Skip to main content
Download PDF
Download ePub

School polices, programmes and facilities, and objectively measured sedentary time, LPA and MVPA: associations in secondary school and over the transition from primary to secondary school

International Journal of Behavioral Nutrition and Physical Activity volume 13, Article number: 54 (2016) Cite this article

Abstract

Background

There is increasing policy interest in ensuring that the school environment supports healthy behaviours. We examined the cross-sectional and longitudinal associations between schools’ policies, programmes and facilities for physical activity (PA) and adolescents’ objectively-measured activity intensity during the school day and lunchtime.

Methods

Accelerometer-derived PA (proportion of time spent in sedentary (SED), light PA (LPA) and moderate-to-vigorous PA (MVPA)) during school hours and lunchtime from 325 participants in the SPEEDY study were obtained from baseline measurements (primary school, age 9/10 years) and +4y follow-up (secondary school). School environment characteristics were assessed by teacher questionnaire. Multivariable multi-level linear regression analyses accounting for school and adjusted for sex, age, BMI and family socio-economic status assessed cross-sectional associations with lunchtime and school-day SED, LPA and MVPA; effect modification by sex was investigated. The association of changes in school environment with changes in outcomes was examined using multivariable cross-classified linear regression models.

Results

There were significant differences between primary and secondary schools for 6/10 school environment characteristics investigated (including secondary schools reporting shorter breaks, more lunchtime PA opportunities, and higher number of sports facilities). Cross-sectional analyses showed that boys attending secondary schools with longer breaks spent significantly less time in SED and more time in MVPA during the school day. Longitudinally, an increase in break-time duration between primary and secondary school was associated with smaller reductions in MVPA during the school day. Moreover, participants who moved from a primary school that did not provide opportunities for PA at lunchtime to a secondary school that did provide such opportunities exhibited smaller increases in SED and smaller reductions in MVPA at lunchtime.

Conclusions

Schools should consider the potential negative impact of reducing break time duration on students’ MVPA and SED during the school day. School-based interventions that combine longer breaks and more PA opportunities during lunchtime may be a fruitful direction for future research. Further research should also explore other factors in the school environment to explain the school-level clustering observed, and study sex differences in the way that the school environment influences activity intensity for adolescent populations.

Background

The promotion of physical activity among young people is a public health priority [1]. Data from several countries suggest that a substantial proportion of children are insufficiently active to achieve health benefit [2, 3], and that levels of physical activity decline throughout childhood and into adolescence [4, 5]. Furthermore, sedentary behaviour may have detrimental health effects in young people, independent of the level of physical activity acquired [6], as well as its own unique correlates [7].

Schools are considered an important setting for the promotion of health and well-being in young people, and there is increasing policy interest in ensuring that the school environment supports activity [810]. A growing number of studies have explored how features of the school’s environment impact upon activity. For example, characteristics of the physical environment, such as better outdoor facilities [11] and larger school campuses and play areas [12], have shown associations with greater moderate-to-vigorous physical activity (MVPA). However, the evidence for the influence of the physical environment (for adolescent populations especially) is generally mixed [13, 14]. For example, in a previous analysis of SPEEDY [15] data, Harrison and colleagues identified few associations between objectively measured features of the school physical environment and adolescent MVPA [14]. The current study extends this research by considering how multiple school-related factors, beyond the objectively measured physical environment, may be associated with adolescent physical activity and sedentary time. This includes “whole-school” policies, programmes and resources for physical activity.

The majority of studies that have explored the school policy environment for physical activity have been undertaken in primary schools [1618], limiting what can be applied to older students in secondary schools. Several studies have shown that the transition from primary to secondary school is marked by a change in activity amount and pattern, with the direction and exact nature of the change seemingly attributable, at least in part, to features of the school environment (e.g., changes in policies, programmes and facilities for physical activity) [4, 19]. A recent study examined the changes in the school environment from primary to secondary school and found that secondary schools were more likely to foster activity during school hours, whereas primary schools were more likely to promote physical activity after-school [19]. Specifically, secondary schools scored more positively on school environment characteristics (e.g., active schoolyards and playgrounds and health education policy) but lower on sport and physical activity after-school. These findings are noteworthy given that other studies have shown that physical activity in school hours decreases during the transition to secondary school (especially during lunch times; [20]). How changes in the school environment between primary and secondary school affect students’ activity behaviour is however largely unknown. Moreover, most research has focused on MVPA and not considered light physical activity and/or sedentary behaviour.

This study aims to add to the limited knowledge on the importance of the secondary school environment for student activity intensity (sedentary time (SED), light physical activity (LPA, and MVPA). The specific objectives are; (a) to explore changes in the physical activity supportiveness of school policies, programmes and facilities between primary and secondary schools, (b) to assess the associations between secondary school policies, practices and facilities for physical activity and objectively measured adolescent activity intensity during the school day and at lunchtime, and (c) to examine the longitudinal association between change in school physical activity policies, practices and facilities and change in objectively measured activity intensity during the school day and at lunchtime.

