| Publication |
Sentence |
Publish Date |
Extraction Date |
Species |
| Robert Hitzemann, Ovidiu D Iancu, Cheryl Reed, Harue Baba, Denesa R Lockwood, Tamara J Phillip. Regional Analysis of the Brain Transcriptome in Mice Bred for High and Low Methamphetamine Consumption. Brain sciences. vol 9. issue 7. 2020-09-30. PMID:31262025. |
three brain reward circuitry regions were explored, the nucleus accumbens (nac), prefrontal cortex (pfc), and ventral midbrain (vmb). |
2020-09-30 |
2023-08-13 |
mouse |
| Yan-Feng Zhang, Stephanie J Crag. Pauses in Striatal Cholinergic Interneurons: What is Revealed by Their Common Themes and Variations? Frontiers in systems neuroscience. vol 11. 2020-09-29. PMID:29163075. |
the respective pause responses observed can demonstrate many commonalities, such as constant latency and duration, synchronous occurrence in a population of cells, and coincidence with phasic activities of midbrain dopamine neurons (dans) that signal reward predictions and errors. |
2020-09-29 |
2023-08-13 |
Not clear |
| Jennifer K Torgersen, Rose Petitti, Sedric Tello, Vincent F Lembo, Cheryl A Fry. Prenatal resident-intruder stress decreases levels of allopregnanolone in the cortex, hypothalamus, and midbrain of males, and increases levels in the hippocampus and cerebellum of female, juvenile rat offspring. Neurobiology of stress. vol 12. 2020-09-28. PMID:32258257. |
prenatal stress (pns) can influence behaviors associated with cognition, reward and emotional regulation, which are controlled by brain areas such as the cortex, hippocampus, hypothalamus, midbrain and cerebellum. |
2020-09-28 |
2023-08-13 |
rat |
| Jesse A Mendoza, Christopher K Lafferty, Angela K Yang, Jonathan P Brit. Cue-Evoked Dopamine Neuron Activity Helps Maintain but Does Not Encode Expected Value. Cell reports. vol 29. issue 6. 2020-09-24. PMID:31693885. |
cue-evoked midbrain dopamine (da) neuron activity reflects expected value, but its influence on reward assessment is unclear. |
2020-09-24 |
2023-08-13 |
mouse |
| John D Boughter, Lianyi Lu, Louis N Saites, Kenichi Tokit. Sweet and bitter taste stimuli activate VTA projection neurons in the parabrachial nucleus. Brain research. vol 1714. 2020-09-17. PMID:30807736. |
these results indicate that information about both appetitive and aversive tastes is delivered to a key midbrain reward interface via direct projections from the pbn. |
2020-09-17 |
2023-08-13 |
mouse |
| Alessandra Porcu, Megan Vaughan, Anna Nilsson, Natsuko Arimoto, Katja Lamia, David K Wels. Vulnerability to helpless behavior is regulated by the circadian clock component CRYPTOCHROME in the mouse nucleus accumbens. Proceedings of the National Academy of Sciences of the United States of America. vol 117. issue 24. 2020-09-14. PMID:32487727. |
the nucleus accumbens (nac), a central component of the midbrain dopamine reward circuit, exhibits disturbed circadian rhythms in the postmortem brains of depressed patients. |
2020-09-14 |
2023-08-13 |
mouse |
| Alessandra Porcu, Megan Vaughan, Anna Nilsson, Natsuko Arimoto, Katja Lamia, David K Wels. Vulnerability to helpless behavior is regulated by the circadian clock component CRYPTOCHROME in the mouse nucleus accumbens. Proceedings of the National Academy of Sciences of the United States of America. vol 117. issue 24. 2020-09-14. PMID:32487727. |
our data reveal a causal role for cry in regulating the midbrain dopamine reward system, and provide a mechanistic link between the nac circadian clock and vulnerability to depression. |
2020-09-14 |
2023-08-13 |
mouse |
| J Gendron, C Colace-Sauty, N Beaume, H Cartonnet, J Guegan, D Ulveling, C Pardanaud-Glavieux, I Moszer, H Cheval, P Ravassar. Long non-coding RNA repertoire and open chromatin regions constitute midbrain dopaminergic neuron - specific molecular signatures. Scientific reports. vol 9. issue 1. 2020-09-11. PMID:30723217. |
midbrain dopaminergic (da) neurons are involved in diverse neurological functions, including control of movements, emotions or reward. |
2020-09-11 |
2023-08-13 |
mouse |
| Lars-Lennart Oettl, Max Scheller, Carla Filosa, Sebastian Wieland, Franziska Haag, Cathrin Loeb, Daniel Durstewitz, Roman Shusterman, Eleonora Russo, Wolfgang Kelsc. Phasic dopamine reinforces distinct striatal stimulus encoding in the olfactory tubercle driving dopaminergic reward prediction. Nature communications. vol 11. issue 1. 2020-08-31. PMID:32651365. |
together, our data reveal that ventral striatal and midbrain reward networks form a reinforcing loop to generate reward prediction coding. |
2020-08-31 |
2023-08-13 |
Not clear |
| Holly J Bowen, Cheryl L Grady, Julia Spanio. Age differences in the neural response to negative feedback. Neuropsychology, development, and cognition. Section B, Aging, neuropsychology and cognition. vol 26. issue 3. 2020-08-24. PMID:29779433. |
