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The association between number and ages of children and the physical activity of mothers: Cross-sectional analyses from the Southampton Women’s Survey

  • Rachel F. Simpson ,

    Roles Conceptualization, Formal analysis, Methodology, Writing – original draft, Writing – review & editing

    rs2056@cam.ac.uk

    Affiliation MRC Epidemiology Unit, University of Cambridge School of Clinical Medicine, Cambridge, United Kingdom

  • Kathryn R. Hesketh,

    Roles Conceptualization, Formal analysis, Supervision, Writing – review & editing

    Affiliations MRC Epidemiology Unit, University of Cambridge School of Clinical Medicine, Cambridge, United Kingdom, UCL Great Ormond Street Institute of Child Health, London, United Kingdom

  • Sarah R. Crozier,

    Roles Data curation, Funding acquisition, Investigation, Project administration, Writing – review & editing

    Affiliations MRC Lifecourse Epidemiology Centre (University of Southampton), Southampton General Hospital, Southampton, United Kingdom, NIHR Applied Research Collaboration Wessex, Southampton, United Kingdom

  • Janis Baird,

    Roles Data curation, Funding acquisition, Investigation, Project administration, Writing – review & editing

    Affiliations MRC Lifecourse Epidemiology Centre (University of Southampton), Southampton General Hospital, Southampton, United Kingdom, NIHR Southampton Biomedical Research Centre, University of Southampton and University Hospital Southampton NHS Foundation Trust, Southampton, United Kingdom

  • Cyrus Cooper,

    Roles Data curation, Funding acquisition, Investigation, Project administration, Writing – review & editing

    Affiliations MRC Lifecourse Epidemiology Centre (University of Southampton), Southampton General Hospital, Southampton, United Kingdom, NIHR Southampton Biomedical Research Centre, University of Southampton and University Hospital Southampton NHS Foundation Trust, Southampton, United Kingdom

  • Keith M. Godfrey,

    Roles Data curation, Funding acquisition, Investigation, Project administration, Writing – review & editing

    Affiliations MRC Lifecourse Epidemiology Centre (University of Southampton), Southampton General Hospital, Southampton, United Kingdom, NIHR Southampton Biomedical Research Centre, University of Southampton and University Hospital Southampton NHS Foundation Trust, Southampton, United Kingdom

  • Nicholas C. Harvey,

    Roles Data curation, Funding acquisition, Investigation, Project administration, Writing – review & editing

    Affiliations MRC Lifecourse Epidemiology Centre (University of Southampton), Southampton General Hospital, Southampton, United Kingdom, NIHR Southampton Biomedical Research Centre, University of Southampton and University Hospital Southampton NHS Foundation Trust, Southampton, United Kingdom

  • Kate Westgate,

    Roles Data curation, Formal analysis, Writing – review & editing

    Affiliation MRC Epidemiology Unit, University of Cambridge School of Clinical Medicine, Cambridge, United Kingdom

  • Hazel M. Inskip,

    Roles Data curation, Funding acquisition, Investigation, Project administration, Writing – review & editing

    Affiliations MRC Lifecourse Epidemiology Centre (University of Southampton), Southampton General Hospital, Southampton, United Kingdom, NIHR Southampton Biomedical Research Centre, University of Southampton and University Hospital Southampton NHS Foundation Trust, Southampton, United Kingdom

  • Esther M. F. van Sluijs

    Roles Conceptualization, Supervision, Writing – review & editing

    Affiliation MRC Epidemiology Unit, University of Cambridge School of Clinical Medicine, Cambridge, United Kingdom

Abstract

Background

Physical activity (PA) has many health benefits, but motherhood is often associated with reduced PA. Considering that ages and number of children may be associated with maternal PA, and that PA patterns may change as children transition to formal schooling, we aimed to investigate the associations between ages and number of children and device-measured maternal PA.

Methods

Cross-sectional analyses were conducted using data from 848 mothers from the Southampton Women’s Survey at two different timepoints. Two-level random intercept linear models were used to investigate associations between ages (≤4y(ears) (“younger”), school-aged, both age groups) and number (1, 2, ≥3) of children, and their interaction, and accelerometer-assessed minutes of maternal moderate or vigorous PA (log-transformed MVPA) and light, moderate or vigorous PA (LMVPA).

