scholarly article | Q13442814 |
review article | Q7318358 |
P6179 | Dimensions Publication ID | 1010901559 |
P356 | DOI | 10.1038/35081582 |
P698 | PubMed publication ID | 11433377 |
P5875 | ResearchGate publication ID | 11908272 |
P2093 | author name string | Buijs RM | |
Kalsbeek A | |||
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Interacting molecular loops in the mammalian circadian clock | Q29616206 | ||
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Transplanted suprachiasmatic nucleus determines circadian period | Q29616365 | ||
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Neuropeptide changes in the suprachiasmatic nucleus in primary hypertension indicate functional impairment of the biological clock | Q31912182 | ||
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A diurnal rhythm of stimulatory input to the hypothalamo-pituitary-adrenal system as revealed by timed intrahypothalamic administration of the vasopressin V1 antagonist. | Q41075420 | ||
Species difference in circadian [14C]2-deoxyglucose uptake by suprachiasmatic nuclei | Q41619353 | ||
Estrogen-receptive neurons in the anteroventral periventricular nucleus are synaptic targets of the suprachiasmatic nucleus and peri-suprachiasmatic region | Q41671554 | ||
Anticipation of 24-hr feeding schedules in rats with lesions of the suprachiasmatic nucleus | Q41723360 | ||
Vasopressin-containing neurons of the suprachiasmatic nuclei inhibit corticosterone release | Q42458458 | ||
Anatomical and functional demonstration of a multisynaptic suprachiasmatic nucleus adrenal (cortex) pathway | Q42471095 | ||
Activation of ventrolateral preoptic neurons during sleep | Q42513216 | ||
Suprachiasmatic nucleus: a central autonomic clock | Q43612704 | ||
A daily rhythm in glucose tolerance: a role for the suprachiasmatic nucleus | Q43618901 | ||
Projections from the nucleus of the solitary tract in the rat | Q44097558 | ||
Ascending projections from the solitary tract nucleus to the hypothalamus. A Phaseolus vulgaris lectin tracing study in the rat. | Q44670990 | ||
Functional connections between the suprachiasmatic nucleus and the thyroid gland as revealed by lesioning and viral tracing techniques in the rat. | Q44909521 | ||
Warning: the short days of winter may be hazardous to your health | Q46209325 | ||
??? | Q60307918 | ||
Inhibin beta, somatostatin, and enkephalin immunoreactivities coexist in caudal medullary neurons that project to the paraventricular nucleus of the hypothalamus | Q46324349 | ||
An autoradiographic and electron microscopic study of retino-hypothalamic connections | Q46689171 | ||
Three period homologs in mammals: differential light responses in the suprachiasmatic circadian clock and oscillating transcripts outside of brain. | Q47877188 | ||
Circadian regulation of cryptochrome genes in the mouse | Q47920491 | ||
Zebrafish Clock rhythmic expression reveals independent peripheral circadian oscillators | Q47972893 | ||
Vasopressin induces a luteinizing hormone surge in ovariectomized, estradiol-treated rats with lesions of the suprachiasmatic nucleus | Q48125409 | ||
A suprachiasmatic nucleus generated rhythm in basal glucose concentrations | Q48136303 | ||
GABA release from suprachiasmatic nucleus terminals is necessary for the light-induced inhibition of nocturnal melatonin release in the rat. | Q48189255 | ||
Suprachiasmatic nuclear lesions do not abolish food-shifted circadian adrenal and temperature rhythmicity | Q48277342 | ||
Pathologic evaluation of the human suprachiasmatic nucleus in severe dementia | Q48284990 | ||
Role of mouse cryptochrome blue-light photoreceptor in circadian photoresponses | Q48347156 | ||
Postmortem tracing reveals the organization of hypothalamic projections of the suprachiasmatic nucleus in the human brain | Q48380015 | ||
Recovery of axonal transport in "dead neurons". | Q48523785 | ||
Evidence for a direct neuronal pathway from the suprachiasmatic nucleus to the gonadotropin-releasing hormone system: combined tracing and light and electron microscopic immunocytochemical studies | Q48637828 | ||
Novel environment induced inhibition of corticosterone secretion: physiological evidence for a suprachiasmatic nucleus mediated neuronal hypothalamo-adrenal cortex pathway | Q48703940 | ||
