Abstract is: The Journal of Circadian Rhythms is a peer-reviewed open access scientific journal covering circadian and nycthemeral (daily) rhythms in living organisms, including processes associated with photoperiodism and daily torpor. It was established in 2003 and originally published by BioMed Central. Since 2015 it is published by Ubiquity Press. The editor-in-chief is Roberto Refinetti (Boise State University).
| academic journal | Q737498 |
| open-access journal | Q773668 |
| scientific journal | Q5633421 |
| P6981 | ACNP journal ID | 2235025 |
| P1159 | CODEN | JCROB5 |
| P8375 | Crossref journal ID | 20817 |
| P5115 | Directory of Open Access Journals ID | 1740-3391 |
| P1058 | ERA Journal ID | 42112 |
| P646 | Freebase ID | /m/012r3q6w |
| P8903 | HAL journal ID | 1385 |
| P236 | ISSN | 1740-3391 |
| P7363 | ISSN-L | 1740-3391 |
| P4730 | Mir@bel journal ID | 7758 |
| P1055 | NLM Unique ID | 101200389 |
| P243 | OCLC control number | 53403314 |
| P856 | official website | http://www.pubmedcentral.nih.gov/tocrender.fcgi?journal=225 |
| https://www.jcircadianrhythms.com/ | ||
| P10283 | OpenAlex ID | V151421263 |
| P3181 | OpenCitations bibliographic resource ID | 42653 |
| P12834 | PMC journal ID | 225 |
| P7662 | Scilit journal ID | 57447 |
| P1156 | Scopus source ID | 15854 |
| P1025 | SUDOC editions | 124375499 |
| P4616 | UniProt journal ID | 4344 |
| P166 | award received | DOAJ seal | Q73548471 |
| P972 | catalog | Directory of Open Access Journals | Q1227538 |
| P275 | copyright license | Creative Commons Attribution | Q6905323 |
| P6216 | copyright status | copyrighted | Q50423863 |
| P17 | country | United Kingdom | Q145 |
| P495 | country of origin | United Kingdom | Q145 |
| P571 | inception | 2003-01-01 | |
| P8875 | indexed in bibliographic review | Scopus | Q371467 |
| P407 | language of work or name | English | Q1860 |
| P921 | main subject | biology | Q420 |
| P123 | publisher | Ubiquity Press | Q7876554 |
| P1476 | title | Journal of Circadian Rhythms |
| Q33875281 | "Time sweet time": circadian characterization of galectin-1 null mice. |
| Q50225677 | A Bibliometric Analysis of the Top 100 Most Cited Chronotype Research Papers. |
| Q113998625 | A Functional Adenosine Deaminase Polymorphism Associates with Evening Melatonin Levels and Sleep Quality |
| Q31082966 | A Functional Data Analysis Approach for Circadian Patterns of Activity of Teenage Girls |
| Q36807047 | A PER3 Polymorphism Interacts with Sleep Duration to Influence Transient Mood States in Women |
| Q36327793 | A QTL on mouse chromosome 12 for the genetic variance in free-running circadian period between inbred strains of mice |
| Q64922161 | A Systematic Search and Mapping Review of Studies on Intracerebral Microdialysis of Amino Acids, and Systematized Review of Studies on Circadian Rhythms. |
| Q36099182 | A dynamic model of circadian rhythms in rodent tail skin temperature for comparison of drug effects |
| Q24653855 | A new approach to understanding the impact of circadian disruption on human health |
| Q37317991 | A possible connection between psychosomatic symptoms and daily rhythmicity in growth hormone secretion in healthy Japanese students |
| Q36953382 | A tryptophan-rich breakfast and exposure to light with low color temperature at night improve sleep and salivary melatonin level in Japanese students |
| Q41878859 | Absence of a serum melatonin rhythm under acutely extended darkness in the horse |
| Q41869606 | Aging related changes of circadian rhythmicity of cytotoxic lymphocyte subpopulations. |
| Q35023169 | Altered expression of circadian clock gene, mPer1, in mouse brain and kidney under morphine dependence and withdrawal |
| Q42252623 | An out-of-lab trial: a case example for the effect of intensive exercise on rhythms of human clock gene expression |
| Q58424826 | Are Type 2 Diabetes Mellitus and Depression Part of a Common Clock Genes Network? |
| Q60909288 | Brain Microdialysate Monoamines in Relation to Circadian Rhythms, Sleep, and Sleep Deprivation – a Systematic Review, Network Meta-analysis, and New Primary Data |
