The physical activity profile of active children in England

  • Sarah Payne1Email author,

    Affiliated with

    • Nick Townsend2 and

      Affiliated with

      • Charlie Foster2

        Affiliated with

        International Journal of Behavioral Nutrition and Physical Activity201310:136

        DOI: 10.1186/1479-5868-10-136

        Received: 24 June 2013

        Accepted: 12 November 2013

        Published: 16 December 2013

        Abstract

        Background

        In line with WHO guidelines, the UK government currently recommends that school-aged children participate in at least 60 minutes, and up to several hours, of at least moderate physical activity on a daily basis. A recent health survey indicates that the amount of reported physical activity varies by age, gender and socioeconomic status. The objective of this study is to identify what types of activity contribute most towards overall physical activity in children who achieve the UK physical activity recommendations; and how this varies according to age, gender and socioeconomic status.

        Methods

        Self-reported physical activity was captured through the Health Survey for England 2008, a nationally representative, cross-sectional survey. We analysed data from 1,110 children aged 5–15 years who reported meeting the UK physical activity recommendations. The proportions of total physical activity achieved in various domains of activity were calculated and associations with age, gender and socioeconomic status were examined.

        Results

        Active play was the largest contributor to overall physical activity (boys = 48%, girls = 53%), followed by walking (boys = 17%, girls = 23%). Active school travel contributed only a small proportion (6% for boys and girls). With increasing age, the contribution from active play decreased (rho = -0.417; p < 0.001) and the contribution of walking (rho = 0.257; p < 0.001) and formal sport (rho = 0.219; p < 0.001) increased. At all ages, sport contributed more among boys than girls. Sport contributed proportionately less with increasing deprivation (rho = -0.191; p < 0.001).

        Conclusions

        The contributors to overall physical activity among active children varies with age, socioeconomic status and gender. This knowledge can be used to target interventions appropriately to increase physical activity in children at a population level.

        Keywords

        ‘Physical activity’ England Children ‘Active play’ Walking Sport Contributors ‘Socioeconomic status’

        Background

        Regular physical activity is associated with a range of health benefits for children including beneficial effects on musculoskeletal health and adiposity [1, 2]; mental health and cardiovascular disease risk factors such as hypertension and high levels of high-density lipoprotein cholesterol (HDL-C) [2]. Participation in regular physical activity in childhood and adolescence has also been reported to positively influence physical activity levels in adulthood [3, 4].

        The UK government currently recommends that school-aged children participate in at least 60 minutes, and up to several hours, of at least moderate physical activity on a daily basis [5]. This recommendation is based on the current evidence and is similar to other national physical activity recommendations [2, 6, 7]. The 2008 Health Survey for England (HSE) reported that only 32% of all boys and 24% of all girls aged 2–15 years in England meet this recommendation [8]. This survey also identified differences in the amount of reported physical activity by age, particularly in girls, and by socioeconomic status. Differences in physical activity in children by age and gender have also been reported elsewhere in the literature [911], however the evidence of association with socioeconomic status is not clear [12, 13].

        There are various domains of activity that contribute to children’s overall physical activity levels including: active travel; organised or structured sport; informal play; domestic and leisure activities. The promotion of physical activity in both adults and children has been an important policy agenda in recent years. Current policies and strategies to increase physical activity in children promote a multi-component approach, across a variety of interventions in different settings [1417]. A better understanding of the types of activity most commonly undertaken by active children could help target interventions toward specific groups of children, to have the most impact on increasing physical activity at a population level.

        This study aims to identify what types of activity contribute most to the overall physical activity levels in children who reported achieving the UK recommendations; and how this varies according to age, gender and socioeconomic status.

        Methods

        This study uses data from the 2008 Health Survey for England, a nationally representative, private-household based, cross-sectional survey of children and adults in England. The 2008 HSE included specific questions on physical activity in addition to the general health questions included in other years. The children’s physical activity questionnaire was validated in 2007 and found to have “moderate external validity for measuring the time spent in moderate or vigorous physical activity” [18].

