scholarly article | Q13442814 |
P2093 | author name string | Nigel T Maidment | |
Niall P Murphy | |||
Sean B Ostlund | |||
Alisa Kosheleff | |||
P2860 | cites work | Distinct opioid circuits determine the palatability and the desirability of rewarding events | Q24642392 |
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Palatability: response to nutritional need or need-free stimulation of appetite? | Q34350723 | ||
Hedonic hot spot in nucleus accumbens shell: where do mu-opioids cause increased hedonic impact of sweetness? | Q34476480 | ||
Micro-opioid receptor activation in the basolateral amygdala mediates the learning of increases but not decreases in the incentive value of a food reward. | Q34847745 | ||
Opioid peptides and the control of human ingestive behaviour | Q35024658 | ||
The Vogel conflict test: procedural aspects, gamma-aminobutyric acid, glutamate and monoamines | Q35071483 | ||
Endogenous opioids and feeding behavior: a 30-year historical perspective | Q35785708 | ||
Hedonic hot spots in the brain. | Q36641847 | ||
μ- and δ-opioid-related processes in the accumbens core and shell differentially mediate the influence of reward-guided and stimulus-guided decisions on choice | Q37093727 | ||
Hedonic and motivational roles of opioids in food reward: implications for overeating disorders | Q37767927 | ||
Opioids as facilitators of feeding: can any food be rewarding? | Q37871132 | ||
The opioid system and food intake: homeostatic and hedonic mechanisms | Q38014599 | ||
General, mu and kappa opioid antagonists in the nucleus accumbens alter food intake under deprivation, glucoprivic and palatable conditions | Q38288915 | ||
Central opioid receptor subtype antagonists differentially alter sucrose and deprivation-induced water intake in rats | Q38326196 | ||
The microstructure of ingestive behavior | Q38780191 | ||
An analysis of licking microstructure in three strains of mice | Q39202699 | ||
Loss of morphine-induced analgesia, reward effect and withdrawal symptoms in mice lacking the mu-opioid-receptor gene | Q41157124 | ||
Effects of naloxone and naltrexone on meal patterns of freely-feeding rats | Q41456198 | ||
Dopamine on D2-like receptors "reboosts" dopamine D1-like receptor-mediated behavioural activation in rats licking for sucrose | Q43165007 | ||
Naltrexone suppresses the late but not early licking response to a palatable sweet solution: opioid hedonic hypothesis reconsidered | Q44176739 | ||
Enhanced anorectic potency of naloxone in rats sham feeding 30% sucrose: reversal by repeated naloxone administration | Q44271954 | ||
Increased body weight in mice lacking mu-opioid receptors | Q44330703 | ||
Selective actions of central μ and κ opioid antagonists upon sucrose intake in sham-fed rats | Q44333399 | ||
Decreased motivation to eat in mu-opioid receptor-deficient mice | Q44335248 | ||
Selective opioid receptor antagonist effects upon intake of a high-fat diet in rats | Q44337850 | ||
Nucleus accumbens opioid, GABAergic, and dopaminergic modulation of palatable food motivation: Contrasting effects revealed by a progressive ratio study in the rat | Q44341327 | ||
Centrally administered opioid peptides stimulate saccharin intake in nondeprived rats | Q44341361 | ||
The stimulation of food intake by selective agonists of mu, kappa and delta opioid receptors | Q44344308 | ||
Mu-opioid receptor knockout mice show diminished food-anticipatory activity | Q44346641 | ||
Motivational effects of cannabinoids and opioids on food reinforcement depend on simultaneous activation of cannabinoid and opioid systems | Q44348590 | ||
Intake of high-fat food is selectively enhanced by mu opioid receptor stimulation within the nucleus accumbens. | Q44348620 | ||
Evidence for early opioid modulation of licking responses to sucrose and intralipid: a microstructural analysis in the rat. | Q44350532 | ||
Resistance to diet-induced obesity in mu-opioid receptor-deficient mice: evidence for a "thrifty gene". | Q44351108 | ||