The sleep-wake switch: A neuronal alarm clock | Q48722519 | ||
GABA and glutamate mediate rapid neurotransmission from suprachiasmatic nucleus to hypothalamic paraventricular nucleus in rat. | Q48876348 | ||
Effects of vagotomy on entrainment of activity rhythms to food access | Q48897950 | ||
Circadian rhythmic changes of neuronal activity in the suprachiasmatic nucleus of the rat hypothalamic slice | Q48898080 | ||
Circadian rhythm of firing rate recorded from single cells in the rat suprachiasmatic brain slice | Q48911615 | ||
A diffusible coupling signal from the transplanted suprachiasmatic nucleus controlling circadian locomotor rhythms | Q48939508 | ||
Parasympathetic and sympathetic control of the pancreas: a role for the suprachiasmatic nucleus and other hypothalamic centers that are involved in the regulation of food intake | Q48971946 | ||
Termination and secondary projections of carotid sinus nerve in the cat brain stem | Q49012999 | ||
Decrease of endogenous vasopressin release necessary for expression of the circadian rise in plasma corticosterone: a reverse microdialysis study | Q49019771 | ||
Circadian rhythms in spontaneous neuronal discharges of the cultured suprachiasmatic nucleus | Q49057638 | ||
Circadian rhythms in multiple unit activity inside and outside the suprachiasmatic nucleus in the diurnal chipmunk (Eutamias sibiricus). | Q49085789 | ||
Noninvasive ambulatory 24 h blood pressures and basal blood pressures predict development of sustained hypertension from a borderline state. | Q52038039 | ||
Circadian rhythmicity restored by neural transplant. Immunocytochemical characterization of the graft and its integration with the host brain. | Q52493909 | ||
Adrenal Innervation May Be an Extrapituitary Mechanism Able to Regulate Adrenocortical Rhythmicity in Rats* | Q52499793 | ||
Circadian clock in Malpighian tubules. | Q52552833 | ||
Decreased vasopressin gene expression in the biological clock of Alzheimer disease patients with and without depression. | Q53234225 | ||
IV.—Observations on the Normal Temperature of the Monkey and its Diurnal Variation, and on the Effect of Changes in the Daily Routine on this Variation | Q56268624 | ||
Cryptic clues to clock function | Q58991859 | ||
Circadian oscillation of the multiple unit activity in the guinea pig suprachiasmatic nucleus | Q68294398 | ||
Circadian rhythm of oxygen consumption in rat liver suspension culture: changes of pattern | Q68770947 | ||
The hypothalamic suprachiasmatic nuclei: circadian patterns of vasopressin secretion and neuronal activity in vitro | Q69394745 | ||
Oxytocin, vasopressin, and estrogen-stimulated neurophysin: daily patterns of concentration in cerebrospinal fluid | Q70677900 | ||
GABA receptors in the region of the dorsomedial hypothalamus of rats are implicated in the control of melatonin and corticosterone release | Q71610758 | ||
Colocalization of gamma-aminobutyric acid with vasopressin, vasoactive intestinal peptide, and somatostatin in the rat suprachiasmatic nucleus | Q71744934 | ||
Resetting the biological clock: mediation of nocturnal CREB phosphorylation via light, glutamate, and nitric oxide | Q71954994 | ||
Splanchnic neural activity modulates ultradian and circadian rhythms in adrenocortical secretion in awake rats | Q72291130 | ||
Adrenal sensitivity to adrenocorticotropin varies diurnally | Q72894295 | ||
Impaired diurnal cardiac autonomic function in subjects with type 2 diabetes | Q73249233 | ||
Morphological heterogeneity of the GABAergic network in the suprachiasmatic nucleus, the brain's circadian pacemaker | Q73498571 | ||
Morning and evening circadian oscillations in the suprachiasmatic nucleus in vitro | Q73567699 | ||
Melatonin sees the light: blocking GABA-ergic transmission in the paraventricular nucleus induces daytime secretion of melatonin | Q74346971 | ||
CIRCADIAN METABOLIC PATTERNS IN CULTURED HAMSTER ADRENAL GLANDS | Q76851736 | ||
P433 | issue | 7 | |
P407 | language of work or name | English | Q1860 |
P304 | page(s) | 521-526 | |
P577 | publication date | 2001-07-01 | |
P1433 | published in | Nature Reviews Neuroscience | Q2108225 |
