【 摘 要 】

Background

Accumulating evidence has shown a universality in the temporal organization of activity and rest among animals ranging from mammals to insects. Previous reports in both humans and mice showed that rest bout durations followed long-tailed (i.e., power-law) distributions, whereas activity bouts followed exponential distributions. We confirmed similar results in the fruit fly, Drosophila melanogaster. Conversely, another report showed that the awakening bout durations, which were defined by polysomnography in bed, followed power-law distributions, while sleeping periods, which may correspond to rest, followed exponential distributions. This apparent discrepancy has been left to be resolved.

Methods

Actigraphy data from healthy and disordered children were analyzed separately for two periods: time out of bed (UP period) and time in bed (DOWN period).

Results

When data over a period of 24 h were analyzed as a whole, rest bouts showed a power law distribution as previously reported. However, when UP and DOWN period data were analyzed separately, neither showed power law properties. Using a newly developed strict method, only 30% of individuals satisfied the power law criteria, even when the 24 h data were analyzed. The human results were in contrast to the Drosophila results, which revealed clear power-law distributions for both day time and night time rest through the use of a strict method. In addition, we analyzed the actigraphy data from patients with childhood type chronic fatigue syndrome (CCFS), and found that they showed differences from healthy controls when their UP and DOWN data were analyzed separately.

Conclusions

These results suggested that the DOWN sleep, the bout distribution of which showed exponential properties, contributes to the production of long-tail distributions in human rest periods. We propose that separate analysis of UP and DOWN period data is important for understanding the temporal organization of activity.

【 授权许可】

   
2013 Kawabata et al.; licensee BioMed Central Ltd.

【 预 览 】

附件列表

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【 图 表 】

【 参考文献 】

• [1]Barabási A-L: The origin of bursts and heavy tails in human dynamics. Nature 2005, 435:207-211.
• [2]Nakamura T, Kiyono K, Yoshiuchi K, Nakahara R, Struzik Z, Yamamoto Y: Universal Scaling Law in Human Behavioral Organization. Phys Rev Lett 2007, 99:1-4.
• [3]Nakamura T, Takumi T, Takano A, Aoyagi N, Yoshiuchi K, Struzik ZR, Yamamoto Y: Of mice and men–universality and breakdown of behavioral organization. PLoS One 2008, 3:e2050.
• [4]Shimada I, Minesaki Y, Hara H: Temporal fractal in the feeding behavior of Drosophila melanogaster. J Ethol 1995, 13:153-158.
• [5]Cole B: Fractal time in animal behaviour: the movement activity of Drosophila. Anim Behav 1995, 50:1317-1324.
• [6]Martin J-R, Ernst R, Heisenberg M: Temporal pattern of locomotor activity in Drosophila melanogaster. J Comp Physiol A 1999, 184:73-84.
• [7]Maye A, Hsieh C-H, Sugihara G, Brembs B: Order in spontaneous behavior. PLoS One 2007, 2:e443.
• [8]Reynolds AM, Frye MA: Free-flight odor tracking in Drosophila is consistent with an optimal intermittent scale-free search. PLoS One 2007, 2:e354.
• [9]Ueno T, Masuda N, Kume S, Kume K: Dopamine modulates the rest period length without perturbation of its power law distribution in Drosophila melanogaster. PLoS One 2012, 7:e32007.
• [10]Clauset A, Shalizi CR, Newman MEJ: Power-law distributions in empirical data. SIAM Rev 2009, 51:43.
• [11]Ueno T, Tomita J, Tanimoto H, Endo K, Ito K, Kume S, Kume K: Identification of a dopamine pathway that regulates sleep and arousal in Drosophila. Nat Neurosci 2012, 15:1516-1523.
• [12]Lo C-C, Amaral LAN, Havlin S, Ivanov PC, Penzel T, Peter J-H, Stanley HE: Dynamics of sleep-wake transitions during sleep. Europhysics Letters (EPL) 2002, 57:625-631.
• [13]Teicher MH: Actigraphy and motion analysis: new tools for psychiatry. Harv Rev Psychiatry 1995, 3:18-35.
• [14]Warren JM, Ekelund U, Besson H, Mezzani A, Geladas N, Vanhees L: Assessment of physical activity - a review of methodologies with reference to epidemiological research: a report of the exercise physiology section of the European Association of Cardiovascular Prevention and Rehabilitation. Eur J Cardiovasc Prev Rehabil 2010, 17:127-139.
• [15]Lubans DR, Okely AD, Morgan PJ, Cotton W, Puglisi L, Miller J: Description and evaluation of a social cognitive model of physical activity behaviour tailored for adolescent girls. Health Educ Res 2012, 27:115-128.
• [16]Hasler BP, Dahl RE, Holm SM, Jakubcak JL, Ryan ND, Silk JS, Phillips ML, Forbes EE: Weekend-weekday advances in sleep timing are associated with altered reward-related brain function in healthy adolescents. Biol Psychol 2012, 91:334-341.
• [17]Kawatani J, Mizuno K, Shiraishi S, Takao M, Joudoi T, Fukuda S, Watanabe Y, Tomoda A: Cognitive dysfunction and mental fatigue in childhood chronic fatigue syndrome - A 6-month follow-up study. Brain Dev 2011, 33:832-841.
• [18]Cole RJ, Kripke DF, Gruen W, Mullaney DJ, Gillin JC: Automatic sleep/wake identification from wrist activity. Sleep 1992, 15:461-469.
• [19]Viswanathan GM, Buldyrev SV, Havlin S, Da Luz MG, Raposo EP, Stanley HE: Optimizing the success of random searches. Nature 1999, 401:911-914.
• [20]Edwards AM, Phillips RA, Watkins NW, Freeman MP, Murphy EJ, Afanasyev V, Buldyrev SV, Da Luz MGE, Raposo EP, Stanley HE, Viswanathan GM: Revisiting Lévy flight search patterns of wandering albatrosses, bumblebees and deer. Nature 2007, 449:1044-1048.
• [21]Petrovskii S, Mashanova A, Jansen VAA: Variation in individual walking behavior creates the impression of a Levy flight. Proc Natl Acad Sci U S A 2011, 108:8704-8707.
• [22]Sano W, Nakamura T, Yoshiuchi K, Kitajima T, Tsuchiya A, Esaki Y, Yamamoto Y, Iwata N: Enhanced persistency of resting and active periods of locomotor activity in schizophrenia. PLoS One 2012, 7:e43539.