| Publication |
Sentence |
Publish Date |
Extraction Date |
Species |
| Marc-Andreas Edel, Björn Enzi, Henning Witthaus, Martin Tegenthoff, Sören Peters, Georg Juckel, Silke Lisse. Differential reward processing in subtypes of adult attention deficit hyperactivity disorder. Journal of psychiatric research. vol 47. issue 3. 2014-05-30. PMID:23201229. |
this study sought to compare neural activations in the ventral striatum (vs) and prefrontal regions during reward processing in homogenous adhd subtype groups and healthy adults, using the mid task. |
2014-05-30 |
2023-08-12 |
Not clear |
| Katherine E Powers, Leah H Somerville, William M Kelley, Todd F Heatherto. Rejection sensitivity polarizes striatal-medial prefrontal activity when anticipating social feedback. Journal of cognitive neuroscience. vol 25. issue 11. 2014-04-30. PMID:23859650. |
during this anticipatory period, increased neural activity was observed in the ventral striatum, a central component of the brain's reward circuitry, and dorsomedial pfc, a brain region implicated in mentalizing about others. |
2014-04-30 |
2023-08-12 |
human |
| Erik J Peterson, Carol A Sege. Many hats: intratrial and reward level-dependent BOLD activity in the striatum and premotor cortex. Journal of neurophysiology. vol 110. issue 7. 2014-04-11. PMID:23741040. |
reward magnitude affected neural activity only during stimulus in the caudate, putamen, and premotor cortex, whereas the ventral striatum showed reward sensitivity during both stimulus and feedback. |
2014-04-11 |
2023-08-12 |
human |
| Andrew D Lawrence, David J Brook. Ventral striatal dopamine synthesis capacity is associated with individual differences in behavioral disinhibition. Frontiers in behavioral neuroscience. vol 8. 2014-03-27. PMID:24672449. |
disinhibitory personality traits such as impulsivity and novelty seeking (ns) function as indicators of this broad shared externalizing tendency, which may reflect, at the neurobiological level, variation in the reactivity of dopaminergic (daergic) brain reward systems centered on the ventral striatum (vs). |
2014-03-27 |
2023-08-12 |
human |
| María José Rodrigo, Iván Padrón, Manuel de Vega, Evelyn C Ferst. Adolescents' risky decision-making activates neural networks related to social cognition and cognitive control processes. Frontiers in human neuroscience. vol 8. 2014-03-04. PMID:24592227. |
in addition, brain structures related to cognitive control were active [right anterior cingulate cortex (acc), bilateral dorsolateral prefrontal cortex (dlpfc), bilateral orbitofrontal cortex], whereas no significant clusters were obtained in the reward system (ventral striatum). |
2014-03-04 |
2023-08-12 |
human |
| Sang Soo Cho, Giovanna Pellecchia, Kelly Aminian, Nicola Ray, Barbara Segura, Ignacio Obeso, Antonio P Strafell. Morphometric correlation of impulsivity in medial prefrontal cortex. Brain topography. vol 26. issue 3. 2014-01-23. PMID:23274773. |
the vbm analysis showed that impulsivity appears to be reliant on a network of cortical (medial prefrontal cortex and dorsolateral prefrontal cortex) and subcortical (ventral striatum) structures emphasizing the importance of brain networks associated with reward related decision-making in daily life as morphological biomarkers for impulsivity in a normal healthy population. |
2014-01-23 |
2023-08-12 |
human |
| Ulrike Schwarze, Ulrike Bingel, David Badre, Tobias Somme. Ventral striatal activity correlates with memory confidence for old- and new-responses in a difficult recognition test. PloS one. vol 8. issue 3. 2013-12-03. PMID:23472064. |
based on the prominent role of the ventral striatum in the reward circuit, its activity has been interpreted to reflect the higher subjective value of hits compared to correct rejections in standard recognition tests. |
2013-12-03 |
2023-08-12 |
human |
| Jean-Claude Drehe. Neural coding of computational factors affecting decision making. Progress in brain research. vol 202. 2013-11-19. PMID:23317838. |
when investigating the neural representation of primary and secondary rewards, we found both a common brain network, including the ventromedial prefrontal cortex and ventral striatum, and a functional organization of the orbitofrontal cortex according to reward type. |
2013-11-19 |
2023-08-12 |
Not clear |
| Nina Bothe, Elisabeth Zschucke, Fernando Dimeo, Andreas Heinz, Torsten Wüstenberg, Andreas Ströhl. Acute exercise influences reward processing in highly trained and untrained men. Medicine and science in sports and exercise. vol 45. issue 3. 2013-09-26. PMID:23059859. |
physical activity activates brain regions and transmitter systems that represent the reward system (i.e., the ventral striatum [vs] and dopamine). |
2013-09-26 |
2023-08-12 |
Not clear |
| James K Rillin. The neural and hormonal bases of human parental care. Neuropsychologia. vol 51. issue 4. 2013-09-24. PMID:23333868. |
in neuroimaging studies, exposing parents to child stimuli activates neural systems involved in understanding others' facial expressions (the putative mirror neuron system), others' feelings (anterior insula and thalamocingulate regions) and others' thoughts (dorsomedial prefrontal cortex), as well as reward systems involved in approach-related motivation (ventral tegmental area, substantia nigra, ventral striatum and medial orbitofrontal cortex), and systems involved with emotion regulation (lateral prefrontal cortex). |
2013-09-24 |
2023-08-12 |
human |
| Eva H Telzer, Andrew J Fuligni, Matthew D Lieberman, Adriana Galvá. The effects of poor quality sleep on brain function and risk taking in adolescence. NeuroImage. vol 71. 2013-08-23. PMID:23376698. |
