| Publication |
Sentence |
Publish Date |
Extraction Date |
Species |
| Qingfang Liu, Yao Zhao, Sumedha Attanti, Joel L Voss, Geoffrey Schoenbaum, Thorsten Kahn. Midbrain signaling of identity prediction errors depends on orbitofrontal cortex networks. Nature communications. vol 15. issue 1. 2024-02-24. PMID:38402210. |
previous work across species has shown that the dopaminergic midbrain responds to violations in expected reward identity and that the lateral orbitofrontal cortex (ofc) represents reward identity expectations. |
2024-02-24 |
2024-02-27 |
Not clear |
| Qingfang Liu, Yao Zhao, Sumedha Attanti, Joel L Voss, Geoffrey Schoenbaum, Thorsten Kahn. Midbrain signaling of identity prediction errors depends on orbitofrontal cortex networks. Nature communications. vol 15. issue 1. 2024-02-24. PMID:38402210. |
critically, tms disrupted neural representations of expected reward identity in the ofc and modulated ipe responses in the midbrain. |
2024-02-24 |
2024-02-27 |
Not clear |
| Gail Tripp, Jeff Wicken. Using rodent data to elucidate dopaminergic mechanisms of ADHD: Implications for human personality. Personality neuroscience. vol 7. 2024-02-22. PMID:38384667. |
it is well known that midbrain dopamine neurons are initially activated by unexpected reward and gradually transfer their responses to reward-predicting cues. |
2024-02-22 |
2024-02-24 |
human |
| Borja Gomez Ramos, Jochen Ohnmacht, Nikola de Lange, Elena Valceschini, Aurélien Ginolhac, Marie Catillon, Daniele Ferrante, Aleksandar Rakovic, Rashi Halder, François Massart, Giuseppe Arena, Paul Antony, Silvia Bolognin, Christine Klein, Roland Krause, Marcel H Schulz, Thomas Sauter, Rejko Krüger, Lasse Sinkkone. Multiomics analysis identifies novel facilitators of human dopaminergic neuron differentiation. EMBO reports. 2024-01-04. PMID:38177910. |
midbrain dopaminergic neurons (mdans) control voluntary movement, cognition, and reward behavior under physiological conditions and are implicated in human diseases such as parkinson's disease (pd). |
2024-01-04 |
2024-01-07 |
human |
| S C Simmons, W J Flerlage, L D Langlois, R D Shepard, C Bouslog, E H Thomas, K M Gouty, J L Sanderson, S Gouty, B M Cox, M L Dell'Acqua, F S Nugen. AKAP150-anchored PKA regulation of synaptic transmission and plasticity, neuronal excitability and CRF neuromodulation in the lateral habenula. bioRxiv : the preprint server for biology. 2023-12-18. PMID:38106086. |
here we focused on an unexplored role of akap150 in the lateral habenula (lhb), a diencephalic brain region that integrates and relays negative reward signals from forebrain striatal and limbic structures to midbrain monoaminergic centers. |
2023-12-18 |
2023-12-21 |
mouse |
| Miguel Á Luján, Dan P Covey, Reana Young-Morrison, LanYuan Zhang, Andrew Kim, Fiorella Morgado, Sachin Patel, Caroline E Bass, Carlos Paladini, Joseph F Chee. Mobilization of endocannabinoids by midbrain dopamine neurons is required for the encoding of reward prediction. Nature communications. vol 14. issue 1. 2023-11-24. PMID:37985770. |
however, it is not clear whether mobilization of 2-ag specifically from midbrain dopamine neurons is necessary for dopaminergic responses to external stimuli predicting forthcoming reward. |
2023-11-24 |
2023-11-28 |
mouse |
| Daniel L Albaugh, Aryn H Gitti. Basal ganglia: Appreciating the 'value' of the GPe. Current biology : CB. vol 33. issue 20. 2023-10-26. PMID:37875082. |
