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Light, Sleep, Alertness and Performance

  • Wout van Bommel
Chapter

Abstract

A classical sleep model is based on an interaction of two different processes. A homeostatic one is characterised by increasing and decreasing sleep pressure after waking up and while asleep, respectively. The other process is a circadian one which provides the possibility to sleep: the sleep window. Light and darkness at the appropriate times strongly influence the latter process. Daytime light influences sleep possibility during the night. Here, both the level and the spectrum of light play a role. Cooler white light is more effective than warmer white light. Sleep quality during the night, of course, also influences alertness and performance during the subsequent day. On top of this effect on alertness and performance, there is also a direct photobiological effect of light on alertness and performance. A sufficient high light level for this second route towards alertness and performance is essential. There are contradictory research results on the role of the spectrum in this respect. On the basis of the research discussed in this chapter, a dynamic lighting scenario for daytime workplaces is proposed which dynamically changes both the lighting level and colour. It optimises between energy requirements on the one hand and requirements of visual and non-visual effects of lighting on the other hand.

References

  1. Achermann P, Borbély AA (2003) Mathematical models of sleep regulation. Front Biosci (Landmark eds) 8:S683–S693CrossRefGoogle Scholar
  2. Åkerstedt T, Folkard S (1996) Predicting duration of sleep from the three process model of regulation of alertness. Occup Environ Med 53(2):136–141CrossRefGoogle Scholar
  3. Åkerstedt T, Gillberg M (1990) Subjective and objective sleepiness in the active individual. Int J Neurosci 52:29–37CrossRefGoogle Scholar
  4. Aries M (2005) Human lighting demands, healthy lighting in an office environment. Public presentation of PhD thesis, University of Technology Eindhoven, EindhovenGoogle Scholar
  5. Bakker I, Van Der Voordt T, Vink P, De Boon J (2014) Pleasure, arousal dominance: Mehrabian and Russell revisited. Curr Psychol 33(3):405–421CrossRefGoogle Scholar
  6. Beersma DGM, Gordijn MCM (2007) Circadian control of sleep-wake cycle. Physiol Behav 90:190–195CrossRefGoogle Scholar
  7. Borbély AA, Wirz-Justice A (1982) Sleep, sleep deprivation and depression. A hypothesis derived from a model of sleep regulation. Hum Neurobiol 1:205–210Google Scholar
  8. Borbély AA, Daan S, Wirz-Justice A, DeBoer T (2016) The two-process model of sleep regulation: a reappraisal. J Sleep Res 25:131–143CrossRefGoogle Scholar
  9. Boubekri M, Cheung IN, Reid JR, Wang C-H, Zee PC (2014) Impact of windows and daylight exposures on overall health and sleep quality of office workers: a case-control pilot study. J Clin Sleep Med 10(6):603–611Google Scholar
  10. Boyce PR, Beckstead JW, Eklund NH, Strobel RW, Rea MS (1997) Lighting the graveyard-shift: the influence of a daylight­simulating skylight on the task performance and mood of night-shift. Light Res Technol 29:105–134CrossRefGoogle Scholar
  11. Buysse DJ, Reynolds CF, Monk TH, Berman SR, Kupfer DJ (1989) The Pittsburgh sleep quality index: a new instrument for psychiatric practice and research. Psychiatry Res 28(2):193–213CrossRefGoogle Scholar
  12. Cajochen C (2007) Alerting effects of light. Sleep Med Rev 11:453–464CrossRefGoogle Scholar
  13. Cajochen C, Khalsa SBS, Wyatt JK, Czeisler CA, Dijk D-J (1999) EEG and ocular correlates of circadian melatonin phase and human performance decrements during sleep loss. Am J Physiol Regul Integr Comp Physiol 277:R640–R649CrossRefGoogle Scholar
  14. Canazei M, Dehoff P, Staggl S, Pohl W (2014) Effects of dynamic ambient lighting on female permanent morning shift workers. Lighting Res Technol 46:140:156CrossRefGoogle Scholar
