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Journal articles on the topic 'Wearable light loggers'

Author: Grafiati
Published: 7 June 2025
Last updated: 16 July 2025

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1

Stefani, Oliver, Reto Marek, Jürg Schwarz, Sina Plate, Johannes Zauner, and Björn Schrader. "Wearable Light Loggers in Field Conditions: Corneal Light Characteristics, User Compliance, and Acceptance." Clocks & Sleep 6, no. 4 (2024): 619–34. http://dx.doi.org/10.3390/clockssleep6040042.

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Understanding user challenges with light dosimeters is crucial for designing more acceptable devices and advancing light exposure research. We systematically evaluated the usability and acceptability of a light dosimeter (lido) with 29 participants who wore the dosimeter near the corneal plane of the eye for 5 days. Common reasons for not wearing the dosimeter included exercise, recharging, wet environments, public places, and discomfort. Despite these issues, participants adhered to using the dosimeter with high compliance (89% of recording time). Our findings revealed a significant discrepan
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2

Spitschan, Manuel, Karin Smolders, Benjamin Vandendriessche, et al. "Verification, analytical validation and clinical validation (V3) of wearable dosimeters and light loggers." DIGITAL HEALTH 8 (January 2022): 205520762211448. http://dx.doi.org/10.1177/20552076221144858.

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Background Light exposure is an important driver and modulator of human physiology, behavior and overall health, including the biological clock, sleep-wake cycles, mood and alertness. Light can also be used as a directed intervention, e.g., in the form of light therapy in seasonal affective disorder (SAD), jetlag prevention and treatment, or to treat circadian disorders. Recently, a system of quantities and units related to the physiological effects of light was standardized by the International Commission on Illumination (CIE S 026/E:2018). At the same time, biometric monitoring technologies
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3

Guidolin, Carolina, Sam Aerts, Gabriel Kwaku Agbeshie, et al. "Protocol for a prospective, multicentre, cross-sectional cohort study to assess personal light exposure." BMC Public Health, no. 1 (November 26, 2024): 3285. https://doi.org/10.5281/zenodo.14639233.

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Light profoundly impacts many aspects of human physiology and behaviour, including the synchronization of the circadian clock, the production of melatonin, and cognition. These effects of light, termed the non-visual effects of light, have been primarily investigated in laboratory settings, where light intensity, spectrum and timing can be carefully controlled to draw associations with physiological outcomes of interest. Recently, the increasing availability of wearable light loggers has opened the possibility of studying personal light exposure in free-living conditions where people engage in
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4

Zauner, Johannes, Ljiljana Udovicic, and Manuel Spitschan. "Power analysis for personal light exposure measurements and interventions." PLOS ONE 19, no. 12 (2024): e0308768. https://doi.org/10.1371/journal.pone.0308768.

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Background Light exposure regulates the human circadian system and more widely affects health, well-being, and performance. With the rise in field studies on light exposure’s effects, the amount of data collected through wearable loggers and dosimeters has also grown. These data are more complex than stationary laboratory measurements. Determining sample sizes in field studies is challenging, as the literature shows a wide range of sample sizes (between 2 and 1,887 from a recent review of the field and approaching 105 participants in first studies using large-scale ‘biobank’ databases). Curren
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5

Rhudy, Matthew B., Nathan Greenauer, and Catherine Mello. "Wearable light data logger for studying physiological and psychological effects of light data." HardwareX 8 (October 2020): e00157. http://dx.doi.org/10.1016/j.ohx.2020.e00157.

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6

Danilenko, Konstantin V., Oliver Stefani, Kirill A. Voronin, et al. "Wearable Light-and-Motion Dataloggers for Sleep/Wake Research: A Review." Applied Sciences 12, no. 22 (2022): 11794. http://dx.doi.org/10.3390/app122211794.

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Long-term recording of a person’s activity (actimetry or actigraphy) using devices typically worn on the wrist is increasingly applied in sleep/wake, chronobiological, and clinical research to estimate parameters of sleep and sleep-wake cycles. With the recognition of the importance of light in influencing these parameters and with the development of technological capabilities, light sensors have been introduced into devices to correlate physiological and environmental changes. Over the past two decades, many such new devices have appeared from different manufacturers. One of the aims of this
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7

Beranek, P. "P017 The Sleep and Sleep Environment of Shift Workers in Extractive Industries: Methodology to Assess the On-Site and At-Home Sleep Environment." Sleep Advances 4, Supplement_1 (2023): A40. http://dx.doi.org/10.1093/sleepadvances/zpad035.102.

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Abstract Shift work in extractive industries, such as mining, oil and gas, harvesting, and quarrying industries, often involves long working hours, shifts scheduled opposite the biological rhythm, and a variety of roster designs. Initial studies indicate that shift workers in extractive industries experience poor sleep, including short sleep duration and poor sleep quality. Sleep loss may result in fatigue, increasing the risk of accidents and productivity loss. The sleep environment may be a crucial factor impacting sleep, therefore, warranting investigation and potential optimisation. This s
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8

Hariharan S., Monica R., Deepasri K, and Gayathri T. "A Novel and Reliable SOS Alert Band System for Women Safety." Irish Interdisciplinary Journal of Science & Research 09, no. 01 (2025): 61–72. https://doi.org/10.46759/iijsr.2025.9107.

