Postprandial hormone and metabolic responses in simulated shift work

Hampton, Shelagh M.; Morgan, Linda; Lawrence, Natasha J.; Anastasiadou, T; Norris, Fiona; Deacon, Steve; Ribeiro, D. C. O.; Arendt, Joséphine

doi:10.1677/joe.0.1510259

Cited by 139 publications

(120 citation statements)

References 13 publications

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“…The present study showed that the adverse effects of circadian misalignment during a forced desynchrony protocol are also observed in conditions more similar to those experienced by real-life shift workers, and are sustained over a number of days of repeated exposure. Our data are also consistent with the general notion that various forms of circadian disruption (e.g., SCN lesions, clock gene mutations, continuous light exposure, and simulated shift work) can impair glucose metabolism (19,20,26,28,29).…”

Section: Discussionsupporting

confidence: 90%

“…An endogenous circadian rhythm in circulating glucose and insulin levels has been detected in humans by using intensive protocols performed under constant conditions ("constant routine" protocols) or when the behavioral cycle influences are accounted for by evenly distributing them across the entire circadian cycle ("forced desynchrony" protocols) (4,(10)(11)(12)14). In addition, circadian misalignment-as occurs in shift workers-also leads to impaired glucose metabolism in rodents and humans (10,(25)(26)(27)(28)(29)(30)(31)(32).…”

Section: Significancementioning

confidence: 99%

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Endogenous circadian system and circadian misalignment impact glucose tolerance via separate mechanisms in humans

Morris

Yang

Garcia

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

344

336

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Glucose tolerance is lower in the evening and at night than in the morning. However, the relative contribution of the circadian system vs. the behavioral cycle (including the sleep/wake and fasting/ feeding cycles) is unclear. Furthermore, although shift work is a diabetes risk factor, the separate impact on glucose tolerance of the behavioral cycle, circadian phase, and circadian disruption (i.e., misalignment between the central circadian pacemaker and the behavioral cycle) has not been systematically studied. Here we show-by using two 8-d laboratory protocols-in healthy adults that the circadian system and circadian misalignment have distinct influences on glucose tolerance, both separate from the behavioral cycle. First, postprandial glucose was 17% higher (i.e., lower glucose tolerance) in the biological evening (8:00 PM) than morning (8:00 AM; i.e., a circadian phase effect), independent of the behavioral cycle effect. Second, circadian misalignment itself (12-h behavioral cycle inversion) increased postprandial glucose by 6%. Third, these variations in glucose tolerance appeared to be explained, at least in part, by different mechanisms: during the biological evening by decreased pancreatic β-cell function (27% lower earlyphase insulin) and during circadian misalignment presumably by decreased insulin sensitivity (elevated postprandial glucose despite 14% higher late-phase insulin) without change in early-phase insulin. We explored possible contributing factors, including changes in polysomnographic sleep and 24-h hormonal profiles. We demonstrate that the circadian system importantly contributes to the reduced glucose tolerance observed in the evening compared with the morning. Separately, circadian misalignment reduces glucose tolerance, providing a mechanism to help explain the increased diabetes risk in shift workers.circadian disruption | shift work | night work | glucose metabolism | diabetes I n healthy humans, there is a strong time-of-day variation in glucose tolerance, with a peak in the morning and a trough in the evening and night (1-6). Understanding the underlying mechanisms of the day/night variation in glucose tolerance is important for diurnally active individuals as well as shift workers, who are at increased risk for developing type 2 diabetes (7-9). The endogenous circadian system and circadian misalignment (i.e., misalignment between the endogenous circadian system and 24-h environmental/behavioral cycles) have been shown to affect glucose metabolism (4,(10)(11)(12)(13)(14). However, the relative and separate importance of the endogenous circadian system and circadian misalignment-after accounting for behavioral cycle effects (including the sleep/wake, fasting/feeding, and physical inactivity/activity cycles, etc.)-on 24-h variation in glucose tolerance is not well understood.Most species have evolved an endogenous circadian timing system that optimally times physiological variations and behaviors relative to the 24-h environmental cycle (15-17). The mammalian circadian system is comp...

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Section: Discussionsupporting

confidence: 90%

Section: Significancementioning

confidence: 99%

Endogenous circadian system and circadian misalignment impact glucose tolerance via separate mechanisms in humans

Morris

Yang

Garcia

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

344

336

View full text Add to dashboard Cite

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“…Others have examined the effect of simulated night shift work on postprandial glucose and insulin with varied results (18,19). Interpretation of these studies is complicated due to differences in premeal conditions between the night and day shifts (e.g., duration of wakefulness before test meals), such that the effects of circadian misalignment alone could not be assessed.…”

Section: Discussionmentioning

confidence: 99%

Adverse metabolic and cardiovascular consequences of circadian misalignment

Scheer

Hilton

Mantzoros

et al. 2009

Proc. Natl. Acad. Sci. U.S.A.