  15. Cappuccio FP, Taggart FM, Kandala N-B, Currie A, Peile E, Stranges S, Miller MA (2008) Meta-analysis of short sleep duration and obesity in children and adults. Sleep 31(5):619–626CrossRefGoogle Scholar
  16. Cappuccio FP, D’Elia L, Strazzullo P, Miller MA (2010a) Sleep duration and all-cause mortality: a systematic review and meta-analysis of prospective studies. Sleep 33(5):585–592CrossRefGoogle Scholar
  17. Cappuccio FP, D’Elia L, Strazzullo P, Miller MA (2010b) Quantity and quality of sleep and incidence of type 2 diabetes. A systematic review and meta-analysis. Diabetes Care 33:414–420CrossRefGoogle Scholar
  18. Cappuccio FP, Cooper D, D’Elia L, Strazzullo P, Miller MA (2011) Sleep duration predicts cardiovascular outcomes: a systematic review and meta-analysis of prospective studies. Eur Heart J 32:1484–1492CrossRefGoogle Scholar
  19. Cheung V, Yuen VM, Wong GTC, Choi SW (2019) The effect of sleep deprivation and disruption on DNA damage and health of doctors. Anaesthesia 2019:1–7.  https://doi.org/10.1111/anae.14533CrossRefGoogle Scholar
  20. Colau A, Fotios S (2015) Using lighting to improve concentration in the classroom. In: Proceedings of 28th CIE Session, ManchesterGoogle Scholar
  21. Costa IC, Carvalho HN, Fernandes L (2013) Aging, circadian rhythms and depressive disorders: a review. Am J Neurodegener Dis 2(4):228–246Google Scholar
  22. Daan S, Beersma DG, Borbély AA (1984) Timing of human sleep: recovery process gated by a circadian pacemaker. Am J Phys 246:R161–R178Google Scholar
  23. Dijk D-J (2012) Sleep and health: beyond sleep duration and sleepiness? J Sleep Res 21:355–356CrossRefGoogle Scholar
  24. Dijk DJ, Archer SN (2010) PERIOD3, circadian phenotypes, and sleep homeostasis. Sleep Med Rev 14:151–160CrossRefGoogle Scholar
  25. Ferlazzo F, Piccardi L, Burattini C, Barbalace M, Giannini AM, Bisegna F (2014) Effects of new light sources on task switching and mental rotation performance. J Environ Psychol 39:92–100CrossRefGoogle Scholar
  26. Ficca G, Axelsson J, Mollicone DJ, Muto V, Vitiell MV (2010) Naps, cognition and performance. Sleep Med Rev 14:249–158CrossRefGoogle Scholar
  27. Figueiro MG, Rea MS (2016) Office lighting and personal light exposures in two seasons: impact on sleep and mood. Lighting Res Technol 48:52–364Google Scholar
  28. Figueiro MG, Hamner R, Bierman A, Rea MS (2013) Comparison of three practical field devices used to measure personal light exposures and activity levels. Light Res Technol 45(4):421–434CrossRefGoogle Scholar
  29. Figueiro MG, Steverson B, Heerwagen J, Kampschroer K, Hunter CM, Gonzales K, Plitnick B, Rea MS (2017) The impact of daytime light exposures on sleep and mood in office workers. Sleep Health 3:204–215CrossRefGoogle Scholar
  30. Figueiro MG, Nagare R, Price LL (2018) Non-visual effects of light: how to use light to promote circadian entrainment and elicit alertness. Lighting Res Technol 50:38–62CrossRefGoogle Scholar
  31. Gifford R, Hine DW, Veitch JA (1997) Meta-analysis for environment-behavior and design research, illuminated with a study of lighting level effects on office task performance. In: Moore GT, Marans RW (eds) Advances in environment, behavior, and design. Plenum Press, New York, pp 223–253Google Scholar
  32. Gornicka GB (2008) Lighting at work: environmental study of direct effects of lighting level and spectrum on psychophysiological variables. PhD thesis, Eindhoven University of Technology, EindhovenGoogle Scholar
  33. Hubalek S, Brink M, Schierz C (2010) Office workers’ daily exposure to light and its influence on sleep quality and mood. Lighting Res Technol 42:33–50CrossRefGoogle Scholar
  34. Huiberts LM, Smolders KCHJ, De Kort YAW (2015a) Shining light on memory: effects of bright light on working memory performance. Behav Brain Res 294:234–245CrossRefGoogle Scholar