Methods

Recruitment and data collection

The SPEEDY (Sport, Physical activity and Eating behaviour: Environmental Determinants in Young people) study is a population based longitudinal cohort study which sought to investigate the factors associated with diet and physical activity behaviour of young people in the county of Norfolk, England. Methods of school and participant recruitment and data collection procedures have been described in detail elsewhere [15, 21] therefore only a brief overview is provided below, focusing on the specific measures utilised in the current analyses.

In 2007, 157 primary schools across the county of Norfolk with at least 12 Year 5 pupils (age 9/10 years) were sampled according to stratification by urban/rural status. Ninety two primary schools were recruited. Baseline data collection was performed (n = 2064) during the school summer term (April to July 2007; ‘SPEEDY 1’). Child height and weight were measured by trained researchers and used to calculate body mass index (BMI, in kg/m2). Parent’s self-reported highest level of education, home ownership, car ownership and ethnicity were obtained from a questionnaire survey.

Participants with an active postal address and who had not withdrawn from the study were contacted via their home address 4 years later, when aged 13/14y (school year 9; the third year of secondary education). Follow-up assessment was undertaken during the school summer term of 2011 (‘SPEEDY 3’), in which all covariates mentioned above were measured again using the same methods [20, 21].

Measurement of activity intensity

At both time points, time spent in activity intensities was measured objectively using an Actigraph (GT1M; Pensacola, FL) accelerometer, set to record at 5-s epochs [22]. The Actigraph has been shown to accurately assess energy expenditure among European children and adolescents during free-living conditions [23, 24]. Participants were instructed to wear the monitor during waking hours for 7 days and to remove it while bathing, showering and swimming.

Accelerometer data were analysed using a batch processing programme (http://www.mrc-epid.cam.ac.uk/research/resources/). Periods of ≥10 min of continuous zeros were considered non-wear time and excluded [25, 26]. Thresholds for defining activity intensities (scaled to 5-s epochs) were as follows: sedentary time (SED) <100 cpm (cpm), light physical activity (LPA) ≥101–1999 cpm [27], MVPA ≥2000 cpm. A lower threshold of 2000 cpm to define MVPA has been used previously in this study [28] and others [26] and is equivalent to walking at 4 km/h [23].

Based on school-reported start and end times of the school day and lunch time break, we derived the duration of these periods at the school level and matched them minute-by-minute with the accelerometry data. The primary outcome variables were expressed as the proportion of accelerometer wear time (cross-sectional analysis) or change in the proportion of accelerometer wear time (longitudinal analysis) in each activity intensity (SED, LPA, MVPA), accounting for differences in duration of break and school day. Outcome variables were derived separately for lunch time and the whole school day. A valid observation was defined as wear time ≥80 % of the duration of lunch time or the school day. For each time period, a minimum of 2 valid days of observation was required for inclusion in the analysis.

School-level variables

At both SPEEDY 1 and SPEEDY 3, a questionnaire asking about the school policies, programmes and facilities was distributed to school head teachers [18]. Table 1 describes the variables assessed. All 92 primary schools at SPEEDY 1 returned the questionnaire. Students who participated in SPEEDY 1 (and agreed to follow-up in SPEEDY 3) attended 49 different secondary schools. Schools with < 2 students from the SPEEDY study in attendance were not asked to complete a school questionnaire (related to N = 8 participants). This left 43 secondary schools at SPEEDY 3 that returned the school questionnaire.

Table 1 Description, descriptive characteristics, and differences between primary and secondary schools for school questionnaire-based data collected
Full size table

Covariates

The child’s sex, age (at SPEEDY 3), BMI (at SPEEDY 3) and family SES (at SPEEDY 1) were included in analytical models as covariates. Family SES was measured as a score calculated as the sum of three variables; parent-reported age at leaving full time education (≤16 years coded 0; >16 years coded 1), car ownership (no coded 0; yes coded 1), and house ownership (rental coded 0; own/buying coded 1). Participants were assigned to low (score 0/1), mid (score 2) or high (score 3) SES groups as used in a previous study [29].

Data analyses

All analyses were undertaken using STATA version 13 (Stata, College Station, TX). Three separate analyses were undertaken to address the objectives outlined above.

Changes in the school environment for PA from primary to secondary school

Differences in the school environment between the primary schools and secondary schools were tested using independent samples t-tests and chi-square tests.

Cross-sectional associations at secondary school

Outcome variables for SED and LPA were normally distributed. MVPA (school-day and lunch time) was not normally distributed, with a small number of extreme outliers; therefore we curtailed outliers to the 95th percentile value to achieve acceptable levels of kurtosis. Multivariable multi-level linear regression was used to assess cross-sectional associations between school policies, programmes, and facilities and activity intensity, accounting for school-level clustering and adjusted for sex, age, BMI and family SES. As previous evidence suggests that features of the school environment impact boys and girls differently [30], interactions with sex were explored.

First, a null-model was created to estimate school-level variance for each outcome, adjusted for all covariates. Second, the association between each exposure variable and each outcome variable was assessed; variables with a P-value of less than .25 were retained at this stage in order to minimise Type 2 error as a result of confounding amongst the exposure variables. Third, interactions between each exposure variable and sex were assessed for each outcome variable. Interactions were retained for inclusion in the multivariable model where they met the following criteria: 1) the interaction term P-value was <0.1 and 2) the determinant was associated at P < 0.05 for at least one of the sexes in a stratified model. This strategy was employed to simplify interpretation of the final multivariable model and to reduce the risk of type 1 error resulting from multiple hypothesis testing. Lastly, the final models were developed, including only those variables and interactions terms retained from steps 2 and 3 described above. This model building strategy was also applied in the longitudinal analyses.