P1476 | title | Hypothalamic integration of central and peripheral clocks | |
P478 | volume | 2 |
Q91999173 | A Robust Model for Circadian Redox Oscillations |
Q34997764 | A brain for all seasons: cellular and molecular mechanisms of photoperiodic plasticity |
Q75354796 | A circadian rhythm in the expression of PERIOD2 protein reveals a novel SCN-controlled oscillator in the oval nucleus of the bed nucleus of the stria terminalis |
Q29618069 | A clockwork web: circadian timing in brain and periphery, in health and disease |
Q57986125 | A molecular perspective of human circadian rhythm disorders |
Q28293459 | A novel link between circadian clocks and adipose tissue energy metabolism |
Q83842160 | Activation of glycine receptor phase-shifts the circadian rhythm in neuronal activity in the mouse suprachiasmatic nucleus |
Q38319522 | Acute physical stress elevates mouse period1 mRNA expression in mouse peripheral tissues via a glucocorticoid-responsive element |
Q37081710 | Adrenal peripheral clock controls the autonomous circadian rhythm of glucocorticoid by causing rhythmic steroid production. |
Q58278053 | Adrenal peripheral clock disruption leads to altered circadian behavioral responses to voluntary exercise in middle-aged female mice |
Q37851167 | Adrenal peripheral oscillator in generating the circadian glucocorticoid rhythm |
Q28577878 | Adrenergic inducibility of AP-1 binding in the rat pineal gland depends on prior photoperiod |
Q35144320 | Adrenergic regulation of clock gene expression in mouse liver |
Q44091164 | Alteration of internal circadian phase relationships after morning versus evening carbohydrate-rich meals in humans. |
Q48231917 | Alterations of locomotor activity rhythm and sleep parameters in patients with advanced glaucoma. |
Q56963458 | Altered circadian rhythm reentrainment to light phase shifts in rats with low levels of brain angiotensinogen |
Q34091480 | Altered expression of circadian rhythm genes among individuals with a history of depression |
Q37267864 | Attenuated circadian rhythms in mice lacking the prokineticin 2 gene |
Q92876079 | BMAL1 controls glucose uptake through paired-homeodomain transcription factor 4 in differentiated Caco-2 cells |
Q48437233 | Biological Rhythms Workshop I: introduction to chronobiology |
Q38122350 | Blood pressure regulation VII. The "morning surge" in blood pressure: measurement issues and clinical significance |
Q36184774 | Bright light therapy in pregnant women with major depressive disorder: study protocol for a randomized, double-blind, controlled clinical trial. |
Q34205597 | Bright-light therapy in the treatment of mood disorders |
Q36439651 | CLOCK gene variation is associated with incidence of type-2 diabetes and cardiovascular diseases in type-2 diabetic subjects: dietary modulation in the PREDIMED randomized trial |
Q47727454 | CREB Protein Mediates Alcohol-Induced Circadian Disruption and Intestinal Permeability. |
Q48148045 | Cardiovascular reactivity to stressors: effect of time of day? |
Q58577519 | Central Circadian Clock Regulates Energy Metabolism |
Q48134073 | Changes in circadian rhythm for mRNA expression of melatonin 1A and 1B receptors in the hypothalamus under a neuropathic pain-like state |
Q48416086 | Chapter 23: history of neuroendocrinology "the spring of primitive existence". |
Q37629676 | Chronobiological disorders: current and prevalent conditions |
Q35236733 | Chronobiology and mood disorders. |
Q36305111 | Circadian Disruption and Diet-Induced Obesity Synergize to Promote Development of β-Cell Failure and Diabetes in Male Rats. |
Q49946039 | Circadian Mechanisms In Alcohol Use Disorder and Tissue Injury. |
Q91588030 | Circadian Rhythms and Measures of CNS/Autonomic Interaction |
Q43922826 | Circadian and Metabolic Effects of Light: Implications in Weight Homeostasis and Health |
Q33766028 | Circadian control of glucose metabolism. |
Q27300322 | Circadian control of the daily plasma glucose rhythm: an interplay of GABA and glutamate |
Q48637314 | Circadian cycling of the mouse liver transcriptome, as revealed by cDNA microarray, is driven by the suprachiasmatic nucleus |
Q34984884 | Circadian disruption and SCN control of energy metabolism |
