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Accurately and unobtrusively testing the effects of snoring and sleep interventions at home has become possible with recent advances in digital measurement technologies.
The aim of this study was to examine the effectiveness of using an adjustable bed base to sleep with the upper body in an inclined position to reduce snoring and improve sleep, measured at home using commercially available trackers.
Self-reported snorers (N=25) monitored their snoring and sleep nightly and completed questionnaires daily for 8 weeks. They slept flat for the first 4 weeks, then used an adjustable bed base to sleep with the upper body at a 12-degree incline for the next 4 weeks.
Over 1000 nights of data were analyzed. Objective snoring data showed a 7% relative reduction in snoring duration (
New measurement technologies allow intervention studies to be conducted in the comfort of research participants’ own bedrooms. This study showed that sleeping at an incline has potential as a nonobtrusive means of reducing snoring and improving sleep in a nonclinical snoring population.
Snoring is common and has been associated with poor sleep, increased risk of coronary artery disease, depressive disorders, and other health-related problems [
These approaches have shown some effectiveness in patients with sleep apnea and other disorders [
However, evidence is lacking in nonclinical populations and settings. The accuracy of new unobtrusive sleep and snoring measurement technologies allows intervention studies to be conducted in research participants’ own bedrooms and may contribute new evidence-based knowledge to the field of applied sleep and snoring research. This method of in-home research using innovative digital health tools has an advantage over traditional sleep laboratory studies. It provides insight into the effectiveness of the intervention under real-life conditions, yielding ecologically valid results while still capturing objective data [
In this study, using an adjustable bed base to sleep with the upper body at a 12-degree incline was compared to sleeping in a flat position. The 12-degree angle is sufficient to elevate the head while still being comfortable for sleep. A mild degree of head-of-bed elevation, compared to larger angles, is most likely to be well tolerated while still being effective according to laboratory studies [
The sample included 25 users of SleepScore Labs technology who self-reported nightly snoring and screened negatively for sleep apnea based on the NoSAS (Neck Circumference, Obesity, Snoring, Age, Sex) screening tool, using a cut-off score of >8 [
All participants provided written informed consent, and all procedures were conducted in accordance with the ethical standards of the 1964 Declaration of Helsinki. Western Institutional Review Board-Copernicus Group reviewed the study under the Common Rule and applicable guidance and determined this to be exempt research.
A within-subjects pre-post design was used. During the baseline period, participants slept on their own mattress in a flat position for 4 weeks. During the intervention period, their bed base was replaced with the Dr Oz Good Life Adjustable Base Pro (2020 collection, Maven) to allow for sleeping in an inclined position for 4 weeks using their original mattress. Participants used the preprogrammed Anti-Snore position, resulting in an electrical motor elevating the head of the bed to a 12-degree incline prior to sleep. During the entire 8-week study, participants were instructed to record their snoring and sleep nightly and complete questionnaires daily. Data were collected during the same time period across all participants to account for weekday and weekend variation.
Objective snoring was measured using the Do I Snore or Grind app (Version 1.2.4(2); SleepScore Labs) on an Apple iPod touch sixth generation (Model A1574; Apple Inc) with snoring sensitivity set to high and grinding sensitivity set to low. This consumer app captures sounds using the microphone of the mobile device and identifies snoring using artificial intelligence–based algorithms that filter out nonsnoring sounds. The app quantifies snoring duration exceeding the set level of sensitivity and transforms the percentage of the night during which the user snored into a snore score.
Objective sleep was measured with the SleepScore Max (SleepScore Labs), a noncontact monitoring device using respiratory and motion signals to detect sleep. It uses ultralow-power radiofrequency waves to monitor body movement while in bed; this measurement is unaffected by bedding or nightwear. High-resolution magnitude and duration data of gross movements, micromovements, and full breathing cycles are captured and transformed into 30-second epoch sleep stage data (Wake, Light, Deep, rapid eye movement [REM]) using proprietary algorithms. Studies have shown good agreement between this approach and polysomnography [
Self-report items were developed for the current study. Perceived snoring (nights per week snored and frequency of waking from snoring) was measured before and after the intervention period and perceived sleep (time to fall asleep, number of awakenings during the night, amount of time spent awake after initially falling asleep, feeling well-rested in the morning, and overall sleep quality) was measured daily. These data were collected on the internet using SurveyMonkey (Momentive Inc).