Longitudinal analyses (primary to secondary school)

To account for differences in school/lunch duration at primary and secondary school, outcomes were derived as change in the proportion of wear-time spent in each intensity category (SED, LPA, MVPA) from primary to secondary school. Outcome variables for change in SED and LPA were normally distributed. Change in MVPA (school-day and lunch time) was not normally distributed, due to a small number of extreme outliers; these values were curtailed at the 99th percentile for use in the analysis.

For continuous exposure variables (e.g., hours of PE, length of break duration etc.) change variables were derived as baseline subtracted from follow-up. Change in PE duration was categorised as ‘no change’, ‘decrease’ or ‘increase’. Categorical variables were derived to reflect changes in binary exposures from baseline to follow-up (e.g., “does the school have a physical activity policy?” was coded into ‘no/no’, ‘no/yes’, ‘yes/yes’ and ‘yes/no’ reflecting all four possible options). Where individual categories contained less than 5 % of responses these were collapsed with other categories where appropriate. For example, the physical activity policy variable contained only12 cases in the ‘no/no’ group. Therefore this was combined with the ‘yes/yes’ group to create one reference group that reflected ‘no change’ in physical activity policy. For exposures relating to the requirement to be outdoors during break times and the use of screens at break time, derivation of change variables resulted in one category that comprised just one observation. These categories were recoded to missing and not estimated in regression models.

The association of changes in school environment with changes in SED, LPA and MPVA was examined using cross-classified multi-level linear regression models. The cross-classified model accounts for the clustering of participants within primary and secondary schools but does not assume a hierarchical structure as children from any given primary school attended several different secondary schools, and each secondary school received pupils from several different primary schools.

As described for the cross-sectional analyses, simple models were developed to look at associations between each exposure (change) variable and each outcome (change) variable. Then interactions with sex were explored. Finally, full models were developed with those variables retained from the initial steps.

Results

There were no differences in the age, sex or BMI (all: p > 0.05) of participants that provided valid accelerometer data for either lunch time or the whole school day at SPEEDY3 relative to those that were assessed at SPEEDY 1. Characteristics of participants who provided valid accelerometer data at both SPEEDY 1 and SPEEDY 3 are shown in Table 2, with participants contributing an average of 4.2 to 4.7 valid days.

Table 2 Sample characteristics for SPEEDY participants included in these analyses (n = 325)
Full size table

Differences in the school-environment between primary and secondary school

Table 1 shows the exposure variable scores for the primary and secondary school samples. Secondary schools had shorter break time, a higher number of good quality sports facilities, a more positive perceived physical environment (for promoting physical activity) surrounding the school, and greater provision of lunchtime extracurricular physical activity compared to primary schools. In relation to school-based break time policies, a greater proportion of secondary schools allowed screen-based activities during break times. In addition, a significant difference was observed for break time policy. Specifically, more primary schools had a rule that pupils must go outdoors if the weather is dry.

Cross-sectional associations between the school environment and adolescent activity intensity

We analysed data from 325 participants at SPEEDY 3 who provided valid accelerometer data. Intraclass correlation coefficients indicated that school-level differences accounted for 16 %, 12 % and 15 % of the variance in lunchtime SED, LPA and MVPA respectively, and 7 %, 2 %, and 23 % of the variance in school-day SED, LPA and MVPA respectively.

Based on the simple models, two variables were taken forwards for lunchtime SED and MVPA models (hours of PE, and compulsory outdoor break) and three variables for the school-day models (hours of PE, length of break time and school attitude). Additional files 1 and 2: Tables S1 and S2 show the results from the simple models for SED, LPA and MVPA during lunchtime and school-day respectively. No exposure variable was associated with LPA at p < 0.25. The final multivariable models are shown in Tables 3 and 4 (lunchtime and school-day, respectively). None of the variables were associated at p < 0.05.

Table 3 Cross-sectional association of school policies, practices and facilities with adolescent sedentary time and physical activity during lunchtime (multivariable models)
Full size table
Table 4 Cross sectional association of school policies, practices and facilities with adolescent sedentary time and physical activity during the whole school day (multivariable models)
Full size table

Sex differences in the cross-sectional associations

Three interactions with sex were explored further in the final models. There was evidence of effect modification by sex for the association between total duration of break and school-day SED (β for interaction = −0.0013, p = .098). Subgroup analyses showed that boys attending schools with longer breaks spent a significantly lower proportion of their wear time in SED (β = −0.0013, p = .024). This equates to approximately 20 min across the school day when comparing the SPEEDY secondary schools with the longest (95 mins) and shortest break duration (50 mins). There was no association for girls (β = −0.000039, p = .995). A second interaction with total duration of break was identified for school-day MVPA (β = −0.00070, p = .040). Subgroup analyses showed that boys attending schools with longer breaks spent a greater proportion of wear time in MVPA (β = 0.00075, p = .018). This equates to approximately 12 min across the school day when comparing the SPEEDY secondary schools with the longest and shortest break duration. There was no association in girls (β = 0.000051, p = .882). Third, the association between break-time physical activity rules (i.e., physically active activities allowed) and school-day MVPA was also moderated by sex (β = −0.012, p = .051). Sex-stratified analyses revealed that the direction of association was in the opposite direction for boys and girls, however the associations were non-significant for both sexes (boys: β = 0.006, p = .397; girls: β = −0.006, p = .374).

