Dorsomedial prefrontal neural ensembles reflect changes in task utility that culminate in task quitting

Porter, Blake; Kl, Hillman

doi:10.1101/2020.11.05.370536

Cited by 2 publications

(2 citation statements)

References 68 publications

(118 reference statements)

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“…ACC neurons can dynamically encode potential actions with multiplexed representation of value, cost, and reward probability [49][50][51][52] . In rats, ACC activity in both single units and at the population level encode choice value that integrates reward magnitude and effort cost 11,14,15,36 . We find that silencing ACC during a choice, or when preparing for choice trials in the start box, disrupts effortful action selection.…”

Section: Discussionmentioning

confidence: 99%

“…These studies find clear encoding of effort-related value, but also find high degrees of heterogeneity in neuron responding suggesting that ACC subpopulations may perform unique functions. Other studies have begun to explore the encoding of effort-related behaviors at the ensemble level using miniaturized head-mounted microscopes, or multielectrode recordings 20,26 . Similarly, local field potential recordings between ACC and reward related regions implicate oscillatory activity in spatial effort-based decision making [27][28][29] .…”

Section: Introductionmentioning

confidence: 99%

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Neural activity in the anterior cingulate cortex is required for effort-based decision making

Kashay

Cheung

Vaknalli

et al. 2022

Preprint

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Adaptive decision making requires the evaluation of cost-benefit tradeoffs to guide action selection. Effort-based decision making involves weighing predicted gains against effort costs and is disrupted in several neuropsychiatric disorders. The ACC is postulated to control effort-base choice via its role in encoding the value of overcoming effort costs in rodent effort-based decision making assays. However, temporally precise methods of manipulating neural activity have rarely been applied to effort-based decision making. We developed and validated a mouse version of the barrier T-maze, and used optogenetics to inhibit ACC excitatory neurons at specific times during this task. Bilateral inhibition of ACC rapidly and reversibly impaired preference to exert greater effort for a larger reward when a less rewarded, low effort alternative was available. Equalizing effort for potential choice options led mice to choose the high reward arm of the maze regardless of whether the ACC was inhibited or not. The mechanics of choice behavior were altered during trials where the ACC was inhibited, but there were no effects on overall mobility or tendency to exert effort in an unrelated assay. These findings establish causality between ACC neural activity during a choice trial and effortful action selection during cost-benefit decision making.SIGNIFICANCE STATEMENTDisturbances in evaluating effort-based costs during decision making occur in depression, schizophrenia, addiction and Parkinson’s disease. Precisely resolving the function of prefrontal brain regions in mediating these processes will reveal key loci of dysfunction and potential therapeutic intervention in these disorders.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Neural activity in the anterior cingulate cortex is required for effort-based decision making

Kashay

Cheung

Vaknalli

et al. 2022

Preprint

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Stimulation in the Rat Anterior Insula and Anterior Cingulate During an Effortful Weightlifting Task

2021

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When performing tasks, animals must continually assess how much effort is being expended, and gage this against ever-changing physiological states. As effort costs mount, persisting in the task may be unwise. The anterior cingulate cortex (ACC) and the anterior insular cortex are implicated in this process of cost-benefit decision-making, yet their precise contributions toward driving effortful persistence are not well understood. Here we investigated whether electrical stimulation of the ACC or insular cortex would alter effortful persistence in a novel weightlifting task (WLT). In the WLT an animal is challenged to pull a rope 30 cm to trigger food reward dispensing. To make the action increasingly effortful, 45 g of weight is progressively added to the rope after every 10 successful pulls. The animal can quit the task at any point – with the rope weight at the time of quitting taken as the “break weight.” Ten male Sprague-Dawley rats were implanted with stimulating electrodes in either the ACC [cingulate cortex area 1 (Cg1) in rodent] or anterior insula and then assessed in the WLT during stimulation. Low-frequency (10 Hz), high-frequency (130 Hz), and sham stimulations were performed. We predicted that low-frequency stimulation (LFS) of Cg1 in particular would increase persistence in the WLT. Contrary to our predictions, LFS of Cg1 resulted in shorter session duration, lower break weights, and fewer attempts on the break weight. High-frequency stimulation of Cg1 led to an increase in time spent off-task. LFS of the anterior insula was associated with a marginal increase in attempts on the break weight. Taken together our data suggest that stimulation of the rodent Cg1 during an effortful task alters certain aspects of effortful behavior, while insula stimulation has little effect.

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Dorsomedial prefrontal neural ensembles reflect changes in task utility that culminate in task quitting

Cited by 2 publications

References 68 publications

Neural activity in the anterior cingulate cortex is required for effort-based decision making

Neural activity in the anterior cingulate cortex is required for effort-based decision making

Stimulation in the Rat Anterior Insula and Anterior Cingulate During an Effortful Weightlifting Task

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