| Publication |
Sentence |
Publish Date |
Extraction Date |
Species |
| Thorsten Kahnt, Jakob Heinzle, Soyoung Q Park, John-Dylan Hayne. Decoding the formation of reward predictions across learning. The Journal of neuroscience : the official journal of the Society for Neuroscience. vol 31. issue 41. 2011-12-06. PMID:21994378. |
we demonstrate that across learning activity patterns in the orbitofrontal cortex, the dorsolateral prefrontal cortex (dlpfc), and the dorsal striatum, coding the value of predicted rewards become similar to the patterns coding the value of actual reward outcomes. |
2011-12-06 |
2023-08-12 |
human |
| Dino J Levy, Paul W Glimche. Comparing apples and oranges: using reward-specific and reward-general subjective value representation in the brain. The Journal of neuroscience : the official journal of the Society for Neuroscience. vol 31. issue 41. 2011-12-06. PMID:21994386. |
in both the ventromedial prefrontal cortex (vmpfc) and striatum there was a common area representing the sv of both reward types, but only the vmpfc significantly represented the svs of money and food on a common scale appropriate for choice in our data set. |
2011-12-06 |
2023-08-12 |
human |
| Anna R Moore, Wen-Liang Zhou, Evgeniy S Potapenko, Eun-Ji Kim, Srdjan D Anti. Brief dopaminergic stimulations produce transient physiological changes in prefrontal pyramidal neurons. Brain research. vol 1370. 2011-11-23. PMID:21059342. |
in response to food reward and other pertinent events, midbrain dopaminergic neurons fire short bursts of action potentials causing a phasic release of dopamine in the prefrontal cortex (rapid and transient increases in cortical dopamine concentration). |
2011-11-23 |
2023-08-12 |
rat |
| Jennifer L Perry, Jane E Joseph, Yang Jiang, Rick S Zimmerman, Thomas H Kelly, Mahesh Darna, Peter Huettl, Linda P Dwoskin, Michael T Bard. Prefrontal cortex and drug abuse vulnerability: translation to prevention and treatment interventions. Brain research reviews. vol 65. issue 2. 2011-11-11. PMID:20837060. |
vulnerability to drug abuse is related to both reward seeking and impulsivity, two constructs thought to have a biological basis in the prefrontal cortex (pfc). |
2011-11-11 |
2023-08-12 |
Not clear |
| Helena J V Rutherford, Sarah K Williams, Sheryl Moy, Linda C Mayes, Josephine M John. Disruption of maternal parenting circuitry by addictive process: rewiring of reward and stress systems. Frontiers in psychiatry. vol 2. 2011-11-10. PMID:21779252. |
therefore, addiction reflects the dysregulation between core reward systems, including the prefrontal cortex (pfc), ventral tegmental area (vta), and nucleus accumbens (nac), as well as the hypothalamic-pituitary-adrenal axis and extended amygdala of the stress system. |
2011-11-10 |
2023-08-12 |
human |
| Janet Ng, Eric Stice, Sonja Yokum, Cara Boho. An fMRI study of obesity, food reward, and perceived caloric density. Does a low-fat label make food less appealing? Appetite. vol 57. issue 1. 2011-10-24. PMID:21497628. |
obese relative to lean women showed greater activation in somatosensory (rolandic operculum), gustatory (frontal operculum), and reward valuation regions (amgydala, ventralmedial prefrontal cortex (vmpfc) in response to intake and anticipated intake of milkshake versus tasteless solution, though there was little evidence of reduced striatal activation. |
2011-10-24 |
2023-08-12 |
Not clear |
| Simone Kühn, Barbara C N Müller, Andries van der Leij, Ap Dijksterhuis, Marcel Brass, Rick B van Baare. Neural correlates of emotional synchrony. Social cognitive and affective neuroscience. vol 6. issue 3. 2011-10-10. PMID:20504869. |
our results indicate that being in a congruent emotional state, irrespective of the emotion, activates the medial orbitofrontal cortex and ventromedial prefrontal cortex, brain areas that have been associated with positive feelings and reward processing. |
2011-10-10 |
2023-08-12 |
human |
| Ian C Ballard, Vishnu P Murty, R McKell Carter, Jeffrey J MacInnes, Scott A Huettel, R Alison Adcoc. Dorsolateral prefrontal cortex drives mesolimbic dopaminergic regions to initiate motivated behavior. The Journal of neuroscience : the official journal of the Society for Neuroscience. vol 31. issue 28. 2011-09-12. PMID:21753011. |
motivation to obtain reward is thought to depend on the midbrain [particularly the ventral tegmental area (vta)], the nucleus accumbens (nacc), and the dorsolateral prefrontal cortex (dlpfc), but it is not clear how the interactions among these regions relate to reward-motivated behavior. |
2011-09-12 |
2023-08-12 |
human |
| Siri Leknes, Michael Lee, Chantal Berna, Jesper Andersson, Irene Trace. Relief as a reward: hedonic and neural responses to safety from pain. PloS one. vol 6. issue 4. 2011-08-25. PMID:21490964. |
relief and appetitive reward task activity converged in the ventromedial prefrontal cortex, which also correlated with appetitive reward pleasantness ratings. |
2011-08-25 |