  35. Huiberts LM, Smolders KCHJ, De Kort YAW (2015b) Shining light on memory: effects of bright light on working performance. Behav Brain Res 194:234–245CrossRefGoogle Scholar
  36. Huiberts LM, Smolders KCHJ, De Kort YAW (2017) Seasonal and time-of-day variations in acute non-image forming effects of illuminance level on performance, physiology, and subjective Well-being. Chronobiol Int 34(7):827–844CrossRefGoogle Scholar
  37. Ishii H, Kanagawa H, Shimamura Y, Uchiyama K, Miyagi K, Obayashi F, Shimoda H (2018) Intellectual productivity under task ambient lighting. Lighting Res Technol 50:237–252CrossRefGoogle Scholar
  38. Iskra-Golec I, Wazna A, Smith L (2012) Effects of blue-enriched light on the daily course of mood, sleepiness and light perception: a field experiment. Lighting Res Technol 44:506–513CrossRefGoogle Scholar
  39. Kaida K, Takahashi M, Åkerstedt T, Nakata A, Otsuka Y, Haratani T, Fukasawa K (2006a) Validation of the Karolinska sleepiness scale against performance and EEG variables. Clin Neurophysiol 117:1574–1581CrossRefGoogle Scholar
  40. Kaida K, Takahashi M, Haratani T, Otsuka Y, Fukasawa K, Nakata A (2006b) Indoor exposure to natural bright light prevents afternoon sleepiness. Sleep 29:462–469CrossRefGoogle Scholar
  41. Kaida K, Takeda Y, Tsuzuki K (2013) The effects of short afternoon nap and bright light on task switching performance and error-related negativity. Sleep Biol Rhythms 11:125–134CrossRefGoogle Scholar
  42. Kim Y, Wilkens LR, Schembre SM, Henderson BE, Kolonel LN, Goodman MT (2013) Insufficient and excessive amounts of sleep increase the risk of premature death from cardiovascular and other diseases: the multi-ethnic cohort study. Prev Med 57:377–385CrossRefGoogle Scholar
  43. Knez I, Kers C (2000) Effects of indoor lighting, gender, and age on mood and cognitive performance. Environ Behav 32:817–831CrossRefGoogle Scholar
  44. Küller R, Wetterberg L (1993) Melatonin, cortisol, EEG, ECG and subjective comfort in healthy humans: Impact of two fluorescent lamp types at two light intensities. Lighting Res. Technol 25(2):71–80CrossRefGoogle Scholar
  45. Lee KA, Hicks G, Nini-Murcia G (1990) Validity and reliability of a scale to assess fatigue. Psychiatry Res 36:291–298CrossRefGoogle Scholar
  46. Leger D, Bayon V, Elbas M, Philip P, Choudat D (2007) Underexposure to light at work and its association to insomnia and sleepiness. J Psychosom Res 70:29–36CrossRefGoogle Scholar
  47. Mednick SC, Ehrman M (2006) Take a nap! Change your life. Workman Publishing Company, New YorkGoogle Scholar
  48. Mehrabian A, Russell JA (1974) An approach to environmental psychology. MIT Press, Cambridge, MAGoogle Scholar
  49. Meijman TF, De Vries-Griever AH, De Vries G, Kampman R (1988) The evaluation of the Groningen sleep quality scale. Heymans Bulletins Psychologische Instituten, Groningen, University of Groningen, GroningenGoogle Scholar
  50. Mills PM, Tomkins SC, Schlangen LJM (2007) The effect of high correlated colour temperature office lighting on employee wellbeing and work performance. J Circadian Rhythms 5:2–10CrossRefGoogle Scholar
  51. Noguchi H, Sakaguchi T (1999) Effect of illuminance and color temperature on lowering of physiological activity. Appl Hum Sci 18:117–123CrossRefGoogle Scholar
  52. Odds W (ed) (2015) Sleep, circadian rhythms, and metabolism: the rhythm of life. Apple Academic Press, Inc., Oakville, ONGoogle Scholar
  53. Phipps-Nelson J, Redman JR, Dijk D-J, Rajaratman SMW (2003) Daytime exposure to bright light, as compared to dim light, decreases sleepiness and improves psychomotor vigilance performance. Sleep 26:695–700CrossRefGoogle Scholar
  54. Rasch B, Born J (2013) About sleep’s role in memory. Physiol Rev 93:681–766CrossRefGoogle Scholar