a newly discovered cell type, the slow pacemaker, robustly encodes reward value and generates prediction errors in a manner remarkably similar to midbrain dopamine neurons. |
2023-10-26 |
2023-11-08 |
Not clear |
| Pol Bech, Sylvain Crochet, Robin Dard, Parviz Ghaderi, Yanqi Liu, Meriam Malekzadeh, Carl C H Petersen, Mauro Pulin, Anthony Renard, Christos Sourmpi. Striatal Dopamine Signals and Reward Learning. Function (Oxford, England). vol 4. issue 6. 2023-10-16. PMID:37841525. |
neuronal circuits of the basal ganglia have been strongly implicated in action selection, as well as the learning and execution of goal-directed behaviors, with accumulating evidence supporting the hypothesis that midbrain dopamine neurons might encode a reward signal useful for learning. |
2023-10-16 |
2023-11-08 |
Not clear |
| Chia-Yueh Chang, Yu-Chen Chan, Hsueh-Chih Che. The differential processing of verbal jokes by neural substrates in Indigenous and Han Chinese populations: An fMRI study. Behavioural brain research. 2023-10-09. PMID:37813282. |
ind participants when encountered with jokes displayed a greater activation of the mesolimbic dopaminergic reward system, including the amygdala, midbrain, and nucleus accumbens than han participants. |
2023-10-09 |
2023-10-15 |
human |
| Sho K Sugawara, Tetsuya Yamamoto, Yoshihisa Nakayama, Yuki H Hamano, Masaki Fukunaga, Norihiro Sadato, Yukio Nishimur. Premovement activity in the mesocortical system links peak force but not initiation of force generation under incentive motivation. Cerebral cortex (New York, N.Y. : 1991). 2023-10-09. PMID:37814358. |
extensive areas in the mesocortical system, including the ventral midbrain (vm) and cortical motor-related areas, exhibited motivation-dependent activity in the premovement "ready" period when the anticipated monetary reward was displayed. |
2023-10-09 |
2023-10-15 |
human |
| Yuji K Takahashi, Zhewei Zhang, Marlian Montesinos-Cartegena, Thorsten Kahnt, Angela J Langdon, Geoffrey Schoenbau. Expectancy-related changes in firing of dopamine neurons depend on hippocampus. bioRxiv : the preprint server for biology. 2023-10-02. PMID:37781610. |
we recorded midbrain dopamine neurons as rats performed an odor-based choice task, in which errors in the prediction of reward were induced by manipulating the number or timing of the expected rewards across blocks of trials. |
2023-10-02 |
2023-10-07 |
rat |
| Julong Wei, Tova Y Lambert, Aditi Valada, Nikhil Patel, Kellie Walker, Jayna Lenders, Carl J Schmidt, Marina Iskhakova, Adnan Alazizi, Henriette Mair-Meijers, Deborah C Mash, Francesca Luca, Roger Pique-Regi, Michael J Bannon, Schahram Akbaria. Single nucleus transcriptomics of ventral midbrain identifies glial activation associated with chronic opioid use disorder. Nature communications. vol 14. issue 1. 2023-09-12. PMID:37699936. |
dynamic interactions of neurons and glia in the ventral midbrain mediate reward and addiction behavior. |
2023-09-12 |
2023-10-07 |
Not clear |
| Julong Wei, Tova Y Lambert, Aditi Valada, Nikhil Patel, Kellie Walker, Jayna Lenders, Carl J Schmidt, Marina Iskhakova, Adnan Alazizi, Henriette Mair-Meijers, Deborah C Mash, Francesca Luca, Roger Pique-Regi, Michael J Bannon, Schahram Akbaria. Single nucleus transcriptomics of ventral midbrain identifies glial activation associated with chronic opioid use disorder. Nature communications. vol 14. issue 1. 2023-09-12. PMID:37699936. |