        A multi-stage, stratified, random, core sample of 16,056 addresses and a boost sample of 19,404 addresses were selected. Each individual within a selected household was eligible for inclusion. Where there were more than two children in a household, two were randomly selected for inclusion. Interviews were carried out in 64% of households in the general population sample and 73% of households in the boost sample yielding 3,473 children aged 0–15 years and 4,048 children aged 2–15 years respectively giving a total sample of 7,521 children.

        Children aged 13–15 years were interviewed directly, whereas the parents of children aged 0–12 years were asked about their children, with the children present wherever possible. Children were asked to recall their physical activity for each day over the seven days prior to the interview day; excluding physical activity during school curriculum time. Intensity of physical activity was not measured and has not been used in this analysis.

        Data on demographic and social factors were also collected including age, sex and socioeconomic status (measured by Index of Multiple Deprivation 2007 (IMD) quintile). The IMD is a composite score of seven domains: Income deprivation; Employment deprivation; Health deprivation and disability; Education, skills and training; Barriers to housing and services; Crime; The living environment, which are weighted and combined together to create the overall IMD. More detail on the HSE survey methodology can be found elsewhere [19].

        In our analysis we included children aged 5–15 years (1,934 children aged <5 years were excluded). We excluded children who had not attended school on at least one day in the past seven days (n = 952) and children whose self-reported activity per day was less than zero minutes in any category of physical activity (n = 21).

        Summary physical activity variables were derived from the data and activities were grouped into six categories based on those used in the HSE questionnaire: domestic activity (e.g. gardening & housework); active travel (walking or cycling to/from school only); walking (excluding to/from school); cycling (excluding to/from school); active play (e.g. skipping, general play, hopscotch, dancing); sport (including team sports such as rugby or hockey; individual sports; or structured activities such as swimming, gymnastics, yoga or horse riding).

        Statistical analyses

        We calculated the mean minutes per week, across all children, for each category of physical activity and the percentage of mean total minutes of physical activity accounted for by each category. Data were weighted for child selection within each household using HSE weights [19] and analysed using STATA 11 [20]. Descriptive analysis investigated the contribution of each category of physical activity to total physical activity, stratified by demographic and socioeconomic factors. Associations between these factors and reported physical activity were tested using one-way ANOVA and trends were tested using Spearman’s Rank test.

        Children were considered to have achieved the recommended level of physical activity if they reported at least 60 minutes of physical activity a day on all seven days of the week; in line with the 2011 UK Government recommendations.

        Results

        After exclusions, 4,614 children remained in our sample for analysis, of which 24% (1,110) met the recommendation of 60 minutes or more of physical activity per day (19% of girls and 29% of boys). Active play contributed the most to total physical activity (50%), followed by walking (19%). A large proportion of children (58%) did sufficient active play to achieve their total weekly recommendation of physical activity through this activity alone; 18% achieved it through walking alone, whereas only 11% achieved it through sport alone.

        Gender

        Stratified by gender, active play contributed 48% among boys; the next largest contributor was walking (17%) followed closely by sport and cycling (16% and 12% respectively). Active travel contributed only 6% and domestic activities such as housework and gardening contributed minimally (Table 1).
        Table 1

        Contribution of categories of physical activity among girls and boys by age and socioeconomic status (mean minutes per week; and mean percentage contribution to total weekly physical activity)

          

        All physical activity

        Sport

        Active travel

        Active play

        Walking

        Cycling

        Domestic activity

          

        Mins

        Mins

        %

        Mins

        %

        Mins

        %

        Mins

        %

        Mins

        %

        Mins

        %

        Boys (n)

        All (668)

        1,229

        201

        16

        71

        6

        574

        48

        225

        17

        144

        12

        13

        1

        Age group (n)

        5-6 yrs (123)

        1,035

        85

        8

        54

        6

        665

        63

        141

        13

        85

        9

        6

        1

         

        7-8 yrs (118)

