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| Name | Class |
|---|---|
| National Medical Research Council (NMRC), Singapore | OTHER_GOV |
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The aim of this study is to examine the neurobehavioural responses to two successive cycles of sleep manipulation nights and recovery nights in adolescents, and to determine the benefits of napping on cognitive performance, alertness and mood. Using a split-sleep design, 60 participants, aged 15 to 19 years old, are divided into a nap and a no-nap group. Both groups undergo two cycles of sleep manipulation nights and recovery nights over a period of 15 days. The no-nap group receives an 8-hour sleep opportunity on sleep restriction nights, with no daytime nap opportunity. The nap group receives a 6.5-hour sleep opportunity on sleep restriction nights, and has a 1.5-hour nap opportunity the following afternoon.
The present study investigates whether a continuous stretch of night time sleep (8 hours) will lead to better neurobehavioural outcomes relative to nocturnal sleep restriction (6.5 hours) and daytime nap (1.5 hours) of the same total duration. The 15-day protocol is conducted in a dormitory on 60 high school students, aged 15 to 19 years old. Participants are assigned to a nap or no-nap group. Both groups start with two 9-hour adaptation and baseline nights, followed by two successive cycles of sleep restriction (6.5-h time in bed (TIB); 00:15-06:45 or 8-h TIB; 23:30-07:30) and recovery (9-h TIB; 23:00-08:00). Following each sleep-restricted night, the nap group receives a 1.5-h nap opportunity, while participants in the no-nap group watch a documentary. Throughout the protocol, sleep-wake patterns are assessed with actigraphy and polysomnography. Sleepiness levels, mood, vigilance, working memory / executive functions, and speed of processing are assessed 3 times daily (10:00, 16:15, and 20:00).
All participants stay in air-conditioned, twin-share bedrooms with en-suite bathrooms. Bedroom windows are fitted with blackout panels to ensure participants are not woken up prematurely by sunlight. Earplugs are provided, and participants are allowed to adjust the temperature of their bedrooms to their personal comfort. Three main meals are served each day, with snacks being provided for upon request. Caffeinated drinks, unscheduled sleep, and strenuous physical activities are prohibited.
Outside of scheduled sleep, meal, and cognitive testing times, participants spend the majority of their free time in a common room that is illuminated by natural and artificial lighting. They are allowed to read, play non-physically exerting games, watch videos, and interact with research staff and other participants. Participants are under constant supervision by the research staff.
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| Label | Type | Description | Intervention Names |
|---|---|---|---|
| Nap | Experimental | After each night with a 6.5-hour sleep opportunity, participants have a daytime nap opportunity of 1.5 hours. |
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| No nap | No Intervention | After each night with a 8-hour sleep opportunity, participants do not have a daytime nap opportunity, but instead have free time. |
| Name | Type | Description | Arm Group Labels | Other Names |
|---|---|---|---|---|
| Nap | Behavioral | Looking at the difference between continuous sleep opportunities and split-sleep opportunities. |
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| Measure | Description | Time Frame |
|---|---|---|
| 1.Change in sustained attention assessed with the Psychomotor Vigilance Task from morning to afternoon and then evening from baseline days to the first and second cycles of sleep restriction and recovery | Number of attention lapses (>500ms) | 3 times daily (10:00, 16:15, and 20:00) for 15 days |
| 2.Change in working memory assessed with the 1-back task from morning to afternoon and then evening from baseline days to the first and second cycles of sleep restriction and recovery | Number of correct responses in the 1-back task | 3 times daily (10:00, 16:15, and 20:00) for 15 days |
| 3.Change in executive functions assessed with the 3-back task from morning to afternoon and then evening from baseline days to the first and second cycles of sleep restriction and recovery | Number of correct responses in the 3-back task | 3 times daily (10:00, 16:15, and 20:00) for 15 days |
| 4.Change in the level of subjective sleepiness assessed with the Karolinska Sleepiness Scale from morning to afternoon and then evening from baseline days to the first and second cycles of sleep restriction and recovery | Score on the Karolinska Sleepiness Scale (1-9 points) | 3 times daily (10:00, 16:15, and 20:00) for 15 days |
| 5.Change in positive mood assessed with the Positive and Negative Affect Scale (PANAS) from morning to afternoon and then evening from baseline days to the first and second cycles of sleep restriction and recovery | Total score on the positive subscale of the PANAS | 3 times daily (10:00, 16:15, and 20:00) for 15 days |
| 6.Change in negative mood assessed with the Positive and Negative Affect Scale (PANAS) from morning to afternoon and then evening from baseline days to the first and second cycles of sleep restriction and recovery |