Longitudinal associations between changes in the school environment and changes in activity intensity

As reported in Table 2, and previously [21], lunchtime and school-day levels of MVPA and LPA decreased over the transition to secondary school, and both lunchtime and school-day SED increased. Additional files 3 and 4: Tables S3 and S4 show the results from the simple models for changes in SED, LPA and MVPA during lunchtime and school-day, respectively. Several school-level variables were taken forwards to the multivariable models, based on an association in the simple models, or evidence of a significant interaction (and sub-group) effect by sex.

Multivariable models for lunchtime and school-day are presented in Tables 5 and 6 respectively. Participants who moved from a primary school that did not provide extra-curricular physical activity at lunchtime to a secondary school that did provide such opportunities exhibited smaller increases in the proportion of monitor wear time spent sedentary during lunchtime and during the whole school day. They also exhibited smaller reductions in MVPA at lunchtime and during the school day. An increase in the duration of break time from primary to secondary school was associated with smaller reductions in MVPA across the whole school day. None of the examined exposures were associated with changes in LPA at p < 0.05 for lunchtime or school-day.

Table 5 Longitudinal association of changes in the school environment with changes in activity intensity during lunchtime (multivariable models)
Full size table
Table 6 Longitudinal association of changes in the school environment with changes in activity intensity during the whole school day (multivariable models)
Full size table

Sex differences in the longitudinal associations

We examined the multivariable models with the inclusion of the interaction term taken forwards from the exploration of the simple models. For change in the proportion of wear time spent in LPA during the school-day, there was a significant interaction effect for sex for ‘PE duration increased’ (β = 2.42, p = .052). Boys who went to a secondary school with longer PE duration than primary school demonstrated larger decreases in school-day LPA (β = −1.842, p = .046) compared to those whose PE duration was unchanged. There was no association in girls for an increase in PE duration (from primary to secondary) and change in LPA during the school day (β = 0.57, p = .51). The sex interaction term for the association with lunchtime MVPA of moving from a school that was less permissive of physical activity to one that was more permissive was significant (β = −5.75, p = .03), but subgroups associations were non-significant (boys: β = 2.67, p = .30; girls: β = −3.07, p = .18). None of the other interactions from the simple models were significant in the multivariable models.

Discussion

The analyses presented in this paper show that the supportiveness of the school environment for activity intensity differs between primary and secondary schools in Norfolk, UK. However, only total break duration and extra-curricular physical activity opportunities at lunchtime are associated with adolescent MVPA and SED.

This work shows that secondary schools generally have shorter break times, a higher number of good quality sports facilities, a more positive physical environment surrounding the school, and greater provision of lunchtime extracurricular physical activity compared to primary schools. De Meesters et al. [19] also found that secondary schools in their Belgian sample tended to score higher than primary schools in terms of numbers of physical activity facilities. A recent study also using data from the SPEEDY cohort, but using audit-based objective measures of the physical environment (SPEEDY audit tool [31]) found that primary schools scored more positively than secondary schools for their supportiveness of physical activity, and significantly so for sport and play facilities [14]. The questionnaire-based measures presented here asked schools to report the number of “medium and high quality” facilities at their school, which includes a subjective judgement about quality. In contrast, the audit tool [31] objectively assesses individual components relating to specific facilities for sport and play. In both the present study and in Harrison et al’s [14] study, there was no association with activity intensity for the number of quality facilities. However, this highlights the challenges of using different measures to assess the school’s physical environment, which should be considered in its interpretation and future studies.

Total duration of break times in secondary schools was associated with more MVPA and less SED in boys across the whole school day in cross-sectional analyses, whereas an increase in the duration of break time attenuated the reductions in MVPA between primary and secondary school in both sexes. A previous SPEEDY analysis also reported an association between the length of morning break and maintenance of MVPA in primary school children [32]. However, to our knowledge, this is the first study to explore the impact of break time duration on adolescent activity intensity.

The importance of break times within schools has been outlined in a number of reports over the last decade [33, 34]. Break times are becoming shorter, especially in secondary schools [34]. Within our study, there was a vast difference in the secondary school break arrangements with some secondary schools only receiving 50 min break in total throughout the school day, while others received up to 95 min of break throughout the school day. Given that for boys this difference can result in over 20 min less SED and 12 min more MVPA during the school day, these findings add to the body of evidence that supports the importance of protecting break times at schools.

