Abstract
The quality of sleep and its cognitive benefits rely on the cyclic alternance of two distinct sleep stages associated (REM) or not (NREM) with rapid-eye-movements. The ability to predict shifts in sleep stages could help design future interventions in sleep medicine, but it remains unknown how robust the NREM-REM sleep architecture may be for a given individual over many successive nights. We sought to characterize the individual variability and test the predictability of healthy human sleep recorded longitudinally over unprecedented durations (weeks). Based on ultra-long-term sub-scalp electroencephalographic recordings from a newly available, minimally invasive device, we characterized sleep cycles in eight healthy subjects over a median of 30 consecutive days. We first decomposed EEG signals into five frequency bands (δ, θ, α, σ and β) using a multi-taper time-frequency transform. Second, we quantified variability in sleep spectral composition and predictability in sleep stage transitions based on unsupervised and supervised learning methods, respectively. Using dynamic time warping, we quantified the dissimilarity (D) between pairs of nights, showing that it was lower within (D = 2.5 ± 0.7) than across subjects (D = 4.1 ± 0.5, P < 0.001). Further, we extracted archetypal sleep patterns, which are most representative of an individual's NREM-REM spectral architecture. Based on the found interplay between δ and σ power bands modeled in a generalized linear model, we predicted transitions from NREM to REM two to four minutes in advance with high accuracy (area under the receiver operating characteristic curve = 0.88). Taken together, these results show that sleep is variable over consecutive nights in healthy subjects but that core dynamics in sleep oscillations are consistently shared across individuals. As a translational outlook, the predictability of certain sleep transitions affords the means to anticipate pathological symptoms specific of a given sleep stage.