Neurocomputational account of how the human brain decides when to have a break

Meyniel, Florent; Sergent, Claire; Rigoux, Lionel; Daunizeau, Jean; Pessiglione, Mathias

doi:10.1073/pnas.1211925110

Cited by 89 publications

(129 citation statements)

References 41 publications

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“…Third, little is known about how the balance between reward and effort will develop over time in terms of learning or fatigue. We have found no evidence of significant trial sequence effects on our behavioral and neural outcomes at group level (results not reported) and experimental design will have to be optimized to investigate temporal trajectories (e.g., Meyniel et al, 2013).…”

Section: Discussionmentioning

confidence: 92%

Balancing reward and work: Anticipatory brain activation in NAcc and VTA predict effort differentially

et al. 2014

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Section: Discussionmentioning

confidence: 92%

Balancing reward and work: Anticipatory brain activation in NAcc and VTA predict effort differentially

et al. 2014

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“…We believe that such findings have applications in the domain of management, because the number and duration of work breaks could be adapted to avoid any dramatic LPFC dysfunction. If workers have control over their time schedule, they might spontaneously decide to take a break on the basis of some cost signal related to LPFC activity, as was shown with insular activity in the case of physical effort (39). Otherwise, LPFC dysfunction following overly intense cognitive work, with insufficient breaks, at longer time scales (weeks or months) might induce pathological conditions such as burnout syndromes.…”

Section: Discussionmentioning

confidence: 99%

Neural mechanisms underlying the impact of daylong cognitive work on economic decisions

Blain

Hollard

Pessiglione

2016

Proc. Natl. Acad. Sci. U.S.A.

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The ability to exert self-control is key to social insertion and professional success. An influential literature in psychology has developed the theory that self-control relies on a limited common resource, so that fatigue effects might carry over from one task to the next. However, the biological nature of the putative limited resource and the existence of carry-over effects have been matters of considerable controversy. Here, we targeted the activity of the lateral prefrontal cortex (LPFC) as a common substrate for cognitive control, and we prolonged the time scale of fatigue induction by an order of magnitude. Participants performed executive control tasks known to recruit the LPFC (working memory and task-switching) over more than 6 h (an approximate workday). Fatigue effects were probed regularly by measuring impulsivity in intertemporal choices, i.e., the propensity to favor immediate rewards, which has been found to increase under LPFC inhibition. Behavioral data showed that choice impulsivity increased in a group of participants who performed hard versions of executive tasks but not in control groups who performed easy versions or enjoyed some leisure time. Functional MRI data acquired at the start, middle, and end of the day confirmed that enhancement of choice impulsivity was related to a specific decrease in the activity of an LPFC region (in the left middle frontal gyrus) that was recruited by both executive and choice tasks. Our findings demonstrate a concept of focused neural fatigue that might be naturally induced in real-life situations and have important repercussions on economic decisions.

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“…Substantial evidence indicates that rapid bursts in VTA/SN neuronal firing rates correlate with expression of an appetitive reinforcement prediction error (RPE; D'Ardenne, McClure, Nystrom, & Cohen, 2008;Tobler, Fiorillo, & Schultz, 2005;Schultz, Dayan, & Montague, 1997). It has been suggested that tonic dopaminergic activity in VTA/SN also plays a key role in instrumental aspects of motivation by representing the average rate of reward (Skvortsova, Palminteri, & Pessiglione, 2014;Meyniel, Sergent, Rigoux, Daunizeau, & Pessiglione, 2013;Niv, Daw, Joel, & Dayan, 2007), which quantifies an opportunity cost of sloth and balances the price of alacrity.…”

Section: Introductionmentioning

confidence: 99%

The Dopaminergic Midbrain Mediates an Effect of Average Reward on Pavlovian Vigor

Rigoli¹,

Chew²,

Dayan³

et al. 2016

Journal of Cognitive Neuroscience

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Abstract■ Dopamine plays a key role in motivation. Phasic dopamine response reflects a reinforcement prediction error (RPE), whereas tonic dopamine activity is postulated to represent an average reward that mediates motivational vigor. However, it has been hard to find evidence concerning the neural encoding of average reward that is uncorrupted by influences of RPEs. We circumvented this difficulty in a novel visual search task where we measured participants' button pressing vigor in a context where information (underlying an RPE) about future average reward was provided well before the average reward itself. Despite no instrumental consequence, participants' pressing force increased for greater current average reward, consistent with a form of Pavlovian effect on motivational vigor. We recorded participants' brain activity during task performance with fMRI. Greater average reward was associated with enhanced activity in dopaminergic midbrain to a degree that correlated with the relationship between average reward and pressing vigor. Interestingly, an opposite pattern was observed in subgenual cingulate cortex, a region implicated in negative mood and motivational inhibition. These findings highlight a crucial role for dopaminergic midbrain in representing aspects of average reward and motivational vigor. ■

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Neurocomputational account of how the human brain decides when to have a break

Cited by 89 publications

References 41 publications

Balancing reward and work: Anticipatory brain activation in NAcc and VTA predict effort differentially

Balancing reward and work: Anticipatory brain activation in NAcc and VTA predict effort differentially

Neural mechanisms underlying the impact of daylong cognitive work on economic decisions

The Dopaminergic Midbrain Mediates an Effect of Average Reward on Pavlovian Vigor

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