ventral midbrain transcriptomic reprogramming in the context of chronic opioid exposure included 325 genes that previous genome-wide studies had linked to risk of substance use traits in the broader population, thereby pointing to heritable risk architectures in the genomic organization of the brain's reward circuitry. |
2023-09-12 |
2023-10-07 |
Not clear |
| Lieneke K Janssen, Iris Duif, Anne E M Speckens, Ilke van Loon, Joost Wegman, Jeanne H M de Vries, Roshan Cools, Esther Aart. The effects of an 8-week mindful eating intervention on anticipatory reward responses in striatum and midbrain. Frontiers in nutrition. vol 10. 2023-08-28. PMID:37637944. |
the effects of an 8-week mindful eating intervention on anticipatory reward responses in striatum and midbrain. |
2023-08-28 |
2023-09-07 |
Not clear |
| Francantonio Devoto, Anna Ferrulli, Giuseppe Banfi, Livio Luzi, Laura Zapparoli, Eraldo Paules. How images of food become cravingly salient in obesity. Obesity (Silver Spring, Md.). vol 31. issue 9. 2023-08-22. PMID:37605635. |
this case-control study was aimed at testing two main hypotheses: (i) obesity is characterized by neurofunctional alterations within the mesocorticolimbic reward system, a brain network originating from the midbrain ventral tegmental area (vta); and (ii) these alterations are associated with a bias for food-related stimuli and craving. |
2023-08-22 |
2023-09-07 |
Not clear |
| Christian Altbürger, Jens Holzhauser, Wolfgang Drieve. CRISPR/Cas9-based QF2 knock-in at the Frontiers in neuroanatomy. vol 17. 2023-08-21. PMID:37603776. |
because of their disease relevance, special attention has been paid to mammalian midbrain dopaminergic systems, which have important functions in motor control, reward, motivation, and cognitive function. |
2023-08-21 |
2023-09-07 |
Not clear |
| Cameron D Hassall, Yan Yan, Laurence T Hun. The neural correlates of continuous feedback processing. Psychophysiology. 2023-07-24. PMID:37485986. |
although studies using continuous feedback are sparse, recent animal work suggests that moment-to-moment changes in reward are tracked by slowly ramping midbrain dopaminergic activity. |
2023-07-24 |
2023-08-14 |
human |
| Virginie J Oberto, Jumpei Matsumoto, Marco N Pompili, Ralitsa Todorova, Francesco Papaleo, Hisao Nishijo, Laurent Venance, Marie Vandecasteele, Sidney I Wiene. Rhythmic oscillations in the midbrain dopaminergic nuclei in mice. Frontiers in cellular neuroscience. vol 17. 2023-07-10. PMID:37426551. |
dopamine release in the forebrain by midbrain ventral tegmental nucleus (vta) and substantia nigra pars compacta (snc) neurons is implicated in reward processing, goal-directed learning, and decision-making. |
2023-07-10 |
2023-08-14 |
mouse |
| Shaohua Ma, Hao Zhong, Xuemei Liu, Liping Wan. Spatial Distribution of Neurons Expressing Single, Double, and Triple Molecular Characteristics of Glutamatergic, Dopaminergic, or GABAergic Neurons in the Mouse Ventral Tegmental Area. Journal of molecular neuroscience : MN. 2023-05-27. PMID:37243808. |
the ventral tegmental area (vta) is a heterogeneous midbrain area that plays a significant role in diverse neural processes such as reward, aversion, and motivation. |
2023-05-27 |
2023-08-14 |
mouse |
| Caroline E Geisler, Matthew R Haye. Metabolic Hormone Action in the VTA: Reward-Directed Behavior and Mechanistic Insights. Physiology & behavior. 2023-05-13. PMID:37178855. |
dysfunctional signaling in midbrain reward circuits perpetuates diseases characterized by compulsive overconsumption of rewarding substances such as substance abuse, binge eating disorder, and obesity. |
2023-05-13 |
2023-08-14 |
Not clear |