        1,083

        147

        15

        66

        6

        597

        55

        134

        12

        131

        12

        9

        1

         

        9-10 yrs (131)

        1,201

        204

        15

        52

        5

        605

        52

        155

        12

        172

        15

        13

        1

         

        11-12 yrs (118)

        1,204

        204

        19

        91

        7

        543

        44

        203

        18

        147

        12

        16

        1

         

        13-15 yrs (178)

        1,498

        313

        20

        88

        6

        495

        34

        408

        27

        173

        11

        20

        1

        Girls (n)

        All (442)

        1,121

        118

        10

        66

        6

        599

        53

        249

        23

        68

        5

        21

        2

        Age group (n)

        5-6 yrs (97)

        1,079

        40

        4

        70

        7

        732

        67

        149

        15

        80

        7

        8

        1

         

        7-8 yrs (93)

        1,083

        86

        9

        62

        6

        745

        67

        125

        13

        46

        4

        18

        2

         

        9-10 yrs (93)

        1,086

        118

        10

        43

        5

        594

        54

        226

        23

        93

        7

        13

        1

         

        11-12 yrs (74)

        1,117

        129

        12

        81

        8

        474

        43

        314

        28

        88

        7

        31

        2

         

        13-15 yrs (85)

        1,255

        231

        16

        79

        7

        403

        32

        468

        38

        35

        3

        39

        4

        Boys (n)

        All (668)

        1,229

        201

        16

        71

        6

        574

        48

        225

        17

        144

        12

        13

        1

        IMD quintile (n)

        Least deprived (118)

        1,059

        212

        20

        59

        6

        457

        44

        217

        20

        103

        9

        11

        1

         

        Q2 (109)

        1,269

        314

        22

        67

        6

        524

        44

        210

        16

        139

        11

        15

        1

         

        Q3 (136)

        1,211

        153

        13

        87

        7

        589

        50

        225

        18

        148

        12

        9

        1

         

        Q4 (139)

        1,222

        178

        14

        68

        5

        601

        52

        187

        14

        170

        13

        18

        1

         

        Most deprived (166)

        1,345

        178

        12

        73

        5

        656

        51

        271

        18

        152

        13

        14

        1

        Girls (n)

        All (442)

        1,121

        118

        10

        66

        6

        599

        53

        249

        23

        68

        5

        21

        2

        IMD quintile (n)

        Least deprived (82)

        991

        141

        14

        56

        6

        496

        50

        207

        22

        72

        6

        18

        2

         

        Q2 (75)

        968

        123

        13

        60

        6

        552

        55

        159

        18

        57

        6

        19

        2

         

        Q3 (82)

        1,064

        123

        9

        58

        6

        543

        53

        248

        23

        80

        7

        14

        2

         

        Q4 (86)

        1,150

        90

        8

        65

        6

        620

        56

        269

        24

        90

        6

        15

        1

         

        Most deprived (117)

        1,331

        116

        8

        84

        7

        727

        54

        323

        26

        49

        3

        33

        3

        Among girls there was a slightly different pattern. Active play contributed slightly more than in boys (53%); as did walking (23%), with smaller contributions coming from sport (10%) and cycling (5%). Similarly with boys, active travel contributed 6% and domestic activities contributed a minimal amount.

        Age

        The main changes in the contributors to overall physical activity with increasing age were a decrease in the proportion contributed from active play (rho = -0.417; p < 0.001) and a corresponding increase in both walking (rho = 0.257; p < 0.001) and sport (rho = 0.219; p < 0.001) (Figure 1; Table 2). Analysis by minutes of activity per week was consistent with these findings (Figure 2). There was a small significant association between age and the proportion of all physical activity achieved through active travel (F = 3.26; p = 0.011) but no significant trend. Though domestic activity contributed a very small proportion to overall physical activity, there was a small but significant increase in this with age (rho = 0.096; p = 0.001).
        http://static-content.springer.com/image/art%3A10.1186%2F1479-5868-10-136/MediaObjects/12966_2013_Article_826_Fig1_HTML.jpg
        Figure 1

        Mean percentage of all physical activity contributed by each category of activity, by age group and gender in England in 2008.