1,833

1,489

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There is considerable epidemiological evidence that shift work is associated with increased risk for obesity, diabetes, and cardiovascular disease, perhaps the result of physiologic maladaptation to chronically sleeping and eating at abnormal circadian times. To begin to understand underlying mechanisms, we determined the effects of such misalignment between behavioral cycles (fasting/ feeding and sleep/wake cycles) and endogenous circadian cycles on metabolic, autonomic, and endocrine predictors of obesity, diabetes, and cardiovascular risk. Ten adults (5 female) underwent a 10-day laboratory protocol, wherein subjects ate and slept at all phases of the circadian cycle-achieved by scheduling a recurring 28-h ''day.'' Subjects ate 4 isocaloric meals each 28-h ''day.'' For 8 days, plasma leptin, insulin, glucose, and cortisol were measured hourly, urinary catecholamines 2 hourly (totaling Ϸ1,000 assays/ subject), and blood pressure, heart rate, cardiac vagal modulation, oxygen consumption, respiratory exchange ratio, and polysomnographic sleep daily. Core body temperature was recorded continuously for 10 days to assess circadian phase. Circadian misalignment, when subjects ate and slept Ϸ12 h out of phase from their habitual times, systematically decreased leptin (؊17%, P < 0.001), increased glucose (؉6%, P < 0.001) despite increased insulin (؉22%, P ‫؍‬ 0.006), completely reversed the daily cortisol rhythm (P < 0.001), increased mean arterial pressure (؉3%, P ‫؍‬ 0.001), and reduced sleep efficiency (؊20%, P < 0.002). Notably, circadian misalignment caused 3 of 8 subjects (with sufficient available data) to exhibit postprandial glucose responses in the range typical of a prediabetic state. These findings demonstrate the adverse cardiometabolic implications of circadian misalignment, as occurs acutely with jet lag and chronically with shift work. autonomic nervous system ͉ diabetes ͉ glucose metabolism ͉ leptin ͉ obesity A pproximately 8.6 million Americans perform shift work (1), which is associated with increased risk of obesity, diabetes, and cardiovascular disease (2-6). The endogenous circadian timing system, including the suprachiasmatic nucleus (SCN) in the hypothalamus and peripheral oscillators in vital organs, optimally regulates much of our physiology and behavior across the 24-h day when it is properly aligned with the sleep/wake cycle. However, shift work is generally associated with chronic misalignment between the endogenous circadian timing system and the behavioral cycles, including sleep/wake and fasting/ feeding cycles (7,8). Shift workers often experience symptoms akin to jet lag, with gastrointestinal complaints, fatigue, and sleepiness during the scheduled wake periods, and poor sleep during the daytime sleep attempts (9). Moreover, chronic circadian misalignment has been proposed to be the underlying cause for the adverse metabolic and cardiovascular health effects of shift work (10, 11). The SCN regulates circadian rhythms in leptin, plasma glucose, glucose tolerance, corticosteroids, and ...

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“…Similarly, chronic exposure to shift work increases risk of metabolic syndrome (87) , as well as CHD, stroke and stroke-related mortality, and type 2 diabetes (88)(89)(90)(91) . Laboratory studies in human subjects have shown that consumption of meals during the biological night results in increased postprandial glucose, insulin and TAG relative to daytime meals (92)(93)(94) . Additionally, rotating shiftwork is associated with higher fasting TAG and free fatty acids, and lower HDLcholesterol (95,96) .…”

Section: Circadian Misalignment and Metabolic Dysfunctionmentioning

confidence: 99%

Circadian regulation of lipid metabolism

Gooley

2016

Proc. Nutr. Soc.

134

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The circadian system temporally coordinates daily rhythms in feeding behaviour and energy metabolism. The objective of the present paper is to review the mechanisms that underlie circadian regulation of lipid metabolic pathways. Circadian rhythms in behaviour and physiology are generated by master clock neurons in the suprachiasmatic nucleus (SCN). The SCN and its efferent targets in the hypothalamus integrate light and feeding signals to entrain behavioural rhythms as well as clock cells located in peripheral tissues, including the liver, adipose tissue and muscle. Circadian rhythms in gene expression are regulated at the cellular level by a molecular clock comprising a core set of clock genes/proteins. In peripheral tissues, hundreds of genes involved in lipid biosynthesis and fatty acid oxidation are rhythmically activated and repressed by clock proteins, hence providing a direct mechanism for circadian regulation of lipids. Disruption of clock gene function results in abnormal metabolic phenotypes and impaired lipid absorption, demonstrating that the circadian system is essential for normal energy metabolism. The composition and timing of meals influence diurnal regulation of metabolic pathways, with food intake during the usual rest phase associated with dysregulation of lipid metabolism. Recent studies using metabolomics and lipidomics platforms have shown that hundreds of lipid species are circadian-regulated in human plasma, including but not limited to fatty acids, TAG, glycerophospholipids, sterol lipids and sphingolipids. In future work, these lipid profiling approaches can be used to understand better the interaction between diet, mealtimes and circadian rhythms on lipid metabolism and risk for obesity and metabolic diseases.

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Postprandial hormone and metabolic responses in simulated shift work

Cited by 139 publications

References 13 publications

Endogenous circadian system and circadian misalignment impact glucose tolerance via separate mechanisms in humans

Endogenous circadian system and circadian misalignment impact glucose tolerance via separate mechanisms in humans

Adverse metabolic and cardiovascular consequences of circadian misalignment

Circadian regulation of lipid metabolism

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