In view of emerging evidence that sedentary behaviour may have independent health effects in young people [6], the findings of this study suggest that secondary schools should consider the potential impact of break time in order to foster health and well-being in students. Furthermore, increasing break time duration may also result in other social and educational benefits [33]. This is a topic worthy of further observational and intervention research. It may be that increasing break time length may provide a cost-effective way of reducing sedentary time in schools. However, it is unknown if there is any trade-off with educational attainment if classroom time is reduced to accommodate more break time. One might hypothesise that educational attainment would not be negatively impacted if the breaks are physically active in nature [35, 36], however this link might not arise from simply increasing break time duration alone. The acceptability and feasibility of this idea should be considered, with more research to understand why the association is not shown in girls. A recent qualitative study in primary schools found that boys and girls experiences of break times were different and called for interventions that focus on the wider social environment of break times [37] to optimise break times for boys and girls. A similar study in secondary schools would be useful to explore the differences in how boys and girls experience break times and what school policies and practices might improve the break time experience in female students, as increasing the length of break alone might not be sufficient. In our recent review of the literature [13], there was some qualitative evidence that suggested certain polices (such as open gyms during break times) appear to benefit boys more than girls. However, there were no quantitative studies that examined break time specific rules and regulations, let alone how these may be moderated by sex.

As previously reported by Corder et al. [21], our analyses showed that the transition from primary school to secondary school is associated with increases in SED, and decreases in LPA and MVPA (during the school day and during lunchtime specifically). This pattern is also shown in other Western countries [4]. The current analyses showed that an increase in the provision of extra-curricular physical activity at lunchtime between primary and secondary school attenuated these commonly observed changes. A recent systematic review of adolescent PA and SED, showed an indeterminate association for the provision of extra-curricular physical activity opportunities and adolescent physical activity – however, the included studies did not include measures for SED behaviour, nor did they specifically look at extra-curricular provision at lunchtime [13]. Given that this finding is similar for boys and girls, the provision of lunchtime extra-curricular physical activity opportunities should be considered a potential intervention strategy to maintain activity across the transition from primary to secondary school. Furthermore, combining the provision of extra-curricular physical activity opportunities with increasing the length of break duration might improve the break time experience for all young people in secondary schools. The feasibility of this approach however needs further exploration, as it may result in increased supervision requirements and the need to introduce more equipment and facilities. Furthermore, the specific activities that are offered should be considered in greater detail as it is likely that the choice of activities available would determine uptake (e.g., contact sports versus dance versus walking groups), along with the level of student involvement and choice in deciding what these activities will be [10, 38].

We also found that an increase in PE duration from primary to secondary school was associated with lower levels of LPA in boys only. This is an interesting observation and potentially reflects a compensation effect [39] (i.e., boys are reducing light PA due to an increase in activity in PE). No data was available on timing of PE classes and we are therefore unable to further explore this issue. It would however be interesting to probe this research question further, including an exploration of the reasons for the observed gender difference in this association.

A notable observation is the relatively high level of variance explained at the school-level for school-day MVPA. However, the majority of school policies, practices and facilities assessed in the present study are not associated with school-day MVPA. As previously mentioned, Harrison and colleagues [14] have conducted complementary analyses focusing on objective measures of the physical environment (school grounds scores) only. Their analyses found positive cross-sectional associations between active travel provision scores and commuting time MVPA for adolescent boys and those living further from school. However, there were very few associations between changes in school ground scores (between primary and secondary schools) and change in school-based MVPA. Taken together, this indicates that there are other aspects within the school environment that determine the supportiveness of the environment for MVPA across the school day that have not been picked up with either the audit instrument or questionnaire. This could for example include the quality of the PE teaching or other features of the social environment not assessed.

The school environment not only consists of the physical features of the school, but also the wider psycho-social characteristics, which includes school leadership and the wider school ethos surrounding physical activity and also individual teacher behaviours [13]. It is unlikely that these features are captured within our one item that assessed school ‘attitudes’ towards physical activity promotion. Future research should seek to utilise (or develop) better measures of the school’s social environment that capture constructs such as physical activity-related leadership and the wider ethos of the school relating to physical activity. There could be scope for developing more objective measures of these features – similar to an audit tool that could better assess policy and social environment related factors in schools.

Strengths and limitations

We used a validated, objective measure of activity intensity, and followed up the same participants in order to assess change in behaviour in relation to change in school policies, programmes and facilities. Furthermore, individual school-level time segments for the school day (and lunch time) were incorporated to be able to explore precise effects on each time segment and reduce error in activity estimates. Finally, we also examined the associations of school policies, programmes and facilities and different activity intensities. This is important given the relative lack of research on secondary school students’ SED and LPA, compared to the abundance of research that focuses on MVPA [13].

Limitations should also be noted. Although the sample in SPEEDY 3 was representative of those included in the SPEEDY 1 sample within the current analyses, this overall sample represented 15 % of the original SPEEDY sample (n = 2064), which itself contained a higher proportion of girls, and a lower proportion of obese children than the Norfolk population [15]. In addition, the Norfolk population, and hence our sample, is largely white, potentially making these results less relevant to other populations. The analytical sample size may have led to Type 2 errors although our analytical approach was designed to take this into consideration. In relation to our exposure measures, as outlined in the section above, a limitation is the relatively narrow focus of the school environment measure.

