Abstract
Noise exposure is becoming extremely common in urban area, but its specific impact on sleep remains controversial. Considering the limitations of previous researches, a field study which can conduct both horizontal and longitudinal analysis was designed. Urban participants were tested during two weeks in their homes, and the noise level of bedroom was artificially regulated by changing the status of window and door. During the 1050 test nights in 75 households, noise exposure was reflected from both instrument monitoring at night and perception questionnaire in the morning, and sleep quality was accessed from actigraphy and questionnaire. The analysis results showed that, 92.3% of the bedroom acoustic environment did not meet the minimum requirements of Chinese standards, and 87.9% of subjects had ever experienced harmful noise during the test period. Furthermore, sleep quality was affected by noise exposure from the perspective of both physiological and psychological; the duration of rapid eye movement (REM) sleep was significantly (p < 0.05) shortened with the increase of sound intensity, the duration of deep sleep shortened and subjective sleep quality worsened significantly (p < 0.05) with the increase of acoustic sensation vote. In addition, females were more sensitive to noise exposure and their subjective sleep quality was more likely to be influenced by emotions. This study has important implications for acoustic environment design of bedrooms in cities, and suggested more attention should be paid to the anxiety caused by noise exposure.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Abbasi AM, Darvishi E, Rodrigues MA, et al. (2022). Gender differences in cognitive performance and psychophysiological responses during noise exposure and different workloads. Applied Acoustics, 189: 108602.
Anomohanran O (2013). Evaluation of environmental noise pollution in Abuja, the capital city of Nigeria. International Journal of Research and Reviews in Applied Sciences, 14: 470–476.
Baudin C, Lefèvre M, Laumon B, et al. (2017). The effects of aircraft noise exposure on psychological distress: The results of the DEBATS study in France, Zurich, Switzerland.
Beheshti MH, Taban E, Samaei SE, et al. (2019). The influence of personality traits and gender on noise annoyance in laboratory studies. Personality and Individual Differences, 148: 95–100.
Berry RB, Brooks R, Gamaldo C, et al. (2017). AASM Scoring Manual Updates for 2017 (Version 2.4). Journal of Clinical Sleep Medicine, 13: 665–666.
BSI (1999). Sound Insulation and Noise Reduction for Buildings. Code of Practice. British Standards Institution.
Buysse DJ, Reynolds CF III, Monk TH, et al. (1989). The Pittsburgh sleep quality index: A new instrument for psychiatric practice and research. Psychiatry Research, 28: 193–213.
Cai Y, Ramakrishnan R, Rahimi K (2021). Long-term exposure to traffic noise and mortality: A systematic review and meta-analysis of epidemiological evidence between 2000 and 2020. Environmental Pollution, 269: 116222.
Cao T, Lian Z, Ma S, et al. (2021). Thermal comfort and sleep quality under temperature, relative humidity and illuminance in sleep environment. Journal of Building Engineering, 43: 102575.
Cao T, Lian Z, Zhu J, et al. (2022). Parametric study on the sleep thermal environment. Building Simulation, 15: 885–898.
Chen Y, Chen B, Deng J, et al. (2022). The integration model of objective and subjective data of residential indoor environment quality in Northeast China based on structural equation modeling. Building Simulation, 15: 741–754.
Cohen J (1977). Statistical Power Analysis for the Behavioral Sciences, Revised Edition. New York: Academic Press.
Çolakkadioğlu D, Yücel M (2017). Modeling of Tarsus-Adana-Gaziantep highway-induced noise pollution within the scope of Adana city and estimated the affected population. Applied Acoustics, 115: 158–165.
Dong X, Wu Y, Chen X, et al. (2021). Effect of thermal, acoustic, and lighting environment in underground space on human comfort and work efficiency: A review. Science of the Total Environment, 786: 147537.
Fiorentini A, Valente R, Perciaccante A, et al. (2007). Sleep’s quality disorders in patients with hypertension and type 2 diabetes mellitus. International Journal of Cardiology, 114: E50–E52.
Halonen JI, Vahtera J, Stansfeld S, et al. (2012). Associations between nighttime traffic noise and sleep: The Finnish public sector study. Environmental Health Perspectives, 120: 1391–1396.
Hornung OP, Regen F, Danker-Hopfe H, et al. (2007). The relationship between REM sleep and memory consolidation in old age and effects of cholinergic medication. Biological Psychiatry, 61: 750–757.
Hudson JL, Gradisar M, Gamble A, et al. (2009). The sleep patterns and problems of clinically anxious children. Behaviour Research and Therapy, 47: 339–344.
Jafarian S, Gorouhi F, Taghva A, et al. (2008). High-altitude sleep disturbance: Results of the Groningen Sleep Quality Questionnaire survey. Sleep Medicine, 9: 446–449.
Jalali L, Bigelow P, Nezhad-Ahmadi MR, et al. (2016). Before-after field study of effects of wind turbine noise on polysomnographic sleep parameters. Noise and Health, 18: 194.
Karni A, Tanne D, Rubenstein BS, et al. (1994). Dependence on REM sleep of overnight improvement of a perceptual skill. Science, 265(5172): 679–682.
Korsavi SS, Jones RV, Fuertes A (2022). Operations on windows and external doors in UK primary schools and their effects on indoor environmental quality. Building and Environment, 207: 108416.
Lai D, Jia S, Qi Y, et al. (2018). Window-opening behavior in Chinese residential buildings across different climate zones. Building and Environment, 142: 234–243.