2023-08-12 |
human |
| Anna B Smith, Rozmin Halari, Vincent Giampetro, Michael Brammer, Katya Rubi. Developmental effects of reward on sustained attention networks. NeuroImage. vol 56. issue 3. 2011-07-25. PMID:21300162. |
the effect of reward on sustained attention networks was associated with increased activation with age in regions associated with both executive attention control and reward processing, including dorsolateral, inferior and ventromedial prefrontal cortices (pfc), striatum, and temporo-parietal regions, suggestive of greater integration and executive control of motivation and cognition with maturity. |
2011-07-25 |
2023-08-12 |
human |
| Gorica D Petrovic. Forebrain circuits and control of feeding by learned cues. Neurobiology of learning and memory. vol 95. issue 2. 2011-07-20. PMID:20965265. |
here, i will provide an overview of the two behavioral models and the critical neural network components mapped thus far, which include areas in the forebrain, the amygdala and prefrontal cortex, critical for associative learning and decision-making, and the lateral hypothalamus, which is an integrator for feeding, reward and motivation. |
2011-07-20 |
2023-08-12 |
Not clear |
| Jonathan I Ritvo, Charles Par. The psychiatric management of patients with alcohol dependence. Current treatment options in neurology. vol 9. issue 5. 2011-07-14. PMID:17716602. |
alcohol dependence is a chronic, relapsing biobehavioral disease mediated by various parts of the brain, including reward systems, memory circuits, and the prefrontal cortex. |
2011-07-14 |
2023-08-12 |
Not clear |
| Hackjin Kim, Shinsuke Shimojo, John P O'Dohert. Overlapping responses for the expectation of juice and money rewards in human ventromedial prefrontal cortex. Cerebral cortex (New York, N.Y. : 1991). vol 21. issue 4. 2011-07-13. PMID:20732900. |
at the group level, we found partially overlapping value-related activity within ventromedial prefrontal cortex (vmpfc) during anticipation of juice and money reward outcomes. |
2011-07-13 |
2023-08-12 |
human |
| Luke J Chang, Alec Smith, Martin Dufwenberg, Alan G Sanfe. Triangulating the neural, psychological, and economic bases of guilt aversion. Neuron. vol 70. issue 3. 2011-07-11. PMID:21555080. |
we observed increased activation in the insula, supplementary motor area, dorsolateral prefrontal cortex (pfc), and temporal parietal junction when participants were behaving consistent with our model, and found increased activity in the ventromedial pfc, dorsomedial pfc, and nucleus accumbens when they chose to abuse trust and maximize their financial reward. |
2011-07-11 |
2023-08-12 |
human |
| James J Young, Matthew L Shapir. Dynamic coding of goal-directed paths by orbital prefrontal cortex. The Journal of neuroscience : the official journal of the Society for Neuroscience. vol 31. issue 16. 2011-06-30. PMID:21508224. |
here, we tested how reward history and recent memory influenced coding by orbital prefrontal cortex (ofc) neurons. |
2011-06-30 |
2023-08-12 |
rat |
| Todd F Heatherton, Dylan D Wagne. Cognitive neuroscience of self-regulation failure. Trends in cognitive sciences. vol 15. issue 3. 2011-06-15. PMID:21273114. |
cognitive neuroscience research suggests that successful self-regulation is dependent on top-down control from the prefrontal cortex over subcortical regions involved in reward and emotion. |
2011-06-15 |
2023-08-12 |
Not clear |
| Rebecca Browning, J Bruce Overmier, Michael Colomb. Delay activity in avian prefrontal cortex--sample code or reward code? The European journal of neuroscience. vol 33. issue 4. 2011-05-31. PMID:21175883. |
delay activity in avian prefrontal cortex--sample code or reward code? |
2011-05-31 |
2023-08-12 |
Not clear |
| Rebecca Browning, J Bruce Overmier, Michael Colomb. Delay activity in avian prefrontal cortex--sample code or reward code? The European journal of neuroscience. vol 33. issue 4. 2011-05-31. PMID:21175883. |
in the current study, we examined whether delay activity in the avian equivalent of the prefrontal cortex (pfc) represents a neural correlate of a to-be-remembered sample stimulus or an upcoming reward. |
2011-05-31 |
2023-08-12 |
Not clear |
| Rebecca Browning, J Bruce Overmier, Michael Colomb. Delay activity in avian prefrontal cortex--sample code or reward code? The European journal of neuroscience. vol 33. issue 4. 2011-05-31. PMID:21175883. |
our findings suggest that activity in the avian pfc represents the outcome associated with each sample (reward or no reward) rather than memory for the sample itself. |
2011-05-31 |
2023-08-12 |
Not clear |
| Lourdes Nogueira, Antonieta Lavi. Strong somatic stimulation differentially regulates the firing properties of prefrontal cortex neurons. Brain research. vol 1351. 2011-05-17. PMID:20624375. |
in contrast to our understanding of the reward stimuli, less is known about how strong somatic stimulation is processed within the pfc. |
2011-05-17 |
2023-08-12 |
rat |