Conclusions

To conclude, we observed differences in school policies, programmes and facilities for physical activity between primary and secondary schools in Norfolk, UK. However, the findings indicate that only two of the school-level variables assessed, total break duration and extra-curricular physical activity opportunities at lunchtime, are associated with adolescent MVPA and SED. These findings support the development of interventions to promote physical activity and reduce sedentary behaviour in adolescents that focus on school break duration and the provision of extra-curricular activities at lunchtime. Further research should explore other factors in the school environment, especially features of the social environment, in order to explain the school-level clustering observed and inform intervention development.

Ethics approval

University of East Anglia Faculty of Health Ethics Committee.

References

  1. Public Health England. Everybody Active, Every Day: An Evidence Based Approach to Physical Activity. London, England: Public Health England; 2014.

  2. Janssen I, Leblanc AG. Systematic review of the health benefits of physical activity and fitness in school-aged children and youth. Int J Behav Nutr Phys Act. 2010;7:40.

    Article  Google Scholar 

  3. Andersen LB, Harro M, Sardinha LB, Froberg K, Ekelund U, Brage S, Anderssen SA. Physical activity and clustered cardiovascular risk in children: a cross-sectional study (The European Youth Heart Study). Lancet (London, England). 2006;368:299–304.

    Article  Google Scholar 

  4. Marks J, Barnett LM, Strugnell C, Allender S. Changing from primary to secondary school highlights opportunities for school environment interventions aiming to increase physical activity and reduce sedentary behaviour: a longitudinal cohort study. Int J Behav Nutr Phys Act. 2015;12:59.

    Article  Google Scholar 

  5. Dumith SC, Gigante DP, Domingues MR, Kohl HW. Physical activity change during adolescence: a systematic review and a pooled analysis. Int J Epidemiol. 2011;40:685–98.

    Article  Google Scholar 

  6. Tremblay MS, LeBlanc AG, Kho ME, Saunders TJ, Larouche R, Colley RC, Goldfield G, Connor Gorber S. Systematic review of sedentary behaviour and health indicators in school-aged children and youth. Int J Behav Nutr Phys Act. 2011;8:98.

    Article  Google Scholar 

  7. Pearson N, Braithwaite RE, Biddle SJH, van Sluijs EMF, Atkin AJ. Associations between sedentary behaviour and physical activity in children and adolescents: a meta-analysis. Obes Rev. 2014;15:666–75.

    Article  CAS  Google Scholar 

  8. Nike. Designed to Move: Active Schools. 2015. Available at: http://e13c7a4144957cea5013-f2f5ab26d5e83af3ea377013dd602911.r77.cf5.rackcdn.com/resources/pdf/en/active-schools-full-report.pdf. Accessed 8 Jan 2016.

  9. HM Government. Healthy Lives, Healthy People: Our Strategy for Public Health in England. Norwich, UK: The Stationery Office; 2010.

  10. What works in schools and colleges to increase physical activity [https://www.gov.uk/government/publications/what-works-in-schools-to-increase-physical-activity-briefing]. Accessed 23 Feb 2016.

  11. Haug E, Torsheim T, Sallis JF, Samdal O. The characteristics of the outdoor school environment associated with physical activity. Health Educ Res. 2010;25:248–56.

    Article  Google Scholar 

  12. Cradock AL, Melly SJ, Allen JG, Morris JS, Gortmaker SL. Characteristics of school campuses and physical activity among youth. Am J Prev Med. 2007;33:106–13.

    Article  Google Scholar 

  13. Morton KL, Atkin AJ, Corder K, Suhrcke M, van Sluijs EMF. The school environment and adolescent physical activity and sedentary behaviour: a mixed-studies systematic review. Obes Rev. 2015;17:142–58.

    Article  Google Scholar 

  14. Harrison F, van Sluijs EMF, Corder K, Jones A. School grounds and physical activity: Associations at secondary schools, and over the transition from primary to secondary schools. Health Place. 2016;39:34–42.

    Article  Google Scholar 

  15. Van Sluijs EMF, Skidmore PML, Mwanza K, Jones AP, Callaghan AM, Ekelund U, Harrison F, Harvey I, Panter J, Wareham NJ, Cassidy A, Griffin SJ. Physical activity and dietary behaviour in a population-based sample of British 10-year old children: the SPEEDY study (Sport, Physical activity and Eating behaviour: environmental Determinants in Young people). BMC Public Health. 2008;8:388.

    Article  Google Scholar 

  16. Leatherdale ST, Manske S, Faulkner G, Arbour K, Bredin C. A multi-level examination of school programs, policies and resources associated with physical activity among elementary school youth in the PLAY-ON study. Int J Behav Nutr Phys Act. 2010;7:6.

    Article  Google Scholar 

  17. Faulkner G, Zeglen L, Leatherdale S, Manske S, Stone M. The relationship between school physical activity policy and objectively measured physical activity of elementary school students: a multilevel model analysis. Arch public Heal. 2014;72:20.

    Article  Google Scholar 

  18. Van Sluijs EMF, Jones NR, Jones AP, Sharp SJ, Harrison F, Griffin SJ. School-level correlates of physical activity intensity in 10-year-old children. Int J Pediatr Obes. 2011;6:e574–81.

