O014 Impact of circadian adaptation on sleep architecture and neurobehavioural performance

Authors

S. Osmond, Brigham and Women's Hospital, Harvard Medical School
L. Grant, Brigham and Women's Hospital, Harvard Medical School
Melissa St. Hilaire, Merrimack CollegeFollow
L. Barger, Brigham and Women's Hospital, Harvard Medical School
G. Brainard, Thomas Jefferson University
E. Klerman, Brigham and Women's Hospital, Harvard Medical School, Massachusetts General Hospital
Steven W. Lockley, Brigham and Women's Hospital and Harvard Medical School
Shadab A. Rahman, Brigham and Women's Hospital and Harvard Medical School

Document Type

Conference Proceeding

Publication Title

Sleep Advances

Publication Date

10-2025

Meeting Name

Sleep DownUnder 2025

Meeting Date

October 8-11, 2025

Meeting Location

Adelaide, Australia

Abstract/ Summary

Introduction

We examined the impact of dynamic lighting schedules on circadian adaptation, sleep architecture, and neurobehavioural performance in a simulated shiftwork paradigm.

Methods

Healthy adults (n = 19, 10F, mean age[±SD]: 36.2 ± 9.2 years) completed an 8-day inpatient protocol that included 4 consecutive simulated nightshifts in which the sleep–wake schedule was delayed by 8 hours relative to habitual sleep–wake schedule. Participants were randomised to one of three dynamic lighting schedules (DLS). Circadian adaptation was assessed by comparing the plasma dim light melatonin onset measured before and after the nightshifts; sleep architecture was assessed immediately before beginning nightshifts (baseline) and after the fourth nightshift by polysomnography. Neurobehavioural performance (10-minute auditory and visual Psychomotor Vigilance Tasks, and Probed Recall Memory) and alertness (Karolinska Sleepiness Scale) were assessed every 1-2 hours during wake.

Results

Shiftwork disrupted sleep, compared to baseline, as indicated by significantly reduced total sleep time (TST), stage 2 sleep (N2), and sleep efficiency (SlEff), and increased wake after sleep onset (WASO, all p< .05). Sleep architecture did not differ between DLS schedules. The mean(±SEM) circadian phase-delay shift across the DLS schedules was -5.2 ± 0.4 hours. More circadian adaptation (i.e., larger circadian phase-shifts) was significantly correlated with TST, SlEff, and REM sleep, and decreased WASO (all p< .001). More circadian adaptation was significantly correlated with better alertness and memory function (both p = < 0.05), but not PVT reaction time or attentional failure (all p≥.30).

Conclusion

Better circadian adaptation during nightshift work is associated with better sleep architecture, subjective alertness, and memory function but not reaction time or sustained attention.