Warning: Undefined array key "mm" in /www/wwwroot/www.ai-bt.com/si.php on line 10 Deprecated: trim(): Passing null to parameter #1 ($string) of type string is deprecated in /www/wwwroot/www.ai-bt.com/si.php on line 10 Illicit dopamine transients: reconciling actions of abused drugs.

Literature DB >> 24656971

Illicit dopamine transients: reconciling actions of abused drugs.

Dan P Covey¹, Mitchell F Roitman², Paul A Garris³.

Abstract

Phasic increases in brain dopamine are required for cue-directed reward seeking. Although compelling within the framework of appetitive behavior, the view that illicit drugs hijack reward circuits by hyperactivating these dopamine transients is inconsistent with established psychostimulant pharmacology. However, recent work reclassifying amphetamine (AMPH), cocaine, and other addictive dopamine-transporter inhibitors (DAT-Is) supports transient hyperactivation as a unifying hypothesis of abused drugs. We argue here that reclassification also identifies generating burst firing by dopamine neurons as a keystone action. Unlike natural rewards, which are processed by sensory systems, drugs act directly on the brain. Consequently, to mimic natural rewards and exploit reward circuits, dopamine transients must be elicited de novo. Of available drug targets, only burst firing achieves this essential outcome.

Entities: Chemical Disease Gene Species

Mesh：

Substances：

Year: 2014 PMID： 24656971 PMCID： PMC4064368 DOI： 10.1016/j.tins.2014.02.002

Source DB: PubMed Journal: Trends Neurosci ISSN： 0166-2236 Impact factor: 13.837

130 in total

1. In vivo voltammetric monitoring of catecholamine release in subterritories of the nucleus accumbens shell.

Authors: J Park; B J Aragona; B M Kile; R M Carelli; R M Wightman
Journal: Neuroscience Date: 2010-05-06 Impact factor: 3.590

Review 2. Ethanol action on dopaminergic neurons in the ventral tegmental area: interaction with intrinsic ion channels and neurotransmitter inputs.

Authors: Hitoshi Morikawa; Richard A Morrisett
Journal: Int Rev Neurobiol Date: 2010 Impact factor: 3.230

3. Glutamate regulates the spontaneous and evoked release of dopamine in the rat striatum.

Authors: N V Kulagina; M J Zigmond; A C Michael
Journal: Neuroscience Date: 2001 Impact factor: 3.590

4. Delays conferred by escalating costs modulate dopamine release to rewards but not their predictors.

Authors: Matthew J Wanat; Camelia M Kuhnen; Paul E M Phillips
Journal: J Neurosci Date: 2010-09-08 Impact factor: 6.167

5. Synapsins differentially control dopamine and serotonin release.

Authors: Brian M Kile; Thomas S Guillot; B Jill Venton; William C Wetsel; George J Augustine; R Mark Wightman
Journal: J Neurosci Date: 2010-07-21 Impact factor: 6.167

Review 6. Regulation of dopamine transporter function by protein-protein interactions: new discoveries and methodological challenges.

Authors: Jacob Eriksen; Trine Nygaard Jørgensen; Ulrik Gether
Journal: J Neurochem Date: 2010-01-18 Impact factor: 5.372

7. Cocaine increases dopamine release by mobilization of a synapsin-dependent reserve pool.

Authors: B Jill Venton; Andrew T Seipel; Paul E M Phillips; William C Wetsel; Daniel Gitler; Paul Greengard; George J Augustine; R Mark Wightman
Journal: J Neurosci Date: 2006-03-22 Impact factor: 6.167

8. Effects of acute amphetamine exposure on two kinds of Pavlovian approach behavior.

Authors: John Michael Holden; Laura L Peoples
Journal: Behav Brain Res Date: 2009-11-13 Impact factor: 3.332

Review 9. Neural systems of reinforcement for drug addiction: from actions to habits to compulsion.

Authors: Barry J Everitt; Trevor W Robbins
Journal: Nat Neurosci Date: 2005-11 Impact factor: 24.884

10. Chronic microsensors for longitudinal, subsecond dopamine detection in behaving animals.

Authors: Jeremy J Clark; Stefan G Sandberg; Matthew J Wanat; Jerylin O Gan; Eric A Horne; Andrew S Hart; Christina A Akers; Jones G Parker; Ingo Willuhn; Vicente Martinez; Scott B Evans; Nephi Stella; Paul E M Phillips
Journal: Nat Methods Date: 2009-12-27 Impact factor: 28.547

34 in total

Review 1. Dopamine tunes prefrontal outputs to orchestrate aversive processing.

Authors: Caitlin M Vander Weele; Cody A Siciliano; Kay M Tye
Journal: Brain Res Date: 2018-12-01 Impact factor: 3.252

2. Real-time monitoring of electrically evoked catecholamine signals in the songbird striatum using in vivo fast-scan cyclic voltammetry.

Authors: Amanda R Smith; Paul A Garris; Joseph M Casto
Journal: J Chem Neuroanat Date: 2015-04-18 Impact factor: 3.052

3. Dopamine neuron dependent behaviors mediated by glutamate cotransmission.

Authors: Susana Mingote; Nao Chuhma; Abigail Kalmbach; Gretchen M Thomsen; Yvonne Wang; Andra Mihali; Caroline Sferrazza; Ilana Zucker-Scharff; Anna-Claire Siena; Martha G Welch; José Lizardi-Ortiz; David Sulzer; Holly Moore; Inna Gaisler-Salomon; Stephen Rayport
Journal: Elife Date: 2017-07-13 Impact factor: 8.140

4. Central GLP-1 receptor activation modulates cocaine-evoked phasic dopamine signaling in the nucleus accumbens core.

Authors: Samantha M Fortin; Mitchell F Roitman
Journal: Physiol Behav Date: 2017-03-16

5. Modafinil Activates Phasic Dopamine Signaling in Dorsal and Ventral Striata.

Authors: Martin J Bobak; Matthew W Weber; Melissa A Doellman; Douglas R Schuweiler; Jeana M Athens; Steven A Juliano; Paul A Garris
Journal: J Pharmacol Exp Ther Date: 2016-10-12 Impact factor: 4.030

6. Hypocretin receptor 1 blockade produces bimodal modulation of cocaine-associated mesolimbic dopamine signaling.

Authors: K A Levy; Z D Brodnik; J K Shaw; D A Perrey; Y Zhang; R A España
Journal: Psychopharmacology (Berl) Date: 2017-06-30 Impact factor: 4.530

7. Accelerated development of cocaine-associated dopamine transients and cocaine use vulnerability following traumatic stress.

Authors: Zachary D Brodnik; Emily M Black; Rodrigo A España
Journal: Neuropsychopharmacology Date: 2019-09-20 Impact factor: 7.853