Distributed Attribute Representation in the Superior Parietal Lobe During Probabilistic Decision-making

Overview

Journal Hum Brain Mapp

Publisher Wiley

Specialty Neurology

Date 2023 Aug 24

PMID 37614216

Authors

Pinchun Wang

Shuning Chen

Kun Deng

Bin Zhang

Hohjin Im

Junjiao Feng

Liqing Liu

Qinghao Yang

Guang Zhao

Qinghua He

Chunhui Chen

He Wang

Qiang Wang

Affiliations

Soon will be listed here.

Abstract

Several studies have examined the neural substrates of probabilistic decision-making, but few have systematically investigated the neural representations of the two objective attributes of probabilistic rewards, that is, the reward amount and the probability. Specifically, whether there are common or distinct neural activity patterns to represent the objective attributes and their association with the neural representation of the subjective valuation remains largely underexplored. We conducted two studies (n = 34, n = 41) to uncover distributed neural representations of the objective attributes and subjective value as well as their association with individual probability discounting rates. The amount and probability were independently manipulated to better capture brain signals sensitive to these two attributes and were presented simultaneously in Study 1 and successively in Study 2. Both univariate and multivariate pattern analyses showed that the brain activities in the superior parietal lobule (SPL), including the postcentral gyrus, were modulated by the amount of rewards and probability in both studies. Further, representational similarity analysis revealed a similar neural representation between these two objective attributes and between the attribute and valuation. Moreover, the SPL tracked the subjective value integrated by the hyperbolic function. Probability-related brain activations in the inferior parietal lobule were associated with the variability in individual discounting rates. These findings provide novel insights into a similar neural representation of the two attributes during probabilistic decision-making and perhaps support the common neural coding of stimulus objective properties and subjective value in the field of probabilistic discounting.

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