Shift work sleep disorder
Shift work sleep disorder (SWSD) is a circadian rhythm sleep disorder characterized by insomnia and excessive sleepiness affecting people whose work hours overlap with the typical sleep period. Insomnia can be the difficulty to fall asleep or to wake up before the individual has slept enough.[1] About 20% of the working population participates in shift work. SWSD commonly goes undiagnosed, so it's estimated that 10–40% of shift workers suffer from SWSD.[2] The excessive sleepiness appears when the individual has to be productive, awake and alert.[1] Both symptoms are predominant in SWSD.[3] There are numerous shift work schedules, and they may be permanent, intermittent, or rotating; consequently, the manifestations of SWSD are quite variable. Most people with different schedules than the ordinary one (from 8 AM to 6 PM) might have these symptoms but the difference is that SWSD is continual, long-term, and starts to interfere with the individual's life.[1]
Shift work sleep disorder | |
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Other names | shift work disorder; SWD |
Specialty | Neurology, psychology |
Health effects
There have been many studies suggesting health risks associated with shift work. Many studies have associated sleep disorders with decreased bone mineral density (BMD) and risk for fracture. Researchers have found that those who work long-term in night positions, like nurses, are at a great risk for wrist and hip fractures (RR=1.37).[4] Low fertility and issues during pregnancy are increased in shift workers.[5] Obesity, diabetes, insulin resistance, and dyslipidemias were shown to be much higher in those who work night shift.[6] SWSD can increase the risk of mental disorders.[1] Specifically, depression, anxiety, and alcohol abuse is increased in shift workers.[5] Because the circadian system regulates the rate of chemical substances in the body, when it is impaired, several consequences are possible.[1] Acute sleep loss has been shown to increase the levels of t-tau in blood plasma, which may explain the neurocognitive effects of sleep loss.[7]
Sleep quality
Sleep loss and decreased quality of sleep is another effect of shift work. To promote a healthy lifestyle, the American Academy of Sleep Medicine recommended that an adult have 7 or more hours of sleep per day.[8] Each year there are almost 100,000 deaths estimated in the U.S. because of medical errors.[8] Sleep deprivation and sleep disorders are factors that contribute significantly to these errors.[8] In the same article, the authors affirm that there is a high prevalence of sleepiness and symptoms of sleep disorders related to the circadian system in medical center nurses.[8] In a study done with around 1100 nurses, almost half of them (49%) reported sleeping less than 7 hours per day, a significant increase compared to national figures, in which 28% of people claimed to sleep less than 7 hours per night.[9] Having a lack of sleep can impact cognitive performance.[1] For example, it might become difficult to stay focused and concentrate, and reaction times might also be slowed down.[10][1] SWSD might interfere with making decisions quickly, driving, or flying safely.[1] Sleep loss seen in shift workers greatly impairs cognitive performance, being awake for 24 hrs. straight results in a cognitive performance that is equal to a blood-alcohol of 0.10, which is over the legal limit in most states.[5] All of these factors can affect work efficiency and cause accidents. Michael Lee et al. demonstrated that those working night shifts had a significantly higher risk of hazardous driving events when compared to those on a typical day shift schedule.[11] Accidents in the workplace have been found to be 60% higher in shift workers.[5] They can affect the individual's social life and cause a lack of well-being and happiness.[1] Poor sleep quality has also been associated with decreased quality of life, based on a SF-36 assessment.[12]
Sleep and alertness
Although SWD affects a majority of shift workers, its manifestation is still unclear within the general shift-working population.[13] A field study investigating the nature of SWD in an experimental (with SWD) and control (non-SWD) group of Finnish shift workers revealed decreased total sleep time (TST) and increased sleep deficit before morning shifts.[13] Furthermore, the SWD group also exhibited decreased objective sleep efficiency, decreased in sleep compensation over the weekends, increased sleep latency, and finally poorer sleep quality was recorded in the SWD group compared to the non-SWD group.[13] Moreover, shift workers with SWD scored significantly higher on the Karolinska Sleepiness Scale (KSS) when assessed at the end of night shifts but at the beginning and the end of morning shifts.[13]
