| scholarly article | Q13442814 |
| P819 | ADS bibcode | 2011PNAS..108.5813A |
| P356 | DOI | 10.1073/PNAS.1015551108 |
| P932 | PMC publication ID | 3078408 |
| P698 | PubMed publication ID | 21402951 |
| P5875 | ResearchGate publication ID | 50395123 |
| P50 | author | Chun-Xia Yi | Q64218626 |
| Pertti Panula | Q30232813 | ||
| P2093 | author name string | Jan van der Vliet | |
| Ruud M Buijs | |||
| Jack H Jhamandas | |||
| Carolina Escobar | |||
| Manuel Angeles-Castellanos | |||
| María Del Carmen Basualdo | |||
| Guadalupe Acosta-Galvan | |||
| P2860 | cites work | Unpredictable feeding schedules unmask a system for daily resetting of behavioural and metabolic food entrainment | Q46900875 |
| c-Fos expression in hypothalamic nuclei of food-entrained rats | Q47671792 | ||
| Differential regulation of the expression of Period2 protein in the limbic forebrain and dorsomedial hypothalamus by daily limited access to highly palatable food in food-deprived and free-fed rats. | Q48148792 | ||
| Ultrastructural evidence for intra- and extranuclear projections of GABAergic neurons of the suprachiasmatic nucleus | Q48174027 | ||
| Projections of the suprachiasmatic nucleus to stress‐related areas in the rat hypothalamus: A light and electron microscopic study | Q48229986 | ||
| The ventromedial hypothalamic nucleus is not essential for the prefeeding corticosterone peak in rats under restricted daily feeding | Q48232046 | ||
| Suprachiasmatic nuclear lesions do not abolish food-shifted circadian adrenal and temperature rhythmicity | Q48277342 | ||
| The projections of the dorsomedial hypothalamic nucleus in the rat. | Q48381084 | ||
| Restricted feeding schedules phase shift daily rhythms of c-Fos and protein Per1 immunoreactivity in corticolimbic regions in rats | Q48395608 | ||
| Correlation with behavioral activity and rest implies circadian regulation by SCN neuronal activity levels. | Q48402719 | ||
| Persistence of a behavioral food-anticipatory circadian rhythm following dorsomedial hypothalamic ablation in rats | Q48460198 | ||
| Fos-like immunoreactivity in the circadian timing system of calorie-restricted rats fed at dawn: daily rhythms and light pulse-induced changes | Q48559364 | ||
| In vivo metabolic activity of the suprachiasmatic nuclei: a comparative study. | Q48739043 | ||
| Cholecystokinin activates C-fos expression in hypothalamic oxytocin and corticotropin-releasing hormone neurons | Q48742064 | ||
| Ventromedial arcuate nucleus communicates peripheral metabolic information to the suprachiasmatic nucleus | Q48757989 | ||
| Ventromedial hypothalamic lesions abolish food-shifted circadian adrenal and temperature rhythmicity | Q49161288 | ||
| Feeding-entrained circadian rhythms are attenuated by lesions of the parabrachial region in rats | Q50136434 | ||
| The dorsomedial hypothalamic nucleus is not necessary for the expression of circadian food-anticipatory activity in rats. | Q51970580 | ||
| Role of ion flux in the control of c-fos expression | Q57963317 | ||
| Feeding schedules and the circadian organization of behavior in the rat | Q70935383 | ||
| Masking of locomotor activity in hamsters | Q77908578 | ||
| A circulating ghrelin mimetic attenuates light-induced phase delay of mice and light-induced Fos expression in the suprachiasmatic nucleus of rats | Q81085178 | ||
| Circadian Rhythms in Drinking Behavior and Locomotor Activity of Rats Are Eliminated by Hypothalamic Lesions | Q24563025 | ||
| Differential rescue of light- and food-entrainable circadian rhythms | Q24618271 | ||
| The dorsomedial hypothalamic nucleus as a putative food-entrainable circadian pacemaker | Q24670445 | ||
| The dorsomedial hypothalamic nucleus is critical for the expression of food-entrainable circadian rhythms | Q28298448 | ||
| Neuropeptide FF reduces food intake in rats | Q28576905 | ||
| Stomach ghrelin-secreting cells as food-entrainable circadian clocks | Q30489507 | ||
| Robust food anticipatory activity in BMAL1-deficient mice | Q33419850 | ||
| Loss of a circadian adrenal corticosterone rhythm following suprachiasmatic lesions in the rat. | Q34053330 | ||
| Formation of projection pathways from the arcuate nucleus of the hypothalamus to hypothalamic regions implicated in the neural control of feeding behavior in mice. | Q34306814 | ||
| Reduced anticipatory locomotor responses to scheduled meals in ghrelin receptor deficient mice. | Q34378314 | ||
| Local origins of some GABAergic projections to the paraventricular and supraoptic nuclei of the hypothalamus in the rat | Q36696192 | ||
| Daily rhythms of food-anticipatory behavioral activity do not require the known circadian clock | Q37151633 | ||
