Quantifying the biological impacts of nightlights: implications for sleep and circadian health in children

Children are routinely exposed to nighttime light levels far exceeding those found in nature, with significant implications for sleep and circadian health. Nighttime illumination from natural sources, such as moonlight and stars, typically measures below 1 lux (lx), several orders of magnitude dimmer than direct sunlight. The human circadian system evolved under these stark day-night contrasts, yet modern electric lighting disrupts natural cues, contributing to adverse health outcomes, including sleep disturbance, mood disorders, and metabolic dysfunction¹.

Many children spend daytime hours indoors under electric lighting and remain exposed to ambient light well into the evening. Evening light exposure, particularly from electronic screens (typically 10–100 lx), has been linked to delayed sleep onset and reduced sleep duration, prompting recommendations to limit screen use before bedtime^2,3. Nevertheless, a substantial proportion of children sleep in illuminated environments; one study found 39% of kindergarten children slept with room lights on and 50% used a nightlight⁴. These lighting practices, intended for comfort or safe navigation, may suppress nocturnal melatonin and alter circadian timing, negatively impacting sleep¹. Sleep disturbances affect up to 30% of preschool-aged children⁵ and are associated with long-term effects on health, learning, and development⁶. Thus, evening and nighttime light exposure represents a critical yet often overlooked factor in pediatric sleep health.

While light is essential for vision, it also regulates non-visual physiological processes, including circadian rhythms, melatonin secretion, and alertness. Perceived brightness does not always reflect biological impact because non-visual responses are mediated by intrinsically photosensitive retinal ganglion cells (ipRGCs) that contain melanopsin, distinct from the rods and cones used for vision^7,8. These ipRGCs project to the suprachiasmatic nucleus in the hypothalamus, the central circadian pacemaker, influencing neuroendocrine and behavioral rhythms^1,7–9.

Because of this physiology, responses to light depend on timing, intensity, spectral composition, and spatial distribution. Light exposure in the early biological night can delay circadian rhythms, acutely suppress the nocturnal hormone melatonin, and disturb sleep. These effects are amplified with higher intensity and greater short-wavelength (blue) content^10–13. White lights that appear visually similar may also have dramatically different physiological effects, depending on spectral content¹⁴. As a consequence, the biological potency of light for non-visual responses is quantified via melanopic equivalent daylight illuminance (melanopic EDI), which weights intensity according to the melanopsin absorption curve^15,16. In adults, half-maximal circadian phase shifting and melatonin suppression occur with melanopic EDI of approximately 25–70 lx, based on a meta-analysis of multiple studies, including the primary study by Zeitzer et al.that was originally reported in photopic terms^9,17. Consensus guidelines recommend adults maintain melanopic exposure >250 lx during the day, <10 lx in the evening, and <1 lx at night¹⁸. Although formal guidelines for children are lacking, evidence suggests they are 5 or more times as sensitive as adults, with significant melatonin suppression and phase delays occurring at melanopic EDI as low as 5 lx^19–22.

Reducing light exposure before bedtime may promote earlier sleep onset and longer sleep duration. Because children have longer overall sleep needs and an earlier circadian phase than adolescents and adults, they are particularly vulnerable to the effects of evening light exposure. This is likely why interventions advancing sleep times are particularly promising for improving overall sleep health in children, but may also be partly due to early school schedules limiting morning sleep extension²³. However, minimizing evening light exposure in young children remains challenging in practice. Despite the growing evidence linking light exposure to pediatric sleep disruption, this issue remains largely absent from clinical guidelines and consumer safety standards.

Manufacturers rarely report melanopic or even photopic intensities on nightlight packaging, leaving caregivers and clinicians without clear guidance. Considering the widespread use of nightlights, it is surprising that their biological potency has not been systematically assessed. Understanding how the melanopic intensities of nightlights compare to physiologically relevant thresholds is critical for developing evidence-based recommendations that support pediatric sleep and circadian health.