Statistical analyses were performed in R (version 3.5.2; R Foundation for Statistical Computing). Nightly objective snoring data, objective sleep data, and self-reported sleep data were analyzed using multilevel regression with a random intercept model, accounting for nights nested within participants and comparing nights during the baseline period to nights during the intervention period for each outcome. The regression model used was the following: SleepMeasureij = Const0ij + β × TestPeriodij; TestPeriod was coded as 0 for observations during the baseline and 1 for nights during the intervention period.
Self-reported snoring outcomes were analyzed with paired-samples
Discrepancies in sample sizes (N=1181 for snoring, N=991 for sleep, and N=1185 for self-report) occurred as the data sources were incomplete. Participants tracked their snoring and sleep at home and at times were not fully compliant with using these measurement tools or completing daily surveys on the internet. All results reported reflect the largest sample available for each set of analyses.
Night-to-night objective measurement of snoring (1181 nights nested within 25 participants) revealed a 7% relative reduction in snoring duration (
Similar to the objective findings, self-report data indicated that participants felt they snored less often (decreasing on average from 6 nights per week to 5;
Objective snoring and objective sleep multilevel regression results comparing the baseline to the intervention period.
| Outcomes | Observed mean (SD)a | Estimated marginal meansb | ||||||||||
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Baseline period | Intervention period | Intercept (SE) | βc | ||||||||
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Snore scored | 9.28 (4.29) | 8.61 (3.64) | 9.31 (0.24) | –0.756 | .001 | ||||||
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Time in bed in minutes | 452.76 (76.35) | 445.66(75.57) | 450.24 (5.16) | –4.689 | .18 | ||||||
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Total sleep time in minutes | 391.27 (69.05) | 383.78(68.16) | 388.79 (4.61) | –5.534 | .12 | ||||||
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Sleep efficiencye | 85.43 (5.66) | 84.02(5.92) | 86.19 (0.41) | 0.137 | .37 | ||||||
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Sleep onset latency in minutes | 18.65 (14.81) | 18.05(13.23) | 18.54 (1.01) | 0.095 | .46 | ||||||
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Number of awakenings | 4.45 (1.99) | 4.25(2.07) | 4.43 (0.13) | –0.237 | .04 | ||||||
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Percentage of time spent awake after sleep onset | 9.10 (4.87) | 9.25(5.52) | 9.10 (0.37) | 0.032 | .47 | ||||||
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Percentage of time in light sleep | 54.30 (7.07) | 53.55(6.86) | 54.40 (0.46) | –0.668 | .07 | ||||||
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Percentage of time in deep sleep | 19.30 (6.55) | 20.20(7.44) | 19.30 (0.45) | 0.905 | .02 | ||||||
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Percentage of time in REMf sleep | 17.30 (5.37) | 17.00(5.66) | 17.20 (0.36) | –0.298 | .21 | ||||||
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SleepScoreg | 77.63 (9.73) | 78.27(9.98) | 77.40 (0.67) | 0.633 | .17 | ||||||
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BodyScoreg | 78.93 (9.59) | 81.10(10.13) | 78.85 (0.63) | 2.109 | <.001 | ||||||
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MindScoreg | 76.99 (12.99) | 75.62(14.46) | 76.61 (0.93) | –1.421 | .06 | ||||||
aFor the baseline and intervention periods, each mean was calculated by averaging nights across participants, then averaging those participants’ averages to a single simple average.
bThese are the outcomes of separate multilevel regression analyses. Each row shows results from a different single-predictor, single-outcome model.
cThe beta values are unstandardized and can therefore be interpreted on the same scale as the original data.
dSnore score is reported as a percentage.
eSleep efficiency is calculated as the ratio of time spent asleep to time spent in bed and reported as a percentage.
fREM: rapid eye movement.
gThese scores range from 0 to 100.