    Article  Google Scholar 

  19. De Meester F, Van Dyck D, De Bourdeaudhuij I, Deforche B, Cardon G. Changes in physical activity during the transition from primary to secondary school in Belgian children: what is the role of the school environment? BMC Public Health. 2014;14:261.

    Article  Google Scholar 

  20. Brooke HL, Atkin AJ, Corder K, Ekelund U, van Sluijs EMF. Changes in time-segment specific physical activity between ages 10 and 14 years: A longitudinal observational study. J Sci Med Sport. 2014.

  21. Corder K, Sharp SJ, Atkin AJ, Griffin SJ, Jones AP, Ekelund U, van Sluijs EMF. Change in objectively measured physical activity during the transition to adolescence. Br J Sports Med. 2015;49:730–6.

    Article  Google Scholar 

  22. Edwardson CL, Gorely T. Epoch length and its effect on physical activity intensity. Med Sci Sports Exerc. 2010;42:928–34.

    Article  Google Scholar 

  23. Ekelund U, Aman J, Westerterp K. Is the ArteACC index a valid indicator of free-living physical activity in adolescents? Obes Res. 2003;11:793–801.

    Article  Google Scholar 

  24. Ekelund U, Sjöström M, Yngve A, Poortvliet E, Nilsson A, Froberg K, Wedderkopp N, Westerterp K. Physical activity assessed by activity monitor and doubly labeled water in children. Med Sci Sports Exerc. 2001;33:275–81.

    Article  CAS  Google Scholar 

  25. Mattocks C, Ness A, Leary S, Tilling K, Blair SN, Shield J, Kirkby J, Smith GD, Wells J, Wareham N, Reilly J, Riddoch C. Use of accelerometers in a large field-based study of children: protocols, design issues, and effects on precision. J Phys Act Health. 2008;5 Suppl 1:S98–111.

  26. Riddoch CJ, Bo Andersen L, Wedderkopp N, Harro M, Klasson-Heggebø L, Sardinha LB, Cooper AR, Ekelund U. Physical activity levels and patterns of 9- and 15-yr-old European children. Med Sci Sports Exerc. 2004;36:86–92.

    Article  Google Scholar 

  27. Ridgers ND, Salmon J, Ridley K, O’Connell E, Arundell L, Timperio A. Agreement between activPAL and ActiGraph for assessing children’s sedentary time. Int J Behav Nutr Phys Act. 2012;9:15.

    Article  Google Scholar 

  28. Corder K, van Sluijs EMF, Ekelund U, Jones AP, Griffin SJ. Changes in Children’s Physical Activity Over 12 Months: Longitudinal Results From the SPEEDY Study. Pediatrics. 2010;126:e926–35.

    Article  Google Scholar 

  29.  Atkin AJ, Corder K, van Sluijs EMF. Bedroom media, sedentary time and screen-time in children: a longitudinal analysis. Int J Behav Nutr Phys Act. 2013;10:137.

  30. Hobin EP, Leatherdale ST, Manske S, Dubin JA, Elliott S, Veugelers P. A multilevel examination of gender differences in the association between features of the school environment and physical activity among a sample of grades 9 to 12 students in Ontario, Canada. BMC Public Health. 2012;12:74

  31. Jones NR, Jones A, van Sluijs EMF, Panter J, Harrison F, Griffin SJ. School environments and physical activity: The development and testing of an audit tool. Health Place. 2010;16:776–83.

  32. Mantjes JA, Jones AP, Corder K, Jones NR, Harrison F, Griffin SJ, van Sluijs EM. School related factors and 1 yr change in physical activity amongst 9–11 year old English schoolchildren. Int J Behav Nutr Phys Act. 2012;9:153.

  33. The Nuffield Foundation. The social and educational significance of school break times: seminar briefing paper. Available at: http://www.nuffieldfoundation.org/sites/default/files/BRIEFING_PAPER003.pdf. Accessed 18 Jan 2016.

  34. Blatchford P, Baines E. A follow up national survey of break times in primary and secondary schools. London, UK: Nuffield Foundation; 2006.

  35. Corder K, Atkin AJ, Bamber DJ, Brage S, Dunn VJ, Ekelund U, Owens M, van Sluijs EMF, Goodyer IM. Revising on the run or studying on the sofa: prospective associations between physical activity, sedentary behaviour, and exam results in British adolescents. Int J Behav Nutr Phys Act. 2015;12:106.

  36. Singh A, Uijtdewilligen L, Twisk JWR, van Mechelen W, Chinapaw MJM. Physical activity and performance at school: a systematic review of the literature including a methodological quality assessment. Arch Pediatr Adolesc Med. 2012;166:49–55.

  37. Powell E, Woodfield LA, Nevill AA. Children’s physical activity levels during primary school break times: A quantitative and qualitative research design. Eur Phys Educ Rev. 2016;22(1):82-98.

  38. Morton KL. Recommendations for Creating Active School Environments: An Exploration of UK-Based Grey Literature. 2015. Available at: http://www.cedar.iph.cam.ac.uk/wp-content/uploads/2014/10/CASE_UK-grey-literature-report.pdf. Accessed 18 Dec 2016.

