Over the past few years, I have posted quite some studies about the negative effect of noise on learning (check e.g. here and here). This new study suggests that traffic noise at schools has a detrimental effect on the development of working memory and attention in primary-school students.
From the press release:
Road traffic noise is a widespread problem in cities whose impact on children’s health remains poorly understood. A new study conducted at 38 schools in Barcelona suggests that traffic noise at schools has a detrimental effect on the development of working memory and attention in primary-school students. The findings of this study, led by the Barcelona Institute for Global Health (ISGlobal), a centre supported by the “la Caixa” Foundation, have been published in PLoS Medicine.
The study, which forms part of the BREATHE project and was led by researchers Maria Foraster and Jordi Sunyer, included 2,680 children between 7 and 10 years of age. In order to assess the possible impact of traffic noise on cognitive development, the researchers focused on two abilities that develop rapidly during preadolescence and are essential for learning and school attainment: attention and working memory.
Attention includes processes such as selectively attending to specific stimuli or focusing on a specific task for a prolonged period of time. Working memory is the system that allows us to hold information in the mind and manipulate it over a short period of time. When we need to continuously and effectively process information stored in the working memory, we use what is known as complex working memory.
The field work for the study was carried out over a 12-month period in 2012 and 2013, during which participants completed the cognitive tests four times. The aim of these tests was not only to assess working memory and attention, but also to study their evolution over time. Over the same period, noise measurements were taken in front of the 38 participating schools, as well as in the playgrounds and inside classrooms.
On completion of the yearlong study period, the findings showed that the progression of working memory, complex working memory and attention was slower in students attending schools with higher levels of traffic noise. By way of example, a 5 dB increase in outdoor noise levels resulted in working memory development that was 11.4% slower than average and complex working memory development that was 23.5% slower than average. Similarly, exposure to an additional 5 dB of outdoor traffic noise resulted in attention capacity development that was 4.8% slower than average.
Differences Between Inside and Outside the Classroom
In the analysis of outdoor noise at schools, higher average noise level and greater fluctuation in noise levels were both associated with poorer student performance on all tests. Inside the classroom, greater fluctuation in noise levels was also associated with slower progress over the course of the year on all cognitive tests. However, children exposed to higher average classroom noise levels over the course of the year performed worse than students in quieter classrooms only on the attention test, but not on the working memory tests.
“This finding suggests that noise peaks inside the classroom may be more disruptive to neurodevelopment than average decibel level,” commented ISGlobal researcher Maria Foraster, lead author of the study. “This is important because it supports the hypothesis that noise characteristics may be more influential than average noise levels, despite the fact that current policies are based solely on average decibels.”
“Our study supports the hypothesis that childhood is a vulnerable period during which external stimuli such as noise can affect the rapid process of cognitive development that takes place before adolescence,” explained ISGlobal researcher Jordi Sunyer, last author of the study.
Noise Exposure at Home
The researchers used the 2012 road traffic noise map of the city of Barcelona to estimate the average noise level at each participant’s home. In this case, however, no association was observed between residential noise and cognitive development.
“This could be because noise exposure at school is more detrimental as it affects vulnerable windows of concentration and learning processes,” commented Maria Forester. “On the other hand, although noise measurements were taken at the schools, noise levels at the children’s homes were estimated using a noise map that may be less accurate and, in any case, only reflected outdoor noise. This, too, may have influenced the results.”
The study adds to the body of evidence on the effects of transport on children’s cognitive development, which to date have been observed at schools exposed to aircraft noise as well as at schools exposed to traffic-related air pollution. The researchers underscored the need for further studies on road traffic noise in other populations to determine whether these initial findings can be extrapolated to other cities and settings.
Abstract of the study:
Road traffic noise is a prevalent and known health hazard. However, little is known yet about its effect on children’s cognition. We aimed to study the association between exposure to road traffic noise and the development of working memory and attention in primary school children, considering school-outdoor and school-indoor annual average noise levels and noise fluctuation characteristics, as well as home-outdoor noise exposure.
Methods and findings
We followed up a population-based sample of 2,680 children aged 7 to 10 years from 38 schools in Barcelona (Catalonia, Spain) between January 2012 to March 2013. Children underwent computerised cognitive tests 4 times (n = 10,112), for working memory (2-back task, detectability), complex working memory (3-back task, detectability), and inattentiveness (Attention Network Task, hit reaction time standard error, in milliseconds). Road traffic noise was measured indoors and outdoors at schools, at the start of the school year, using standard protocols to obtain A-weighted equivalent sound pressure levels, i.e., annual average levels scaled to human hearing, for the daytime (daytime LAeq, in dB). We also derived fluctuation indicators out of the measurements (noise intermittency ratio, %; and number of noise events) and obtained individual estimated indoor noise levels (LAeq) correcting for classroom orientation and classroom change between years. Home-outdoor noise exposure at home (Lden, i.e., EU indicator for the 24-hour annual average levels) was estimated using Barcelona’s noise map for year 2012, according to the European Noise Directive (2002). We used linear mixed models to evaluate the association between exposure to noise and cognitive development adjusting for age, sex, maternal education, socioeconomical vulnerability index at home, indoor or outdoor traffic-related air pollution (TRAP) for corresponding school models or outdoor nitrogen dioxide (NO2) for home models. Child and school were included as nested random effects.
The median age (percentile 25, percentile 75) of children in visit 1 was 8.5 (7.8; 9.3) years, 49.9% were girls, and 50% of the schools were public. School-outdoor exposure to road traffic noise was associated with a slower development in working memory (2-back and 3-back) and greater inattentiveness over 1 year in children, both for the average noise level (e.g., ‒4.83 points [95% CI: ‒7.21, ‒2.45], p-value < 0.001, in 2-back detectability per 5 dB in street levels) and noise fluctuation (e.g., ‒4.38 [‒7.08, ‒1.67], p-value = 0.002, per 50 noise events at street level). Individual exposure to the road traffic average noise level in classrooms was only associated with inattentiveness (2.49 ms [0, 4.81], p-value = 0.050, per 5 dB), whereas indoor noise fluctuation was consistently associated with all outcomes. Home-outdoor noise exposure was not associated with the outcomes. Study limitations include a potential lack of generalizability (58% of mothers with university degree in our study versus 50% in the region) and the lack of past noise exposure assessment.
We observed that exposure to road traffic noise at school, but not at home, was associated with slower development of working memory, complex working memory, and attention in schoolchildren over 1 year. Associations with noise fluctuation indicators were more evident than with average noise levels in classrooms.