Chronobiology international
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Review Comparative Study
Euchronism, allochronism, and dyschronism: is internal desynchronization of human circadian rhythms a sign of illness?
The authors define a subject as euchronic when the circadian parameters--tau (tau=period), Ø (acrophse or peak time), A (amplitude), and M (MESOR=24 h rhythm-adjusted mean)--of a set of circadian variables are within the confidence limits of appropriate reference values of healthy subjects (HS). We define internal desynchronization as a state in which the circadian tau of a set of rhythms differs from 24 h and when the tau of a given variable differs from that of other variables. Such a state was first observed in singly isolated HS without access to time cues and clues. ⋯ Taking into account the high incidence of internal desynchronization found in past investigations and the clinical observation that sleep deprivation is a consequence of many acute and chronic medical conditions (nocturnal pain, nocturnal asthma, etc.), it is suggested that dyschronism may be responsible for the asthenia of unknown origin, at least for some persons. The interindividual (including sex-related) variability in the propensity to exhibit an altered temporal organization, whether it be transient or persistent (i.e., reversible or non-reversible) suggests the involvement of genetic factors. The Dian-Circadian genetic model previously proposed by the authors seems pertinent to conceptualize and explain the various levels and output of internal desynchronization.
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Comparative Study
Circadian-rhythm differences among emergency department patients with chronic obstructive pulmonary disease exacerbation.
The purpose of the study was determine whether patients with chronic obstructive pulmonary disease (COPD) exacerbation who present to the emergency department (ED) during the night (00:00 to 07:59 h) vs. other times of the day have more severe COPD exacerbation, require more intensive treatment, and have worse clinical outcomes. A multicenter cohort study was completed involving 29 EDs in the United States and Canada. Using a standard protocol, consecutive ED patients with COPD exacerbation were interviewed, and their charts were reviewed. ⋯ Nighttime patients were approximately three-fold more likely to be intubated in the ED (odds ratio, 3.46; 95% confidence interval, 1.10-10.9). There were no day-night differences regarding ED disposition and post-ED relapse. Except for some features indicating more severe exacerbation, nighttime ED patients had similar chronic COPD characteristics, received similar treatments in the ED, and had similar clinical outcomes compared with patients presenting to the ED at other times of the day.
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Comparative Study
Disturbance of circadian rhythms in analgosedated intensive care unit patients with and without craniocerebral injury.
Melatonin, cortisol, heart rate, blood pressure, spontaneous motor activity, and body temperature follow stable circadian rhythms in healthy individuals. These circadian rhythms may be influenced or impaired by the loss of external zeitgebers during analgosedation, critical illness, continuous therapeutic intervention in the intensive care unit (ICU), and cerebral injury. This prospective, observational, clinical study examined 24 critically ill analgo-sedated patients, 13 patients following surgery, trauma, or acute respiratory distress (ICU), and 11 patients with acute severe brain injury following trauma or cerebral hemorrhage (CCI). ⋯ These rhythm disturbances were more pronounced in patients with brain injury. The results of this study provide evidence for a pronounced disturbance of the physiological temporal organization in ICU patients. The relative contribution of analgosedation and/or brain injury, however, is a point of future investigation.
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The rhythmic expression of circadian clock genes in the neurons of the suprachiasmatic nucleus (SCN) underlies the manifestation of endogenous circadian rhythmicity in behavior and physiology. Recent evidence demonstrating rhythmic clock gene expression in non-SCN tissues suggests that functional clocks exist outside the central circadian pacemaker of the brain. In this investigation, the nature of an oscillator in peripheral blood mononuclear cells (PBMCs) is evaluated by assessing clock gene expression throughout both a typical sleep/wake cycle (LD) and during a constant routine (CR). ⋯ HPER1 and HPER2 expression in PBMCs demonstrated significant circadian rhythmicity that peaked early after wake-time and was comparable under LD and CR conditions. HBMAL1 expression was more variable, and peaked in the middle of the wake period under LD conditions and during the habitual sleep period under CR conditions. For the first time, bi-hourly sampling over three consecutive days is used to compare clock gene expression in a human peripheral oscillator under different sleep/wake conditions.
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Melatonin signals time of day and time of year in mammals by virtue of its pattern of secretion, which defines 'biological night.' It is supremely important for research on the physiology and pathology of the human biological clock. Light suppresses melatonin secretion at night using pathways involved in circadian photoreception. The melatonin rhythm (as evidenced by its profile in plasma, saliva, or its major metabolite, 6-sulphatoxymelatonin [aMT6s] in urine) is the best peripheral index of the timing of the human circadian pacemaker. ⋯ Exogenous melatonin acts as a 'chronobiotic.' Acutely, it increases sleep propensity during 'biological day.' These properties have led to successful treatments for serveal circadian rhythm disorders. Endogenous melatonin acts to reinforce the functioning of the human circadian system, probably in many ways. The future holds much promise for melatonin as a research tool and as a therapy for various conditions.