| Publication |
Sentence |
Publish Date |
Extraction Date |
Species |
| Cristina Cusin, Daniel G Dillon, Emily Belleau, Marc D Normandin, Yoann Petibon, Georges El-Fakri, Maeva Dhaynaut, Jacob Hooker, Ted Kaptchuk, Madison McKee, Emma Hayden, Ashley Meyer, Aava Jahan, Julianne Origlio, Yuen-Siang Ang, Devon Brunner, Min Kang, Yinru Long, Maurizio Fava, Diego A Pizzagall. Novel multi-modal methodology to investigate placebo response in major depressive disorder. Journal of affective disorders. 2024-09-05. PMID:39233242. |
inspired by preclinical and clinical findings that have implicated dopamine in the occurrence, prediction, and expectation of reward, we hypothesized that dopaminergic activity in the mesolimbic system is a critical mediator of placebo response in mdd. |
2024-09-05 |
2024-09-08 |
Not clear |
| Sha Zhao, Zhao-Liang Gu, Ya-Nan Yue, Xia Zhang, Yuan Don. Cannabinoids and monoaminergic system: implications for learning and memory. Frontiers in neuroscience. vol 18. 2024-08-29. PMID:39206116. |
the monoaminergic system includes a variety of neurotransmitters, such as dopamine, norepinephrine, and serotonin, which play important roles in regulating mood, cognition, and reward. |
2024-08-29 |
2024-09-04 |
Not clear |
| Jordan E Elum, Eric R Szelenyi, Barbara Juarez, Alexandria D Murry, Grigory Loginov, Catalina A Zamorano, Pan Gao, Ginny Wu, Scott Ng-Evans, Joshua X Yee, Xiangmin Xu, Sam A Golden, Larry S Zweife. Distinct dynamics and intrinsic properties in ventral tegmental area populations mediate reward association and motivation. Cell reports. vol 43. issue 9. 2024-08-29. PMID:39207900. |
vta gaba neuron activity strongly contrasts vta dopamine population activity and preferentially encodes reward outcome and retrieval. |
2024-08-29 |
2024-09-04 |
mouse |
| Marcos Maroto-Gómez, Javier Burguete-Alventosa, Sofía Álvarez-Arias, María Malfaz, Miguel Ángel Salich. A Bio-Inspired Dopamine Model for Robots with Autonomous Decision-Making. Biomimetics (Basel, Switzerland). vol 9. issue 8. 2024-08-28. PMID:39194483. |
human decisions highly depend on dopamine, a brain substance that regulates motivation and reward, acknowledging positive and negative situations. |
2024-08-28 |
2024-08-30 |
human |
| James D Howard, Donnisa Edmonds, Geoffrey Schoenbaum, Thorsten Kahn. Distributed midbrain responses signal the content of positive identity prediction errors. Current biology : CB. 2024-08-28. PMID:39197457. |
recent work across species has shown that midbrain dopamine neurons signal not only errors in the prediction of reward value but also in the prediction of value-neutral sensory features. |
2024-08-28 |
2024-09-01 |
human |
| Paolo S D'Aquil. Licking microstructure in response to novel rewards, reward devaluation and dopamine antagonists: possible role of D1 and D2 medium spiny neurons in the nucleus accumbens. Neuroscience and biobehavioral reviews. 2024-08-19. PMID:39159734. |
licking microstructure in response to novel rewards, reward devaluation and dopamine antagonists: possible role of d1 and d2 medium spiny neurons in the nucleus accumbens. |
2024-08-19 |
2024-08-22 |
Not clear |
| Paolo S D'Aquil. Licking microstructure in response to novel rewards, reward devaluation and dopamine antagonists: possible role of D1 and D2 medium spiny neurons in the nucleus accumbens. Neuroscience and biobehavioral reviews. 2024-08-19. PMID:39159734. |
evidence on the effect of dopamine d1 and d2-like antagonists and of manipulations of reward value on licking microstructure is reanalysed considering recent findings on the role of nucleus accumbens (nac) medium spiny neurons (msns) in the control of sugar intake. |