| Q33787302 | CLOCK is suggested to associate with comorbid alcohol use and depressive disorders |
| Q24803986 | Central fatigue and nycthemeral change of serum tryptophan and serotonin in the athletic horse |
| Q113998623 | Changes in 24 h Rhythmicity of Spontaneous Locomotor Activity in the Triple Transgenic Mouse for Alzheimer’s Disease (3xTg-AD) in a Jet Lag Protocol: Correlations with Retinal Sensitivity |
| Q36604558 | Characterization of locomotor activity circadian rhythms in athymic nude mice |
| Q30431353 | Chronic inhibition of endoplasmic reticulum calcium-release channels and calcium-ATPase lengthens the period of hepatic clock gene Per1. |
| Q49880945 | Chronobiological Hypothesis about the Association Between Height Growth Seasonality and Geographical Differences in Body Height According to Effective Day Length. |
| Q42066350 | Chronotolerance study of the antiepileptic drug valproic acid in mice |
| Q37224939 | Chronotypology and melatonin alterations in minimal hepatic encephalopathy. |
| Q58801911 | Circadian Effects on Performance and Effort in Collegiate Swimmers |
| Q40159317 | Circadian Pattern of Melatonin MT1 and MT2 Receptor Localization in the Rat Suprachiasmatic Nucleus |
| Q36807059 | Circadian Phase-Shifting Effects of Bright Light, Exercise, and Bright Light + Exercise |
| Q91418597 | Circadian Rhythms, Exercise, and Cardiovascular Health |
| Q91046421 | Circadian Variation in Vasoconstriction and Vasodilation Mediators and Baroreflex Sensitivity in Hypertensive Rats |
| Q45756945 | Circadian and Geotactic Behaviors: Genetic Pleiotropy in Drosophila Melanogaster. |
| Q37153448 | Circadian behavior of mice deficient in PER1/PML or PER2/PML |
| Q33777263 | Circadian light |
| Q28218292 | Circadian phase response curves to light in older and young women and men |
| Q24815472 | Circadian phase-shifting effects of a laboratory environment: a clinical trial with bright and dim light. |
| Q37142227 | Circadian polymorphisms associated with affective disorders. |
| Q33784815 | Circadian rhythm and its role in malignancy |
| Q36473589 | Circadian rhythm dysfunction in glaucoma: A hypothesis |
| Q35070266 | Clock mutation affects circadian regulation of circulating blood cells. |
| Q55261556 | Comparison of Melatonin Profile and Alertness of Firefighters with Different Work Schedules. |
| Q46942289 | DEC2 Blocks the Effect of the ARNTL2/NPAS2 Dimer on the Expression of PER3 and DBP. |
| Q47117588 | Daily Rhythms of Blood Parameters in Broiler Chickens Reared under Tropical Climate Conditions. |
| Q37523396 | Daily blood feeding rhythms of laboratory-reared North American Culex pipiens |
| Q30430107 | Daily cycling of nitric oxide synthase (NOS) in the hippocampus of pigeons (C. livia) |
| Q25255533 | Daily illumination exposure and melatonin: influence of ophthalmic dysfunction and sleep duration |
| Q24802151 | Daily oviposition patterns of the African malaria mosquito Anopheles gambiae Giles (Diptera: Culicidae) on different types of aqueous substrates |
| Q24804315 | Daily rhythm of cerebral blood flow velocity |
| Q24793212 | Daily rhythm of circulating fat soluble vitamin concentration (A, D, E and K) in the horse |
| Q24792275 | Daily rhythm of nociception in rats |
| Q35171993 | Daily rhythm of salivary and serum urea concentration in sheep. |
| Q24796420 | Daily rhythms in plasma levels of homocysteine |
| Q113998622 | Day-Night Variations in the Concentration of Neurotransmitters in the Rat Lumbar Spinal Cord |
| Q21245388 | Delayed sleep phase cases and controls |
| Q41815852 | Determinants of the daily rhythm of blood fluidity |
| Q24522301 | Development of daily rhythmicity in heart rate and locomotor activity in the human fetus |
| Q54158427 | Differences in Photic Entrainment of Circadian Locomotor Activity Between Lean and Obese Volcano Mice (Neotomodon alstoni). |
| Q47159458 | Differential Expression of Circadian Genes in Leukemia and a Possible Role for Sirt1 in Restoring the Circadian Clock in Chronic Myeloid Leukemia. |