Results

Women with any school-aged children engaged in more MVPA than those with only ≤4y (e.g. % difference in minutes of MVPA [95% confidence interval]: 46.9% [22.0;77.0] for mothers with only school-aged vs only ≤4y). Mothers with multiple children did less MVPA than those with 1 child (e.g. 12.5% [-1.1;24.3] less MVPA for those with 2 children). For mothers with multiple children, those with any school-aged children did less LMVPA than those with only ≤4y (e.g. amongst mothers with 2 children, those with only school-aged children did 34.0 [3.9;64.1] mins/day less LMVPA). For mothers with any ≤4y, those with more children did more LMVPA (e.g. amongst mothers with only ≤4y, those with 2 children did 42.6 [16.4;68.8] mins/day more LMVPA than those with 1 child).

Conclusions

Mothers with multiple children and only children aged ≤4y did less MVPA. Considering that many of these women also did more LMVPA than mothers with fewer or older children, interventions and policies are needed to increase their opportunities for higher intensity PA to maximise health benefits.

Trial registration

ClinicalTrials.gov Identifier: NCT04715945.

Introduction

Physical activity has many health benefits [1]. It decreases the risk of multiple physical health outcomes, ranging from various cancers to cardiovascular disease [2]. It is also associated with weight maintenance [2], better mental health [2], and mitigation of negative effects of sedentary behaviour [3]. There are additional potential benefits of physical activity for parents. These include increased confidence in ability to cope with the daily challenges of being a parent, and strengthening of parent-child relationships through co-participation [4, 5]. There is also evidence that parental physical activity is positively associated with that of children, especially in studies using device-based measurements [6, 7]. However, despite the many potential gains which physical activity could bring to parents, they are less active than non-parents [8].

It is important to decipher what factors are associated with parental physical activity to understand this behaviour, identify sub-groups of parents who are more at risk of insufficient physical activity and determine which factors could be targeted to increase physical activity. Previous review-level evidence concerning factors, including ages and number of children, associated with parental or specifically maternal physical activity has mostly been inconclusive [8, 9]. Considering that ages and number of children are correlates specific to parents, rather than adults in general, and that previous reviews were inconclusive, it is important to further investigate the association between these factors and parental physical activity. The few studies that have used device-based physical activity assessment to investigate either the association between ages or number of children and maternal physical activity suggest that mothers of younger children do less moderate or vigorous physical activity (MVPA) than mothers of older children, but report mixed findings for the number of children [1012].

Data from the UK Southampton Women’s Survey (SWS) provide accelerometer-assessed physical activity in mothers, along with details of number of younger and older siblings of the index child at 4 years of age (4y) and 6 years of age (6y). Previous analyses in this cohort, when the index child was 4y, found that mothers who had younger children, as well as the index child, engaged in more light physical activity (LPA) [13], but no association was found with MVPA [13]. This work extends the previous analysis by examining the separate effects of number and ages of children, also determining whether there is an interaction between the two variables in relation to maternal physical activity. This allows us to identify which subgroups of mothers are more at risk of insufficient physical activity than others. In the UK, children start school in the September before they turn 5y [14]. It is plausible that maternal physical activity and opportunities to be active may change at this point as previous evidence suggests that the relationship between mother-child physical activity also changes during this transition [15]. It is therefore useful to compare the physical activity levels of mothers with school-aged vs younger children. Using data from the SWS, the aim of this cross-sectional study is to investigate the association between number and ages of children, categorised as ≥5y (hereafter referred to as school-aged) and ≤4y (hereafter referred to as younger children), and maternal accelerometer-assessed physical activity.

Methods

These analyses are reported following the STROBE guidelines for cross-sectional studies (S1 Appendix) [16].

Population

The SWS is a cohort study based in Southampton, UK. Between 1998 and 2002, non-pregnant women aged 20–34 years were recruited through general practices and participated in interviews [17]. Women who subsequently became pregnant were invited to take part, and live births were followed up at various intervals [13, 17]. Twins and higher-order pregnancies were not included in the study. A sub-study of mothers and the index child was conducted for children reaching 4y (mean age 4.1 (standard deviation (SD) 0.1)) between March 2006 and June 2009 to investigate their physical activity [15]. Mothers with index children born after January 2000 were then approached for a visit when the index child was 6–7 years (mean age 6.7 (SD 0.3) and hereafter referred to as 6y) between March 2007 and August 2012 [15]. The Southampton and South West Hampshire Local Research Ethics committee granted ethical approval for the study. Direct written consent was obtained from all women and written parental consent with verbal child assent was gained for children.