| Standards of evidence in chronobiology: critical review of a report that restoration of Bmal1 expression in the dorsomedial hypothalamus is sufficient to restore circadian food anticipatory rhythms in Bmal1-/- mice | Q37162934 | ||
| Intrinsic, nondeterministic circadian rhythm generation in identified mammalian neurons | Q37364031 | ||
| Lesion studies targeting food-anticipatory activity | Q37623043 | ||
| Peripheral oscillators: the driving force for food-anticipatory activity | Q37624847 | ||
| Entrainment of circadian rhythms by feeding schedules in rats with suprachiasmatic lesions | Q41723411 | ||
| A major role for perifornical orexin neurons in the control of glucose metabolism in rats | Q41888343 | ||
| Mapping patterns of c-fos expression in the central nervous system after seizure | Q42206675 | ||
| The cerebellum harbors a circadian oscillator involved in food anticipation. | Q43174619 | ||
| The suprachiasmatic nucleus participates in food entrainment: a lesion study | Q43224462 | ||
| Intracerebroventricular injection of neuropeptide FF, an opioid modulating neuropeptide, acutely reduces food intake and stimulates water intake in the rat. | Q43780983 | ||
| Neuropeptide FF exerts pro- and anti-opioid actions in the parabrachial nucleus to modulate food intake | Q44343092 | ||
| Ascending projections from the solitary tract nucleus to the hypothalamus. A Phaseolus vulgaris lectin tracing study in the rat. | Q44670990 | ||
| The dorsomedial hypothalamic nucleus is not necessary for food-anticipatory circadian rhythms of behavior, temperature or clock gene expression in mice. | Q45972908 | ||
| Environmental light and suprachiasmatic nucleus interact in the regulation of body temperature. | Q46414512 | ||
| P4510 | describes a project that uses | ImageJ | Q1659584 |
| P433 | issue | 14 | |
| P407 | language of work or name | English | Q1860 |
| P304 | page(s) | 5813-5818 | |
| P577 | publication date | 2011-03-14 | |
| P1433 | published in | Proceedings of the National Academy of Sciences of the United States of America | Q1146531 |
| P1476 | title | Interaction between hypothalamic dorsomedial nucleus and the suprachiasmatic nucleus determines intensity of food anticipatory behavior | |
| P478 | volume | 108 |
| Q34456527 | A circadian clock in the olfactory bulb anticipates feeding during food anticipatory activity. |
| Q30370281 | Activity-Based Anorexia Reduces Body Weight without Inducing a Separate Food Intake Microstructure or Activity Phenotype in Female Rats-Mediation via an Activation of Distinct Brain Nuclei |
| Q33734974 | Adaptation to short photoperiods augments circadian food anticipatory activity in Siberian hamsters |
| Q33914477 | Age-related circadian disorganization caused by sympathetic dysfunction in peripheral clock regulation |
| Q35593227 | Artificial feeding synchronizes behavioral, hormonal, metabolic and neural parameters in mother-deprived neonatal rabbit pups. |
| Q35164738 | Behavioral and neural correlates of acute and scheduled hunger in C57BL/6 mice. |
| Q48033695 | Bmal1 in the nervous system is essential for normal adaptation of circadian locomotor activity and food intake to periodic feeding. |
| Q52597446 | Brain Activity during Methamphetamine Anticipation in a Non-Invasive Self-Administration Paradigm in Mice. |
| Q58577519 | Central Circadian Clock Regulates Energy Metabolism |
| Q29616556 | Central and peripheral circadian clocks in mammals |
| Q91817189 | Chocolate for breakfast prevents circadian desynchrony in experimental models of jet-lag and shift-work |
| Q50599434 | Circadian Rhythms in Diet-Induced Obesity. |
| Q27000418 | Circadian adaptations to meal timing: neuroendocrine mechanisms |
| Q34166475 | Circadian clocks for all meal-times: anticipation of 2 daily meals in rats |
| Q48172497 | Circadian discrimination of reward: evidence for simultaneous yet separable food- and drug-entrained rhythms in the rat. |
| Q35516264 | Circadian mechanisms of food anticipatory rhythms in rats fed once or twice daily: clock gene and endocrine correlates |
| Q35272998 | Circadian rhythms have broad implications for understanding brain and behavior |
| Q27314930 | Cognitive performance as a zeitgeber: cognitive oscillators and cholinergic modulation of the SCN entrain circadian rhythms |
| Q99202953 | Comprehensive Topographical Map of the Serotonergic Fibers in the Male Mouse Brain |
| Q38026657 | Contribution of the mesolimbic dopamine system in mediating the effects of leptin and ghrelin on feeding |
| Q51325859 | Daily patterns and adaptation of the ghrelin, growth hormone and insulin-like growth factor-1 system under daytime food synchronisation in rats. |
| Q35192127 | Deficiency of Prdm13, a dorsomedial hypothalamus-enriched gene, mimics age-associated changes in sleep quality and adiposity |
