Circasemidian rhythm

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Numerous studies have demonstrated that human circadian rhythms in many measures of performance and physiological activity actually have a 2-peak daily (circasemidian) pattern. [1][2][3] The name, circasemidian, is based upon the Latin words circa ("about"), semi ("half") and dia ("day"). Thus, this is a rhythm that has two cycles per day. It usually serves to (1) deepen the pre-dawn nadir in body temperature and cognitive performance, (2) create a flat spot during the early afternoon in the daytime increase in body temperature and cognitive performance (the "post-lunch dip"), and (3) heighten the early-evening peak in body temperature and cognitive performance. Broughton was the first to bring this characteristic of human performance to the attention of researchers.[4][5][6]

No evidence exists to support the presence of a circasemidian rhythm in the rhythmic cells of the suprachiasmatic nucleus, the accepted internal timing source for the major circadian rhythms of the body. However, a number of published data sets have shown a daily two-peak error pattern in industrial and transportation environments.[7][8][9][10][11][12][13][14][15][16][17] The pattern was also obvious in many of the charts shown in the review by Rutenfranz and Colquhoun,[18] though they did not suggest a circasemidian rhythm as a mediator for the pattern. Other investigators have reported a circasemidian rhythm in body temperature,[19][20][21][22] melatonin[23] and slow-wave sleep.[24]

These behavioral and physiological observations support the need to consider a 12-h rhythmicity in the quantification of daily variations in physiological function and some kinds of cognitive performance in fatigue modeling efforts such as the Fatigue Avoidance Scheduling Tool.

References

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  1. Mitler MM, Carskadon MA, Czeisler CA, Dement WC, Dinges DF, Graeber RC. Catastrophes, sleep, and public policy: consensus report. Sleep 11:100-109, 1988.
  2. Eastman C. Are separate temperature and activity oscillators necessary to explain the phenomena of human circadian rhythms? In: Moore-Ede MC, Czeisler CA, editors. Mathematical Models of the Circadian Sleep-Wake Cycle. New York, Raven, 1984. pp. 81–103.
  3. US Congress Office of Technology Assessment. Biological Rhythms: Implications for the Worker. Washington DC, US Government Printing Office, 1991.
  4. Broughton RJ. SCN controlled circadian arousal and the afternoon "nap zone." Sleep Res Online 1(4):166-178, 1998.
  5. Broughton RJ. Biorhythmic variations in consciousness and psychological functions. Canadian Psychological Reviews 16:217-230, 1975.
  6. Broughton RJ. Chronobiological aspects and models of sleep and napping. In: Dinges DF, Broughton RJ (Eds.), Sleep and Alertness: Chronobiological, Behavioral and Medical Aspects of Napping. New York, Raven Press, 71-98, 1989.
  7. Bjerner B, Holm A, Swennson A. Diurnal variation in mental performance: A study of three-shift workers. Br J Ind Med 12:103-110, 1955.
  8. Browne RC. The day and night performance of teleprinter switchboard operators. Occupational Psychology 23:1-6, 1949.
  9. Folkard S, Lombardi DA, Tucker PT. Shiftwork: safety, sleepiness and sleep. Industrial Health 43:20–23, 2005.
  10. Harris W. Fatigue, circadian rhythm, and truck accidents. Chapter 8 in Mackie RR (ed.), Vigilance: Operational Performance, and Physiological Correlates. New York, Plenum Press, 1977.
  11. Harris W. Relationships between length of time driving, time of day, and certains kinds of accidents. Pages 51-64 in Mackie RR, Miller JC, Effects of Hours of Service, Regularity of Schedules, and Cargo Loading on Truck and Bus Driver Fatigue (NTIS PB290957). Goleta CA, Human Factors Research, Inc., 1978.
  12. Hildebrandt G, Rohmert W, Rutenfranz J 12 and 24 h rhythms in error frequency of locomotive drivers and the influence of tiredness. Int J Chronobiology 2:175-180, 1974
  13. Kogi K, Ohta T. Incidence of near accidental drowsing in locomotive driving during a period of rotation. J Human Ergology 4:65-76, 1975.
  14. Langlois PH, Smolensky MH, His BP, Weir FW. Temporal patterns of reported single-vehicle car and truck accidents in Texas, USA, during 1980-1983. Chronobiologia 2:131-140, 1985.
  15. Lavie P, Wollma M, Pollack I. Frequency of sleep–related traffic accidents and hour of the day. Sleep Research 15:275, 1986.
  16. Mitler MM. Two-peak patterns in sleep, mortality and error. Proc Intl Sympos on Sleep and Health Risk, Springer Verlag, 1989.
  17. Prokop O, Prokop L. Ermuding und einschlafen am steuer. Dtsch Z Gerichtl Med 44:343-355, 1955.
  18. Rutenfranz J, Colquhoun P. Circadian rhythms in human performance. Scand J Work Environ & Health 5:167-177, 1979.
  19. Colquhoun WP, Blake MJF, Edwards RS. Experimental studies of shift-work I: A comparison of 'rotating' and 'stabilized' 4-hours shift systems. Ergonomics 11:437-453, 1968.
  20. Colquhoun WP, Paine MWPH, Fort A. Circadian rhythm of body temperature during prolonged undersea voyages. Aviat Space Environ Med 49(5):671-678, 1978.
  21. Colquhoun WP, Paine MWPH, Fort A. Changes in the temperature rhythm of submariners following a rapidly rotating watchkeeping system for a prolonged period. Int. Arch. Occup. Environ. Health 42:185-190, 1979.
  22. Martineaud JP, Cisse F, Samb A. Circadian variability of temperature in fasting subjects. Scripta Medica (Brno) 73(1):15–24, 2000.
  23. Maggioni C, Cornelissen G, Antinozzi R, Ferrario M, Grafe A, Halberg F. A half-yearly aspect of circulating melatonin in pregnancies complicated by intrauterine growth retardation. Neuroendicrinology Letters 20:55-68, 1999.
  24. Hayashi M, Morikawa T, Hori T. Circasemidian 12 h cycle of slow wave sleep under constant darkness. Clin Neurophysiol 113(9):1505-16, 2002.