        Table 2

        Associations of the contributions of activity categories to total activity with age-group, or socioeconomic status

         

        ANOVA (F)*

        ANOVA (p-value)

        Spearman’s (rho)

        Spearman’s (p-value)

        Total minutes of physical activity by age-group (all, n = 1,110)

        9.4

        <0.001

        0.176

        <0.001

        Total minutes of physical activity by age-group (boys, n = 668)

        8.81

        <0.001

        0.253

        <0.001

        Total minutes of physical activity by age-group (girls, n = 442)

        0.95

        0.433

        0.035

        0.461

        Contribution by age-group, % (all)

            

          Sport†

        18.24

        <0.001

        0.219

        <0.001

          Active travel

        3.26

        0.011

        0.040

        0.180

          Active Play†

        59.75

        <0.001

        -0.417

        <0.001

          Walking†

        31.5

        <0.001

        0.257

        <0.001

          Cycling

        1.83

        0.121

        0.005

        0.871

          Domestic activity†

        2.45

        0.045

        0.096

        0.001

        Contribution by age-group, % (boys)

            

          Sport†

        9.11

        <0.001

        0.206

        <0.001

          Active travel

        1.36

        0.248

        0.043

        0.271

          Active Play†

        29.17

        <0.001

        -0.385

        <0.001

          Walking†

        17.19

        <0.001

        0.228

        <0.001

          Cycling

        1.78

        0.132

        0.026

        0.508

          Domestic activity

        0.91

        0.456

        0.079

        0.041

        Contribution by age-group, % (girls)

            

          Sport†

        8.33

        <0.001

        0.195

        <0.001

          Active travel

        2.12

        0.077

        0.032

        0.504

          Active Play†

        31.41

        <0.001

        -0.448

        <0.001

          Walking†

        20.61

        <0.001

        0.348

        <0.001

          Cycling

        2.82

        0.025

        -0.082

        0.084

          Domestic activity†

        2.67

        0.032

        0.134

        0.005

        Contributions in minutes by age-group (all)

            

          Sport†

        19.51

        <0.001

        0.251

        <0.001

          Active travel†

        6.79

        <0.001

        0.089

        0.003

          Active Play†

        9.55

        <0.001

        -0.234

        <0.001

          Walking†

        37.74

        <0.001

        0.291

        <0.001

          Cycling

        2.5

        0.041

        0.025

        0.416

          Domestic activity†

        3.46

        0.008

        0.101

        <0.001

        Contributions in minutes by age-group (boys)

            

          Sport†

        10.17

        <0.001

        0.262

        <0.001

          Active travel†

        4.61

        0.001

        0.117

        0.002

          Active Play†

        2.91

        0.021

        -0.168

        <0.001

          Walking†

        21.46

        <0.001

        0.269

        <0.001

          Cycling

        2.84

        0.024

        0.060

        0.121

          Domestic activity

        1.23

        0.295

        0.086

        0.027

        Contributions in minutes by age-group (girls)

            

          Sport†

        8.9

        <0.001

        0.196

        <0.001

          Active travel

        2.66

        0.032

        0.039

        0.408

          Active Play†

        8.14

        <0.001

        -0.329

        <0.001

          Walking†

        22.13

        <0.001

        0.355

        <0.001

          Cycling

        1.8

        0.128

        -0.081

        0.090

          Domestic activity†

        3.08

        0.016

        0.136

        0.004

        Contribution by IMD, % (all)

            

          Sport†

        10.36

        <0.001

        -0.191

        <0.001

          Active travel

        0.96

        0.427

        0.036

        0.236

          Active Play

        2.22

        0.650

        0.077

        0.010

          Walking

        1.6

        0.173

        -0.017

        0.575

          Cycling

        0.75

        0.560

        -0.066

        0.029

          Domestic activity

        0.67

        0.611

        -0.011

        0.708

        Contribution by IMD, % (boys)