| Q42323137 | Differential roles of breakfast only (one meal per day) and a bigger breakfast with a small dinner (two meals per day) in mice fed a high-fat diet with regard to induced obesity and lipid metabolism |
| Q39831037 | Diurnal Preference Predicts Phase Differences in Expression of Human Peripheral Circadian Clock Genes |
| Q94672570 | Diurnal Preference and Grey Matter Volume in a Large Population of Older Adults: Data from the UK Biobank |
| Q42846772 | Diurnal and nutritional adjustments of intracellular Ca2+ release channels and Ca2+ ATPases associated with restricted feeding schedules in the rat liver |
| Q36649365 | Diurnal-and sex-related difference of metallothionein expression in mice |
| Q64103014 | Dysregulation of Circadian Rhythm Gene Expression in Cystic Fibrosis Mice |
| Q37164869 | Effect of chronic ethanol exposure on the liver of Clock-mutant mice |
| Q24814860 | Effect of litter separation on 24-hour rhythmicity of plasma prolactin, follicle-stimulating hormone and luteinizing hormone levels in lactating rabbit does |
| Q50299966 | Effects of Cold-Dry (Harmattan) and Hot-Dry Seasons on Daily Rhythms of Rectal and Body Surface Temperatures in Sheep and Goats in a Natural Tropical Environment. |
| Q28392428 | Effects of Shift Work on Cognitive Performance, Sleep Quality, and Sleepiness among Petrochemical Control Room Operators |
| Q42991993 | Effects of altitude on circadian rhythm of adult locomotor activity in Himalayan strains of Drosophila helvetica |
| Q24804128 | Effects of evening light conditions on salivary melatonin of Japanese junior high school students |
| Q35177678 | Effects of restraint stress on the daily rhythm of hydrolysis of adenine nucleotides in rat serum |
| Q34506894 | Effects of saliva collection using cotton swabs on melatonin enzyme immunoassay |
| Q36975386 | Efficacy and hypnotic effects of melatonin in shift-work nurses: double-blind, placebo-controlled crossover trial |
| Q35046498 | Emergence of physiological rhythmicity in term and preterm neonates in a neonatal intensive care unit |
| Q34173232 | Evidence of circadian rhythms in non-photosynthetic bacteria? |
| Q24810223 | Evolution of temporal order in living organisms |
| Q36769556 | FMR1, circadian genes and depression: suggestive associations or false discovery? |
| Q24814423 | Failure to respond to endogenous or exogenous melatonin may cause nonphotoresponsiveness in Harlan Sprague Dawley rats |
| Q21245389 | Fine-scale differences in diel activity among nocturnal freshwater planarias (Platyhelminthes: Tricladida) |
| Q37325467 | Food anticipation in Bmal1-/- and AAV-Bmal1 rescued mice: a reply to Fuller et al. |
| Q64094637 | Free-Living Humans Cross Cardiovascular Disease Risk Categories Due to Daily Rhythms in Cholesterol and Triglycerides |
| Q34220580 | Gastrointestinal complaints in shift-working and day-working nurses in Iran |
| Q33999012 | Gemvid, an open source, modular, automated activity recording system for rats using digital video |
| Q113998624 | Genes Relevant to Tissue Response to Cancer Therapy Display Diurnal Variation in mRNA Expression in Human Oral Mucosa |
| Q91866061 | Genetic Variants in Circadian Rhythm Genes and Self-Reported Sleep Quality in Women with Breast Cancer |
| Q42092190 | Glycogen synthase kinase 3, circadian rhythms, and bipolar disorder: a molecular link in the therapeutic action of lithium |
| Q64263896 | Heat the Clock: Entrainment and Compensation in Circadian Rhythms |
| Q37448362 | Impact of oral melatonin on the electroretinogram cone response |
| Q46510843 | In vitro and in vivo Phase Changes of the Mouse Circadian Clock by Oxidative Stress |
| Q33968242 | Insomnia in chronic renal patients on dialysis in Saudi Arabia |
| Q36797331 | Intermittent Food Absence Motivates Reallocation of Locomotion and Feeding in Spotted Munia (Lonchura punctulata). |
| Q24815932 | Intermittent long-wavelength red light increases the period of daily locomotor activity in mice |
| Q93353809 | Intracerebral Adenosine During Sleep Deprivation: A Meta-Analysis and New Experimental Data |
| Q36444978 | Investigation of a non-invasive method of assessing the equine circadian clock using hair follicle cells. |