| Measure | Description | Time Frame |
|---|---|---|
| Change in total sleep duration at night assessed with polysomnography from baseline nights to the first and second cycles of sleep restriction and recovery | Total duration of nocturnal sleep was determined to establish baseline sleep characteristics (first and second nights) and changes in the first sleep restriction period (third, fifth and seventh night), the first recovery period (eighth night), the second sleep restriction period (tenth and twelfth night), and the second recovery period (13th night). |
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Exclusion Criteria:
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| Name | Affiliation | Role |
|---|---|---|
| Michael WL Chee, MBBS | Duke-NUS Graduate Medical School | Principal Investigator |
| Facility | Status | City | State | ZIP | Country | Contacts |
|---|---|---|---|---|---|---|
| Duke-NUS Medical School | Singapore | 169857 | Singapore |
| PubMed Identifier | Type | Citation | Retractions |
|---|---|---|---|
| 38938171 | Derived | Leong RLF, Tian L, Yu N, Teo TB, Ong JL, Chee MWL. Bidirectional associations between the duration and timing of nocturnal sleep and daytime naps in adolescents differ from weekdays to weekends. Sleep. 2024 Sep 9;47(9):zsae147. doi: 10.1093/sleep/zsae147. | |
| 37193282 | Derived | Golkashani HA, Ghorbani S, Leong RLF, Ong JL, Chee MWL. Advantage conferred by overnight sleep on schema-related memory may last only a day. Sleep Adv. 2023 Apr 14;4(1):zpad019. doi: 10.1093/sleepadvances/zpad019. eCollection 2023. |
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Total score on the negative subscale of the PANAS |
| 3 times daily (10:00, 16:15, and 20:00) for 15 days |
| 7.Change in speed of processing assessed with the Mental Arithmetic Task from morning to afternoon and then evening from baseline days to the first and second cycles of sleep restriction and recovery | Number of correct responses in the task | 3 times daily (10:00, 16:15, and 20:00) for 15 days |
| 8.Change in speed of processing assessed with the Symbol Digit Modalities Task from morning to afternoon and then evening from baseline days to the first and second cycles of sleep restriction and recovery | Number of correct responses in the task | 3 times daily (10:00, 16:15, and 20:00) for 15 days |
| 11.Change in memory performance in picture-word association task over sleep restriction nights and recovery night | Score on picture-word association task | 12 times (morning and evening): after sleep restriction night 1, 2, 3, 4 and 5 (sleep restriction period 1) and after recovery night 2 (recovery period 1) |
| 14.Effect of sleep versus wake during delay on memory for rewarded pictures, where the pictures will be encoded either before a 12-hr interval including a night of sleep or a day of wakefulness | Memory score of correctly remembered encoded pictures following the wake or sleep | Single session during the 15-day protocol, after baseline night 1 or before sleep restriction night 1 (first sleep restriction period) |
| 15.Effect of sleep restriction on learning of novel material (about different animal species) across separate sessions | Memory score on test of learned material | Single session during the 15-day protocol, after recovery night 2 (first recovery period) |
| 16.Effect of sleep restriction on memory of spatial locations | Performance in four mountains task | Single session during the 15-day protocol, after sleep restriction night 3 (first sleep restriction period) |
| 18.Effect of sleep restriction on picture encoding | Memory score of correctly remembered encoded pictures of non-famous people, landscapes, scenes and objects | Single session during the 15-day protocol, after recovery night 2 (second recovery period) |
| 19.Effect of sleep restriction on effort/temporal discounting | Choice preference (perform a longer duration task for a higher reward, or to take a break for a lower/no reward) in effort/temporal discounting task is measured | Three sessions during the 15-day protocol (after baseline night 1, after sleep restriction night 5 (first sleep restriction period) and after recovery night 2 (first recovery period)) |
| Nocturnal sleep on nights 1 & 2 (baseline), 3, 5 & 7 (first sleep restriction period), 8 (first recovery period), 10 & 12 (second sleep restriction period), & 13 (second recovery period) |
| Change in N1 sleep duration at night assessed with polysomnography from baseline nights to the first and second cycles of sleep restriction and recovery | Duration of nocturnal N1 sleep was determined to establish baseline sleep characteristics (first and second nights) and changes in the first sleep restriction period (third, fifth and seventh night), the first recovery period (eighth night), the second sleep restriction period (tenth and twelfth night), and the second recovery period (13th night). | Nocturnal sleep on nights 1 & 2 (baseline), 3, 5 & 7 (first sleep restriction period), 8 (first recovery period), 10 & 12 (second sleep restriction period), & 13 (second recovery period) |
