Exposure to bright nights and dim days disrupts circadian rhythms, heightening mortality risk, while consistent daylight exposure supports health and longevity.
A study analyzing over 13 million hours of data from light sensors worn by 89,000 participants found that increased exposure to bright nights and dim days is linked to a higher risk of mortality.
Researchers investigated whether personal day and night light, and lighting patterns that disrupt our circadian rhythms, predicted mortality risk.
Published in the journal Proceedings of the National Academy of Sciences, the results show that those who were exposed to high levels of light at night had a 21–34% increased risk of death, whilst those exposed to high levels of daylight had a 17–34% reduction in their risk of death.
“Exposure to brighter nights and darker days can disrupt our circadian rhythms, a disruption that is known to lead to various health issues including diabetes, obesity, cardiovascular disease, mental health issues and increase the risk of death,” says senior author and sleep expert Professor Sean Cain from Flinders University.
“These new insights into the potential adverse impact of light have shown us just how important personal light exposure patterns are for your health.”
Co-senior author, Associate Professor Andrew Phillips says that light exposure at night disrupts circadian rhythms by shifting the timing (phase-shift) and weakening the signal (amplitude suppression) of the central circadian ‘pacemaker’ which orchestrates circadian rhythms throughout the body.
Links to Cardiometabolic Health
“Disruption to the body’s circadian rhythms is linked to the development of metabolic syndrome, diabetes, and obesity and is also strongly implicated in the development of cardiometabolic diseases including myocardial infarction, stroke, and hypertension,” says Associate Professor Phillips.
“The observed relationships of night light exposure with mortality risk may be explained by night light disrupting circadian rhythms, leading to adverse cardiometabolic outcomes.
“Our findings clearly show that avoiding night light and seeking daylight may promote optimal health and longevity, and this recommendation is easy, accessible, and cost-effective,” adds Associate Professor Phillips.
The study authors, from FHMRI Sleep Health, examined the relationship of personal light exposure with all-cause and cardiometabolic mortality risk in 89,000 UK Biobank participants, who were between 40 and 69 years old. Metrics were recorded with wrist worn sensors and participant mortality was captured by the National Health Service across a follow-up period of approximately 8 years.
Sleep duration, sleep efficiency, and midsleep were estimated from motion data, while cardiometabolic mortality was defined as any cause of death corresponding to diseases of the circulatory system, or endocrine and metabolic diseases.
Findings on Circadian Rhythms and Mortality
The research also showed a disrupted circadian rhythm predicted higher mortality risk, which the authors were able to determine using computer modeling. Findings accounted for age, sex, ethnicity, photoperiod, and sociodemographic and lifestyle factors.
Lead author, Dr Daniel Windred says that the findings demonstrate the importance of maintaining a dark environment across the late night and early morning hours, when the central circadian ‘pacemaker’ is most sensitive to light, and seeking bright light during the day to enhance our circadian rhythms.
“Protection of lighting environments may be especially important in those at risk for both circadian disruption and mortality, such as in intensive care or aged-care settings,” says Dr Windred.
“Across the general population, avoiding night light and seeking daylight may lead to a reduction in disease burden, especially cardiometabolic diseases, and may increase longevity.”
Reference: “Brighter nights and darker days predict higher mortality risk: A prospective analysis of personal light exposure in >88,000 individuals” by Daniel P. Windred, Angus C. Burns, Jacqueline M. Lane, Patrick Olivier, Martin K. Rutter, Richa Saxena, Andrew J. K. Phillips and Sean W. Cain, 15 October 2024, Proceedings of the National Academy of Sciences.
DOI: 10.1073/pnas.2405924121
This research has been conducted using data from UK Biobank, a major biomedical database (Project ID: 6818). M.K.R. was supported by the NIHR Manchester Biomedical Research Centre. D.P.W. was supported by the Australian Government Research Training Program and the Australian Research Council (DP210102924 and DP220102812).