Measures used in the current analyses

Physical activity assessment and variables.

Maternal physical activity was assessed using a combined heart rate and uniaxial accelerometer (Actiheart, CamNtech, Cambridgeshire, UK) secured to the chest and set to record at 60-second epochs [15]. Participants were asked to wear the monitor continuously for seven days, including during water-based activity and sleep, and return them via secure post [15]. Only accelerometer data were used for these analyses due to the focus on physical activity intensity, and that heart rate data were not dynamically individually calibrated.

Data periods of ≥100 minutes with zero-activity were removed and recordings between 11pm and 6am were excluded to remove time spent sleeping [13]. Mothers were eligible for inclusion in analyses if they had ≥10 hours of valid accelerometer data for at least one day [13, 18]. Valid accelerometer data were available for 621 and 608 women at the 4y and 6y waves respectively (total n = 1034; n = 195 women with both timepoints).

Daily maternal MVPA and light, moderate or vigorous physical activity (LMVPA) were the outcome measures.

The main outcomes examined were average minutes of MVPA and LMVPA per day, on weekdays and on weekend days. Exploratory outcome variables were average daily minutes MVPA and LMVPA for periods when mothers might be more or less likely to be with their children: 6-9am (weekday morning); 9am-3pm (weekday school/work day); 3-7pm (weekday late afternoon); 7-11pm (weekday evening) and weekends: 6am-7pm (weekend day); 7-11pm (weekend evening). MVPA was chosen as an outcome as it has been shown to have additional health benefits to LPA even when volume of physical activity energy expenditure is taken into consideration [19]. However, LMVPA was also chosen as an outcome as a measure of overall physical activity since it may be more likely that mothers of young children engage in greater LPA than MVPA, and LPA has also been shown to have health benefits [20]. Cut-points for MVPA (≥400cpm) and LMVPA (≥20cpm) were applied having been scaled using a conversion factor of 5 from the Actiheart accelerometer as previously validated [18, 21]. The Actiheart intensity thresholds equate to 2000 counts for MVPA and 100 counts for LPA in the Actigraph 7164 accelerometer (Actigraph, Pensacola, FL) [21, 22].

Other physical activity variables derived for descriptive purposes were: meeting physical activity guidelines (≥150 minutes of MVPA/week, or a mean of ≥21.4 mins/day), valid days of collection, and average daily wear-time.

Exposure variables.

Data from questionnaires administered when the index child was 4y or 6y were used to derive the exposure variables, ages of children and number of children (see Table 1).

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Table 1. Derivation of exposure variables (ages of children and number of children categories).

https://doi.org/10.1371/journal.pone.0276964.t001

Covariates and descriptor variables.

To identify covariates to include in models as potential confounders and competing exposures, direct acyclic graphs (DAGs) were created for both the association between ages of children and maternal MVPA and LMVPA (Ages of Children Analyses) and number of children and maternal MVPA and LMVPA (Number of Children Analyses) [23] (see S2 and S3 Appendices). Variables assessed in the DAGs were living with the father of the index child, maternal education, maternal age, maternal body mass index (BMI), maternal employment and pre-school attendance.

Data collected at age 4y or 6y and earlier waves were used to derive covariates. Unless otherwise stated, they were derived from data at time of accelerometer data collection. Potential confounders were maternal age (continuous), maternal highest qualification level from pre-pregnancy data (none; certificate of secondary education; O-levels, A-levels. higher national diploma; degree), and living with the father of the index child (lives with father; does not live with father).

For all analyses, competing exposures included in models were season when accelerometry was conducted (winter; spring; summer; autumn), time of the week (weekday; weekend), and survey (age 4y; age 6y).

Additional descriptor variables were: self-reported employment (unemployed; employed), and maternal BMI and BMI categories according to World Health Organisation classifications [24] (underweight/ normal weight; overweight; obese) from measured height and weight data. Both were collected at the relevant age (4y or 6y).

Statistical analyses

Analyses were conducted using Stata 16 [25]. Descriptive characteristics were calculated by ages of children. Means and SD were presented for normally distributed continuous variables and median and interquartile range (IQR) otherwise. To assess the representativeness of this sample, women in these analyses were compared with those who did not have any accelerometer data with respect to the following variables: maternal age at birth of index child, BMI at initial survey, and highest qualification level from the initial survey.