investigations into the neural responses associated with reward anticipation have revealed that older and younger adults recruit the same midbrain reward regions, but other evidence suggests this recruitment may differ depending on the valence (gain, loss) of the incentive cue. |
2020-08-24 |
2023-08-13 |
human |
| Ivan Trujillo-Pisanty, Kent Conover, Pavel Solis, Daniel Palacios, Peter Shizga. Dopamine neurons do not constitute an obligatory stage in the final common path for the evaluation and pursuit of brain stimulation reward. PloS one. vol 15. issue 6. 2020-08-24. PMID:32502210. |
in rats working for direct, optical activation of midbrain dopamine neurons, we varied the strength and opportunity cost of the stimulation and measured time allocation, the proportion of trial time devoted to reward pursuit. |
2020-08-24 |
2023-08-13 |
rat |
| Kristoffer Carl Aberg, Emily Elizabeth Kramer, Sophie Schwart. Interplay between midbrain and dorsal anterior cingulate regions arbitrates lingering reward effects on memory encoding. Nature communications. vol 11. issue 1. 2020-07-21. PMID:32286275. |
interplay between midbrain and dorsal anterior cingulate regions arbitrates lingering reward effects on memory encoding. |
2020-07-21 |
2023-08-13 |
Not clear |
| Lea E Frank, Alison R Preston, Dagmar Zeithamov. Functional connectivity between memory and reward centers across task and rest track memory sensitivity to reward. Cognitive, affective & behavioral neuroscience. vol 19. issue 3. 2020-07-17. PMID:30805850. |
reward-based memory modulation is thought to result from encoding and post-encoding interactions between dopaminergic midbrain, signaling reward, and hippocampus and parahippocampal cortex, supporting episodic memory. |
2020-07-17 |
2023-08-13 |
Not clear |
| Lea E Frank, Alison R Preston, Dagmar Zeithamov. Functional connectivity between memory and reward centers across task and rest track memory sensitivity to reward. Cognitive, affective & behavioral neuroscience. vol 19. issue 3. 2020-07-17. PMID:30805850. |
reward-related regions of interest were generated using a meta-analysis of existing studies on reward and included ventral striatum, medial and orbital prefrontal cortices and anterior cingulate cortex, in addition to midbrain. |
2020-07-17 |
2023-08-13 |
Not clear |
| Jasmin M Kizilirmak, Björn H Schott, Hannes Thuerich, Catherine M Sweeney-Reed, Anni Richter, Kristian Folta-Schoofs, Alan Richardson-Klaveh. Learning of novel semantic relationships via sudden comprehension is associated with a hippocampus-independent network. Consciousness and cognition. vol 69. 2020-05-14. PMID:30763808. |
moreover, difficult compared to easy sudden comprehension elicited midbrain activations and was associated with successful learning, pointing to learning via intrinsic reward. |
2020-05-14 |
2023-08-13 |
Not clear |
| Kwang Lee, Leslie D Claar, Ayaka Hachisuka, Konstantin I Bakhurin, Jacquelyn Nguyen, Jeremy M Trott, Jay L Gill, Sotiris C Masmanidi. Temporally restricted dopaminergic control of reward-conditioned movements. Nature neuroscience. vol 23. issue 2. 2020-04-13. PMID:31932769. |
midbrain dopamine (da) neurons encode both reward- and movement-related events and are implicated in disorders of reward processing as well as movement. |
2020-04-13 |
2023-08-13 |
Not clear |
| Amber L Alhadeff, Nitsan Goldstein, Onyoo Park, Michelle L Klima, Alexandra Vargas, J Nicholas Betle. Natural and Drug Rewards Engage Distinct Pathways that Converge on Coordinated Hypothalamic and Reward Circuits. Neuron. vol 103. issue 5. 2020-03-27. PMID:31277924. |
here, we describe coordinated regulation of hypothalamic feeding and midbrain reward circuits in awake behaving mice. |
2020-03-27 |
2023-08-13 |
mouse |
| Xin-Yu Su, Ming Chen, Yuan Yuan, Ying Li, Su-Shan Guo, Huo-Qing Luo, Chen Huang, Wenzhi Sun, Yong Li, Michael X Zhu, Ming-Gang Liu, Ji Hu, Tian-Le X. Central Processing of Itch in the Midbrain Reward Center. Neuron. vol 102. issue 4. 2020-03-25. PMID:31000426. |
central processing of itch in the midbrain reward center. |
2020-03-25 |
2023-08-13 |
Not clear |
| Ben Engelhard, Joel Finkelstein, Julia Cox, Weston Fleming, Hee Jae Jang, Sharon Ornelas, Sue Ann Koay, Stephan Y Thiberge, Nathaniel D Daw, David W Tank, Ilana B Witte. Specialized coding of sensory, motor and cognitive variables in VTA dopamine neurons. Nature. vol 570. issue 7762. 2020-03-04. PMID:31142844. |
there is increased appreciation that dopamine neurons in the midbrain respond not only to reward |
2020-03-04 |
2023-08-13 |
Not clear |
| D J Merlino, J R Barton, B A Charsar, M D Byrne, J A Rappaport, R J Smeyne, A C Lepore, A E Snook, S A Waldma. Two distinct GUCY2C circuits with PMV (hypothalamic) and SN/VTA (midbrain) origin. Brain structure & function. vol 224. issue 8. 2020-02-24. PMID:31485718. |
further, gucy2c mrna and protein are expressed in the ventral midbrain, a principal structure regulating hedonic reward from behaviors including eating. |
2020-02-24 |
2023-08-13 |
Not clear |