Abstract
Learning from errors or negative feedback is crucial for adaptive behavior. FMRI studies have demonstrated enhanced anterior cingulate cortex activity for errors that were later corrected versus repeated errors even when a substantial delay between the error and the opportunity to correct was introduced. We aimed at identifying the electrophysiological correlates of these processes by investigating the feedback‐related negativity (FRN) and stimulus‐locked P3. Participants had to learn and recall the location of 2‐digit targets over consecutive rounds. Feedback was provided in two steps, first a color change indicated a correct or incorrect response (feedback phase) followed by presentation of the correct digit information (re‐encoding phase). Behaviorally, participants improved performance from the first to the third round. FRN amplitudes time‐locked to feedback were enhanced for corrected compared to repeated errors. The P3 in response to re‐encoding did not differ between the two error types. The finding that FRN amplitudes positively predicted memory performance is consistent with the idea that the FRN reflects prediction errors and the need for enhanced cognitive control. Interestingly, this happens early during feedback processing and not at a later time point when re‐encoding of correct information takes place. The prediction error signal reflected in the FRN is usually elicited by performance errors, but may thus also play a role in preparing/optimizing the system for memory formation. This supports the existence of a close link between action control and memory processes even when there is a substantial delay between error feedback and the opportunity to correct the error.
Highlights
Using neuroimaging methods such as electroencephalography (EEG) and functional magnetic resonance imaging, it has been well established that areas in posterior medial frontal cortex including anterior cingulate cortex (ACC) and pre‐supplementary motor area play a central role in action or performance monitoring processes, such as error detection and regulation of adaptive behavior
The aim of the present study was to investigate the electrophysiological correlates of learning from errors, by comparing feedback‐related negativity (FRN) and P300 amplitudes for corrected and repeated errors at different stages of information processing
The FRN is thought to originate from areas in posterior medial frontal cortex, ACC and pre‐supplemental motor area
Summary
Using neuroimaging methods such as electroencephalography (EEG) and functional magnetic resonance imaging (fMRI), it has been well established that areas in posterior medial frontal cortex (pMFC) including anterior cingulate cortex (ACC) and pre‐supplementary motor area (pre‐SMA) play a central role in action or performance monitoring processes, such as error detection and regulation of adaptive behavior (see e.g., de Bruijn, de Lange, von Cramon, & Ullsperger, 2009; Debener et al, 2005). As increased cognitive control is not required on expected or positive outcomes, this negative component is suppressed on these trials and often referred to as the feedback correct‐ related positivity or the reward positivity (Holroyd et al, de BRUIJN et al.2008; Proudfit, 2015; Williams, Hassall, Trska, Holroyd, & Krigolson, 2017) This more recent interpretation of increased cognitive control fits with previous studies that have demonstrated a relationship between enhanced medial frontal negativities and subsequent behavioral adjustments (e.g., Cohen & Ranganath, 2007; Holroyd & Coles, 2002; Sallet, Camille, & Procyk, 2013; but see Chase, Swainson, Durham, Benham, & Cools, 2011; Von Borries, Verkes, Bulten, Cools, & de Bruijn, 2013). For the P3, we expected enhanced amplitudes for corrected errors in response to the re‐encoding information, because of the component's role in context updating and working memory
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