            

          Sport†

        7.41

        <0.001

        -0.195

        <0.001

          Active travel

        1.3

        0.267

        0.011

        0.777

          Active Play†

        2.79

        0.026

        0.102

        0.009

          Walking

        1.72

        0.145

        -0.074

        0.057

          Cycling

        1.14

        0.334

        -0.019

        0.632

          Domestic activity

        0.62

        0.652

        -0.049

        0.205

        Contribution by IMD, % (girls)

            

          Sport†

        3.77

        0.005

        -0.193

        <0.001

          Active travel

        0.57

        0.684

        0.068

        0.155

          Active Play

        0.43

        0.789

        0.038

        0.426

          Walking

        1.44

        0.219

        0.066

        0.168

          Cycling

        1.38

        0.241

        -0.129

        0.007

          Domestic activity

        0.92

        0.455

        0.038

        0.428

        Contributions in minutes by IMD (all)†

        5.38

        <0.001

        0.132

        <0.001

        †Significant at p < 0.05 for both ANOVA and spearman's.

        *Degrees of freedom for all ANOVA tests is 4.

        http://static-content.springer.com/image/art%3A10.1186%2F1479-5868-10-136/MediaObjects/12966_2013_Article_826_Fig2_HTML.jpg
        Figure 2

        Mean minutes of all physical activity and contributions by each category of activity- by age group and gender in England in 2008.

        The changes with age were similar in both boys and girls, though the increase in the proportion of all physical activity accounted for by walking was greater among girls. Among boys, the overall increase in total minutes of physical activity with age included an increase in active travel (rho = 0.117; p = 0.002) in addition to walking (rho = 0.269; p < 0.001) and sport (rho = 0.262; p < 0.001). Among girls, though there was no increase in minutes of physical activity with increasing age, mean minutes of walking and sport both increased with age (rho = 0.355 and rho = 0.196; p < 0.001) and mean minutes of active play decreased (rho = -0.329; p < 0.001) (Figure 2; Table 2).

        SES

        Sport contributed proportionately less with increasing deprivation (rho = -0.191; p < 0.001) and active play contributed more (rho = 0.077; p = 0.01). Stratified by gender, this trend in contribution of sport remained significant for both boys (rho = -0.195) and girls (rho = -0.193) (p < 0.001 for both) but the increase in active play with increasing deprivation only remained significant for boys (rho = 0.102; p = 0.009).

        Discussion

        Overall, this study found significant differences by age, gender and socioeconomic status in the contributors to physical activity among those children who reported doing the recommended amount of physical activity per week. Walking and active play were the biggest contributors to overall physical activity; sport and active school travel contributed a comparatively small proportion each.

        Active play was the largest contributor to overall physical activity in younger children but with increasing age walking took over. Such changes with age in the type of activity undertaken by children are not unexpected given their changing maturity across the age range 5–15 years and their increasing independence, particularly given that some of the time spent walking may be for active travel purposes (excluding to/from school). The contribution from sport increased with age for both boys and girls, contributing the most among older boys. A similar pattern of a substantial contribution from walking and a comparatively small contribution to overall physical activity from sport has also been reported in adults in England [21] indicating that this pattern continues into adulthood.

        The main differences between the activity profile of girls and boy were the contributions from sport and cycling, which made a smaller contribution among girls than boys (15% combined among girls compared to 28% among boys); and walking and active play which contributed a larger proportion among girls (76% combined compared to 65%). At all ages, sport contributed a larger proportion to physical activity among boys than among girls.

        The substantial contributions of walking and active play highlight the important role that informal exercise plays in childrens’ physical activity. This emphasis on informal play activity is also supported by qualitative research which highlights that among young children fun, social interaction and variety, without the element of competition are factors which encourage participation in physical activity [22].

