On a ‘failed’ attempt to manipulate visual metacognition with transcranial magnetic stimulation to prefrontal cortex

Achoui

Cleeremans

2020

Sci Rep

Metacognitive abilities allow us to adjust ongoing behavior and modify future decisions in the absence of external feedback. Although metacognition is critical in many daily life settings, it remains unclear what information is actually being monitored and what kind of information is being used for metacognitive decisions. In the present study, we investigated whether response information connected to perceptual events contribute to metacognitive decision-making. Therefore, we recorded EEG signals during a perceptual color discrimination task while participants were asked to provide an estimate about the quality of their decision on each trial. Critically, the moment participants provided their confidence judgments varied across conditions, thereby changing the amount of action information (e.g., response competition or response fluency) available for metacognitive decisions. Results from three experiments demonstrate that metacognitive performance improved when firstorder action information was available at the moment metacognitive decisions about the perceptual task had to be provided. This behavioral effect was accompanied by enhanced functional connectivity (beta phase synchrony) between motor areas and prefrontal regions, exclusively observed during metacognitive decision-making. Our findings demonstrate that action information contributes to metacognitive decision-making, thereby painting a picture of metacognition as a process that integrates sensory evidence and information about our interactions with the world.

Section: Models Of Metacognitive Decision-makingmentioning

confidence: 99%

Action information contributes to metacognitive decision-making

Achoui

Cleeremans

2020

Sci Rep

“…Similarly, disrupting prefrontal activity via theta burst stimulation has been shown to selectively alter metacognitive performance (Rounis et al 2010;Ryals et al 2016;Shekhar and Rahnev 2018, but see Bor at al. 2017and Ruby et al 2018). The detection of erroneous behavior, a key aspect of metacognition (Yueng and Summerfield 2012;Fleming and Daw 2017), has been strongly linked to a rapidly emerging central frontal negativity in the EEG signal (error-related negativity, Falkenstein et al 1991), thought to reflect coordinated theta oscillatory mechanisms (Luu and Tucker 2001;Cohen et al 2008;Bates et al 2009;Cavenagh et al 2009;Cohen and Cavenagh 2011).…”

Section: Prefrontal Cortex and Metacognitionmentioning

confidence: 99%

Action information contributes to metacognitive decision-making

Achoui

Cleeremans

2019

Preprint

Monitoring and control of our decision process are key ingredients of adept decisionmaking. Such metacognitive abilities allow us to adjust ongoing behavior and modify future decisions in the absence of external feedback. Although metacognition is critical in many daily life settings, it remains unclear what information is actually being monitored and what kind of information is being used for metacognitive decisions. In the present study, we investigated whether response information connected to perceptual events contribute to metacognitive decision-making. Therefore, we recorded EEG signals during a perceptual color discrimination task while participants were asked to provide an estimate about the quality of their decision on each trial. Critically, the moment participants provided second-order decisions varied across conditions, thereby changing the amount of action information (e.g., response competition or response fluency) available for metacognitive decisions.Results from three experiments demonstrate that metacognitive performance improved when first-order action information was available at the moment metacognitive decisions about the perceptual task had to be provided. This behavioral effect was accompanied by enhanced functional connectivity (beta phase synchrony) between motor areas and prefrontal regions, exclusively observed during metacognitive decision-making. Our findings demonstrate that action information contributes to metacognitive decision-making, thereby painting a picture of metacognition as a secondorder process, integrating sensory evidence and the state of the decider during decisionmaking. SignificanceMonitoring and control of our decision process is a critical part of every day decisionmaking. When feedback is not available, metacognitive skills enable us to modify current behavior and adapt prospective decision-making. Here, we investigated what kind information is being used to compute an estimate about the quality of our decisions.Results demonstrate that during perceptual decision-making, information about one's actions towards perceptual events is being used to evaluate the quality of one's decisions. EEG results indicate that functional connectivity between motor regions and prefrontal cortex could serve as a mechanism to convey action information during metacognitive decision-making. Considered together, our results demonstrate that postdecisional information contributes to metacognition, thereby evaluating not only what one perceives (e.g., strength of perceptual evidence) but also how one responds towards perceptual events.

“…The use of different hands for these different responses would more definitively rule out contributions from these types of response biases. Finally, in the current study, hit rates were relatively high for some participants, creating potentially unstable estimates of second-order performance (Bor et al, 2017;Ruby et al, 2018). A staircase procedure before the experiment could address this issue in future studies.…”

Section: Limitationsmentioning

confidence: 79%

Competitive Frontoparietal Interactions Mediate Implicit Inferences

2019

J. Neurosci.

Frequent experience with regularities in our environment allows us to use predictive information to guide our decision process. However, contingencies in our environment are not always explicitly present and sometimes need to be inferred. Heretofore, it remained unknown how predictive information guides decision-making when explicit knowledge is absent and how the brain shapes such implicit inferences. In the present experiment, 17 human participants (9 females) performed a discrimination task in which a target stimulus was preceded by a predictive cue. Critically, participants had no explicit knowledge that some of the cues signaled an upcoming target, allowing us to investigate how implicit inferences emerge and guide decision-making. Despite unawareness of the cue-target contingencies, participants were able to use implicit information to improve performance. Concurrent EEG recordings demonstrate that implicit inferences rely upon interactions between internally and externally oriented networks, whereby prefrontal regions inhibit parietal cortex under internal implicit control.