scholarly article | Q13442814 |
P50 | author | Steven H. Strogatz | Q1384920 |
P2093 | author name string | Liu C | |
Reppert SM | |||
Weaver DR | |||
P2860 | cites work | RIGUI, a putative mammalian ortholog of the Drosophila period gene | Q24316037 |
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Positional cloning of the mouse circadian clock gene | Q28238809 | ||
Mutagenesis and mapping of a mouse gene, Clock, essential for circadian behavior | Q28252722 | ||
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A Mutation of the Circadian System in Golden Hamsters | Q28297923 | ||
Transplanted suprachiasmatic nucleus determines circadian period | Q29616365 | ||
Individual neurons dissociated from rat suprachiasmatic nucleus express independently phased circadian firing rhythms | Q34058703 | ||
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Genetic analysis of circadian clocks | Q40893616 | ||
Forward genetic approach strikes gold: cloning of a mammalian clock gene | Q41478716 | ||
Gamma-aminobutyrate, gastrin releasing peptide, serotonin, somatostatin, and vasopressin: ultrastructural immunocytochemical localization in presynaptic axons in the suprachiasmatic nucleus | Q44547626 | ||
Sealing cultured invertebrate neurons to embedded dish electrodes facilitates long-term stimulation and recording | Q46179929 | ||
GABAA receptor agonist muscimol can reset the phase of neural activity rhythm in the rat suprachiasmatic nucleus in vitro | Q48189179 | ||
Maternal suprachiasmatic nuclei are necessary for maternal coordination of the developing circadian system | Q48303859 | ||
The suprachiasmatic nucleus of the golden hamster: immunohistochemical analysis of cell and fiber distribution | Q48619694 | ||
The effects of GABA and benzodiazepines on neurones in the suprachiasmatic nucleus (SCN) of Syrian hamsters | Q48706200 | ||
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Multi-neuronal signals from the retina: acquisition and analysis. | Q52219585 | ||
Frequency Plateaus in a Chain of Weakly Coupled Oscillators, I | Q64386608 | ||
Central administration of muscimol phase-shifts the mammalian circadian clock | Q69503705 | ||
Demonstration of GABAergic cell bodies in the suprachiasmatic nucleus: in situ hybridization of glutamic acid decarboxylase (GAD) mRNA and immunocytochemistry of GAD and GABA | Q69551827 | ||
Recording action potentials from cultured neurons with extracellular microcircuit electrodes | Q71069659 | ||
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Tau-mutant hamster SCN clock neurones express a 20 h firing rate rhythm in vitro | Q72568636 | ||
P433 | issue | 6 | |
P407 | language of work or name | English | Q1860 |
P921 | main subject | circadian rhythm | Q208353 |
P304 | page(s) | 855-860 | |
P577 | publication date | 1997-12-01 | |
P1433 | published in | Cell | Q655814 |
P1476 | title | Cellular construction of a circadian clock: period determination in the suprachiasmatic nuclei | |
P478 | volume | 91 |
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Q28657406 | A mechanism for circadian control of pacemaker neuron excitability |
Q30308680 | A model for "splitting" of running-wheel activity in hamsters |
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Q35794588 | A molecular model for intercellular synchronization in the mammalian circadian clock |
Q57986125 | A molecular perspective of human circadian rhythm disorders |
Q34463961 | A neural clockwork for encoding circadian time |
Q42114483 | A plastic clock |
Q37373255 | A role for the clock gene per1 in prostate cancer |
Q29615207 | A serum shock induces circadian gene expression in mammalian tissue culture cells |
Q40836093 | AII amacrine neurons of the rat retina show diurnal and circadian rhythms of parvalbumin immunoreactivity. |
Q33604201 | Accelerating recovery from jet lag: prediction from a multi-oscillator model and its experimental confirmation in model animals |