this association was paralleled by less recruitment of the dorsolateral prefrontal cortex (dlpfc) during cognitive control, greater insula activation during reward processing, and reduced functional coupling between the dlpfc and affective regions including the insula and ventral striatum during reward processing. |
2013-08-23 |
2023-08-12 |
Not clear |
| R Shao, J Read, T E J Behrens, R D Roger. Shifts in reinforcement signalling while playing slot-machines as a function of prior experience and impulsivity. Translational psychiatry. vol 3. 2013-08-13. PMID:23443361. |
impulsivity, itself linked to problem gambling and heightened vulnerability to other addictive disorders, is associated with divergent coding of winning outcomes and almost-winning experiences within the ventral striatum and amygdala, potentially enhancing the reward value of successful slot-machine game outcomes but, at the same time,modulating the aversive motivational consequences of near-miss outcomes. |
2013-08-13 |
2023-08-12 |
human |
| Brandy Schmidt, Andrew Papale, A David Redish, Etan J Marku. Conflict between place and response navigation strategies: effects on vicarious trial and error (VTE) behaviors. Learning & memory (Cold Spring Harbor, N.Y.). vol 20. issue 3. 2013-08-06. PMID:23418392. |
vte co-occurs with neurophysiological information processing, including sweeps of representation ahead of the animal in the hippocampus and transient representations of reward in the ventral striatum and orbitofrontal cortex. |
2013-08-06 |
2023-08-12 |
rat |
| George F Koo. Addiction is a Reward Deficit and Stress Surfeit Disorder. Frontiers in psychiatry. vol 4. 2013-08-05. PMID:23914176. |
specific neurochemical elements in these structures include not only decreases in reward system function (within-system opponent processes) but also recruitment of the brain stress systems mediated by corticotropin-releasing factor (crf) and dynorphin-κ opioid systems in the ventral striatum, extended amygdala, and frontal cortex (both between-system opponent processes). |
2013-08-05 |
2023-08-12 |
Not clear |
| Stephan Geuter, Falk Eippert, Catherine Hindi Attar, Christian Büche. Cortical and subcortical responses to high and low effective placebo treatments. NeuroImage. vol 67. 2013-07-09. PMID:23201367. |
these results directly link placebo analgesia to anticipatory activity in the ventral striatum, a region involved in reward processing, and highlight the role of the rostral anterior cingulate cortex, as its activity consistently scaled with increasing analgesic efficacy. |
2013-07-09 |
2023-08-12 |
human |
| Jonathan Savitz, Colin A Hodgkinson, Chantal Martin-Soelch, Pei-Hong Shen, Joanna Szczepanik, Allison Nugent, Peter Herscovitch, Anthony A Grace, David Goldman, Wayne C Drevet. The functional DRD3 Ser9Gly polymorphism (rs6280) is pleiotropic, affecting reward as well as movement. PloS one. vol 8. issue 1. 2013-07-08. PMID:23365649. |
a linear regression analysis controlling for age, sex, diagnosis, and self-reported anhedonia indicated that during receipt of unpredictable monetary reward the glycine allele was associated with a greater reduction in d2/3 receptor binding (i.e., increased reward-related da release) in the middle (anterior) caudate (p<0.01) and the ventral striatum (p<0.05). |
2013-07-08 |
2023-08-12 |
human |
| R Shao, J Read, T E J Behrens, R D Roger. Shifts in reinforcement signalling while playing slot-machines as a function of prior experience and impulsivity. Translational psychiatry. vol 3. 2013-07-04. PMID:23321810. |
impulsivity, itself linked to problem gambling and heightened vulnerability to other addictive disorders, is associated with divergent coding of winning outcomes and almost-winning experiences within the ventral striatum and amygdala, potentially enhancing the reward value of successful slot-machine game outcomes but, at the same time, modulating the aversive motivational consequences of near-miss outcomes. |
2013-07-04 |
2023-08-12 |
human |
| Xavier Caseras, Natalia S Lawrence, Kevin Murphy, Richard G Wise, Mary L Phillip. Ventral striatum activity in response to reward: differences between bipolar I and II disorders. The American journal of psychiatry. vol 170. issue 5. 2013-06-28. PMID:23558337. |
ventral striatum activity in response to reward: differences between bipolar i and ii disorders. |
2013-06-28 |
2023-08-12 |
human |
| Xavier Caseras, Natalia S Lawrence, Kevin Murphy, Richard G Wise, Mary L Phillip. Ventral striatum activity in response to reward: differences between bipolar I and II disorders. The American journal of psychiatry. vol 170. issue 5. 2013-06-28. PMID:23558337. |
while bipolar i disorder is associated with abnormally elevated activity in response to reward in the ventral striatum, a key component of reward circuitry, no studies have compared reward circuitry function in bipolar i and bipolar ii disorders. |
2013-06-28 |
2023-08-12 |
human |
| Xavier Caseras, Natalia S Lawrence, Kevin Murphy, Richard G Wise, Mary L Phillip. Ventral striatum activity in response to reward: differences between bipolar I and II disorders. The American journal of psychiatry. vol 170. issue 5. 2013-06-28. PMID:23558337. |
the authors examined reward activity in the ventral striatum in participants with bipolar i and ii disorders and healthy individuals, the relationships between ventral striatal activity and reward sensitivity across all participants, and between-group differences in striatal gray matter volume and relationships with ventral striatal activity across all participants. |
2013-06-28 |
2023-08-12 |
human |