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Literature DB >> 21109477

Reward, dopamine and the control of food intake: implications for obesity.

Nora D Volkow¹, Gene-Jack Wang, Ruben D Baler.

Abstract

The ability to resist the urge to eat requires the proper functioning of neuronal circuits involved in top-down control to oppose the conditioned responses that predict reward from eating the food and the desire to eat the food. Imaging studies show that obese subjects might have impairments in dopaminergic pathways that regulate neuronal systems associated with reward sensitivity, conditioning and control. It is known that the neuropeptides that regulate energy balance (homeostatic processes) through the hypothalamus also modulate the activity of dopamine cells and their projections into regions involved in the rewarding processes underlying food intake. It is postulated that this could also be a mechanism by which overeating and the resultant resistance to homoeostatic signals impairs the function of circuits involved in reward sensitivity, conditioning and cognitive control. Published by Elsevier Ltd.

Entities: Chemical Disease Gene Species

Mesh：

Substances：
Dopamine

Year: 2010 PMID： 21109477 PMCID： PMC3124340 DOI： 10.1016/j.tics.2010.11.001

Source DB: PubMed Journal: Trends Cogn Sci ISSN： 1364-6613 Impact factor: 20.229

106 in total

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Authors: S Mobini; S Body; M-Y Ho; C M Bradshaw; E Szabadi; J F W Deakin; I M Anderson
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2. Enhanced resting activity of the oral somatosensory cortex in obese subjects.

Authors: Gene-Jack Wang; Nora D Volkow; Christoph Felder; Joanna S Fowler; Alejandro V Levy; Naomi R Pappas; Christopher T Wong; Wei Zhu; Noelwah Netusil
Journal: Neuroreport Date: 2002-07-02 Impact factor: 1.837

3. Genetic linkage and association of the growth hormone secretagogue receptor (ghrelin receptor) gene in human obesity.

Authors: Andrea Baessler; Michael J Hasinoff; Marcus Fischer; Wibke Reinhard; Gabriele E Sonnenberg; Michael Olivier; Jeanette Erdmann; Heribert Schunkert; Angela Doering; Howard J Jacob; Anthony G Comuzzie; Ahmed H Kissebah; Anne E Kwitek
Journal: Diabetes Date: 2005-01 Impact factor: 9.461

4. Dopamine production in the caudate putamen restores feeding in dopamine-deficient mice.

Authors: M S Szczypka; K Kwok; M D Brot; B T Marck; A M Matsumoto; B A Donahue; R D Palmiter
Journal: Neuron Date: 2001-06 Impact factor: 17.173

Review 5. Getting formal with dopamine and reward.

Authors: Wolfram Schultz
Journal: Neuron Date: 2002-10-10 Impact factor: 17.173

6. Brain dopamine and obesity.

Authors: G J Wang; N D Volkow; J Logan; N R Pappas; C T Wong; W Zhu; N Netusil; J S Fowler
Journal: Lancet Date: 2001-02-03 Impact factor: 79.321

7. "Nonhedonic" food motivation in humans involves dopamine in the dorsal striatum and methylphenidate amplifies this effect.

Authors: Nora D Volkow; Gene-Jack Wang; Joanna S Fowler; Jean Logan; Millard Jayne; Dinko Franceschi; Cristopher Wong; Samuel J Gatley; Andrew N Gifford; Yu-Shin Ding; Naomi Pappas
Journal: Synapse Date: 2002-06-01 Impact factor: 2.562

8. Altered hypothalamic function in response to glucose ingestion in obese humans.

Authors: M Matsuda; Y Liu; S Mahankali; Y Pu; A Mahankali; J Wang; R A DeFronzo; P T Fox; J H Gao
Journal: Diabetes Date: 1999-09 Impact factor: 9.461

9. Body mass predicts orbitofrontal activity during visual presentations of high-calorie foods.

Authors: William D S Killgore; Deborah A Yurgelun-Todd
Journal: Neuroreport Date: 2005-05-31 Impact factor: 1.837

10. Feeding-induced dopamine release in dorsal striatum correlates with meal pleasantness ratings in healthy human volunteers.

Authors: Dana M Small; Marilyn Jones-Gotman; Alain Dagher
Journal: Neuroimage Date: 2003-08 Impact factor: 6.556

385 in total

1. Dnmt3a in Sim1 neurons is necessary for normal energy homeostasis.

Authors: Daisuke Kohno; Syann Lee; Matthew J Harper; Ki Woo Kim; Hideyuki Sone; Tsutomu Sasaki; Tadahiro Kitamura; Guoping Fan; Joel K Elmquist
Journal: J Neurosci Date: 2014-11-12 Impact factor: 6.167

2. Body mass index correlates negatively with white matter integrity in the fornix and corpus callosum: a diffusion tensor imaging study.

Authors: Jiansong Xu; Yang Li; Haiqun Lin; Rajita Sinha; Marc N Potenza
Journal: Hum Brain Mapp Date: 2011-12-03 Impact factor: 5.038

Review 3. Genetic and epigenetic control of metabolic health.

Authors: Robert Wolfgang Schwenk; Heike Vogel; Annette Schürmann
Journal: Mol Metab Date: 2013-09-25 Impact factor: 7.422

4. Competing dopamine neurons drive oviposition choice for ethanol in Drosophila.

Authors: Reza Azanchi; Karla R Kaun; Ulrike Heberlein
Journal: Proc Natl Acad Sci U S A Date: 2013-12-09 Impact factor: 11.205

5. Pain in the Developing Brain: Early Life Factors Alter Nociception and Neurobiological Function in Adolescent Rats.

Authors: Sabrina Salberg; Glenn R Yamakawa; Yannick Griep; Jesse Bain; Jaimie K Beveridge; Mujun Sun; Stuart J McDonald; Sandy R Shultz; Rhys D Brady; David K Wright; Melanie Noel; Richelle Mychasiuk
Journal: Cereb Cortex Commun Date: 2021-02-24

Review 6. Does a shared neurobiology for foods and drugs of abuse contribute to extremes of food ingestion in anorexia and bulimia nervosa?

Authors: Walter H Kaye; Christina E Wierenga; Ursula F Bailer; Alan N Simmons; Angela Wagner; Amanda Bischoff-Grethe
Journal: Biol Psychiatry Date: 2013-02-04 Impact factor: 13.382

10. Alpha-melanocyte stimulating hormone increases the activity of melanocortin-3 receptor-expressing neurons in the ventral tegmental area.

Authors: Katherine Stuhrman West; Chunxia Lu; David P Olson; Aaron G Roseberry
Journal: J Physiol Date: 2019-05-26 Impact factor: 5.182