Q36635161 | Circadian disruption leads to loss of homeostasis and disease. |
Q34127839 | Circadian gene variants in cancer. |
Q47414437 | Circadian hormone control in a human-on-a-chip: In vitro biology's ignored component? |
Q28082902 | Circadian molecular clock in lung pathophysiology |
Q57292407 | Circadian monitoring as an aging predictor |
Q44589063 | Circadian oscillations of neuropeptide expression in the human biological clock. |
Q50302137 | Circadian oscillators in the mouse brain: molecular clock components in the neocortex and cerebellar cortex |
Q90016052 | Circadian regulation of depression: A role for serotonin |
Q47658216 | Circadian regulation of glucose, lipid, and energy metabolism in humans |
Q30416725 | Circadian rhythm generation and entrainment in astrocytes |
Q51756387 | Circadian rhythm of intraocular pressure in cats. |
Q39315051 | Circadian rhythmicity as a predictor of weight-loss effectiveness. |
Q48589136 | Circadian rhythms in murine pups develop in absence of a functional maternal circadian clock |
Q37990529 | Clock genes and clock-controlled genes in the regulation of metabolic rhythms |
Q35943690 | Clock genes in cell clocks: roles, actions, and mysteries |
Q37435208 | Clock genes, intestinal transport and plasma lipid homeostasis |
Q41650291 | Clock-controlled StAR's expression and corticosterone production contribute to the endotoxemia immune response |
Q42499688 | Clock-driven vasopressin neurotransmission mediates anticipatory thirst prior to sleep |
Q37193371 | Consequences of exposure to light at night on the pancreatic islet circadian clock and function in rats. |
Q33555476 | Cooperative roles of the suprachiasmatic nucleus central clock and the adrenal clock in controlling circadian glucocorticoid rhythm |
Q37753323 | Corticotropin-releasing hormone and arginine vasopressin in depression focus on the human postmortem hypothalamus |
Q37710849 | Corticotropin-releasing hormone, glutamate, and γ-aminobutyric acid in depression |
Q48291333 | Crosstalk between environmental light and internal time in humans. |
Q43955799 | Day-night contrast as source of health for the human circadian system |
Q94526208 | Decreased VIP and VPAC2 receptor expression in the biological clock of the R6/2 Huntington's disease mouse |
Q56506284 | Depression: chronophysiology and chronotherapy |
Q46119141 | Development of diabetes does not alter behavioral and molecular circadian rhythms in a transgenic rat model of type 2 diabetes mellitus. |
Q37117291 | Differential maturation of circadian rhythms in clock gene proteins in the suprachiasmatic nucleus and the pars tuberalis during mouse ontogeny |
Q33601559 | Disrupting circadian homeostasis of sympathetic signaling promotes tumor development in mice |
Q37918401 | Disruption of circadian rhythms: a crucial factor in the etiology of depression |
Q37154356 | Disruption of the circadian output molecule prokineticin 2 results in anxiolytic and antidepressant-like effects in mice |
Q47389458 | Disturbances of diurnal phase markers, behavior, and clock genes in a rat model of depression; modulatory effects of agomelatine treatment |
Q46754168 | Diurnal and circadian rhythms in melatonin synthesis in the turkey pineal gland and retina |
Q44799131 | Diurnal rhythms of free estradiol and cortisol during the normal menstrual cycle in women with major depression |
Q36473162 | Do corticosteroids damage the brain? |
Q27026480 | Does disruption of circadian rhythms contribute to beta-cell failure in type 2 diabetes? |
Q40902323 | Early development of circadian rhythmicity in the suprachiamatic nuclei and pineal gland of teleost, flounder (Paralichthys olivaeus), embryos |
Q46405612 | Effect of streptozotocin-induced diabetes on daily expression of per2 and dbp in the heart and liver and melatonin rhythm in the pineal gland of Wistar rat. |
Q91687429 | Effects of Light-at-Night on the Rat Liver - A Role for the Autonomic Nervous System |
Q36085717 | Effects of Photoperiod Extension on Clock Gene and Neuropeptide RNA Expression in the SCN of the Soay Sheep. |
Q48344668 | Effects of medial hypothalamic lesions on feeding-induced entrainment of locomotor activity and liver Per2 expression in Per2::luc mice |