        Few other studies have looked at the role of informal play, active travel and domestic activity in addition to structured sport and exercise, in the total physical activity of children and yet this study shows that play in particular is an important contributor. This study is also unique in looking specifically at the contributors to physical activity among active children rather than the population as a whole. Limiting the study sample to only active children allows a clearer view of the types of activity that contribute a substantial amount to overall time spent physically active and provides an indication of what types of activity children do when they are achieving the recommended levels of physical activity.

        Differences in the activity profile of boys and girls, particularly the role played by sport, may reflect gender differences in motivations for physical activity. Several studies have found that males are more motivated by competition than females [23, 24]. Vilhjalmsson and Kristjansdottir [25] concluded, in a study of the gender differences in activity among Icelandic schoolchildren, that the difference in overall physical activity between boys and girls was entirely attributable to lower participation in sport among girls. Our study indicates that although the proportion of all activity achieved through sport does differ between boys and girls, other domains of activity such as cycling also contribute to the gender difference in overall physical activity.

        Several UK studies have concluded that active school travel does not make a substantial contribution to overall daily physical activity [2628]; although there is evidence to suggest that active school travel is associated with increased overall physical activity [26, 27, 29], supporting the ‘activity synergy’ hypothesis. The indication from our analysis, that active school travel contributes only a small amount to total physical activity even among active children, further supports these findings. The categorisation of activity data into ‘walking’, ‘cycling’ or ‘active travel to/from school’ does not allow for analysis of the overall contribution of active travel to total physical activity. However, one recent study has shown that non-school active travel is only a small contributor to overall daily moderate to vigorous physical activity in a group of British 8–13 year olds [27].

        Our finding that sport contributes less to total physical activity in more deprived children; and that they report less time undertaking sport despite higher overall levels of physical activity, concurs with an Australian study investigating socio-economic position and sports participation which found that adolescents from lower income backgrounds participated in less sport compared with those from wealthier backgrounds [30].

        Study strengths and limitations

        Strengths of this study include the use of a large, nationally representative sample. The overall response rate to the HSE (64% of the core and 73% of the boost sample) reduces the likelihood of non-response bias.

        Self-reported physical activity can be subject to recall and social desirability bias. However, it remains one of the most practical ways to assess physical activity in a large population survey. The physical activity questionnaire used in the HSE was validated and found to have “moderate validity” for measuring the volume of activity when tested against accelerometry data [18]. Self-reporting is a useful tool for determining the types of activity undertaken therefore this questionnaire is a pragmatic method for measuring the contributors to physical activity in this study. Recall bias, if consistent across respondents and for different categories of activity, is unlikely to affect the comparative analysis by age, gender and socioeconomic status or the relative contributions of categories of physical activity.

        A limitation of this study is that curriculum-time school-based physical activity was not captured, based on the assumption that curriculum time physical activity is prescriptive and would vary little across the survey population. This is likely to have led to a small underestimate of total minutes of physical activity. Moreover, intensity of physical activity was not captured on the assumption that all children’s physical activity is at least of moderate intensity. This may have led to an overestimate of total time spent doing ‘at least moderate activity’. Different categories of activity may be more or less at risk of this intensity misclassification than others, introducing bias to our results which cannot be accounted for. However, a recent study of physical activity in British children found that the proportion of physical activity time that was spent at moderate to vigorous intensity when engaged in structured sport, out of home play and non-school active travel (which would include both walking and cycling) was similar [27].

        This study adds evidence of the differences in the activities that contribute to total physical activity levels, by age, gender and deprivation. It confirms the importance of informal physical activity for boys and girls of all ages, and highlights the gender differences in adoption of activities such as cycling and sport, even among those children considered active. There is a growing body of qualitative evidence on the barriers and facilitators to physical activity in children that supports the need to target interventions by factors such as age and gender [22, 31].

        The literature also highlights the important role of environmental facilities for physical activity such as traffic safety; perception of the local environment; and the culture of car use, in influencing physical activity in children [22, 3133]. Knowledge of the types of activities most commonly adopted among children who are active can be used alongside the body of evidence on barriers, motivators and effectiveness of interventions, to help target interventions appropriately and influence the success of strategies to increase physical activity in children at a population level.

