Establishing the acute physiological and sleep disruption characteristics of wind farm versus road traffic noise disturbances in sleep: a randomized controlled trial protocol

Gorica Micic; Branko Zajamsek; Bastien Lechat; Kristy Hansen; Hannah Scott; Barbara Toson; Tessa Liebich; Claire Dunbar; Duc Phuc Nguyen; Felix Decup; Andrew Vakulin; Nicole Lovato; Leon Lack; Colin Hansen; Dorothy Bruck; Ching Li Chai-Coetzer; Jeremy Mercer; Con Doolan; Peter Catcheside

doi:10.1093/sleepadvances/zpad033

Establishing the acute physiological and sleep disruption characteristics of wind farm versus road traffic noise disturbances in sleep: a randomized controlled trial protocol

Sleep Adv. 2023 Sep 6;4(1):zpad033. doi: 10.1093/sleepadvances/zpad033. eCollection 2023.

Authors

Gorica Micic¹, Branko Zajamsek¹, Bastien Lechat¹, Kristy Hansen², Hannah Scott¹, Barbara Toson¹, Tessa Liebich³, Claire Dunbar³, Duc Phuc Nguyen², Felix Decup², Andrew Vakulin^{1

4}, Nicole Lovato¹, Leon Lack^{1

3}, Colin Hansen⁵, Dorothy Bruck⁶, Ching Li Chai-Coetzer^{1

7}, Jeremy Mercer⁷, Con Doolan⁸, Peter Catcheside¹

Affiliations

¹ Flinders University, Flinders Health and Medical Research Institute: Sleep Health, College of Medicine and Public Health, Australia.
² Flinders University, College of Science and Engineering, Australia.
³ Flinders University, College of Education, Psychology and Social Work, Australia.
⁴ University of Sydney, NEUROSLEEP, Woolcock Institute of Medical Research, Australia.
⁵ The University of Adelaide, School of Mechanical Engineering, Australia.
⁶ Victoria University, Institute for Health and Sport, Australia.
⁷ Department of Respiratory, Sleep Medicine and Ventilation, Southern Adelaide Local Health Network, SA Health, Australia.
⁸ University of New South Wales, School of Mechanical and Manufacturing Engineering, Australia.

Abstract

Study objectives: Despite the global expansion of wind farms, effects of wind farm noise (WFN) on sleep remain poorly understood. This protocol details a randomized controlled trial designed to compare the sleep disruption characteristics of WFN versus road traffic noise (RTN).

Methods: This study was a prospective, seven night within-subjects randomized controlled in-laboratory polysomnography-based trial. Four groups of adults were recruited from; <10 km away from a wind farm, including those with, and another group without, noise-related complaints; an urban RTN exposed group; and a group from a quiet rural area. Following an acclimation night, participants were exposed, in random order, to two separate nights with 20-s or 3-min duration WFN and RTN noise samples reproduced at multiple sound pressure levels during established sleep. Four other nights tested for continuous WFN exposure during wake and/or sleep on sleep outcomes.

Results: The primary analyses will assess changes in electroencephalography (EEG) assessed as micro-arousals (EEG shifts to faster frequencies lasting 3-15 s) and awakenings (>15 s events) from sleep by each noise type with acute (20-s) and more sustained (3-min) noise exposures. Secondary analyses will compare dose-response effects of sound pressure level and noise type on EEG K-complex probabilities and quantitative EEG measures, and cardiovascular activation responses. Group effects, self-reported noise sensitivity, and wake versus sleep noise exposure effects will also be examined.

Conclusions: This study will help to clarify if wind farm noise has different sleep disruption characteristics compared to road traffic noise.

Keywords: electroencephalogram; environment noise; road traffic; sleep disruption; sleep disturbance; sleep quality; wind farm; wind turbine.