| Q57443628 | Differences in locomotor activity before and during the access to food in a restricted feeding protocol between obese and lean female miceNeotomodon alstoni |
| Q34983700 | Differential effects of light and feeding on circadian organization of peripheral clocks in a forebrain Bmal1 mutant |
| Q28543723 | Dopamine receptor 1 neurons in the dorsal striatum regulate food anticipatory circadian activity rhythms in mice |
| Q89155239 | Dorsal striatum dopamine oscillations: Setting the pace of food anticipatory activity |
| Q35231871 | Dorsomedial hypothalamic lesions counteract decreases in locomotor activity in male Syrian hamsters transferred from long to short day lengths |
| Q26750880 | Endocrine regulation of circadian physiology |
| Q36099540 | Entrainment of mouse peripheral circadian clocks to <24 h feeding/fasting cycles under 24 h light/dark conditions |
| Q34017865 | Evidence for time-of-day dependent effect of neurotoxic dorsomedial hypothalamic lesions on food anticipatory circadian rhythms in rats |
| Q34287635 | Field and laboratory studies provide insights into the meaning of day-time activity in a subterranean rodent (Ctenomys aff. knighti), the tuco-tuco |
| Q48335076 | Food cues and ghrelin recruit the same neuronal circuitry. |
| Q38064453 | Food entrainment: major and recent findings. |
| Q55546705 | Food-Anticipatory Behavior in Neonatal Rabbits and Rodents: An Update on the Role of Clock Genes. |
| Q35602973 | Food-anticipatory activity in Syrian hamsters: behavioral and molecular responses in the hypothalamus according to photoperiodic conditions |
| Q42281684 | GHS-R1a signaling in the DMH and VMH contributes to food anticipatory activity. |
| Q46629444 | Ghrelin receptor-knockout mice display alterations in circadian rhythms of activity and feeding under constant lighting conditions. |
| Q36075142 | Histamine and motivation. |
| Q39427040 | Hypothalamic Integration of Metabolic, Endocrine, and Circadian Signals in Fish: Involvement in the Control of Food Intake. |
| Q36909642 | Interactive Effects of Dorsomedial Hypothalamic Nucleus and Time-Restricted Feeding on Fractal Motor Activity Regulation |
| Q34257171 | Isolating neural correlates of the pacemaker for food anticipation |
| Q34219410 | Laser-capture microdissection and transcriptional profiling of the dorsomedial nucleus of the hypothalamus |
| Q61816847 | Mechanisms of Communication in the Mammalian Circadian Timing System |
| Q37339548 | Molecular profiling of activated neurons by phosphorylated ribosome capture |
| Q38557082 | Molecular regulation of hypothalamic development and physiological functions |
| Q41884548 | Neither the SCN nor the adrenals are required for circadian time-place learning in mice |
| Q38600079 | Neural Correlates of Food Anticipatory Activity in Mice Subjected to Once or Twice-daily Feeding Periods |
| Q91781637 | New Insights Into the Circadian Rhythm and Its Related Diseases |
| Q38395194 | Patterning, specification, and differentiation in the developing hypothalamus |
| Q35063996 | Photic and pineal modulation of food anticipatory circadian activity rhythms in rodents |
| Q94441082 | Retinal innervation tunes circuits that drive nonphotic entrainment to food |
| Q37067778 | Rev-erbα in the brain is essential for circadian food entrainment. |
| Q38654302 | Scheduled feeding restores memory and modulates c-Fos expression in the suprachiasmatic nucleus and septohippocampal complex |
| Q47715016 | Scheduled meal accelerates entrainment to a 6-h phase advance by shifting central and peripheral oscillations in rats. |
| Q33656079 | Simulated shift work in rats perturbs multiscale regulation of locomotor activity |
| Q48116538 | Stem cells and the circadian clock. |
| Q29248275 | Suprachiasmatic Nucleus Interaction with the Arcuate Nucleus; Essential for Organizing Physiological Rhythms |
| Q90397591 | The Mysterious Food-Entrainable Oscillator: Insights from Mutant and Engineered Mouse Models |
| Q28069041 | The mammalian circadian clock and its entrainment by stress and exercise |
| Q48786572 | The medial preoptic nucleus as a site of the thermogenic and metabolic actions of melanotan II in male rats. |
| Q39273992 | The median preoptic nucleus exhibits circadian regulation and is involved in food anticipatory activity in rabbit pups |
| Q34625822 | The output signal of Purkinje cells of the cerebellum and circadian rhythmicity |
| Q48049593 | The suprachiasmatic nucleus drives day-night variations in postprandial triglyceride uptake into skeletal muscle and brown adipose tissue. |
| Q36164254 | Time-Specific Fear Acts as a Non-Photic Entraining Stimulus of Circadian Rhythms in Rats |
| Q36850798 | Unravelling the mysterious roles of melanocortin-3 receptors in metabolic homeostasis and obesity using mouse genetics |
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