| Publication |
Sentence |
Publish Date |
Extraction Date |
Species |
| Michael M Plichta, Adam J Schwarz, Oliver Grimm, Katrin Morgen, Daniela Mier, Leila Haddad, Antje B M Gerdes, Carina Sauer, Heike Tost, Christine Esslinger, Peter Colman, Frederick Wilson, Peter Kirsch, Andreas Meyer-Lindenber. Test-retest reliability of evoked BOLD signals from a cognitive-emotive fMRI test battery. NeuroImage. vol 60. issue 3. 2012-08-06. PMID:22330316. |
results showed robust evoked activation of all three tasks in their respective target regions (emotional task=amygdala; motivational task=ventral striatum; cognitive task=right dorsolateral prefrontal cortex and parietal cortices) with high effect sizes (es) of roi-mean summary values (es=1.11-1.44 for the faces task, 0.96-1.43 for the reward task, 0.83-2.58 for the n-back task). |
2012-08-06 |
2023-08-12 |
human |
| Uğur M Erdem, Michael Hasselm. A goal-directed spatial navigation model using forward trajectory planning based on grid cells. The European journal of neuroscience. vol 35. issue 6. 2012-07-18. PMID:22393918. |
after exploration, the rat retrieves memory of the goal location, picks its next movement direction by forward linear look-ahead probe of trajectories in several candidate directions while stationary in one location, and finds the one activating pfc cells with the highest reward signal. |
2012-07-18 |
2023-08-12 |
rat |
| Uğur M Erdem, Michael Hasselm. A goal-directed spatial navigation model using forward trajectory planning based on grid cells. The European journal of neuroscience. vol 35. issue 6. 2012-07-18. PMID:22393918. |
navigation with barriers requires a pfc map topology based on the temporal vicinity of visited place cells and a reward signal diffusion process. |
2012-07-18 |
2023-08-12 |
rat |
| Alice Lin, Ralph Adolphs, Antonio Range. Social and monetary reward learning engage overlapping neural substrates. Social cognitive and affective neuroscience. vol 7. issue 3. 2012-07-16. PMID:21427193. |
we found substantial overlap between the two types of rewards for all components of the learning process: a common area of ventromedial prefrontal cortex (vmpfc) correlated with stimulus value at the time of choice and another common area of vmpfc correlated with reward magnitude and common areas in the striatum correlated with prediction errors. |
2012-07-16 |
2023-08-12 |
human |
| Michael T Treadway, Joshua W Buckholtz, Ronald L Cowan, Neil D Woodward, Rui Li, M Sib Ansari, Ronald M Baldwin, Ashley N Schwartzman, Robert M Kessler, David H Zal. Dopaminergic mechanisms of individual differences in human effort-based decision-making. The Journal of neuroscience : the official journal of the Society for Neuroscience. vol 32. issue 18. 2012-06-25. PMID:22553023. |
we found that individual differences in da function in the left striatum and ventromedial prefrontal cortex were correlated with a willingness to expend greater effort for larger rewards, particularly when probability of reward receipt was low. |
2012-06-25 |
2023-08-12 |
human |
| Gabriel S Dichter, Jennifer N Felder, Steven R Green, Alison M Rittenberg, Noah J Sasson, James W Bodfis. Reward circuitry function in autism spectrum disorders. Social cognitive and affective neuroscience. vol 7. issue 2. 2012-06-06. PMID:21148176. |
group × reward-type-interaction tests revealed robust interaction effects in bilateral nucleus accumbens during reward anticipation and in ventromedial prefrontal cortex during reward outcomes, indicating differential responses contingent on reward type in these regions. |
2012-06-06 |
2023-08-12 |
human |
| Zivjena Vucetic, Jesse Lea Carlin, Kathy Totoki, Teresa M Reye. Epigenetic dysregulation of the dopamine system in diet-induced obesity. Journal of neurochemistry. vol 120. issue 6. 2012-06-01. PMID:22220805. |
dopamine (da) system changes in response to hf diet have been observed in the hypothalamus, important in the homeostatic control of food intake, as well as within the central reward circuitry [ventral tegmental area (vta), nucleus accumbens (nac), and pre-frontal cortex (pfc)], critical for coding the rewarding properties of palatable food and important in hedonically driven feeding behavior. |
2012-06-01 |
2023-08-12 |
mouse |
| Matthew R Holahan, Erin P Westby, Katrina Alber. Comparison of the MK-801-induced appetitive extinction deficit with pressing for reward and associated pERK1/2 staining in prefrontal cortex and nucleus accumbens. Behavioural brain research. vol 228. issue 1. 2012-05-24. PMID:22182675. |
comparison of the mk-801-induced appetitive extinction deficit with pressing for reward and associated perk1/2 staining in prefrontal cortex and nucleus accumbens. |
2012-05-24 |
2023-08-12 |
Not clear |
| Sonja Yokum, Janet Ng, Eric Stic. Attentional bias to food images associated with elevated weight and future weight gain: an fMRI study. Obesity (Silver Spring, Md.). vol 19. issue 9. 2012-05-07. PMID:21681221. |
bmi correlated positively with activation in brain regions related to attention and food reward, including the anterior insula/frontal operculum, lateral orbitofrontal cortex (ofc), ventrolateral prefrontal cortex (vlpfc), and superior parietal lobe, during initial orientation to food cues. |
2012-05-07 |
2023-08-12 |
Not clear |
| Tamara K Berdyyeva, Carl R Olso. Relation of ordinal position signals to the expectation of reward and passage of time in four areas of the macaque frontal cortex. Journal of neurophysiology. vol 105. issue 5. 2012-04-17. PMID:21389312. |
