| Dopamine transients are sufficient and necessary for acquisition of model-based associations MJ Sharpe, CY Chang, MA Liu, HM Batchelor, LE Mueller, JL Jones, ... Nature Neuroscience 20 (5), 735-742, 2017 | 216 | 2017 |
| Model-based predictions for dopamine AJ Langdon, MJ Sharpe, G Schoenbaum, Y Niv Current opinion in neurobiology 49, 1-7, 2018 | 147 | 2018 |
| The dopamine prediction error: contributions to associative models of reward learning HM Nasser, DJ Calu, G Schoenbaum, MJ Sharpe Frontiers in psychology 8, 244, 2017 | 94 | 2017 |
| An integrated model of action selection: distinct modes of cortical control of striatal decision making MJ Sharpe, T Stalnaker, NW Schuck, S Killcross, G Schoenbaum, Y Niv Annual review of psychology 70, 53-76, 2019 | 91 | 2019 |
| Lateral hypothalamic GABAergic neurons encode reward predictions that are relayed to the ventral tegmental area to regulate learning MJ Sharpe, NJ Marchant, LR Whitaker, CT Richie, YJ Zhang, ... Current Biology 27 (14), 2089-2100. e5, 2017 | 88 | 2017 |
| Back to basics: Making predictions in the orbitofrontal–amygdala circuit MJ Sharpe, G Schoenbaum Neurobiology of learning and memory 131, 201-206, 2016 | 70 | 2016 |
| Dopamine transients do not act as model-free prediction errors during associative learning MJ Sharpe, HM Batchelor, LE Mueller, C Yun Chang, EJP Maes, Y Niv, ... Nature communications 11 (1), 106, 2020 | 50 | 2020 |
| The prelimbic cortex uses higher-order cues to modulate both the acquisition and expression of conditioned fear MJ Sharpe, S Killcross Frontiers in systems neuroscience 8, 235, 2015 | 50 | 2015 |
| The prelimbic cortex contributes to the down-regulation of attention toward redundant cues MJ Sharpe, S Killcross Cerebral cortex 24 (4), 1066-1074, 2014 | 47 | 2014 |
| Causal evidence supporting the proposal that dopamine transients function as temporal difference prediction errors EJP Maes, MJ Sharpe, AA Usypchuk, M Lozzi, CY Chang, MPH Gardner, ... Nature neuroscience 23 (2), 176-178, 2020 | 46 | 2020 |
| The prelimbic cortex uses contextual cues to modulate responding towards predictive stimuli during fear renewal M Sharpe, S Killcross Neurobiology of learning and memory 118, 20-29, 2015 | 46 | 2015 |
| Preconditioned cues have no value MJ Sharpe, HM Batchelor, G Schoenbaum Elife 6, e28362, 2017 | 39 | 2017 |
| Modulation of attention and action in the medial prefrontal cortex of rats. MJ Sharpe, S Killcross Psychological review 125 (5), 822, 2018 | 38 | 2018 |
| The prelimbic cortex directs attention toward predictive cues during fear learning MJ Sharpe, S Killcross Learning & Memory 22 (6), 289-293, 2015 | 37 | 2015 |
| Daily exposure to sucrose impairs subsequent learning about food cues: a role for alterations in ghrelin signaling and dopamine D2 receptors MJ Sharpe, KJ Clemens, MJ Morris, RF Westbrook Neuropsychopharmacology 41 (5), 1357-1365, 2016 | 26 | 2016 |
| Responding to preconditioned cues is devaluation sensitive and requires orbitofrontal cortex during cue-cue learning EE Hart, MJ Sharpe, MPH Gardner, G Schoenbaum Elife 9, e59998, 2020 | 25 | 2020 |
| Evaluation of the hypothesis that phasic dopamine constitutes a cached-value signal MJ Sharpe, G Schoenbaum Neurobiology of learning and memory 153, 131-136, 2018 | 25 | 2018 |
| The state of the orbitofrontal cortex MJ Sharpe, AM Wikenheiser, Y Niv, G Schoenbaum Neuron 88 (6), 1075-1077, 2015 | 23 | 2015 |
| Past experience shapes the neural circuits recruited for future learning MJ Sharpe, HM Batchelor, LE Mueller, MPH Gardner, G Schoenbaum Nature Neuroscience 24 (3), 391-400, 2021 | 22 | 2021 |
| The prediction-error hypothesis of schizophrenia: new data point to circuit-specific changes in dopamine activity SJ Millard, CE Bearden, KH Karlsgodt, MJ Sharpe Neuropsychopharmacology 47 (3), 628-640, 2022 | 21 | 2022 |
