Hypothesis

Evening exposure to narrow‑band 480 nm blue light combined with a brief bout of low‑intensity aerobic exercise reduces sleep latency by accelerating adenosine clearance and homeostatic sleep pressure, independent of melatonin suppression.

Mechanistic Rationale

• Morning bright light (≥2500 lux) advances circadian phase via intrinsically photosensitive retinal ganglion cells and improves sleep efficiency[https://pmc.ncbi.nlm.nih.gov/articles/PMC2387132/].
• Evening light (~550 lux for several hours) saturates phase‑delay responses and suppresses melatonin[https://pmc.ncbi.nlm.nih.gov/articles/PMC6751071/][https://journals.sagepub.com/doi/10.1177/14771535211014792].
• However, adenosine accumulates during wakefulness and its clearance during sleep promotes sleep pressure dissipation; exercise increases cerebral blood flow and adenosine metabolism[https://formative.jmir.org/2026/1/e73969].
• We propose that 480 nm light, which minimally affects melanopsin‑driven melatonin suppression relative to broader blue spectra, synergizes with exercise‑induced adenosine washout to hasten the onset of sleep without shifting circadian timing.

Testable Predictions

1. Participants receiving 30 min of 480 nm light (≈150 lux) followed by 10 min of treadmill walking at 3 km/h will show a ≥15 % reduction in sleep latency compared with light‑only or exercise‑only controls.
2. Salivary melatonin levels will not differ significantly between the combined condition and dim‑light control, indicating that latency changes are not mediated by melatonin suppression.
3. Polysomnographic adenosine metabolites in prefrontal cortex (measured via microdialysis in a subset) will decline faster during the first sleep cycle in the combined condition.
4. Night‑to‑night variability of sleep latency, a marker of insomnia severity[https://formative.jmir.org/2026/1/e73969], will decrease over a 2‑week intervention period.

Experimental Design

• Recruit 60 adults with moderate insomnia (ISI > 14) and confirmed delayed sleep phase.
• Randomize to four groups: (a) 480 nm light + exercise, (b) 480 nm light only, (c) exercise only, (d) dim‑light (<30 lux) control.
• Interventions occur 2 hours before habitual bedtime for 14 consecutive nights.
• Primary outcome: objective sleep latency measured by contactless radar (SleepScore Max) validated against actigraphy[https://formative.jmir.org/2026/1/e73969].
• Secondary outcomes: sleep efficiency, salivary melatonin, adenosine metabolites, and night‑to‑night latency variability.
• Statistical analysis: mixed‑effects models with group, night, and interaction terms; falsifiability established if the combined group does not show a significant latency reduction versus controls (p > 0.05).

Potential Impact

If supported, this hypothesis offers a non‑pharmacological, chronobiologically neutral strategy to tackle sleep‑onset insomnia by targeting homeostatic rather than circadian pathways, complementing existing morning‑light recommendations.[https://medicalupdateonline.com/2026/01/sleep-duration-timing-and-quality-how-smartphone-data-predict-labor-productivity/]