Q39559322 | Endocrine and cardiovascular rhythms differentially adapt to chronic phase-delay shifts in rats. |
Q36185506 | Entrainment of peripheral clock genes by cortisol. |
Q38184291 | Epigenetic control and the circadian clock: linking metabolism to neuronal responses. |
Q28207575 | Estrogen-receptor-beta distribution in the human hypothalamus: similarities and differences with ER alpha distribution |
Q36912491 | Evening physical activity alters wrist temperature circadian rhythmicity |
Q93203056 | Exercise, the diurnal cycle of cortisol and cognitive impairment in older adults |
Q43084526 | Exogenous corticosterone induces the expression of the clock protein, PERIOD2, in the oval nucleus of the bed nucleus of the stria terminalis and the central nucleus of the amygdala of adrenalectomized and intact rats |
Q47662415 | Expression of the clock gene Rev-erbα in the brain controls the circadian organisation of food intake and locomotor activity, but not daily variations of energy metabolism. |
Q37161082 | FGF21 regulates metabolism and circadian behavior by acting on the nervous system |
Q47746192 | Feeding during the rest phase promotes circadian conflict in nuclei that control energy homeostasis and sleep-wake cycle in rats. |
Q50468271 | Flexible clock systems: adjusting the temporal programme. |
Q37282556 | Food for thought: hormonal, experiential, and neural influences on feeding and obesity. |
Q34997754 | Functional plasticity of the circadian timing system in old age: light exposure |
Q48730406 | Genetic interaction of Per1 and Dec1/2 in the regulation of circadian locomotor activity |
Q30435771 | Genetic suppression of the circadian Clock mutation by the melatonin biosynthesis pathway |
Q37005459 | Genetics of circadian rhythms in Mammalian model organisms |
Q57471225 | Ghrelin Restores the Disruption of the Circadian Clock in Steatotic Liver |
Q28552603 | Glucose Alters Per2 Rhythmicity Independent of AMPK, Whereas AMPK Inhibitor Compound C Causes Profound Repression of Clock Genes and AgRP in mHypoE-37 Hypothalamic Neurons |
Q50618539 | Glucose metabolism during rotational shift-work in healthcare workers. |
Q39707055 | HSG cells, a model in the submandibular clock. |
Q37202998 | How to assess circadian rhythm in humans: a review of literature |
Q35009353 | Human clock genes |
Q33930296 | Hypertension and cardiovascular remodelling in rats exposed to continuous light: protection by ACE-inhibition and melatonin. |
Q34567401 | Hypocretins: the timing of sleep and waking |
Q38235229 | Hypothalamic alterations in Huntington's disease patients: comparison with genetic rodent models. |
Q37808731 | Hypothalamic control of energy metabolism via the autonomic nervous system. |
Q35138575 | Impact of nutrients on circadian rhythmicity |
Q48336867 | Impaired sodium levels in the suprachiasmatic nucleus are associated with the formation of cardiovascular deficiency in sleep‐deprived rats |
Q36691419 | In synch but not in step: Circadian clock circuits regulating plasticity in daily rhythms |
Q44197961 | Indirect projections from the suprachiasmatic nucleus to the ventrolateral preoptic nucleus: a dual tract-tracing study in rat. |
Q44810838 | Influence of the corticosterone rhythm on photic entrainment of locomotor activity in rats. |
Q30543329 | Intercellular coupling confers robustness against mutations in the SCN circadian clock network |
Q46283721 | Introduction to Chronobiology |
Q90265798 | Ion Channels Controlling Circadian Rhythms in Suprachiasmatic Nucleus Excitability |
Q36198496 | Just the two of us: melatonin and adenosine in rodent pituitary function |
Q36636975 | Kisspeptins and RFRP-3 Act in Concert to Synchronize Rodent Reproduction with Seasons |
Q38298605 | Leptin modulates the daily rhythmicity of blood glucose |
Q44366961 | Light induces cortical activation and yawning in rats |
Q36411345 | Loss of the mu opioid receptor on different genetic backgrounds leads to increased bromodeoxyuridine labeling in the dentate gyrus only after repeated injection |
Q29619081 | Mammalian circadian biology: elucidating genome-wide levels of temporal organization |
Q36944717 | Mammalian circadian signaling networks and therapeutic targets. |
Q82240414 | Melatonin |