Many studies have shown evidence of how partial and total sleep deprivation affects work productivity, absenteeism, fatal workplace accidents, and more.[14][15] In a study by Akkerstedt et al., those who had a hard time sleeping in the past two weeks were at a greater risk for having a fatal workplace accident (RR=1.89, 95% CI 1.22–2.94).[16] Other sleep disorders, like OSA which are risk factors for SWSD, have also been associated with low productivity, absenteeism, and accidents.[17] At a cognitive level, sleep deprivation has been shown to cause decreased attentiveness, increased micro-sleeps, delayed psychomotor response, performance deterioration, neglect of activities, decline in working memory, and more.[15]
Immune functioning
Partial and total sleep deprivation has been linked to an increase of pro-inflammatory markers,[18] such as IL-6,[19] and a decrease in anti-inflammatory markers, such as IL-10, that plays a role in tumor suppression.[20] Chronic shift work has been associated with decreased immune function in nurses. In a study by Naigi, et. al., over the course of a shift, nurses exhibited decreasing levels of Natural Killer cells, an innate immune response that plays a role in infectious disease and tumor suppression.[21] Other researchers have found that less sleep at night increased the risk of developing the common cold.[22] A supporting study by Moher et al. showed that shift workers were more likely to develop infectious diseases after exposure compared to daytime workers.[23] A poorly functioning immune system may leave workers vulnerable for developing occupational illnesses. Sleep loss is also associated with an increase in TNF, a marker of systemic immune functioning.[24]
Cardiovascular disease
Decreased sleep quality and duration have also been associated with other chronic illnesses, such as cardiovascular disease. Many studies have shown that prolonged sleeplessness and sleep disorders, such as OSA, increases systemic levels of CRP, a marker of cardiovascular disease.[18] Many studies have shown that lack of sleep causes blood pressure to increase from the prolonged stimulation of the nervous system.[24] The increase of inflammatory markers, like IL-6, up-regulate the production of CRP.[24]
SWSD in firefighters
SWSD can effect many occupations, but firefighters are at a greater risk because of their extended (24hr) shift and frequent sleep interruptions due to emergencies. Many firefighters suffer from sleep disorders as a result of their extended shift and frequently disrupted sleep. In a study on firefighters by Barger, et al., over a third of study participants screened positive for a sleep disorder, but most had not received a previous medical diagnosis for any sleep disorders.[25] Those with sleep disorders were also at a higher risk for being in a motor vehicle crash (OR=2.0 95% CI 1.29–3.12, p=0.0021), near crash (OR=2.49 95% CI 2.13–2.91, p < 0.0001), and nodding off while driving (OR=2.41 95% CI 2.06–2.82, p < 0.0001).[25]
Symptoms
Cause
Insomnia and wake-time sleepiness are related to misalignment between the timing of a non-standard wake–sleep schedule and the endogenous circadian propensity for sleep and wake. In addition to circadian misalignment, attempted sleep at unusual times can be interrupted by noise, social obligations, and other factors. There is an inevitable degree of sleep deprivation associated with sudden transitions in sleep schedule.[26]
The prevalence of SWSD is unclear because it is not often formally diagnosed but it is estimated to affect 5–10% of night and rotating workers.[27][28][3] There are various risk factors, including age. Although SWSD can appear at any age, the highest prevalence is in the 50 years old and above age bracket and even more so in cases of irregular schedules.[3]
Gender is also a factor.[27] It may be that female night workers sleep less than their male counterparts.[27] A possible explanation is the social obligations that can increase their vulnerability to SWSD. Female night workers also seem to be more sleepy at work.[27]
Some people are more affected by shift work and sleeplessness than others, and some will be impaired on some tasks while others will always perform well on the same tasks.[29] Some people have a morning preference but others not.[29] Genetic predisposition is an important predictor of which people are vulnerable to SWSD.[29]
Mechanism
Brain arousal is stimulated by the circadian system during the day and sleep is usually stimulated at night.[30] The rhythms are maintained in the suprachiasmatic nucleus (SCN), located in the anterior hypothalamus in the brain, and synchronized with the day/night cycle.[30] Gene-transcription feedback loops in individual SCN cells form the molecular basis of biological timekeeping.[30] Circadian phase shifts are dependent on the schedule of light exposure, the intensity, and previous exposure to light.[31] Variations in exposure can advance or delay these rhythms. For example, the rhythms can be delayed due to light exposure at night.[31]