| Q41949202 | Is a purpose of REM sleep atonia to help regenerate intervertebral disc volumetric loss? |
| Q43242224 | Ischemic stroke destabilizes circadian rhythms |
| Q43063585 | Journal of Circadian Rhythms: 10th anniversary |
| Q24802389 | Journal of Circadian Rhythms: 21st-century publishing for 21st-century science |
| Q21245390 | Light-dark cycle synchronization of circadian rhythm in blind primates |
| Q28506430 | Magel2, a Prader-Willi syndrome candidate gene, modulates the activities of circadian rhythm proteins in cultured cells |
| Q34575251 | Mating rhythms of Drosophila: rescue of tim01 mutants by D. ananassae timeless |
| Q40123492 | Maximum entropy spectral analysis for circadian rhythms: theory, history and practice |
| Q34047576 | Measuring the impact of apnea and obesity on circadian activity patterns using functional linear modeling of actigraphy data |
| Q41829708 | Methods for serial analysis of long time series in the study of biological rhythms |
| Q33262921 | Modeling biological rhythms in failure time data |
| Q47171164 | Muscle Bmal1 is Dispensable for the Progress of Neurogenic Muscle Atrophy in Mice |
| Q64063951 | Musicians: Larks, Owls or Hummingbirds? |
| Q37229372 | NPAS2 and PER2 are linked to risk factors of the metabolic syndrome |
| Q34504242 | Natural daylight restricted to twilights delays the timing of testicular regression but does not affect the timing of the daily activity rhythm of the house sparrow (Passer domesticus) |
| Q47112294 | Neurophysiological Processing of an Emotional Task is Sensitive to Time-of-Day. |
| Q25257183 | Neurotransmitters of the suprachiasmatic nuclei |
| Q58747016 | Non-Image Forming Effects of Light on Brainwaves, Autonomic Nervous Activity, Fatigue, and Performance |
| Q36809930 | Opening the Debate: How to Fulfill the Need for Physicians' Training in Circadian-Related Topics in a Full Medical School Curriculum |
| Q59341567 | Overexpression of Prokineticin 2 in Transgenic Mice Leads to Reduced Circadian Behavioral Rhythmicity and Altered Molecular Rhythms in the Suprachiasmatic Clock |
| Q36477073 | Ovipositional periodicity of caged Anopheles gambiae individuals |
| Q91418595 | P19 Cells as a Model for Studying the Circadian Clock in Stem Cells before and after Cell Differentiation |
| Q36628463 | Period-2: a tumor suppressor gene in breast cancer. |
| Q28390142 | Phase delaying the human circadian clock with a single light pulse and moderate delay of the sleep/dark episode: no influence of iris color |
| Q24288941 | Polymorphisms in melatonin synthesis pathways: possible influences on depression |
| Q25256687 | Preliminary evidence for a change in spectral sensitivity of the circadian system at night |
| Q49385508 | Prevalence of Insomnia and Sleep Patterns among Liver Cirrhosis Patients. |
| Q24795405 | Prolactin daily rhythm in suckling male rabbits |
| Q41852640 | Rapid phase adjustment of melatonin and core body temperature rhythms following a 6-h advance of the light/dark cycle in the horse. |
| Q55238677 | Relationship Between the Cortisol-Estradiol Phase Difference and Affect in Women. |
| Q35505166 | Relationship between daylength and suicide in Finland |
| Q38391670 | Relationship between nocturnal serotonin surge and melatonin onset in rodent pineal gland |
| Q35231294 | Relationship between psychosomatic complaints and circadian rhythm irregularity assessed by salivary levels of melatonin and growth hormone |
| Q37359528 | Restless Legs Syndrome in shift workers: A cross sectional study on male assembly workers |
| Q36801130 | Rhythmic Trafficking of TRPV2 in the Suprachiasmatic Nucleus is Regulated by Prokineticin 2 Signaling |
| Q41780979 | SCN-AVP release of mPer1/mPer2 double-mutant mice in vitro |
| Q55004078 | Seasonal Variation in Bright Daylight Exposure, Mood and Behavior among a Group of Office Workers in Sweden. |
| Q37418311 | Sex and hand differences in circadian wrist activity are independent from sex and hand differences in 2D:4D. |
| Q25257581 | Shift work as an oxidative stressor |