Q34596664 | Melatonin and anesthesia: a clinical perspective. |
Q36793940 | Melatonin as a potential antihypertensive treatment |
Q38580390 | Melatonin in animal models. |
Q36474461 | Melatonin in the multi-oscillatory mammalian circadian world |
Q38809126 | Melatonin receptors as therapeutic targets in the suprachiasmatic nucleus |
Q28387301 | Melatonin: a novel indolamine in oral health and disease |
Q36835794 | Melatonin: potential functions in the oral cavity. |
Q46808029 | Melatoninergic receptor agonists and antagonists: pharmacological aspects and therapeutic perspective |
Q51466101 | Metabolic homeostasis in mice with disrupted Clock gene expression in peripheral tissues. |
Q49160552 | Microconnectomics of the pretectum and ventral thalamus in the chicken (Gallus gallus). |
Q97533418 | Molecular Mechanisms Underlying the Circadian Rhythm of Blood Pressure in Normotensive Subjects |
Q89665986 | Multilevel Interactions of Stress and Circadian System: Implications for Traumatic Stress |
Q55315021 | Multimodal Regulation of Circadian Glucocorticoid Rhythm by Central and Adrenal Clocks. |
Q34688145 | Neurohypophyseal peptides in aging and Alzheimer's disease |
Q35952741 | Neuropeptides in hypothalamic neuronal disorders |
Q40868967 | Neurosteroidogenesis is required for the physiological response to stress: role of neurosteroid-sensitive GABAA receptors |
Q25257183 | Neurotransmitters of the suprachiasmatic nuclei |
Q88641699 | Nighttime light exposure enhances Rev-erbα-targeting microRNAs and contributes to hepatic steatosis |
Q47793695 | Olanzapine-induced early cardiovascular effects are mediated by the biological clock and prevented by melatonin |
Q47608533 | Orexin neurons function in an efferent pathway of a food-entrainable circadian oscillator in eliciting food-anticipatory activity and wakefulness. |
Q33817309 | PER2 rhythms in the amygdala and bed nucleus of the stria terminalis of the diurnal grass rat (Arvicanthis niloticus) |
Q24568134 | PERIOD2::LUCIFERASE real-time reporting of circadian dynamics reveals persistent circadian oscillations in mouse peripheral tissues |
Q62511339 | POMC: The Physiological Power of Hormone Processing |
Q64074460 | Perinatal Stress Programs Sex Differences in the Behavioral and Molecular Chronobiological Profile of Rats Maintained Under a 12-h Light-Dark Cycle |
Q46459431 | Peripheral circadian clocks--a conserved phenotype? |
Q48526746 | Phenotypic rescue of a peripheral clock genetic defect via SCN hierarchical dominance |
Q89457666 | Physiological Glucocorticoid Replacement in Adrenal Insufficiency: Does It Fix the Broken Clock? |
Q33763925 | Postnatal ontogenesis of clock genes in mouse suprachiasmatic nucleus and heart |
Q33737223 | Prevention of depression and sleep disturbances in elderly with memory-problems by activation of the biological clock with light--a randomized clinical trial |
Q35568614 | Prokineticin receptor 2 (Prokr2) is essential for the regulation of circadian behavior by the suprachiasmatic nuclei. |
Q37115125 | Reduction of scale invariance of activity fluctuations with aging and Alzheimer's disease: Involvement of the circadian pacemaker |
Q36329903 | Replication of cortisol circadian rhythm: new advances in hydrocortisone replacement therapy |
Q28509376 | Rhythmic SAF-A binding underlies circadian transcription of the Bmal1 gene |
Q33403741 | Rhythmicity in mice selected for extremes in stress reactivity: behavioural, endocrine and sleep changes resembling endophenotypes of major depression |
Q48101291 | Role of the Suprachiasmatic and Arcuate Nuclei in Diurnal Temperature Regulation in the Rat. |
Q36654635 | SCN outputs and the hypothalamic balance of life |
Q39739995 | Selective parasympathetic innervation of subcutaneous and intra-abdominal fat--functional implications |
Q30427868 | Sex difference in the near-24-hour intrinsic period of the human circadian timing system |
Q33699208 | Sex differences in circadian timing systems: implications for disease. |
Q34658096 | Shift work or food intake during the rest phase promotes metabolic disruption and desynchrony of liver genes in male rats |
Q47648366 | Shift-work: is time of eating determining metabolic health? Evidence from animal models |