Photoreceptors located in the retina of the eye send information about environmental light through the retinohypothalamic tract to the SCN.[30][31] The SCN regulates the pineal gland, which secretes the hormone melatonin.[31] Typically, the secretion of melatonin begins two hours before bedtime and ends two hours prior to waking up.[31] A decline in neuronal firing in the SCN is caused by the binding of melatonin to the MT1 and MT2 melatonin receptors. It is believed that the reduction in firing in the SCN stimulates sleep.[30] While day-active individuals produce melatonin at night, night shift workers' production of melatonin is suppressed at night due to light exposure.[31]
Circadian misalignment
Circadian misalignment plays a major role in shift work sleep disorder. Circadian misalignment occurs when there is no complete adaptation to a night shift schedule.[31] The hormones cortisol and melatonin are an important part of the circadian rhythm.[31] In circadian misalignment, cortisol and melatonin lack entrainment to a night oriented schedule and stay on a daytime schedule.[31] Melatonin continues to peak at night during a shift workers awake time and decreases during a shift workers sleep time.[31] Cortisol levels are lower during a shift workers awake time and remain higher during shift workers sleep time.[31]
Diagnosis
The primary symptoms of shift work sleep disorder are insomnia and excessive sleepiness associated with working (and sleeping) at non-standard times. Shift work sleep disorder is also associated with falling asleep at work. Total daily sleep time is usually shortened and sleep quality is less in those who work night shifts compared to those who work day shifts.[26] Sleepiness is manifested as a desire to nap, unintended dozing, impaired mental acuity, irritability, reduced performance, and accident proneness. Shift work is often combined with extended hours of duty, so fatigue can be a compounding factor.[32] The symptoms coincide with the duration of shift work and usually remit with the adoption of a conventional sleep-wake schedule.[32] The boundary between a "normal response" to the rigors of shift work and a diagnosable disorder is not sharp.
There are criteria of SWSD in the International Classification of Sleep Disorder – Third Edition (ICSD-3) and in the International Classification of Diseases (ICD-10). The diagnosis requires the following assumptions :[33][34][5]
- There is an insomnia or/and an excessive sleepiness with a reduction of total sleep time, all combined with an overlap of work period occurring during the habitual sleep time.
- The presence of these symptoms has lasted for at least 3 months and are associated with the shift work schedules.
- Sleep log or actigraphy monitoring (with sleep diaries) demonstrate for more than 14 days (work and free days included) circadian and sleep-time misalignment.
- Sleep disturbance is associated with impairment of social, occupational, and/or other waking functioning.
- These symptoms are not better explained by another sleep disorder, medical or neurologic disorder, mental disorder, medication use, poor sleep hygiene, or substance use disorder.
Assessments
There are different tools to assess shift work disorder.[27] Patients can keep a diary.[27] Some questionnaires could be useful as the Morningness-Eveningness Questionnaire.[27] Actigraphy and polysomnography could indicate some interesting patterns.[27] Further studies are needed to see if some phase markers as the body temperature rhythm or the melatonin rhythm are efficient to assess shift work disorder.[27] Decreased sleep quality may be assessed using the Pittsburg Sleep Quality Index (PQSI).[17]
Treatment
Prescribed sleep/wake scheduling
Experts agree that there is no such thing as an "ideal" night work schedule, but some schedules may be better than others. For example, rotating shifts every two weeks in a forward (delaying) direction was found to be easier than rotation in a backward (advancing) direction.[35] Gradual delays (“nudging” the circadian system about an hour per day) has been shown in a laboratory setting to maintain synchrony between sleep and the endogenous circadian rhythms,[36] but this schedule is impractical for most real world settings. Some experts have advocated short runs (1 to 2 days) of night work with time for recovery; however, in the traditional heavy industries, longer (5 to 7 day) runs remain the rule. In the end, scheduling decisions usually involve maximizing leisure time, fairness in labor relations, etc. rather than chronobiological considerations. Shift workers can benefit from adhering to sleep hygiene practices related to sleep/wake scheduling.[10] Symptoms typically only fully resolve once a normal sleep schedule is resumed.[32]
Many night workers take naps during their breaks, and in some industries, planned napping at work (with facilities provided) is beginning to be accepted. A nap before starting a night shift is a logical prophylactic measure. However, naps that are too long (over 30 minutes) may generate sleep inertia, a groggy feeling after awakening that can impair performance. Therefore, brief naps (10 to 30 minutes) are preferred to longer naps (over 30 minutes). Also, long naps may interfere with the main sleep period.[37]
In the transportation industry, safety is a major concern, and mandated hours of service rules attempt to enforce rest times.