Two-level random intercept linear models were run, using daily minutes of maternal MVPA (log-transformed) and LMVPA as outcome variables. Minutes of MVPA were log-transformed as the distribution was skewed. Models were used to assess the association between ages of children or number of children and daily maternal log MVPA and LMVPA. Two-level random intercept linear models were used as they take into account variation in the outcome variable between day of accelerometer data collection (level 1) and between mothers (level 2) [26]. The correlation between observations was taken into account by allowing the intercept to vary randomly between mothers [13]. The model also takes into account that data from the age 4y and age 6y surveys were pooled and some mothers appear in both datasets.

An interaction term was added between number and ages of children using a likelihood ratio test (LRT) to compare models both with and without this term (Interaction Analyses). Analyses were stratified where an interaction was identified (defined a priori as p<0.05).

For MVPA, regression coefficients were back-transformed to produce the geometric mean ratio (GMR) for which a deviation from 1 indicates the percentage change in MVPA compared with the reference category for each analysis. Percentage difference (and 95% confidence interval (95%CI)) compared with the reference category is presented for each of the MVPA outcomes. For LMVPA, beta coefficients for mean daily minutes and 95%CI are presented for each of the outcomes.

Models were adjusted for competing exposures detailed earlier and confounders identified from the DAGs. Confounders were maternal age and number of children (Ages of Children Analyses), and maternal age, maternal education level and living with the father of the child (Number of Children Analyses and Interaction Analyses). A complete case analysis was conducted for each of the three individual analyses. Fig 1 shows the flow chart for mothers included in analyses. 848 women were included in analyses related to the ages of children and 844 in analyses related to number of children in the household.

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Fig 1. A flow diagram chart of SWS mothers in analyses.

*n = 621 for age 4y and n = 608 for age 6y. **n = 607 for age 4y and n = 592 for age 6y. ***n = 457 for age 4y and n = 525 for age 6y.

https://doi.org/10.1371/journal.pone.0276964.g001

For the periods of the day exploratory analyses, data were restricted to those women with 17 hours per day of accelerometer data in order to facilitate comparisons between parts of the day.

Sensitivity analyses

To assess the impact of the accelerometer inclusion criteria, Number of Children Analyses and Ages of Children Analyses for all days available were re-run, first for women with 3 or more valid days of accelerometer data (n = 801 for Ages of Children Analyses and n = 797 for Number of Children Analyses), and then for women with 5 or more valid days (n = 725 for Ages of Children Analyses and n = 721 for Number of Children Analyses). We excluded women with missing data for number of younger or older children, conducting sensitivity analyses with the assumption that those women had no children in these groups. The statistical analysis plan also included a complete case analysis for women with sufficient data for all three sets of analyses (Ages of Children, Number of Children and Interaction Analyses), but as only 4 women would have been excluded, these were not conducted.

Results

Tables 2 and 3 show the descriptive characteristics of mothers by ages of their children for those mothers contributing data from the age 4y and age 6y surveys respectively. In all groups, less than 50% of mothers met the physical activity guidelines (29.8% of mothers with only younger children and 41.6% with younger and school-aged children at the age 4y survey (Table 2); 49.3% with only school-aged children and 39.8% with younger and school-aged children at the age 6y survey (Table 3). Median valid wear-time of the days included was 16.3 hours (IQR 16.0–17.0 hours) and median valid days was 6 (IQR 6–7) at the age 4y survey. The respective values at the age 6y survey were 16.3 (16.0–16.9) hours and 6 (IQR 5–7) days.

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Table 2. Descriptive characteristics of SWS mothers providing data at the age 4y survey (n = 457)*.

https://doi.org/10.1371/journal.pone.0276964.t002

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Table 3. Descriptive characteristics of SWS mothers providing data at the age 6y survey (n = 525)*.

https://doi.org/10.1371/journal.pone.0276964.t003

S4 Appendix shows a comparison of descriptive characteristics between women included in analyses (n = 848) and those excluded (n = 2124). Mothers were comparable in age at birth of the index child and BMI, but those included were more likely to have achieved a higher level of educational qualification than those excluded.