2024-08-19 |
2024-08-22 |
Not clear |
| Matthias Fritsche, Antara Majumdar, Lauren Strickland, Samuel Liebana Garcia, Rafal Bogacz, Armin La. Temporal regularities shape perceptual decisions and striatal dopamine signals. Nature communications. vol 15. issue 1. 2024-08-17. PMID:39154025. |
we demonstrate that dorsal striatal dopamine tracks predictions of the model and behavior, suggesting that striatal dopamine reports reward predictions associated with adaptive choice history biases. |
2024-08-17 |
2024-08-20 |
mouse |
| Abhinav Goyal, Una Karanovic, Charles D Blaha, Kendall H Lee, Hojin Shin, Yoonbae O. Toward Precise Modeling of Dopamine Release Kinetics: Comparison and Validation of Kinetic Models Using Voltammetry. ACS omega. vol 9. issue 31. 2024-08-12. PMID:39130585. |
dopamine (da) is a neurotransmitter present within the animal brain that is responsible for a wide range of physiologic functions, including motivation, reward, and movement control. |
2024-08-12 |
2024-08-14 |
Not clear |
| Qian Huang, Hiu Ham Lee, Bryan Volpe, Qingchen Zhang, Chang Xue, Brian C Liu, Yahia R Abuhasan, Lingyun Li, Jeremy S Yang, Julie Egholm, Cristina Gutierrez-Vazquez, Allen Li, Alyssa Lee, Sharon Tang, Chun Wa Wong, Tiemin Liu, Yuan Huang, Raddy L Ramos, Randy F Stout, Abdelfattah El Ouaamari, Francisco J Quintana, Bradford B Lowell, C Ronald Kahn, Emmanuel N Pothos, Weikang Ca. Deletion of murine astrocytic vesicular nucleotide transporter increases anxiety and depressive-like behavior and attenuates motivation for reward. Molecular psychiatry. 2024-08-09. PMID:39122778. |
together, these data demonstrate a key modulatory role of astrocytic exocytosis of atp in anxiety, depressive-like behavior, and motivation for reward, by regulating the mesolimbic dopamine circuitry. |
2024-08-09 |
2024-08-13 |
mouse |
| Chenfeng Zhang, Redas Dulinskas, Christian Ineichen, Alexandra Greter, Hannes Sigrist, Yulong Li, Gregorio Alanis-Lobato, Bastian Hengerer, Christopher R Pryc. Chronic stress deficits in reward behaviour co-occur with low nucleus accumbens dopamine activity during reward anticipation specifically. Communications biology. vol 7. issue 1. 2024-08-09. PMID:39123076. |
chronic stress deficits in reward behaviour co-occur with low nucleus accumbens dopamine activity during reward anticipation specifically. |
2024-08-09 |
2024-08-13 |
mouse |
| Chenfeng Zhang, Redas Dulinskas, Christian Ineichen, Alexandra Greter, Hannes Sigrist, Yulong Li, Gregorio Alanis-Lobato, Bastian Hengerer, Christopher R Pryc. Chronic stress deficits in reward behaviour co-occur with low nucleus accumbens dopamine activity during reward anticipation specifically. Communications biology. vol 7. issue 1. 2024-08-09. PMID:39123076. |
imaging studies in human reward pathology indicate attenuated bold activity in nucleus accumbens (nac) coincident with reward anticipation but not reinforcement; potentially, this is dopamine (da) related. |
2024-08-09 |
2024-08-13 |
mouse |
| Lining Yin, Fang Han, Qingyun Wan. A biophysical model for dopamine modulating working memory through reward system in obsessive-compulsive disorder. Cognitive neurodynamics. vol 18. issue 4. 2024-08-06. PMID:39104680. |
a biophysical model for dopamine modulating working memory through reward system in obsessive-compulsive disorder. |
2024-08-06 |
2024-08-08 |
Not clear |