Q33656079 | Simulated shift work in rats perturbs multiscale regulation of locomotor activity |
Q30405372 | Sleep Disturbance and Altered Expression of Circadian Clock Genes in Patients With Sudden Sensorineural Hearing Loss |
Q47637646 | Sleep Disturbance, Cognitive Decline, and Dementia: A Review |
Q38290962 | Sleep disturbances and dementia |
Q33661852 | Studying sex and gender differences in pain and analgesia: a consensus report. |
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Q37802477 | Suprachiasmatic nucleus and autonomic nervous system influences on awakening from sleep |
Q37141101 | Suprachiasmatic nucleus clock time in the mammalian circadian system |
Q44781000 | Suprachiasmatic nucleus input to autonomic circuits identified by retrograde transsynaptic transport of pseudorabies virus from the eye. |
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Q33778695 | Taxicab tipping and sunlight |
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Q37730230 | The Circadian Clock in the Ventromedial Hypothalamus Controls Cyclic Energy Expenditure |
Q38800342 | The Circadian System: A Regulatory Feedback Network of Periphery and Brain |
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Q28207565 | The VPAC(2) receptor is essential for circadian function in the mouse suprachiasmatic nuclei |
Q37908474 | The adrenal peripheral clock: glucocorticoid and the circadian timing system |
Q34319072 | The biological clock: the bodyguard of temporal homeostasis. |
Q35684024 | The brain's calendar: neural mechanisms of seasonal timing. |
Q35118733 | The circadian clock: pacemaker and tumour suppressor |
Q28299078 | The clock gene Per2 influences the glutamatergic system and modulates alcohol consumption |
Q35541524 | The emotional ear in stress |
Q36051556 | The human pineal gland and melatonin in aging and Alzheimer's disease |
Q36550663 | The hypothalamic clock and its control of glucose homeostasis |
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Q35964417 | The importance of biological oscillators for hypothalamic-pituitary-adrenal activity and tissue glucocorticoid response: coordinating stress and neurobehavioural adaptation |
Q26828996 | The islet circadian clock: entrainment mechanisms, function and role in glucose homeostasis |
Q35145874 | The mammalian circadian clock |
Q34625822 | The output signal of Purkinje cells of the cerebellum and circadian rhythmicity |
Q35966467 | The role of circadian rhythmicity in reproduction |
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Q44515248 | The suprachiasmatic nucleus balances sympathetic and parasympathetic output to peripheral organs through separate preautonomic neurons |
Q48049593 | The suprachiasmatic nucleus drives day-night variations in postprandial triglyceride uptake into skeletal muscle and brown adipose tissue. |
Q37382549 | The suprachiasmatic nucleus functions beyond circadian rhythm generation. |
Q34571113 | The transcription factor Runx2 is under circadian control in the suprachiasmatic nucleus and functions in the control of rhythmic behavior |
Q35006489 | Time after time: inputs to and outputs from the mammalian circadian oscillators |
Q50067287 | Time for Bed: Genetic Mechanisms Mediating the Circadian Regulation of Sleep. |
Q36895164 | Tumor suppression and circadian function |
Q57049937 | Ultradian calcium rhythms in the paraventricular nucleus and subparaventricular zone in the hypothalamus |
Q34664130 | Uncovering different masking factors on wrist skin temperature rhythm in free-living subjects. |
Q48197801 | Vagal regulation of respiratory clocks in mice. |
Q28508879 | Vascular PPARgamma controls circadian variation in blood pressure and heart rate through Bmal1 |
Q38882451 | When to eat? The influence of circadian rhythms on metabolic health: are animal studies providing the evidence? |
Q35586150 | White Adipose Tissue: Getting Nervous |
Q79374871 | [Interactions of melatonin with the central nervous system] |
Q79374873 | [The melatoninergic system] |
Q57682974 | β-carotene ameliorates CUS-induced circadian alternations of locomotor activity and melatonin patterns in rats |
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