This study is the first to systematically quantify the biological potency of commercially available nightlights using melanopic equivalent daylight illuminance (EDI) metrics. Our findings reveal that a substantial proportion of nightlights exceed thresholds known to impact circadian physiology, even under typical-use conditions.

While the maximal exposures recorded in laboratory conditions may represent source-level, worst-case scenarios (e.g., holding a bright nightlight immediately up to the eye), the simulated bedroom measurements suggest that more typical usage still often results in melanopic EDI levels that exceed nighttime recommendations and thresholds^18,21,22. At the lowest exposure levels, measurements approach the practical noise floor of the spectroradiometer, and values reported as zero reflect signals below the detection threshold under the measurement conditions rather than a confirmed absence of light emission²⁴. Yet, such low levels represent the minority of nightlight settings, which is particularly concerning given accumulating evidence that children’s circadian systems are more sensitive to light than adults (and even adults may be more sensitive than presumed²⁴); thus, the actual physiological effects of nightlights may be even greater than these data suggest. Importantly, although we did not explicitly evaluate compliance with ICNIRP or toy optical radiation standards, all measured nightlight intensities were far below levels associated with photochemical retinal hazard, indicating minimal risk from blue-light exposure under typical usage conditions.

The variation observed across nightlight types highlights two important considerations for pediatric sleep health. First, spectral composition plays a crucial role: red-hued nightlights consistently showed the lowest theoretical biological potency, which is largely due to reduced ipRGC activation at longer wavelengths¹. Second, placement and distance from the child’s eye are critical determinants of actual exposure, due to the inverse square law of light propagation and the effects of room reflectance²⁵. Our bedroom simulations also underscore that wall plug-in nightlights and projectors (when positioned farther from the bed) generally produce safer light levels, although exceptions exist. In contrast, handheld nightlights, despite often having lower maximum intensity, pose a greater risk of sleep and circadian disruption because they are typically used close to the eyes.

Balancing visual needs and circadian health remains a challenge. Children with a fear of the dark are also at risk for poor sleep quality²⁶. Thus, eliminating nightlights from the bedroom altogether may be counterproductive. Instead, the goal should be to provide nightlights that allow children to see but without eliciting non-visual physiological responses to light. Nightlights that provide sufficient photopic illumination for safe navigation typically exceed melanopic thresholds for circadian disruption¹⁸. Conversely, those that maintain low melanopic exposure often fail to provide adequate light for practical use. However, our data show that some products can strike this balance, suggesting feasible design improvements.

From a clinical perspective, pediatricians should counsel families on the importance of selecting nightlights with lower melanopic content, particularly red or amber lights at the dimmest settings. Placement recommendations include positioning lights away from direct line-of-sight and increasing the distance from the child’s bed, out of reach, when possible. Additional strategies to reduce reliance on nightlights, such as comfort objects or consistent bedtime routines, may also be beneficial.

The absence of standardized labeling or regulatory guidance on nightlight spectral and intensity characteristics is a notable gap. Manufacturers rarely report melanopic or even photopic illuminance, leaving caregivers without critical information to make informed decisions. Given the widespread use of nightlights⁴ and the known heightened sensitivity of children’s circadian systems^19–22, establishing clinical guidelines, regulatory standards, and clear product labeling is essential to supporting healthy pediatric sleep and circadian health.

Our light measurement data raise practical concerns about the health and safety impacts of nightlights. Future research should empirically test the impact of nightlights with varying melanopic EDI levels on melatonin secretion, sleep timing, and behavioral outcomes in children, including real-world use with handheld lights. Long-term studies are also needed to evaluate the chronic effects of low-level nocturnal light exposure in pediatric populations.

This study involved measuring the spectral irradiance of a range of commercially available children’s nightlights under both laboratory and ecologically valid conditions. Our goal was to calculate melanopic equivalent daylight illuminance (melanopic EDI) and evaluate each nightlight’s theoretical biological potency relative to established circadian thresholds.

Supplementary Information