Q51813638 | Activity rhythm of golden hamster (Mesocricetus auratus) can be entrained to a 19-h light-dark cycle. |
Q47560607 | Aging transition in systems of oscillators with global distributed-delay coupling |
Q24299368 | Alternative splicing yields novel BMAL2 variants: tissue distribution and functional characterization |
Q48256679 | An abrupt shift in the day/night cycle causes desynchrony in the mammalian circadian center. |
Q73555192 | Analysis of clock proteins in mouse SCN demonstrates phylogenetic divergence of the circadian clockwork and resetting mechanisms |
Q37799147 | Approaching the molecular origins of collective dynamics in oscillating cell populations |
Q39274167 | Autonomous synchronization of the circadian KaiC phosphorylation rhythm |
Q36670251 | BK channel inactivation gates daytime excitability in the circadian clock |
Q33390371 | BK channels regulate spontaneous action potential rhythmicity in the suprachiasmatic nucleus |
Q37597772 | Basis of robustness and resilience in the suprachiasmatic nucleus: individual neurons form nodes in circuits that cycle daily |
Q30545439 | Bioluminescence imaging of individual fibroblasts reveals persistent, independently phased circadian rhythms of clock gene expression |
Q30310118 | Bulla gouldiana period exhibits unique regulation at the mRNA and protein levels |
Q48143100 | Calbindin expression in the hamster suprachiasmatic nucleus depends on day-length |
Q26738550 | Cancer Clocks Out for Lunch: Disruption of Circadian Rhythm and Metabolic Oscillation in Cancer |
Q37177687 | Cell autonomy and synchrony of suprachiasmatic nucleus circadian oscillators. |
Q34391826 | Cellular communication and coupling within the suprachiasmatic nucleus |
Q29616556 | Central and peripheral circadian clocks in mammals |
Q48525934 | Ceruloplasmin regulates iron levels in the CNS and prevents free radical injury. |
Q73930242 | Changes in circadian period and morphology of the hypothalamic suprachiasmatic nucleus in fyn kinase-deficient mice |
Q37232958 | Chimera analysis of the Clock mutation in mice shows that complex cellular integration determines circadian behavior |
Q30541014 | Chimera states in mechanical oscillator networks |
Q50560481 | Chimera states in two populations with heterogeneous phase-lag. |
Q33995017 | Chronic stimulation of the hypothalamic vasoactive intestinal peptide receptor lengthens circadian period in mice and hamsters |
Q42066350 | Chronotolerance study of the antiepileptic drug valproic acid in mice |
Q46273899 | Circadian clock cryptochrome proteins regulate autoimmunity |
Q48353112 | Circadian entrainment to temperature, but not light, in the isolated suprachiasmatic nucleus |
Q34202092 | Circadian organization and the role of the pineal in birds |
Q44872967 | Circadian ovulatory rhythms in Japanese quail: role of ocular and extraocular pacemakers |
Q48409144 | Circadian periods of single suprachiasmatic neurons in rats. |
Q34473694 | Circadian regulation of food-anticipatory activity in molecular clock-deficient mice |
Q33645413 | Circadian regulation of human sleep and age-related changes in its timing, consolidation and EEG characteristics |
Q33784815 | Circadian rhythm and its role in malignancy |
Q30416725 | Circadian rhythm generation and entrainment in astrocytes |
Q48173439 | Circadian rhythm regulation: a central role for the neuropeptide vasoactive intestinal polypeptide |
Q37556350 | Circadian rhythms and obesity in mammals |
Q48786020 | Circadian rhythms in firing rate of individual suprachiasmatic nucleus neurons from adult and middle-aged mice |
Q30308429 | Circadian rhythms in isolated brain regions. |
Q38110525 | Circadian rhythms in liver physiology and liver diseases |
Q37917313 | Circadian rhythms, aging, and life span in mammals |
Q61731526 | Circadian rhythms: A fine c(l)ocktail! |