        Conclusions

        This study provides a greater understanding of the physical activity profile of children who meet the UK physical activity recommendations. This knowledge could help guide future policy decisions to increase physical activity in children and inform effective strategies to increase the proportion of children meeting the physical activity recommendations. In developing interventions, consideration should be given to age, socioeconomic status and gender-related differences in the types of physical activity most likely to be adopted by children. Future research based on objective measures of physical activity behaviours, in combination with qualitative research on the motivations and barriers to specific types of activity will enable a better understanding of what drives physical activity in children.

        Declarations

        Authors’ Affiliations

        (1)
        Department of Public Health, University of Oxford
        (2)
        British Heart Foundation Health Promotion Research Group, Department of Public Health, University of Oxford

        References

        1. 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: 40-10.1186/1479-5868-7-40.View Article
        2. Strong WB, Malina RM, Blimkie CJR, Daniels SR, Dishman RK, Gutin B, et al: Evidence based physical activity for school-age youth. J Pediatr. 2005, 146: 732-737. 10.1016/j.jpeds.2005.01.055.View Article
        3. Telama R, Yang X, Viikari J, Välimäki I, Wanne O, Raitakari O: Physical activity from childhood to adulthood: a 21-year tracking study. Am J Prev Med. 2005, 28: 267-273. 10.1016/j.amepre.2004.12.003.View Article
        4. Tammelin T, Näyhä S, Hills AP, Järvelin MR: Adolescent participation in sports and adult physical activity. Am J Prev Med. 2003, 24: 22-28. 10.1016/S0749-3797(02)00575-5.View Article
        5. Chief Medical Officers of England, Scotland, Wales, and Northern Ireland: Start Active, Stay Active: A Report on Physical Activity for Health from the Four Home Countries’ Chief Medical Officers. 2011, London: Department of Health
        6. Janssen IJI: Physical activity guidelines for children and youth. Can J Public Health. 2007, 98 (Suppl 2): 109-121.
        7. World Health Organization: Global recommendations on physical activity for health. 2010, Geneva: World Health Organization, 8-10.
        8. Craig R, Mindell J, Hirani V: Health survey for England 2008: Volume 1, physical activity and fitness. 2009, Leeds: The NHS Information Centre for health and social care
        9. Crespo NC, Corder K, Marshall S, Norman G, Patrick K, Sallis JF, et al: An Examination of Multilevel Factors that May Explain Gender Differences in Children's Physical Activity. J Phys Act Health. in press
        10. Simen-Kapeu A, Veugelers PJ: Should public health interventions aimed at reducing childhood overweight and obesity be gender-focused?. BMC Public Health. 2010, 10: 340-10.1186/1471-2458-10-340.View Article
        11. Thompson AM, Baxter-Jones ADG, Mirwald RL, Bailey DA: Comparison of physical activity in male and female children: does maturation matter?. Med Sci Sports Exerc. 2003, 35: 1684-1690. 10.1249/01.MSS.0000089244.44914.1F.View Article
        12. Riddoch CJ, Mattocks C, Deere K, Saunders J, Kirkby J, Tilling K, et al: Objective measurement of levels and patterns of physical activity. Arch Dis Child. 2007, 92: 963-969. 10.1136/adc.2006.112136.View Article
        13. Sallis JF, Prochaska JJ, Taylor WC: A review of correlates of physical activity of children and adolescents. Med Sci Sports Exerc. 2000, 32: 963-975.View Article
        14. National Institute for Health and Clinical Excellence: Walking and cycling: local measures to promote walking and cycling as forms of travel or recreation public health guidance 41. 2012, NICE
        15. National Institute for Health and Clinical Excellence: Promoting physical activity, active play and sport for pre-school and school-age children and young people in family, pre-school, school and community settings public health guidance 17. 2009, NICE