Bright light treatment
The light-dark cycle is the most important environmental time cue for entraining circadian rhythms of most species, including humans, and bright artificial light exposure has been developed as a method to improve circadian adaptation in night workers. The timing of bright light exposure is critical for its phase shifting effects. To maximize a delay of the body clock, bright light exposure should occur in the evening or first part of the night, and bright light should be avoided in the morning. Wearing dark goggles[38] (avoiding bright light) or blue-blocking goggles during the morning commute home from work can improve circadian adaptation. For workers who want to use bright light therapy, appropriate fixtures of the type used to treat winter depression are readily available[39] but patients need to be educated regarding their appropriate use, especially the issue of timing. Bright light treatment is not recommended for patients with light sensitivity or ocular disease.
Melatonin treatment
Melatonin is a hormone secreted by the pineal gland in darkness, normally at night. Its production is suppressed by light exposure,[40] principally blue light around 460 to 480 nm. Light restriction, or dark therapy, in the hours before bedtime allows its production. Dark therapy does not require total darkness. Amber or orange colored goggles eliminate blue light to the eyes while allowing vision.
Melatonin is also available as an oral supplement. In the US and Canada, the hormone melatonin is not classified as a drug; it is sold as a dietary supplement. In other countries, it requires a prescription or is unavailable. Although it is not licensed by the FDA as a treatment for any disorder, there have been no serious side effects or complications reported to date.
Melatonin has been shown to accelerate the adaptation of the circadian system to a nighttime work schedule.[41] Melatonin may benefit daytime sleep in night workers by an additional direct sleep promoting mechanism. Melatonin treatment may increase sleep length during both daytime and nighttime sleep in night shift workers.[26]
Medications that promote alertness
Caffeine is the most widely used alerting drug in the world and has been shown to improve alertness in simulated night work.[42] Caffeine and naps before a night shift reduces sleepiness during the shift.[26] Modafinil and armodafinil are non-amphetamine alerting drugs originally developed for the treatment of narcolepsy that have been approved by the FDA (the US Food and Drug Administration) for excessive sleepiness associated with SWSD.[43]
Medications that promote daytime sleep
Obtaining enough sleep during the day is a major problem for many night workers. Hypnotics given in the morning can lengthen daytime sleep; however, some studies have shown that nighttime sleepiness may be unaffected.[44] Zopiclone has been shown to be ineffective in increasing sleep in shift workers.[26]
See also
- Shift work
- Jet lag
- Human factors
- Human reliability
References
- "Shift Work Disorder Symptoms". National Sleep Foundation. Retrieved 2019-06-20.
- "Shift Work Sleep Disorder (SWSD)". Cleveland Clinic. Retrieved 2020-04-12.
- American Psychiatric Association (2013). Diagnostic and statistical manual of mental disorders (DSM-5®). American Psychiatric Publications.
- Feskanich D, Hankinson SE, Schernhammer ES (April 2009). "Nightshift work and fracture risk: the Nurses' Health Study". Osteoporosis International. 20 (4): 537–42. doi:10.1007/s00198-008-0729-5. PMC 2651998. PMID 18766292.
