in parietal cortex at the time of curiosity induction. Outcome updating when curiosity was relieved resulted in an increased signal in the insula, orbitofrontal cortex, and parietal cortex. Furthermore, the insula showed a linear increase corresponding to the size of the information update. These results suggest that curiosity is monotonically related to the uncertainty about one's current world model, the induction and relief of which are associated with activity in parietal and insular cortices, respectively. Humans are curious by nature. When you hear your phone beep, you probably feel the urge to check the message right away, even though the message itself likely does not give you a direct reward. In this study, we demonstrated that curiosity can be driven by outcome uncertainty, over and above of reward. The induction of curiosity was accompanied by increased activity in the parietal cortex, whereas the information update at the time of curiosity relief was associated with activity in insular cortex. These findings advance our understanding of the behavioral and neural constituents of curiosity, which lies at the core of human information seeking and serves to optimize the individual's current world model.

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