| E A Cross, J M Borland, E K Shaughnessy, S D Lee, V Vu, E A Sambor, K L Huhman, H E Alber. Distinct subcircuits within the mesolimbic dopamine system encode the salience and valence of social stimuli. bioRxiv : the preprint server for biology. 2024-08-02. PMID:39091886. |
the mesolimbic dopamine (da) system (mds) is the canonical "reward" pathway that has been studied extensively in the context of the rewarding properties of sex, food, and drugs of abuse. |
2024-08-02 |
2024-08-05 |
Not clear |
| Kenneth Blum, Abdalla Bowirrat, Keerthy Sunder, Panayotis K Thanos, Colin Hanna, Mark S Gold, Catherine A Dennen, Igor Elman, Kevin T Murphy, Milan T Makal. Dopamine Dysregulation in Reward and Autism Spectrum Disorder. Brain sciences. vol 14. issue 7. 2024-07-27. PMID:39061473. |
dopamine dysregulation in reward and autism spectrum disorder. |
2024-07-27 |
2024-07-29 |
Not clear |
| Kenneth Blum, Abdalla Bowirrat, Keerthy Sunder, Panayotis K Thanos, Colin Hanna, Mark S Gold, Catherine A Dennen, Igor Elman, Kevin T Murphy, Milan T Makal. Dopamine Dysregulation in Reward and Autism Spectrum Disorder. Brain sciences. vol 14. issue 7. 2024-07-27. PMID:39061473. |
the mesolimbic dopamine (da) mediated brain reward system is held to play a key role, but the rapidly expanding literature reveals intricate, nuanced signaling involving a wide array of mesolimbic loci, neurotransmitters and receptor subtypes, and neuronal variants. |
2024-07-27 |
2024-07-29 |
Not clear |
| Jingjing Yang, Hongjuan Wang, Huan Chen, Hongwei Hou, Qingyuan H. The association of genetic polymorphisms within the dopaminergic system with nicotine dependence: A narrative review. Heliyon. vol 10. issue 12. 2024-07-18. PMID:39021905. |
nicotine acts on the limbic dopamine reward loop in the midbrain by binding to nicotinic acetylcholine receptors, promoting the release of dopamine, and resulting in a rewarding effect or satisfaction. |
2024-07-18 |
2024-07-20 |
Not clear |
| Sarah Warren Gooding, Elinor Lewis, Christine Chau, Suhail Sandhu, Julianna Glienke, Jennifer L Whistle. Nucleus accumbens sub-regions experience distinct dopamine release responses following acute and chronic morphine exposure. bioRxiv : the preprint server for biology. 2024-07-15. PMID:39005415. |
it is well established that dopamine neurons of the ventral tegmental area (vta) play a critical role in reward and aversion as well as pathologies including drug dependence and addiction. |
2024-07-15 |
2024-07-18 |
mouse |
| Mohammad Navid Ebrahimi, Mohammad Banazadeh, Zahra Alitaneh, Ali Jaafari Suha, Ali Esmaeili, Behnam Hasannejad-Asl, Ali Siahposht-Khachaki, Amin Hasanshahi, Saeid Bagheri-Mohammad. The distribution of neurotransmitters in the brain circuitry: mesolimbic pathway and addiction. Physiology & behavior. 2024-07-14. PMID:39004195. |
while the role of some reward circuits, like the cerebral dopamine (da)/glutamate (glu)/gamma aminobutyric acid (gaba)ergic pathways, in drug reward, is well known, new research using molecular-based methods has shown functional alterations throughout the reward circuitry that contribute to various aspects of addiction, including craving and relapse. |
2024-07-14 |
2024-07-18 |
human |
| Ian Cone, Claudia Clopath, Harel Z Shouva. Learning to express reward prediction error-like dopaminergic activity requires plastic representations of time. Nature communications. vol 15. issue 1. 2024-07-12. PMID:38997276. |
we propose an alternate framework to describe dopamine signaling in the brain, flex (flexibly learned errors in expected reward). |
2024-07-12 |
2024-07-15 |
Not clear |