- Wickwire EM, Geiger-Brown J, Scharf SM, Drake CL (May 2017). "Shift Work and Shift Work Sleep Disorder: Clinical and Organizational Perspectives". Chest. 151 (5): 1156–1172. doi:10.1016/j.chest.2016.12.007. PMC 6859247. PMID 28012806.
- Ulhôa MA, Marqueze EC, Burgos LG, Moreno CR (2015). "Shift work and endocrine disorders". International Journal of Endocrinology. 2015: 826249. doi:10.1155/2015/826249. PMC 4393906. PMID 25892993.
- Benedict, Christian; Blennow, Kaj; Zetterberg, Henrik; Cedernaes, Jonathan (2020-03-17). "Effects of acute sleep loss on diurnal plasma dynamics of CNS health biomarkers in young men". Neurology. 94 (11): e1181–e1189. doi:10.1212/WNL.0000000000008866. ISSN 0028-3878. PMID 31915189.
- "Nurses have increased risk of sleep disorders, sleep deprivation". American Academy of Sleep Medicine – Association for Sleep Clinicians and Researchers. 2019-06-07. Retrieved 2019-06-22.
- Christian F, Muppavarapu K, Aston C, Bauer CY, Doshi V (2019-04-13). "0630 Sleep Health of Nursing Staff in an Academic Medical Center: Results of a Survey Study". Sleep. 42 (Supplement_1): A251. doi:10.1093/sleep/zsz067.628. ISSN 0161-8105.
- Jehan S, Zizi F, Pandi-Perumal SR, Myers AK, Auguste E, Jean-Louis G, McFarlane SI (2017). "Shift Work and Sleep: Medical Implications and Management". Sleep Medicine and Disorders : International Journal. 1 (2). PMC 5836745. PMID 29517053.
- Lee ML, Howard ME, Horrey WJ, Liang Y, Anderson C, Shreeve MS, et al. (January 2016). "High risk of near-crash driving events following night-shift work". Proceedings of the National Academy of Sciences of the United States of America. 113 (1): 176–81. Bibcode:2016PNAS..113..176L. doi:10.1073/pnas.1510383112. PMC 4711869. PMID 26699470.
- Lo CM, Lee PH (June 2012). "Prevalence and impacts of poor sleep on quality of life and associated factors of good sleepers in a sample of older Chinese adults". Health and Quality of Life Outcomes. 10 (1): 72. doi:10.1186/1477-7525-10-72. PMC 3445836. PMID 22709334.
- Vanttola P, Härmä M, Viitasalo K, Hublin C, Virkkala J, Sallinen M, et al. (May 2019). "Sleep and alertness in shift work disorder: findings of a field study". International Archives of Occupational and Environmental Health. 92 (4): 523–533. doi:10.1007/s00420-018-1386-4. PMC 6435614. PMID 30511341.
- Kucharczyk, Erica R.; Morgan, Kevin; Hall, Andrew P. (December 2012). "The occupational impact of sleep quality and insomnia symptoms". Sleep Medicine Reviews. 16 (6): 547–559. doi:10.1016/j.smrv.2012.01.005. ISSN 1087-0792. PMID 22401983.
- Goel, Namni; Rao, Hengyi; Durmer, Jeffrey; Dinges, David (September 2009). "Neurocognitive Consequences of Sleep Deprivation". Seminars in Neurology. 29 (4): 320–339. doi:10.1055/s-0029-1237117. ISSN 0271-8235. PMC 3564638. PMID 19742409.
- AKERSTEDT, T.; FREDLUND, P.; GILLBERG, M.; JANSSON, B. (March 2002). "A prospective study of fatal occupational accidents - relationship to sleeping difficulties and occupational factors". Journal of Sleep Research. 11 (1): 69–71. doi:10.1046/j.1365-2869.2002.00287.x. ISSN 0962-1105. PMID 11869429.
- Jurado-Gámez, Bernabé; Guglielmi, Ottavia; Gude, Francisco; Buela-Casal, Gualberto (May 2015). "Workplace Accidents, Absenteeism and Productivity in Patients With Sleep Apnea". Archivos de Bronconeumología (English Edition). 51 (5): 213–218. doi:10.1016/j.arbr.2014.12.002. ISSN 1579-2129.
