Punishment Feedback Impairs Memory and Changes Cortical Feedback-Related Potentials During Motor Learning

Overview

Journal Front Hum Neurosci

Specialty Neurology

Date 2020 Aug 28

PMID 32848669

Citations 7

Authors

Christopher M Hill

Mason Stringer

Dwight E Waddell

Alberto Del Arco

Affiliations

Soon will be listed here.

Abstract

Reward and punishment have demonstrated dissociable effects on motor learning and memory, which suggests that these reinforcers are differently processed by the brain. To test this possibility, we use electroencephalography to record cortical neural activity after the presentation of reward and punishment feedback during a visuomotor rotation task. Participants were randomly placed into Reward, Punishment, or Control groups and performed the task under different conditions to assess the adaptation (learning) and retention (memory) of the motor task. These conditions featured an incongruent position between the cursor and the target, with the cursor trajectory, rotated 30° counterclockwise, requiring the participant to adapt their movement to hit the target. Feedback based on error magnitude was provided during the Adaptation condition in the form of a positive number (Reward) or negative number (Punishment), each representing a monetary gain or loss, respectively. No reinforcement or visual feedback was provided during the No Vision condition (retention). Performance error and event-related potentials (ERPs) time-locked to feedback presentation were calculated for each participant during both conditions. Punishment feedback reduced performance error and promoted faster learning during the Adaptation condition. In contrast, punishment feedback increased performance error during the No Vision condition compared to Control and Reward groups, which suggests a diminished motor memory. Moreover, the Punishment group showed a significant decrease in the amplitude of ERPs during the No Vision condition compared to the Adaptation condition. The amplitude of ERPs did not change in the other two groups. These results suggest that punishment feedback impairs motor retention by altering the neural processing involved in memory encoding. This study provides a neurophysiological underpinning for the dissociative effects of punishment feedback on motor learning.

Citing Articles

Exploring the Impact of Declarative Learning on the Consolidation of Acquired Motor Skills Under Valence Feedback.

Farrokhi A, Habibi M, Daliri M Hum Brain Mapp. 2025; 46(2):e70105.

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The effects of reward and punishment on the performance of ping-pong ball bouncing.

Yin C, Wang Y, Li B, Gao T Front Behav Neurosci. 2024; 18:1433649.

PMID: 38993267 PMC: 11236609. DOI: 10.3389/fnbeh.2024.1433649.

Reinforcement feedback impairs locomotor adaptation and retention.

Hill C, Sebastiao E, Barzi L, Wilson M, Wood T Front Behav Neurosci. 2024; 18:1388495.

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Punishment Leads to Greater Sensorimotor Learning But Less Movement Variability Compared to Reward.

Roth A, Lokesh R, Tang J, Buggeln J, Smith C, Calalo J Neuroscience. 2024; 540:12-26.

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The effect of combining punishment and reward can transfer to opposite motor learning.

Yin C, Gao T, Li B PLoS One. 2023; 18(4):e0282028.

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