  55. Rüger M, Gordijn MCM, Beersma DG, De Vries B, Daan S (2006) Time-of-day-dependent effects of bright light exposure on human psychophysiology: comparison of daytime and nighttime exposure. Am J Physiol Regul Integr Comp Physiol 290(5):R1413–RR142CrossRefGoogle Scholar
  56. Ryan RM, Frederick C (1997) On energy, personality, and health: subjective vitality as a dynamic reflection of well-being. J Pers 65:529–565CrossRefGoogle Scholar
  57. Santhi N, Groeger JA, Archer SN, Giminez M, Schlangen LJM, Dijk D-J (2013) Morning sleep inertia in alertness and performance: effect of cognitive domain and white light condition. PLoS One 8:e79688ADSCrossRefGoogle Scholar
  58. Shi L, Katsuura T, Shimomura Y, Iwanaga K (2009) Effects of different light source color temperature during physical exercise in human EEG and subjective evaluation. J Human Environ Syst 12:27–34CrossRefGoogle Scholar
  59. Smolders KCHJ, De Kort YAW (2017) Investigating daytime effects of correlated colour temperature on experiences, performance and arousal. J Environ Psychol 50:80–93CrossRefGoogle Scholar
  60. Smolders KCHJ, De Kort YAW, Cluitmans PJM (2012) A higher illuminance induces alertness even during office hours: findings on subjective measures, task performance and heart rate measures. Physiol Behav 107:7–16CrossRefGoogle Scholar
  61. Smolders KCHJ, De Kort YAW, Van Den Berg SM (2013) Daytime light exposure and feelings of vitality: results of a field study during regular weekdays. J Environ Psychol 36:270–279CrossRefGoogle Scholar
  62. Stampi C (ed) (1992) Why we nap; evolution, chronobiological functions of polyphasic and ultrashort sleep. Springer Science+Business Media, New YorkGoogle Scholar
  63. Takahashi M, Nakata A, Haratani T, Ogawa Y, Arito H (2004) Post-lunch nap as a worksite intervention to promote alertness on the job. Ergonomics 47:1003–1013CrossRefGoogle Scholar
  64. Turnage JJ, Kennedy RS, Smith MG, Baltzley DR, Lane NE (1992) Development of microcomputer-based mental acuity tests. Ergonomics 35(10):1271–1295CrossRefGoogle Scholar
  65. Van Bommel WJM (2006) Non-visual biological effect of lighting and the practical meaning for lighting for work. Appl Ergon 37:461–466ADSCrossRefGoogle Scholar
  66. Vandewalle G, Balteau E, Phillips C, Degueldre C, Moreau V, Sterpenich V, Albouy G, Darsaud A, Desseilles M, Dang-Vu TT, Peigneux P, Luxen A, Dijk D-J, Maquet P (2006) Daytime light exposure dynamically enhances brain responses. Curr Biol 16:1616–1621CrossRefGoogle Scholar
  67. Viola AU, James LM, Schlangen LJM, Dijk D-J (2008) Blue-rich white light in the workplace improves self-reported alertness, performance and sleep quality. Scand J Work Environ Health 34:297–306CrossRefGoogle Scholar
  68. Wams EJ, Woelders T, Marring I, van Rosmalen L, Beersma DGM, Gordijn MCM, Hut RA (2017) Linking light exposure and subsequent sleep: a field polysomnography study in humans. Sleep 40:zsx165CrossRefGoogle Scholar
  69. Westerlund A, Lagerros YT, Kecklund G, Axelsson J, Åkerstedt T (2016) Relationships between questionnaire ratings of sleep quality and polysomnography in healthy adults. Behav Sleep Med 14(2):185–199CrossRefGoogle Scholar
  70. Ye M, Zheng SQ, Wang ML, Luo MR (2018) The effect of dynamic correlated colour temperature changes on alertness and performance. Lighting Res Technol 50:1070–1081CrossRefGoogle Scholar
  71. Yin J, Jin X, Shan Z, Li S, Huang H, Li P, Peng X, Peng Z, Yu K, Bao W, Yang W, Chen X, Liu L (2017) Relationship of sleep duration with all-cause mortality and cardiovascular events: a systematic review and dose-response meta-analysis of prospective cohort studies. J Am Heart Assoc 6(9):e005947CrossRefGoogle Scholar

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© Springer Nature Switzerland AG 2019

Authors and Affiliations

  • Wout van Bommel
    • 1
  1. 1.Van Bommel Lighting ConsultantNuenenThe Netherlands

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