Q28141047 | Clock controls circadian period in isolated suprachiasmatic nucleus neurons |
Q57490706 | Clock-Generated Temporal Codes Determine Synaptic Plasticity to Control Sleep |
Q92000794 | Clocks in the Wild: Entrainment to Natural Light |
Q50852672 | Collective phase response curves for heterogeneous coupled oscillators. |
Q51950093 | Collective synchronization in populations of globally coupled phase oscillators with drifting frequencies. |
Q26751434 | Collective timekeeping among cells of the master circadian clock |
Q33936315 | Contribution of circadian physiology and sleep homeostasis to age-related changes in human sleep |
Q37146498 | Controlling bursting in cortical cultures with closed-loop multi-electrode stimulation |
Q47266225 | Correlations, fluctuations, and stability of a finite-size network of coupled oscillators |
Q48546891 | Cryptochrome-deficient mice lack circadian electrical activity in the suprachiasmatic nuclei |
Q35758660 | Cyanobacterial clock, a stable phase oscillator with negligible intercellular coupling |
Q41438450 | Delayed Cryptochrome Degradation Asymmetrically Alters the Daily Rhythm in Suprachiasmatic Clock Neuron Excitability |
Q37024388 | Design principles for phase-splitting behaviour of coupled cellular oscillators: clues from hamsters with 'split' circadian rhythms |
Q39382511 | Determining the impact of cell mixing on signaling during development |
Q35288277 | Differentially timed extracellular signals synchronize pacemaker neuron clocks |
Q33523819 | Distinct functions of Period2 and Period3 in the mouse circadian system revealed by in vitro analysis |
Q34323488 | Distributed processing in cultured neuronal networks |
Q34291404 | Diurnal rhythms in neurexins transcripts and inhibitory/excitatory synapse scaffold proteins in the biological clock |
Q50872956 | Driven synchronization in random networks of oscillators. |
Q42129434 | Drosophila pacemaker neurons require g protein signaling and GABAergic inputs to generate twenty-four hour behavioral rhythms |
Q46679677 | Dynamical heterogeneity of suprachiasmatic nucleus neurons based on regularity and determinism |
Q35742358 | Dynamical signatures of cellular fluctuations and oscillator stability in peripheral circadian clocks |
Q51591746 | Dynamics of a large ring of coupled active and inactive oscillators. |
Q33722180 | Effect of feeding regimens on circadian rhythms: implications for aging and longevity |
Q34197828 | Effect of network architecture on synchronization and entrainment properties of the circadian oscillations in the suprachiasmatic nucleus |
Q74593918 | Effect of short light-dark cycles on young and adult TGR(mREN2)27 rats |
Q51774622 | Effects of light on the circadian activity rhythm of Djungarian hamsters (Phodopus sungorus) with delayed activity onset. |
Q38322135 | Electrical activity can impose time of day on the circadian transcriptome of pacemaker neurons |
Q48242435 | Electrical activity in endocrine pituitary cells in situ: a support for a multiple-function coding. |
Q35118258 | Electrophysiology of the circadian pacemaker in mammals. |
Q47318702 | Emergence of localized patterns in globally coupled networks of relaxation oscillators with heterogeneous connectivity |
Q27323028 | Emergence of noise-induced oscillations in the central circadian pacemaker |
Q36654638 | Encoding the ins and outs of circadian pacemaking |
Q33589926 | Endogenous rhythms in Period1 mutant suprachiasmatic nuclei in vitro do not represent circadian behavior. |
Q35763348 | Exploring spatiotemporal organization of SCN circuits |
Q35744463 | Expression of Period genes: rhythmic and nonrhythmic compartments of the suprachiasmatic nucleus pacemaker |
Q48264383 | Expression of basic helix-loop-helix/PAS genes in the mouse suprachiasmatic nucleus |
Q34711943 | Extracellular nitric oxide signaling in the hamster biological clock |
