Circadian rhythms in human performance and mood under constant conditions

Monk, Timothy H.; Buysse, Daniel J.; Reynolds, Charles F.; Berga, Sarah L.; Jarrett, David B.; Begley, Amy; Kupfer, David J.

doi:10.1046/j.1365-2869.1997.00023.x

Cited by 258 publications

(173 citation statements)

References 7 publications

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“…With regard to ECP influence, the present results confirm earlier studies (e.g., Johnson et al, 1992;Dijk et al, 1992;Monk et al, 1997) that have concluded that troughs in performance and temperature occur together when educed at a period length of tau or when studied in a protocol involving a suspension of the sleep/wake cycle. Indeed, they extend the generality of previous findings to a broader range of tasks than that previously studied under forced desynchrony.…”

Section: Discussionsupporting

confidence: 90%

“…Thus, the phase of the ECP at which body temperature was lowest corresponded exactly to the phase at which performance was lowest, whatever the task given. This has very recently been confirmed using unmasking studies of dexterity, serial search, and verbal reasoning performance in our own laboratories (Monk et al, 1997). Noted in Johnson et al's (1992) and Dijk et al's (1992) studies, but comparatively underemphasized, was the fact that when educed at T, both temperature and performance still showed rhythms (or, more accurately, time of day effects given that performance was not assessed during sleep).…”

Section: Introductionmentioning

confidence: 54%

“…Whereas Kleitman (1963) espoused a causal relationship, Colquhoun and coworkers (in today's terms) considered performance and body temperature rhythms to be "sister" rhythms, both driven by the endogenous circadian pacemaker (ECP). In a series of studies (summarized in Folkard and Monk, 1985;Folkard, 1983Folkard, , 1989Monk, 1986), the Colquhoun group demonstrated that there were intertask differences not only in baseline time of day effects but also in the rate of phase adjustment to a phase shift (Hughes and Fol-kard, 1976;Monk et al, 1978). This suggested that rhythmic processes other than the ECP were additionally involved in determining how performance might change over the 24 h. The obvious candidate was time since waking (a variable related to Process S, the Y oscillator or Group II oscillators, the term used depending on the model employed).…”

Section: Introductionmentioning

confidence: 99%

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A Parallelism between Human Body Temperature and Performance Independent of the Endogenous Circadian Pacemaker

Monk¹,

Carrier

1998

J Biol Rhythms

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A battery of performance tests involving manual dexterity, serial search, and verbal reasoning was given about seven times per day to 2 healthy young male subjects (22 and 25 years of age) involved in separate forced desynchrony studies, each involving several months of temporal isolation. In these studies, the period lengths (denoted T) of the imposed day lengths (sleep/wake and light/dark cycles) were 25.8 and 26.0 h for the 2 subjects. For each subject, the endogenous circadian pacemaker (ECP) failed to entrain to a period of T and instead free ran at a period length denoted tau (24.2 and 24.5 h). By educing performance rhythms (and rectal temperature rhythms) separately at tau and at T (after three complete beating cycles for the first subject and two complete beating cycles for the second subject), the hypothesis could be tested as to whether performance and temperature were parallel, both when educed at tau (indicating ECP influence) and when educed at T (indicating sleep/wake cycle influences). The hypothesis was consistently confirmed at tau and mostly confirmed at T. For most variables, when educed at T, both performance speed and body temperature showed an inverted V-shaped function, with a peak about 9 to 12 h after waking.

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Section: Discussionsupporting

confidence: 90%

Section: Introductionmentioning

confidence: 54%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

A Parallelism between Human Body Temperature and Performance Independent of the Endogenous Circadian Pacemaker

Monk¹,

Carrier

1998

J Biol Rhythms

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“…Our study measured cerebral responses in the early evening when participants were near, if not in, the Wake Maintenance Zone (WMZ). The WMZ is a time of day when the drive of the circadian system is such that sleep is least likely to occur (Strogatz et al 1987) and cognitive performance is often near its peak (Monk et al 1997). Thus, it may also be the time of day when cerebral adaptation is most likely to be evident.…”

Section: Potential Confounds and Future Directionsmentioning

confidence: 99%

The Effects of Total Sleep Deprivation on Cerebral Responses to Cognitive Performance