- Meier-Ewert HK, Ridker PM, Rifai N, Regan MM, Price NJ, Dinges DF, Mullington JM (February 2004). "Effect of sleep loss on C-reactive protein, an inflammatory marker of cardiovascular risk". Journal of the American College of Cardiology. 43 (4): 678–83. doi:10.1016/j.jacc.2003.07.050. PMID 14975482.
- Rohleder N, Aringer M, Boentert M (July 2012). "Role of interleukin-6 in stress, sleep, and fatigue". Annals of the New York Academy of Sciences. 1261 (1): 88–96. Bibcode:2012NYASA1261...88R. doi:10.1111/j.1749-6632.2012.06634.x. PMID 22823398.
- Taraz M, Khatami MR, Hajiseyedjavadi M, Farrokhian A, Amini M, Khalili H, et al. (July 2013). "Association between antiinflammatory cytokine, IL-10, and sleep quality in patients on maintenance hemodialysis". Hemodialysis International. International Symposium on Home Hemodialysis. 17 (3): 382–90. doi:10.1111/hdi.12035. PMID 23490309.
- Nagai M, Morikawa Y, Kitaoka K, Nakamura K, Sakurai M, Nishijo M, et al. (September 2011). "Effects of fatigue on immune function in nurses performing shift work". Journal of Occupational Health. 53 (5): 312–9. doi:10.1539/joh.10-0072-oa. PMID 21778660.
- Cohen S, Doyle WJ, Alper CM, Janicki-Deverts D, Turner RB (January 2009). "Sleep habits and susceptibility to the common cold". Archives of Internal Medicine. 169 (1): 62–7. doi:10.1001/archinternmed.2008.505. PMC 2629403. PMID 19139325.
- Mohren, Danielle C.L.; Jansen, Nicole W.H.; Kant, IJmert; Galama, Jochem M.D.; van den Brandt, Piet A.; Swaen, Gerard M.H. (November 2002). "Prevalence of Common Infections Among Employees in Different Work Schedules". Journal of Occupational and Environmental Medicine. 44 (11): 1003–1011. doi:10.1097/00043764-200211000-00005. ISSN 1076-2752. PMID 12449906.
- Mullington, Janet M.; Haack, Monika; Toth, Maria; Serrador, Jorge; Meier-Ewert, Hans (2009). "Cardiovascular, Inflammatory and Metabolic Consequences of Sleep Deprivation". Progress in Cardiovascular Diseases. 51 (4): 294–302. doi:10.1016/j.pcad.2008.10.003. ISSN 0033-0620. PMC 3403737. PMID 19110131.
- Barger LK, Rajaratnam SM, Wang W, O'Brien CS, Sullivan JP, Qadri S, et al. (March 2015). "Common sleep disorders increase risk of motor vehicle crashes and adverse health outcomes in firefighters". Journal of Clinical Sleep Medicine. 11 (3): 233–40. doi:10.5664/jcsm.4534. PMC 4346644. PMID 25580602.
- Liira J, Verbeek JH, Costa G, Driscoll TR, Sallinen M, Isotalo LK, Ruotsalainen JH (August 2014). "Pharmacological interventions for sleepiness and sleep disturbances caused by shift work". The Cochrane Database of Systematic Reviews. 8 (8): CD009776. doi:10.1002/14651858.CD009776.pub2. PMID 25113164.
- Sack RL, Auckley D, Auger RR, Carskadon MA, Wright KP, Vitiello MV, Zhdanova IV (November 2007). "Circadian rhythm sleep disorders: part I, basic principles, shift work and jet lag disorders. An American Academy of Sleep Medicine review". Sleep. 30 (11): 1460–83. doi:10.1093/sleep/30.11.1460. PMC 2082105. PMID 18041480.
- Drake CL, Roehrs T, Richardson G, Walsh JK, Roth T (December 2004). "Shift work sleep disorder: prevalence and consequences beyond that of symptomatic day workers". Sleep. 27 (8): 1453–62. doi:10.1093/sleep/27.8.1453. PMID 15683134.