| Q36797322 | Sleep and Food Choice in a Dutch Student Population |
| Q91866066 | Sleep and Microdialysis: An Experiment and a Systematic Review of Histamine and Several Amino Acids |
| Q91637769 | Sleep and Reproductive Health |
| Q34590857 | Spontaneous internal desynchronization of locomotor activity and body temperature rhythms from plasma melatonin rhythm in rats exposed to constant dim light. |
| Q37558754 | Standards of evidence in chronobiology: A response |
| Q37162934 | 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 |
| Q33741036 | Statistical methods for detecting and comparing periodic data and their application to the nycthemeral rhythm of bodily harm: A population based study |
| Q40120486 | Structural insights into the function of the core-circadian factor TIMING OF CAB2 EXPRESSION 1 (TOC1). |
| Q36299539 | Summer activity patterns among teenage girls: harmonic shape invariant modeling to estimate circadian cycles |
| Q37364312 | Synaptophysin is involved in resetting of the mammalian circadian clock |
| Q36177101 | Temporal variation in the recovery from impairment in adriamycin-induced wound healing in rats |
| Q90962866 | The Effect of a Common Daily Schedule on Human Circadian Rhythms During the Polar Day in Svalbard: A Field Study |
| Q96821934 | The Influence of Shift Work on the Quality of Sleep and Executive Functions |
| Q104690409 | The Peripheral Circadian Clock and Exercise: Lessons from Young and Old Mice |
| Q42991988 | The effect of high correlated colour temperature office lighting on employee wellbeing and work performance. |
| Q36360170 | The effects of lighting conditions and food restriction paradigms on locomotor activity of common spiny mice, Acomys cahirinus |
| Q35023164 | The relationship between the rate of melatonin excretion and sleep consolidation for locomotive engineers in natural sleep settings |
| Q24805996 | Theodor Hellbrugge: 85 years of age - Ad multos transannos, sanos, fortunatos et beatos |
| Q24795882 | Time for sex: nycthemeral distribution of human sexual behavior |
| Q91418592 | Time of Administration of Acute or Chronic Doses of Imipramine Affects its Antidepressant Action in Rats |
| Q35122512 | Time-of-day dependence of neurological deficits induced by sodium nitroprusside in young mice |
| Q34575245 | Toxic effects of methoxychlor on the episodic prolactin secretory pattern: possible mediated effects of nitric oxide production. |
| Q24594506 | Transdisciplinary unifying implications of circadian findings in the 1950s |
| Q25257567 | Transition into daylight saving time influences the fragmentation of the rest-activity cycle |
| Q100465842 | Using Circadian Rhythm Patterns of Continuous Core Body Temperature to Improve Fertility and Pregnancy Planning |
| Q57483777 | Using the Analytic Network Process Method for Prioritizing and Weighing Shift Work Disorders Among the Personnel of Hospitals of Kerman University of Medical Sciences |
| Q39754009 | Validation of a microwave radar system for the monitoring of locomotor activity in mice |
| Q35040158 | Validation of actigraphy to assess circadian organization and sleep quality in patients with advanced lung cancer |
| Q42003303 | Variation in nocturnality and circadian activity rhythms between photoresponsive F344 and nonphotoresponsive Sprague Dawley rats |
| Q37028804 | Wavelet analysis of circadian and ultradian behavioral rhythms. |
| Q92187167 | Weak Associations of Morningness-Eveningness and Stability with Skin Temperature and Cortisol Levels |
| Q33911759 | Weak evidence of bright light effects on human LH and FSH. |
| Q91741644 | Why We Sleep: A Hypothesis for an Ultimate or Evolutionary Origin for Sleep and Other Physiological Rhythms |
| Q35161431 | Wildtype epidermal growth factor receptor (Egfr) is not required for daily locomotor or masking behavior in mice |
| Q24801694 | d24-hour changes in circulating prolactin, follicle-stimulating hormone, luteinizing hormone and testosterone in male rats subjected to social isolation |
| Journal of Circadian Rhythms | wikipedia |
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