Drummond

2001

Neuropsychopharmacology

260

153

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We review the findings from a study utilizing functional magnetic resonance imaging (FMRI) Understanding the impact of sleep deprivation on cognitive performance is increasingly important in a society where many people acutely or chronically fail to obtain adequate sleep. Recent advances in functional brain imaging techniques allow researchers to relate brain function more directly than ever to behavioral performance following sleep deprivation. Prior to our study described below, only three published neuroimaging studies have concomitantly examined the effects of total sleep deprivation (TSD) on cerebral function and behavioral performance in normal control participants. These studies utilized either positron emission tomography (PET) (Thomas et al. 2000;Wu et al. 1991) or functional magnetic resonance imaging (FMRI) (Portas et al. 1998) to study brain activation during performance of attention-demanding tasks. Both of the PET studies reported decreased behavioral performance following TSD, decreased global levels of glucose metabolism, and decreased local activation in attention and arousal-related brain regions such as the thalamus. The FMRI study (Portas et al. 1998) utilized a short-lasting visual reaction time task that resulted in equal performance before and after TSD. The authors reported that the thalamus showed an increased hemodynamic response to the attention task only following TSD. Together, these studies suggest that activity levels in brain systems involved in arousal and attention may influence cognitive performance following TSD. The serial addition/subtraction task used by Thomas et al. (Thomas et al. 2000) required arithmetic working memory in addition to the attentional demands and showed decreased activation in related regions such as prefrontal cortex, inferior parietal lobe, and anterior cingulate gyrus. This suggests that brain regions involved in working memory and arithmetic might be vulnerable to TSD.We recently reported the results from a study utilizing FMRI to examine the effects of 35 h TSD on cogni-

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“…More recent studies have shown a similar relationship when data were collected during extended wakefulness. Minimum performance coincides with low levels of body temperature (1,5,8,10). In these studies, the pressure of the homeostatic process, because of sleep deprivation, continues to increase.…”

mentioning

confidence: 93%

Enhanced mental performance at higher body temperature?

Leproult

Persson

2002

American Journal of Physiology-Regulatory, Integrative and Comp

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MOST OF US HAVE HAD THE REMARKABLE experience of performing several mental tasks very well during slight fever or while body temperature rises unexpectedly during jet lag. This may not simply be a misperception related to the fever process or desynchrony, as pointed out by Wright and colleagues (13) in this issue of the American Journal of Physiology-Regulatory, Integrative and Comparative Physiology. Most neurobehavioral measures depend essentially on two processes: a circadian process depending on the time of day and a homeostatic process relating sleep duration and intensity to the amount of prior wakefulness (2, 7). Body temperature levels also demonstrate a circadian pattern (4, 6, 11), with high levels during the day and low levels during the night. Sleep exerts an influence on body temperature levels because under conditions of total sleep deprivation, the circadian rhythm of body temperature is preserved, but its amplitude is reduced to 0.5°C, compared with an amplitude of ϳ1°C when sleep occurs at a normal time (12).The relationship between the circadian rhythms of body temperature and performance in simple repetitive tasks was already shown by Kleitman in 1963 (9) and by Colquhoun in 1971 (3). Performance for this type of task parallels the circadian rhythm of body temperature. More recent studies have shown a similar relationship when data were collected during extended wakefulness. Minimum performance coincides with low levels of body temperature (1,5,8,10). In these studies, the pressure of the homeostatic process, because of sleep deprivation, continues to increase. Therefore, to distinguish the effects of the homeostatic process from those of the circadian process, some groups have used the forced desynchrony protocol. Under conditions in which the volunteers, for instance, live on 28-h days (with 9 h and 20 min allocated for sleep), the internal clock is not able to synchronize to the environment, allowing for the examination of variables at different circadian phases without sleep depriving the subjects. The parallelism between the circadian rhythms of body temperature and performance on various tasks persists and alertness deteriorates with time spent awake (5, 8). Similar findings have been found when subjects lived on a 20-h day (14).In this issue, Wright et al. (13) report a study in which the subjects performed various tasks during the forced desynchrony protocol, allowing a few observations of the relationship between body temperature and performance at the same circadian phases and after the same amount of hours spent awake. They then split the performance results between the corresponding lowest or highest body temperature for each subject at various circadian phases and at various hours being awake. Globally, better performance is associated with higher body temperature levels, independently of circadian phase and time spent awake. The authors conclude that body temperature is a modulator of the neurobehavioral function.Kleitman and Jackson hypothesized in 1950 that changes in alert...

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Circadian rhythms in human performance and mood under constant conditions

Cited by 258 publications

References 7 publications

A Parallelism between Human Body Temperature and Performance Independent of the Endogenous Circadian Pacemaker

A Parallelism between Human Body Temperature and Performance Independent of the Endogenous Circadian Pacemaker

The Effects of Total Sleep Deprivation on Cerebral Responses to Cognitive Performance

Enhanced mental performance at higher body temperature?

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