        16. Department of Health: Be Active, Be Healthy: A Plan for Getting the Nation Moving. 2009, DH
        17. Kriemler S, Meyer U, Martin E, Van Sluijs E, Andersen L, Martin B: Effect of school-based interventions on physical activity and fitness in children and adolescents: a review of reviews and systematic update. Br J Sports Med. 2011, 45: 923-930. 10.1136/bjsports-2011-090186.View Article
        18. Joint Health Surveys Unit: Health Survey for England physical activity validation study: substantive report. Joint Health Surveys Unit. 2007, (as referenced in Craig R, Mindell J, Hirani V: Health survey for England 2008: Volume 2, Methods and documentation. 2009)
        19. Craig R, Mindell J, Hirani V: Health survey for England 2008: Volume 2, Methods and documentation. 2009, Leeds: The NHS Information Centre for health and social care
        20. Statacorp: Stata Statistical Software: Release 11. 2009, College Station, TX: StataCorp LP
        21. Bélanger M, Townsend N, Foster C: Age-related differences in physical activity profiles of English adults. Prev Med. 2011, 52: 247-249.
        22. Allender S, Cowburn G, Foster C: Understanding participation in sport and physical activity among children and adults: a review of qualitative studies. Health Educ Res. 2006, 21: 826-835. 10.1093/her/cyl063.View Article
        23. Gill DL: Gender differences in competitive orientation and sport participation. Int J Sport Psychol. 1998, 19: 145-159.
        24. Koivula N: Sport participation: Differences in motivation and actual participation due to gender typing. J Sport Behav. 1999, 13: 360-380.
        25. Vilhjalmsson R, Kristjansdottir G: Gender differences in physical activity in older children and adolescents: the central role of organized sport. Soc Sci Med. 2003, 56: 363-374. 10.1016/S0277-9536(02)00042-4.View Article
        26. Van Sluijs E, Fearne VA, Mattocks C, Riddoch C, Griffin SJ, Ness A: The contribution of active travel to children's physical activity levels: cross-sectional results from the ALSPAC study. Prev Med. 2009, 48: 519-10.1016/j.ypmed.2009.03.002.View Article
        27. Goodman A, Mackett RL, Paskins J: Activity compensation and activity synergy in British 8–13 year olds. Prev Med. 2011, 53: 293-298. 10.1016/j.ypmed.2011.07.019.View Article
        28. Metcalf B, Voss L, Jeffery A, Perkins J, Wilkin T: Physical activity cost of the school run: impact on schoolchildren of being driven to school (EarlyBird 22). BMJ. 2004, 329: 832-833. 10.1136/bmj.38169.688102.F71.View Article
        29. Roth MA, Millett CJ, Mindell JS: The contribution of active travel (walking and cycling) in children to overall physical activity levels: a national cross sectional study. Prev Med. 2011, 54: 134-139.View Article
        30. Maher CA, Olds TS: Minutes, MET minutes, and METs: unpacking socio-economic gradients in physical activity in adolescents. J Epidemiol Community Health. 2011, 65: 160-165. 10.1136/jech.2009.099796.View Article
        31. Lorenc T, Brunton G, Oliver S, Oliver K, Oakley A: Attitudes to walking and cycling among children, young people and parents: a systematic review. J Epidemiol Community Health. 2008, 62: 852-857. 10.1136/jech.2007.070250.View Article
        32. De Vet E, de Ridder D, de Wit J: Environmental correlates of physical activity and dietary behaviours among young people: a systematic review of reviews. Obes Rev. 2010, 12: e130-e142.View Article
        33. Veitch J, Bagley S, Ball K, Salmon J: Where do children usually play? A qualitative study of parents’ perceptions of influences on children's active free-play. Health Place. 2006, 12: 383-393. 10.1016/j.healthplace.2005.02.009.View Article

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        © Payne et al.; licensee BioMed Central Ltd. 2013

        This article is published under license to BioMed Central Ltd. This is an open access article distributed under the terms of the Creative Commons Attribution License (http://​creativecommons.​org/​licenses/​by/​2.​0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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