No interaction was found between ages of children and number of children in relation to maternal MVPA (as evidenced by a LRT p-value of 0.32). However, a strong interaction was found for LMVPA (as evidenced by a LRT with p = 0.0006). Thus, all results for MVPA are unstratified and those for LMVPA are stratified (ages of children by number of children and vice-versa).

Association between ages and number of children and maternal MVPA (Table 4)

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Table 4. Associations between number and ages of children and maternal MVPA levelsa.

https://doi.org/10.1371/journal.pone.0276964.t004

Mothers either with only school-aged children or children in both age groups did more MVPA than those with only younger children (by 46.9% [22.0, 77.0] and 42.7% [25.1, 62.8] respectively). There was stronger evidence for this association on weekdays than weekend days. Regarding number of children, compared with mothers who had only 1 child, mothers with ≥2 children did less MVPA (by 12.5%, [-1.1, 24.3] for those with 2 children, and by 13.9% [-1.4, 26.9] for ≥3 children). The evidence for less MVPA amongst women with multiple children was stronger on weekend days than weekdays.

Association between ages of children and maternal LMVPA by number of children (Fig 2)

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Fig 2. Association between ages of children and maternal LMVPA by number of children.

LMVPA = light, moderate or vigorous physical activity; 95%CI = 95% confidence interval. Models adjusted for age of mother, season, age 4y or age 6y survey, time of week.

https://doi.org/10.1371/journal.pone.0276964.g002

For mothers with only one child, there was no evidence of a difference in LMVPA by age of the child. For mothers with 2 children, those with only school-aged children did 34.0 [3.9, 64.1] minutes less LMVPA than those with only younger children. For mothers with ≥3 children, those with any school-aged children did less LMVPA than those with only younger children. There was stronger evidence for these associations on weekend days than weekdays (see S5 Appendix).

Association between number of children and maternal LMVPA by ages of children (Fig 3)

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Fig 3. Association between number of children and maternal LMVPA by ages of children.

LMVPA = light, moderate or vigorous physical activity; 95%CI = 95% confidence interval. Models adjusted for age of mother, maternal highest qualification level, living with father, season, age 4y or age 6y survey, time of week.

https://doi.org/10.1371/journal.pone.0276964.g003

For mothers with only younger children, those with ≥2 children engaged in more minutes of LMVPA per day compared with those with one child (on average 42.6 extra minutes for mothers with 2 children; 49.9 extra minutes for those with ≥3 children), with the effect being more prominent on weekdays (S5 Appendix). For mothers with only school-aged children, there was no evidence of a difference in maternal LMVPA by number of children. For mothers with children in both age groups, having ≥3 children compared with 2 children was associated with more maternal LMVPA, at least on weekdays (see S5 Appendix).

Exploratory analyses for maternal MVPA by time of the day (S6 Appendix)

Mothers with any school-aged children did more MVPA than those with only younger children across all periods of the day and week, with the most pronounced differences on weekday mornings and weekday late afternoons. Regarding number of children, mothers with ≥2 children did less MVPA than mothers with 1 child, particularly on weekday mornings and weekend days.

Exploratory analyses for maternal LMVPA by time of the day (S7 Appendix)

The associations between ages and number of children and maternal LMVPA varied by period of the day on weekdays and weekend. However, there were no clear patterns to support consistent conclusions.

Sensitivity analyses

The pre-planned sensitivity analyses did not substantially affect the main findings (S8 and S9 Appendices).

Discussion

Main findings

Amongst this cohort of British women, we found that mothers with any school-aged children engaged in more MVPA than those with only younger children, and that mothers with multiple children did less MVPA than those with one child. In addition, for mothers with multiple children, those with any school-aged children did less LMVPA than those with only younger children. Finally, among mothers with any younger children, those with more children did more LMVPA.