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The safety of women is a growing concern globally, and ensuring timely assistance in distress situations is critical. The SOS Alert Band System is a wearable device designed to enhance women's personal safety by providing immediate distress signals in emergencies. The system integrates multiple key components, including an easy-to-activate SOS button, real-time GPS tracking, motion and biometric sensors, and wireless connectivity via Bluetooth, Wi-Fi, or cellular networks. When the user faces a dangerous situation, the press of the SOS button triggers the system to send an alert with the user'
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9

Stefani, Oliver, Reto Marek, Jürg Schwarz, Sina Plate, Johannes Zauner, and Björn Schrader. "Wearable Light Loggers in Field Conditions: Corneal Light Characteristics, User Compliance, and Acceptance." Clocks and Sleep, October 25, 2025. https://doi.org/10.5281/zenodo.14035319.

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Abstract:
Understanding user challenges with light dosimeters is crucial for designing more acceptable devices and advancing light exposure research. We systematically evaluated the usability and acceptability of a light dosimeter (lido) with 29 participants who wore the dosimeter near the corneal plane of the eye for 5 days. Common reasons for not wearing the dosimeter included exercise, recharging, wet environments, public places, and discomfort. Despite these issues, participants adhered to using the dosimeter with high compliance (89% of recording time). Our findings revealed a significant discrepan
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10

Balajadia, Eljoh, Sophie Garcia, Janine Stampfli, Björn Schrader, Carolina Guidolin та Manuel Spitschan. "Usability and Acceptability of a Corneal-Plane α-Opic Light Logger in a 24-h Field Trial". Digital Biomarkers, 19 вересня 2023, 139–49. http://dx.doi.org/10.1159/000531404.

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<b><i>Introduction:</i></b> Exposure to light fundamentally influences human physiology and behaviour by synchronising our biological clock to the external light-dark cycle and controlling melatonin production. In addition to well-controlled laboratory studies, more naturalistic approaches to examining these “non-visual” effects of light have been developed in recent years. As naturalistic light exposure is quite unlike well-controlled stimulus conditions in the laboratory, it is critical to measure light exposure in a person-referenced way, the “spectral diet.” To this
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11

van Duijnhoven, J., S. L. Hartmeyer, A. Didikoglu, et al. "Measuring light exposure in daily life: A review of wearable light loggers." Building and Environment, February 2025, 112771. https://doi.org/10.1016/j.buildenv.2025.112771.

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12

Spitschan, Manuel, Grégory Hammad, Christine Blume, et al. "Metadata recommendations for light logging and dosimetry datasets." BMC Digital Health 2, no. 1 (2024). http://dx.doi.org/10.1186/s44247-024-00113-9.

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Abstract Background Light exposure significantly impacts human health, regulating our circadian clock, sleep–wake cycle and other physiological processes. With the emergence of wearable light loggers and dosimeters, research on real-world light exposure effects is growing. There is a critical need to standardize data collection and documentation across studies. Results This article proposes a new metadata descriptor designed to capture crucial information within personalized light exposure datasets collected with wearable light loggers and dosimeters. The descriptor, developed collaboratively
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13

Hammad, Grégory, Katharina Wulff, Debra J. Skene, Mirjam Münch, and Manuel Spitschan. "Open-Source Python Module for the Analysis of Personalized Light Exposure Data from Wearable Light Loggers and Dosimeters." LEUKOS, February 28, 2024, 1–10. http://dx.doi.org/10.1080/15502724.2023.2296863.

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14

Guidolin, Carolina, Sam Aerts, Gabriel Kwaku Agbeshie, et al. "Protocol for a prospective, multicentre, cross-sectional cohort study to assess personal light exposure." BMC Public Health 24, no. 1 (2024). http://dx.doi.org/10.1186/s12889-024-20206-4.

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AbstractLight profoundly impacts many aspects of human physiology and behaviour, including the synchronization of the circadian clock, the production of melatonin, and cognition. These effects of light, termed the non-visual effects of light, have been primarily investigated in laboratory settings, where light intensity, spectrum and timing can be carefully controlled to draw associations with physiological outcomes of interest. Recently, the increasing availability of wearable light loggers has opened the possibility of studying personal light exposure in free-living conditions where people e
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15

Didikoglu, Altug, Navid Mohammadian, Sheena Johnson, et al. "Associations between light exposure and sleep timing and sleepiness while awake in a sample of UK adults in everyday life." Proceedings of the National Academy of Sciences 120, no. 42 (2023). http://dx.doi.org/10.1073/pnas.2301608120.

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Experimental and interventional studies show that light can regulate sleep timing and sleepiness while awake by setting the phase of circadian rhythms and supporting alertness. The extent to which differences in light exposure explain variations in sleep and sleepiness within and between individuals in everyday life remains less clear. Here, we establish a method to address this deficit, incorporating an open-source wearable wrist-worn light logger (SpectraWear) and smartphone-based online data collection. We use it to simultaneously record longitudinal light exposure (in melanopic equivalent
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