Pain intensity has been reported to fluctuate during the day in some experimental and clinical conditions, but the mechanisms underlying these fluctuations are unknown. Although the circadian timing system is known to regulate a wide range of physiological functions, its implication in pain regulation is largely unknown. Using highly controlled laboratory constant-routine conditions, we show that pain sensitivity is rhythmic over the 24 h and strongly controlled by the endogenous circadian timing system. We found that the circadian component of pain sensitivity can be modelled with a sinusoidal function, with a maximum in the middle of the night and a minimum in the afternoon. We also found a weak homeostatic control of pain sensitivity, with a linear increase over the 34 h of prolonged wakefulness, which slowly builds up with sleep pressure. Using mathematical modelling, we describe that the circadian system accounts for ∼80% of the full magnitude of pain sensitivity over the 24 h, and that sleep-related processes account for only ∼20%. Overall, our data reveal the neurobiological mechanisms involved in driving the rhythmicity of pain perception in humans. We show that pain sensitivity is controlled by two superimposed processes: a strong circadian component and a modest homeostatic sleep-related component. Our findings highlight the need to consider time of day in pain assessment, and indicate that personalized circadian medicine may be a promising approach to pain management.
Keywords: circadian; homeostasis; pain; rhythm; sleep.
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