Liebich T, Lack L, Micic G, et al. (2022). The effect of wind turbine noise on polysomnographically measured and self-reported sleep latency in wind turbine noise naïve participants. Sleep, 45: zsab283.
Liu Y, Song Z, Song C, et al. (2021). A novel point source oxygen supply method for sleeping environment improvement at high altitudes. Building Simulation, 14: 1843–1860.
Ma H, Ji X, Yano T (2008). Analysis of community response to noise in Chinese city. Acta Acustica, 33: 275–282. (in Chinese)
Malik J, Bardhan R, Hong T, et al. (2022). Developing occupant archetypes within urban low-income housing: A case study in Mumbai, India. Building Simulation, 15: 1661–1683.
MOHURD (2010). GB 50118-2010. Code for Design of Sound Insulation of Civil Buildings. Ministry of Housing and Urban-Rural Development of China. (in Chinese)
Morsing JA, Smith M, Ögren M, et al. (2018). Wind turbine noise and sleep: Pilot studies on the influence of noise characteristics. International Journal of Environmental Research and Public Health, 15: 2573.
Nassur A-M, Léger D, Lefèvre M, et al. (2019). The impact of aircraft noise exposure on objective parameters of sleep quality: results of the DEBATS study in France. Sleep Medicine, 54: 70–77.
Okada A, Inaba R (1990). Comparative study of the effects of infrasound and low-frequency sound with those of audible sound on sleep. Environment International, 16: 483–490.
Pirrera S, de Valck E, Cluydts R (2014). Field study on the impact of nocturnal road traffic noise on sleep: The importance of in- and outdoor noise assessment, the bedroom location and nighttime noise disturbances. Science of the Total Environment, 500–501: 84–90.
Shamsipour M, Zaredar N, Monazzam MR, et al. (2022). Burden of diseases attributed to traffic noise in the metropolis of Tehran in 2017. Environmental Pollution, 301: 119042.
Smith MG, Ögren M, Ageborg Morsing J, et al. (2019). Effects of ground-borne noise from railway tunnels on sleep: A polysomnographic study. Building and Environment, 149: 288–296.
Smith MG, Ögren M, Thorsson P, et al. (2020). A laboratory study on the effects of wind turbine noise on sleep: Results of the polysomnographic WiTNES study. Sleep, 43: zsaa046.
Sunde E, Bratveit M, Pallesen S, et al. (2016). Noise and sleep on board vessels in the Royal Norwegian Navy. Noise and Health, 18: 85.
Thiesse L, Rudzik F, Kraemer JF, et al. (2020). Transportation noise impairs cardiovascular function without altering sleep: The importance of autonomic arousals. Environmental Research, 182: 109086.
van Schrojenstein Lantman M, MacKus M, Roth T, et al. (2017). Total sleep time, alcohol consumption, and the duration and severity of alcohol hangover. Nature and Science of Sleep, 9: 181–186.
WHO (2011). Burden of Disease from Environmental Noise. Quantification of Healthy Life Years Lost in Europe. World Health Organization.
WHO (2018). Environmental Noise Guidelines for The European Region. World Health Organization.
Wilkinson RT, Campbell KB (1984). Effects of traffic noise on quality of sleep: Assessment by EEG, subjective report, or performance the next day. The Journal of the Acoustical Society of America, 75: 468–475.
Xu X, Lan L, Shen J, et al. (2021a). Five hypotheses concerned with bedroom environment and sleep quality: A questionnaire survey in Shanghai city, China. Building and Environment, 205: 108252.
Xu X, Lian Z, Shen J, et al. (2021b). Experimental study on sleep quality affected by carbon dioxide concentration. Indoor Air, 31: 440–453.
Xu X, Lian Z, Shen J, et al. (2021c). Environmental factors affecting sleep quality in summer: a field study in Shanghai, China. Journal of Thermal Biology, 99: 102977.
Xu X, Lian Z (2022). Objective sleep assessments for healthy people in environmental research: A literature review. Indoor Air, 32: e13034.
Xu X, Du H, Lian Z (2022). Discussion on regression analysis with small determination coefficient in human-environment researches. Indoor Air, 32: e13117.
Yin H, Li Y, Zhang D, et al. (2022). Airflow pattern and performance of attached ventilation for two types of tiny spaces. Building Simulation, 15: 1491–1506.
Zhang L, Bai Y, Cui X, et al. (2022). Negative emotions and brain: Negative emotions mediates the association between structural and functional variations in emotional-related brain regions and sleep quality. Sleep Medicine, 94: 8–16.
Zhang N, Cao B, Zhu Y (2023). An effective method to determine bedding system insulation based on measured data. Building Simulation, 16: 121–132.
Zhou Y, Pan J, Xu R, et al. (2022). Asthma mortality attributable to ambient temperatures: A case-crossover study in China. Environmental Research, 214: 114116.
Zhu P, Tao W, Lu X, et al. (2022). Optimisation design and verification of the acoustic environment for multimedia classrooms in universities based on simulation. Building Simulation, 15: 1419–1436.
Zilli I, Ficca G, Salzarulo P (2009). Factors involved in sleep satisfaction in the elderly. Sleep Medicine, 10: 233–239.
Acknowledgements
This work was supported by the ASHRAE project 1837-RP “Effects of ventilation in sleeping environments”, 2019–2022 and by the National Natural Science Foundation of China (52078291).
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Xu, X., Lan, L., Sun, Y. et al. The effect of noise exposure on sleep quality of urban residents: A comparative study in Shanghai, China. Build. Simul. 16, 603–613 (2023). https://doi.org/10.1007/s12273-022-0972-2
Received:
Revised:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s12273-022-0972-2