  39. Ridgers ND, Timperio A, Cerin E, Salmon J. Compensation of physical activity and sedentary time in primary school children. Med Sci Sports Exerc. 2014;46:1564–9.

Download references

Acknowledgements

The authors thank the schools, children and parents for their participation in the SPEEDY study. The authors would also like to thank everyone who helped with the data collection and Norfolk Children’s Services for their invaluable input and support. In addition, the authors would like to thank Annie Schiff and Jo Worley for help with follow-up data collection and Rebekah Steele for preparing the baseline physical activity data for these analyses. The authors also would like to thank Kate Westgate and Stefanie Mayle from the physical activity technical team at the MRC Epidemiology Unit for their assistance in processing the accelerometer data.

Funding

This report is independent research commissioned and funded by the Department of Health Policy Research Programme (Opportunities within the school environment to shift the distribution of activity intensity in adolescents, PR-R5-0213-25001). The views expressed in this publication are those of the author(s) and not necessarily those of the department of health. The SPEEDY study is funded by the National Prevention Research Initiative (http://www.npri.org.uk), consisting of the following Funding Partners: British Heart Foundation; Cancer Research UK; Department of Health; Diabetes UK; Economic and Social Research Council; Medical Research Council; Health and Social Care Research and Development Office for the Northern Ireland; Chief Scientist Office, Scottish Government Health Directorates; Welsh Assembly Government and World Cancer Research Fund. This work was also supported by the Medical Research Council (Unit Programme numbers MC_UU_12015/7, MC_UU_12015/4, and MC_UU_12015/3) and the Centre for Diet and Activity Research (CEDAR), a UKCRC Public Health Research Centre of Excellence. Funding from the British Heart Foundation, Economic and Social Research Council, Medical Research Council, the National Institute for Health Research, and the Wellcome Trust, under the auspices of the UK Clinical Research Collaboration, is gratefully acknowledged.

Author information

Authors and Affiliations

  1. UKCRC Centre for Diet and Activity Research (CEDAR), MRC Epidemiology Unit, University of Cambridge School of Clinical Medicine, Box 285 Institute of Metabolic Science, Cambridge Biomedical Campus, Cambridge, CB20QQ, UK

    Katie L. Morton, Kirsten Corder, Esther M. F. van Sluijs & Andrew J. Atkin

  2. Centre for Health Economics, University of York, York, UK

    Marc Suhrcke

  3. UKCRC Centre for Diet and Activity Research (CEDAR) and Norwich Medical School, University of East Anglia, Norwich, UK

    Flo Harrison & Andy P. Jones

Authors
  1. Katie L. Morton
    View author publications

    You can also search for this author in PubMed Google Scholar

  2. Kirsten Corder
    View author publications

    You can also search for this author in PubMed Google Scholar

  3. Marc Suhrcke
    View author publications

    You can also search for this author in PubMed Google Scholar

  4. Flo Harrison
    View author publications

    You can also search for this author in PubMed Google Scholar

  5. Andy P. Jones
    View author publications

    You can also search for this author in PubMed Google Scholar

  6. Esther M. F. van Sluijs
    View author publications

    You can also search for this author in PubMed Google Scholar

  7. Andrew J. Atkin
    View author publications

    You can also search for this author in PubMed Google Scholar

Corresponding author

Correspondence to Katie L. Morton.

Additional information

Competing interests

The authors declare that they have no competing interest.

Author contributions

All authors contributed to the analysis plans for this manuscript, critically reviewed and approved the final manuscript. KM, AA and EvS conceptualised the research questions. KM and AA conducted the analyses, interpreted the data and drafted the manuscript. EvS, KC and AJ were involved with the conceptualization, design and data collection of the overall SPEEDY study.

Additional files

Additional file 1: Table S1.

Simple models; Cross-sectional association of school policies, programmes and facilities and adolescent activity intensity during lunchtime. (DOC 41 kb)

Additional file 2: Table S2.

Simple models; Cross-sectional association of school policies, programmes and facilities and adolescent activity intensity during the school day. (DOC 42 kb)

Additional file 3: Table S3.

Simple models; Association of changes in the school environment with changes in activity intensity during the whole school day. (DOC 45 kb)

Additional file 4: Table S4.

Simple models; Association of changes in the school environment with changes in activity intensity during lunchtime. (DOC 44 kb)

Rights and permissions

Open Access This article is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The Creative Commons Public Domain Dedication waiver (http://creativecommons.org/publicdomain/zero/1.0/) applies to the data made available in this article, unless otherwise stated.

Reprints and permissions

About this article

Check for updates. Verify currency and authenticity via CrossMark

Cite this article

Morton, K.L., Corder, K., Suhrcke, M. et al. School polices, programmes and facilities, and objectively measured sedentary time, LPA and MVPA: associations in secondary school and over the transition from primary to secondary school. Int J Behav Nutr Phys Act 13, 54 (2016). https://0-doi-org.brum.beds.ac.uk/10.1186/s12966-016-0378-6

Download citation

  • Received:

  • Accepted:

  • Published:

  • DOI: https://0-doi-org.brum.beds.ac.uk/10.1186/s12966-016-0378-6

Keywords

International Journal of Behavioral Nutrition and Physical Activity

ISSN: 1479-5868

Contact us