Night-to-night objective measurement of sleep (991 nights nested within 25 participants) revealed that when sleeping in the inclined position, participants woke up less often (4% decrease in number of awakenings;
Multilevel analyses of the self-reported sleep data (1185 nights nested within 25 participants) showed that participants perceived that they fell asleep faster (20% decrease in sleep onset latency;
Multilevel regression results for self-reported sleep (1185 nights), comparing the baseline to the intervention period.
| Outcomes | Observed mean (SD)a | Estimated marginal meansb | |||
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Baseline period | Intervention period | Intercept (SE) | βc | |
| Perceived sleep onset latency in minutes | 16.38 (11.80) | 13.13 (9.35) | 16.23 (0.79) | –2.922 | <.001 |
| Perceived number of awakenings | 2.33 (1.44) | 1.97 (1.31) | 2.31 (0.10) | –0.320 | .001 |
| Perceived amount of time spent awake after sleep onset in minutes | 14.10 (14.43) | 13.00 (13.36) | 14.13 (1.38) | –0.898 | .26 |
| Feeling well-rested in morningd | 56.29 (16.38) | 66.09 (16.30) | 56.60 (1.08) | 9.651 | <.001 |
| Perceived sleep qualityd | 58.94 (15.52) | 67.47 (16.78) | 59.47 (1.06) | 8.078 | <.001 |
aFor the baseline and intervention period, each mean was calculated by averaging nights across participants, then averaging those participants’ averages to a single simple average.
bThese are the outcomes of separate multilevel regression analyses. Each row shows results from a different single-predictor, single-outcome model.
cThe beta values are unstandardized and can therefore be interpreted on the same scale as the original data.
dThese outcomes are reported as a score ranging from 0-100.
Recent technological advances enable the accurate digital measurement of sleep and snoring in the comfort and familiarity of one’s habitual bedroom [
Analyses of over 1000 nights of data showed a significant improvement across all 4 areas measured: objective snoring, perceived snoring, objective sleep, and perceived sleep. When sleeping with the upper body in the inclined position, compared to when sleeping flat, objectively measured snoring duration decreased and self-reported snoring outcomes improved. Objective sleep measurements revealed fewer awakenings and more time in deep sleep when sleeping in the inclined position. Related to the increase in deep sleep, participants’ average BodyScore increased. Self-reported sleep data showed fewer perceived awakenings and better sleep quality; additionally, participants felt more well-rested in the morning. Participants also felt that they fell asleep faster in the inclined position, but this finding was not confirmed by the objective sleep data. Taken together, these findings suggest that future in-home product intervention research using commercially available snoring and sleep trackers is merited.
In conclusion, sleeping with the upper body at an incline has potential as a simple nonobtrusive means of reducing snoring and improving sleep in a nonclinical snoring population. This sleeping position is thought to lead to benefits by decreasing upper airway collapsibility and increasing the upper airway area, compared to the flat position, leading to improved breathing and, in turn, better sleep [
Study limitations include the need for further validation testing of the commercially available snoring app and the absence of a control group. Applied in-home product intervention studies have limitations compared to clinical trials; the key is to assess any change from no product use to product use as it would be experienced outside of a research setting. The design best reflecting this real-life experience is a baseline-controlled intervention. By using a within-subjects design with long-term use of the intervention, we have confidence that the observed changes are due to the intervention itself.
In this study, data were not collected regarding the sleeper’s preferred body position (eg, supine or lateral) and therefore, possible interactions of sleeping position with the incline were not explored. These interactions have been shown to be relevant in determining optimal positional therapy for sleep apnea [
Neck Circumference, Obesity, Snoring, Age, Sex screening tool
non–rapid eye movement stage 3
obstructive sleep apnea
rapid eye movement
CVB Inc provided the adjustable bases and funding support to SleepScore Labs to design, conduct, and report the study.
The authors are employed by SleepScore Labs. Dr Oz is an investor in SleepScore Labs.