| Change in N2 sleep duration at night assessed with polysomnography from baseline nights to the first and second cycles of sleep restriction and recovery | Duration of nocturnal N2 sleep was determined to establish baseline sleep characteristics (first and second nights) and changes in the first sleep restriction period (third, fifth and seventh night), the first recovery period (eighth night), the second sleep restriction period (tenth and twelfth night), and the second recovery period (13th night). | Nocturnal sleep on nights 1 & 2 (baseline), 3, 5 & 7 (first sleep restriction period), 8 (first recovery period), 10 & 12 (second sleep restriction period), & 13 (second recovery period) |
| Change in N3 sleep duration at night assessed with polysomnography from baseline nights to the first and second cycles of sleep restriction and recovery | Duration of nocturnal N3 sleep was determined to establish baseline sleep characteristics (first and second nights) and changes in the first sleep restriction period (third, fifth and seventh night), the first recovery period (eighth night), the second sleep restriction period (tenth and twelfth night), and the second recovery period (13th night). | Nocturnal sleep on nights 1 & 2 (baseline), 3, 5 & 7 (first sleep restriction period), 8 (first recovery period), 10 & 12 (second sleep restriction period), & 13 (second recovery period) |
| Change in Rapid Eye Movement (REM) sleep duration at night assessed with polysomnography from baseline nights to the first and second cycles of sleep restriction and recovery | Duration of nocturnal REM sleep was determined to establish baseline sleep characteristics (first and second nights) and changes in the first sleep restriction period (third, fifth and seventh night), the first recovery period (eighth night), the second sleep restriction period (tenth and twelfth night), and the second recovery period (13th night). | Nocturnal sleep on nights 1 & 2 (baseline), 3, 5 & 7 (first sleep restriction period), 8 (first recovery period), 10 & 12 (second sleep restriction period), & 13 (second recovery period) |
| Change in total sleep duration during daytime naps assessed with polysomnography from the first to the second sleep restriction period | Total duration of sleep during the selected nap episodes was determined to track changes in this parameter from the first sleep restriction period (third, fifth and seventh day) to the second sleep restriction period (tenth and twelfth day) | Afternoon naps on days 4, 6 & 8 (first sleep restriction period), 11 & 13 (second sleep restriction period |
| Change in N1 sleep duration during daytime naps assessed with polysomnography from the first to the second sleep restriction period | Duration of N1 sleep during the selected nap episodes was determined to track changes in this parameter from the first sleep restriction period (third, fifth and seventh day) to the second sleep restriction period (tenth and twelfth day) | Afternoon naps on days 4, 6 & 8 (first sleep restriction period), 11 & 13 (second sleep restriction period |
| Change in N2 sleep duration during daytime naps assessed with polysomnography from the first to the second sleep restriction period | Duration of N2 sleep during the selected nap episodes was determined to track changes in this parameter from the first sleep restriction period (third, fifth and seventh day) to the second sleep restriction period (tenth and twelfth day) | Afternoon naps on days 4, 6 & 8 (first sleep restriction period), 11 & 13 (second sleep restriction period |
| Change in N3 sleep duration during daytime naps assessed with polysomnography from the first to the second sleep restriction period | Duration of N3 sleep during the selected nap episodes was determined to track changes in this parameter from the first sleep restriction period (third, fifth and seventh day) to the second sleep restriction period (tenth and twelfth day) | Afternoon naps on days 4, 6 & 8 (first sleep restriction period), 11 & 13 (second sleep restriction period |
| Change in REM sleep duration during daytime naps assessed with polysomnography from the first to the second sleep restriction period | Duration of REM sleep during the selected nap episodes was determined to track changes in this parameter from the first sleep restriction period (third, fifth and seventh day) to the second sleep restriction period (tenth and twelfth day) | Afternoon naps on days 4, 6 & 8 (first sleep restriction period), 11 & 13 (second sleep restriction period |
| 35090173 | Derived | Aghayan Golkashani H, Leong RLF, Ghorbani S, Ong JL, Fernandez G, Chee MWL. A sleep schedule incorporating naps benefits the transformation of hierarchical knowledge. Sleep. 2022 Apr 11;45(4):zsac025. doi: 10.1093/sleep/zsac025. |
| 35089345 | Derived | Lo JC, Koa TB, Ong JL, Gooley JJ, Chee MWL. Staying vigilant during recurrent sleep restriction: dose-response effects of time-in-bed and benefits of daytime napping. Sleep. 2022 Apr 11;45(4):zsac023. doi: 10.1093/sleep/zsac023. |
| 33313925 | Derived | Leong RLF, Yu N, Ong JL, Ng ASC, Jamaluddin SA, Cousins JN, Chee NIYN, Chee MWL. Memory performance following napping in habitual and non-habitual nappers. Sleep. 2021 Jun 11;44(6):zsaa277. doi: 10.1093/sleep/zsaa277. |
| 32619240 | Derived | Lo JC, Leong RLF, Ng ASC, Jamaluddin SA, Ong JL, Ghorbani S, Lau T, Chee NIYN, Gooley JJ, Chee MWL. Cognitive effects of split and continuous sleep schedules in adolescents differ according to total sleep opportunity. Sleep. 2020 Dec 14;43(12):zsaa129. doi: 10.1093/sleep/zsaa129. |