Congenic C57BL/6 mu opiate receptor (MOR) knockout mice: baseline and opiate effects. | Q44528499 | ||
Involvement of dopamine and opioids in the motivation to eat: influence of palatability, homeostatic state, and behavioral paradigms | Q46240943 | ||
Differential regulation of the consummatory, motivational and anticipatory aspects of feeding behavior by dopaminergic and opioidergic drugs | Q46736600 | ||
Differential effects of neuropeptide Y and the mu-agonist DAMGO on 'palatability' vs. 'energy'. | Q48162353 | ||
Effects of naloxone and pimozide on initiation and maintenance measures of free feeding | Q48366556 | ||
Opiate agonists microinjected into the nucleus accumbens enhance sucrose drinking in rats | Q48643158 | ||
Dual action of naloxone on feeding revealed by behavioural analysis: separate effects on initiation and termination of eating | Q49022242 | ||
Naloxone effects on sucrose-motivated behavior | Q50195339 | ||
Morphine enhances selection of both sucrose and ethanol in a two-bottle test. | Q52197749 | ||
Naloxone blocks that portion of feeding driven by sweet taste in food-restricted rats. | Q52915955 | ||
Licking Behavior in the Rat: Measurement and Situational Control of Licking Frequency | Q56865893 | ||
Analysis of lick rate measures the positive and negative feedback effects of carbohydrates on eating | Q68076200 | ||
Increased fat consumption induced by morphine administration in rats | Q70437136 | ||
Naltrexone suppresses hyperphagia induced in the rat by a highly palatable diet | Q70955809 | ||
Modifications of nutrient selection induced by naloxone in rats | Q71572163 | ||
P433 | issue | 1 | |
P921 | main subject | microstructure | Q1498213 |
opioid | Q427523 | ||
knockout mouse | Q1364740 | ||
P304 | page(s) | 105-113 | |
P577 | publication date | 2013-04-09 | |
P1433 | published in | Psychopharmacology | Q1422802 |
P1476 | title | Decreased consumption of sweet fluids in μ opioid receptor knockout mice: a microstructural analysis of licking behavior | |
P478 | volume | 229 |
Q41253350 | A Taste Circuit that Regulates Ingestion by Integrating Food and Hunger Signals |
Q39419249 | Characterizing ingestive behavior through licking microstructure: Underlying neurobiology and its use in the study of obesity in animal models |
Q49185876 | Contributions of Pavlovian incentive motivation to cue-potentiated feeding |
Q35609104 | Elevated dopamine alters consummatory pattern generation and increases behavioral variability during learning. |
Q39067911 | Feeding-modulatory effects of mu-opioids in the medial prefrontal cortex: a review of recent findings and comparison to opioid actions in the nucleus accumbens |
Q38836238 | Genetic control of oromotor phenotypes: A survey of licking and ingestive behaviors in highly diverse strains of mice |
Q36184918 | Involvement of Endogenous Enkephalins and β-Endorphin in Feeding and Diet-Induced Obesity |
Q61805720 | Limbic control over the homeostatic need for sodium |
Q64979167 | Palatability of Goat's versus Cow's Milk: Insights from the Analysis of Eating Behavior and Gene Expression in the Appetite-Relevant Brain Circuit in Laboratory Animal Models. |
Q42155707 | Parsing the hedonic and motivational influences of nociceptin on feeding using licking microstructure analysis in mice |
Q47296929 | Pattern of access determines influence of junk food diet on cue sensitivity and palatability |
Q38805493 | Recent studies of the effects of sugars on brain systems involved in energy balance and reward: Relevance to low calorie sweeteners |
Q90467701 | Reduced mu opioid receptor availability in schizophrenia revealed with [11C]-carfentanil positron emission tomographic Imaging |
Q37394324 | Responses to drugs of abuse and non-drug rewards in leptin deficient ob/ob mice |
Q34939699 | The role of opioid processes in reward and decision-making |
Q64110165 | TouchScreen-based phenotyping: altered stimulus/reward association and lower perseveration to gain a reward in mu opioid receptor knockout mice |
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