- Kecklund G, Axelsson J (November 2016). "Health consequences of shift work and insufficient sleep". BMJ. 355: i5210. doi:10.1136/bmj.i5210. PMID 27803010.
- Wright KP, Bogan RK, Wyatt JK (February 2013). "Shift work and the assessment and management of shift work disorder (SWD)". Sleep Medicine Reviews. 17 (1): 41–54. doi:10.1016/j.smrv.2012.02.002. PMID 22560640.
- Boivin DB, Boudreau P (October 2014). "Impacts of shift work on sleep and circadian rhythms". Pathologie-Biologie. 62 (5): 292–301. doi:10.1016/j.patbio.2014.08.001. PMID 25246026.
- Ker K, Edwards PJ, Felix LM, Blackhall K, Roberts I (May 2010). "Caffeine for the prevention of injuries and errors in shift workers". The Cochrane Database of Systematic Reviews (5): CD008508. doi:10.1002/14651858.CD008508. PMC 4160007. PMID 20464765.
- Cheng P, Drake C (August 2019). "Shift Work Disorder". Neurologic Clinics. 37 (3): 563–577. doi:10.1016/j.ncl.2019.03.003. PMID 31256790.
- Almeida CM, Malheiro A (2016). "Sleep, immunity and shift workers: A review". Sleep Science. 9 (3): 164–168. doi:10.1016/j.slsci.2016.10.007. PMC 5241621. PMID 28123655.
- Czeisler CA, Moore-Ede MC, Coleman RH (July 1982). "Rotating shift work schedules that disrupt sleep are improved by applying circadian principles". Science. 217 (4558): 460–3. Bibcode:1982Sci...217..460C. doi:10.1126/science.7089576. PMID 7089576.
- Gallo LC, Eastman CI (January 1993). "Circadian rhythms during gradually delaying and advancing sleep and light schedules". Physiology & Behavior. 53 (1): 119–26. doi:10.1016/0031-9384(93)90019-C. PMID 8434051.
- Kolla BP, Auger RR (October 2011). "Jet lag and shift work sleep disorders: how to help reset the internal clock" (PDF). Cleveland Clinic Journal of Medicine. 78 (10): 675–84. doi:10.3949/ccjm.78a.10083. PMID 21968474.
- Eastman CI, Stewart KT, Mahoney MP, Liu L, Fogg LF (September 1994). "Dark goggles and bright light improve circadian rhythm adaptation to night-shift work". Sleep. 17 (6): 535–43. doi:10.1093/sleep/17.6.535. PMID 7809567.
- "Seasonal affective disorder treatment: Choosing a light box". MayoClinic.com. Retrieved 2010-12-30.
- deHaro D, Kines KJ, Sokolowski M, Dauchy RT, Streva VA, Hill SM, et al. (July 2014). "Regulation of L1 expression and retrotransposition by melatonin and its receptor: implications for cancer risk associated with light exposure at night". Nucleic Acids Research. 42 (12): 7694–707. doi:10.1093/nar/gku503. PMC 4081101. PMID 24914052.
- Sack RL, Lewy AJ (December 1997). "Melatonin as a chronobiotic: treatment of circadian desynchrony in night workers and the blind". Journal of Biological Rhythms. 12 (6): 595–603. doi:10.1177/074873049701200615. PMID 9406035.
- Muehlbach MJ, Walsh JK (January 1995). "The effects of caffeine on simulated night-shift work and subsequent daytime sleep". Sleep. 18 (1): 22–9. doi:10.1093/sleep/18.1.22. PMID 7761739.
- Czeisler CA, Walsh JK, Roth T, Hughes RJ, Wright KP, Kingsbury L, et al. (August 2005). "Modafinil for excessive sleepiness associated with shift-work sleep disorder". The New England Journal of Medicine. 353 (5): 476–86. doi:10.1056/NEJMoa041292. PMID 16079371.
- Walsh JK, Schweitzer PK, Anch AM, Muehlbach MJ, Jenkins NA, Dickins QS (April 1991). "Sleepiness/alertness on a simulated night shift following sleep at home with triazolam". Sleep. 14 (2): 140–6. doi:10.1093/sleep/14.2.140. PMID 1866527.