to compare the influences of these factors, we monitored neuronal activity in the supplementary motor area (sma), presupplementary motor area (pre-sma), supplementary eye field (sef), and dorsolateral prefrontal cortex during the performance of a serial order task (requiring a series of saccades in three specified directions), a variable reward task (in which a cue displayed early in the trial indicated whether the reward received at the end of the trial would be large or small), and a long delay task (in which the monkey had simply to maintain fixation during a period of time approximating the duration of an average trial in the serial order task). |
2012-04-17 |
2023-08-12 |
monkey |
| Andrew D Lawrence, Ines K Goerendt, David J Brook. Apathy blunts neural response to money in Parkinson's disease. Social neuroscience. vol 6. issue 5-6. 2012-02-24. PMID:21400357. |
we found that apathy was associated with a blunted response to money in the ventromedial prefrontal cortex, amygdala, striatum, and midbrain, all part of a distributed neural circuit integral to the representation of the reward value of stimuli and actions, and the influence of reward cues on behavior. |
2012-02-24 |
2023-08-12 |
human |
| Ninglei Sun, Ning Chi, Nicole Lauzon, Stephanie Bishop, Huibing Tan, Steven R Laviolett. Acquisition, extinction, and recall of opiate reward memory are signaled by dynamic neuronal activity patterns in the prefrontal cortex. Cerebral cortex (New York, N.Y. : 1991). vol 21. issue 12. 2012-02-22. PMID:21531781. |
acquisition, extinction, and recall of opiate reward memory are signaled by dynamic neuronal activity patterns in the prefrontal cortex. |
2012-02-22 |
2023-08-12 |
Not clear |
| M Feb. A bold view of the lactating brain: functional magnetic resonance imaging studies of suckling in awake dams. Journal of neuroendocrinology. vol 23. issue 11. 2012-02-10. PMID:21722215. |
activation patterns within reward regions are consistent with past research on maternal motivation and we explore the possibility that exposure to drugs of abuse might be disruptive of maternal neural responses to pups, particularly in the prefrontal cortex. |
2012-02-10 |
2023-08-12 |
rat |
| Srikanth Padmala, Luiz Pesso. Reward reduces conflict by enhancing attentional control and biasing visual cortical processing. Journal of cognitive neuroscience. vol 23. issue 11. 2012-02-08. PMID:21452938. |
brain imaging results revealed that a group of subcortical and fronto-parietal regions was robustly influenced by reward at cue processing and, importantly, that cue-related responses in fronto-parietal attentional regions were predictive of reduced conflict-related signals in the medial pfc (mpfc)/acc during the upcoming target phase. |
2012-02-08 |
2023-08-12 |
human |
| Jason A Cromer, Jefferson E Roy, Timothy J Buschman, Earl K Mille. Comparison of primate prefrontal and premotor cortex neuronal activity during visual categorization. Journal of cognitive neuroscience. vol 23. issue 11. 2012-02-08. PMID:21452948. |
thus, pfc neurons represented all variables required to solve the cognitive problem, whereas pmc neurons instead represented only the final decision variable that drove the appropriate motor action required to obtain a reward. |
2012-02-08 |
2023-08-12 |
Not clear |
| Nobuhito Ab. How the brain shapes deception: an integrated review of the literature. The Neuroscientist : a review journal bringing neurobiology, neurology and psychiatry. vol 17. issue 5. 2012-02-02. PMID:21454323. |
a growing body of evidence suggests that the prefrontal cortex plays a key role in deception, and some researchers have recently emphasized the importance of other brain regions, such as those responsible for emotion and reward. |
2012-02-02 |
2023-08-12 |
Not clear |
| Markus R Staudinger, Susanne Erk, Henrik Walte. Dorsolateral prefrontal cortex modulates striatal reward encoding during reappraisal of reward anticipation. Cerebral cortex (New York, N.Y. : 1991). vol 21. issue 11. 2012-01-23. PMID:21459835. |
dorsolateral prefrontal cortex modulates striatal reward encoding during reappraisal of reward anticipation. |
2012-01-23 |
2023-08-12 |
human |
| Yiran Lang, Ping Du, Hyung-Cheul Shi. Encoding-based brain-computer interface controlled by non-motor area of rat brain. Science China. Life sciences. vol 54. issue 9. 2012-01-12. PMID:21922432. |
these results demonstrated that it is possible for rats to understand an encoding-based bci system and control a 1d machine using pfc activity to obtain reward. |
2012-01-12 |
2023-08-12 |
rat |
| Franco Cauda, Andrea E Cavanna, Federico D'agata, Katiuscia Sacco, Sergio Duca, Giuliano C Geminian. Functional connectivity and coactivation of the nucleus accumbens: a combined functional connectivity and structure-based meta-analysis. Journal of cognitive neuroscience. vol 23. issue 10. 2012-01-05. PMID:21265603. |
the results of the combined rsfc and macm analyses show that spontaneous activity in nacc predicts activity in regions implicated in reward circuitries, including orbitomedial prefrontal cortex, globus pallidus, thalamus, midbrain, amygdala, and insula. |
2012-01-05 |
2023-08-12 |
human |
| Rita Z Goldstein, Nora D Volko. Dysfunction of the prefrontal cortex in addiction: neuroimaging findings and clinical implications. Nature reviews. Neuroscience. vol 12. issue 11. 2011-12-08. PMID:22011681. |
however, imaging studies in addictive behaviours have identified a key involvement of the prefrontal cortex (pfc) both through its regulation of limbic reward regions and its involvement in higher-order executive function (for example, self-control, salience attribution and awareness). |
2011-12-08 |
2023-08-12 |
Not clear |