Abhishek S. Prayag scite author profile

Introduction Light elicits a range of non‐visual responses in humans. Driven predominantly by intrinsically photosensitive retinal ganglion cells (ipRGCs), but also by rods and/or cones, these responses include melatonin suppression. A sigmoidal relationship has been established between melatonin suppression and light intensity; however, photoreceptoral involvement remains unclear. Methods and Results In this study, we first modelled the relationships between alpha‐opic illuminances and melatonin suppression using an extensive dataset by Brainard and colleagues. Our results show that (a) melatonin suppression is better predicted by melanopic illuminance compared to other alpha‐opic illuminances, (b) melatonin suppression is predicted to occur at levels as low as ~1.5 melanopic lux (melanopsin‐weighted irradiance 0.2 µW/cm2), (c) saturation occurs at 305 melanopic lux (melanopsin‐weighted irradiance 36.6 µW/cm2). We then tested this melanopsin‐weighted illuminance‐response model derived from Brainard and colleagues' data and show that it predicts equally well melatonin suppression data from our laboratory, although obtained using different intensities and exposure duration. Discussion Together, our findings suggest that melatonin suppression by monochromatic lights is predominantly driven by melanopsin and that it can be initiated at extremely low melanopic lux levels in experimental conditions. This emphasizes the concern of the non‐visual impacts of low light intensities in lighting design and light‐emitting devices.

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Light Modulation of Human Clocks, Wake, and Sleep

Prayag

Münch

Aeschbach

et al. 2019

Clocks & Sleep

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Light, through its non-imaging forming effects, plays a dominant role on a myriad of physiological functions, including the human sleep–wake cycle. The non-image forming effects of light heavily rely on specific properties such as intensity, duration, timing, pattern, and wavelengths. Here, we address how specific properties of light influence sleep and wakefulness in humans through acute effects, e.g., on alertness, and/or effects on the circadian timing system. Of critical relevance, we discuss how different characteristics of light exposure across the 24-h day can lead to changes in sleep–wake timing, sleep propensity, sleep architecture, and sleep and wake electroencephalogram (EEG) power spectra. Ultimately, knowledge on how light affects sleep and wakefulness can improve light settings at home and at the workplace to improve health and well-being and optimize treatments of chronobiological disorders.

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Abhishek S. Prayag

Melatonin suppression is exquisitely sensitive to light and primarily driven by melanopsin in humans

Light Modulation of Human Clocks, Wake, and Sleep

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