Q46679669 | Fractal stochastic modeling of spiking activity in suprachiasmatic nucleus neurons |
Q29011932 | From Kuramoto to Crawford: exploring the onset of synchronization in populations of coupled oscillators |
Q91822555 | From clock to functional pacemaker |
Q36831463 | Functional network inference of the suprachiasmatic nucleus |
Q52170283 | GABA synchronizes clock cells within the suprachiasmatic circadian clock. |
Q28366518 | GABA-induced current and circadian regulation of chloride in neurones of the rat suprachiasmatic nucleus |
Q35895538 | GABA-mediated repulsive coupling between circadian clock neurons in the SCN encodes seasonal time |
Q48306932 | Gate cells see the light |
Q35763357 | Gates and oscillators II: zeitgebers and the network model of the brain clock |
Q40836161 | Gates and oscillators: a network model of the brain clock. |
Q37005459 | Genetics of circadian rhythms in Mammalian model organisms |
Q34794282 | Heterogeneity of rhythmic suprachiasmatic nucleus neurons: Implications for circadian waveform and photoperiodic encoding |
Q50743449 | History-dependent changes in entrainment of the activity rhythm in the Syrian hamster (Mesocricetus auratus). |
Q27863690 | Human casein kinase Idelta phosphorylation of human circadian clock proteins period 1 and 2. |
Q28593648 | I(A) channels encoded by Kv1.4 and Kv4.2 regulate neuronal firing in the suprachiasmatic nucleus and circadian rhythms in locomotor activity |
Q37080755 | IA Channels Encoded by Kv1.4 and Kv4.2 Regulate Circadian Period of PER2 Expression in the Suprachiasmatic Nucleus |
Q34480043 | Impact of behavior on central and peripheral circadian clocks in the common vole Microtus arvalis, a mammal with ultradian rhythms |
Q36691419 | In synch but not in step: Circadian clock circuits regulating plasticity in daily rhythms |
Q31118396 | In vivo monitoring of multi-unit neural activity in the suprachiasmatic nucleus reveals robust circadian rhythms in Period1⁻/⁻ mice. |
Q30309697 | Interaction of the retina with suprachiasmatic pacemakers in the control of circadian behavior. |
Q30543329 | Intercellular coupling confers robustness against mutations in the SCN circadian clock network |
Q90265798 | Ion Channels Controlling Circadian Rhythms in Suprachiasmatic Nucleus Excitability |
Q50693651 | Kinetic theory of coupled oscillators. |
Q51059899 | Learning-rate-dependent clustering and self-development in a network of coupled phase oscillators. |
Q30416917 | Linking neural activity and molecular oscillations in the SCN. |
Q30486600 | Live imaging of altered period1 expression in the suprachiasmatic nuclei of Vipr2-/- mice. |
Q48491862 | Long-lived alphaMUPA transgenic mice exhibit pronounced circadian rhythms |
Q29619081 | Mammalian circadian biology: elucidating genome-wide levels of temporal organization |
Q36944717 | Mammalian circadian signaling networks and therapeutic targets. |
Q43965417 | Marker rhythms of circadian system function: a study of patients with metastatic colorectal cancer and good performance status. |
Q38688778 | Mathematical Frameworks for Oscillatory Network Dynamics in Neuroscience. |
Q47345333 | Measuring Relative Coupling Strength in Circadian Systems |
Q39155169 | Membrane Currents, Gene Expression, and Circadian Clocks |
Q36178428 | Minireview: The neuroendocrinology of the suprachiasmatic nucleus as a conductor of body time in mammals. |
Q36593216 | Mis-expression of the BK K(+) channel disrupts suprachiasmatic nucleus circuit rhythmicity and alters clock-controlled behavior |
Q28272329 | Modeling a synthetic multicellular clock: repressilators coupled by quorum sensing |
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Q28297151 | Molecular bases for circadian clocks |
Q34476774 | Molecular regulation of circadian rhythms in Drosophila and mammals |
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