Findings in relation to other similar studies

Only one other study has used accelerometer assessment to directly examine the association between ages of children and individual physical activity amongst mothers, and these analyses were only exploratory [10]. Although significant differences in MVPA were not reported between mothers of children of different ages, and the youngest age category was 0–5 years rather than 0–4 years in our study, their estimates did suggest that mothers of children aged 0–5 years did less MVPA (22.9 mins/day) than those with children aged 6–12 years (28.7 mins/day) [10], supporting our findings. However, unlike in our study in which the average amount of MVPA was below the recommended guidelines regardless of child age (see Tables 2 and 3), the average amount of MVPA for all mothers in Candelaria et al. 2012 was above the recommended guidelines [10]. Although they did not make direct comparisons between groups of mothers, two other studies using accelerometer assessment compared the physical activity levels of mothers with children in different age groups to those of non-mothers and showed that only mothers with children ≤5y did significantly less MVPA than non-parents [11, 12]. Again, despite the youngest category of children extending to 5-year-olds rather than 4-year-olds as in our study, this also supports our finding of mothers with younger children doing less MVPA than those with older children. In the one study that investigated accelerometer-assessed LPA by ages of children [12], women with children ≤5y were also the only group of mothers who had significantly higher levels of LPA compared with non-parents, which aligns with our findings of mothers of younger children doing more LMVPA than those with school-aged children. To our knowledge, there have been no recent relevant self-report studies comparing maternal MVPA or LMVPA by whether children in the household are younger children or school-aged.

Regarding number of children, only one study used accelerometer assessment to directly investigate a statistical association with maternal physical activity amongst a sample of parents, finding no association [10]. Two studies using accelerometer assessment also made direct comparisons between mothers with different numbers of children and non-parents; one study found no association [11], while the other, in support of our findings, reported that mothers with ≥2 children did less MVPA than non-parents, whilst there was no difference for those with one child [12]. In the only study to examine accelerometer assessed LPA [12], estimates suggested that there was little or no difference in LPA by number of children, in contrast to our findings, but again direct comparisons were only made between mothers and non-parents. The majority of recent studies using self-reported physical activity have found no difference in maternal physical activity, but outcomes have varied: total physical activity [27], active transport [28] or leisure time physical activity [29]. One study did find that parents with multiple children do less exercise than those with one child, which supports our findings [30].

Possible explanations for our findings

Mothers with younger children spent less time in MVPA but more in LMVPA than those with school-aged children. Evidence suggests that mothers of young children spend a large amount of time in household activities [31], which tend to be of lower intensity. As children grow older, mothers may spend less time purely supervising their children as they play [32], instead engaging in higher intensity activity through co-participation with their children and actively traveling to and from school. These opportunities for increased MVPA would be available to those with purely school-aged or both younger and school-aged children. Having children at school may also provide mothers with more time to engage in structured exercise of higher intensity. Outside school, mothers may feel more comfortable leaving older children with someone else to do their own leisure time physical activity. As children get older, women are also more likely to return to work, providing opportunities for higher intensity physical activity both during the commute, and at work itself in some cases.

Less time spent in MVPA amongst mothers with multiple children could be due to greater time constraints, reducing time available for leisure time physical activity, and perhaps encouraging mothers to avoid active transport in favour of quicker options. More time spent in LMVPA amongst mothers with more children could be explained by additional time spent on household activities, supported by a study which found that mothers of one child spend on average 268 minutes per week on household activities compared with 520 minutes per week amongst mothers with ≥3 children [10].

Strengths and limitations

This is the largest study to assess the association between number and ages of children and accelerometer-assessed maternal physical activity, benefits from the inclusion of testing for statistical interactions, and makes comparisons between groups of mothers as opposed to comparing with non-parents. In addition, the use of accelerometer assessment of physical activity is a key strength, important to ensure that sporadic and spontaneous movement was captured, which is likely to be common amongst mothers of younger children and might be easily missed in self-reported physical activity [33]. The physical activity data is from 2006 to 2012 but is still highly relevant considering that physical activity levels amongst adults in high-income western countries have since continued to decline [34]. Finally, our analyses were detailed, not only accounting for the interaction between number and ages of children in relation to maternal LMVPA and including appropriate confounders, but also exploring associations by period of the day and week.

We lacked data on exact ages of the siblings, and assumed that younger siblings of the 6y index child were ≤4y (i.e. in the younger children category) if they were not mentioned at the age 2y survey. As the average time lapse between the age 2y and age 6y survey was 4.6y, we think this was a reasonable assumption. We lacked data on sex of children other than the index child so this variable was not included in the models. We also do not know the types of physical activity the women engaged in or their locations whilst wearing the accelerometer, and we were unable to consider all factors which might be related to maternal physical activity, such as size of garden, and social support. Finally, due to the number of tests conducted, some of our findings, especially those from exploratory analyses, may be due to chance.

Policy implications and future research needed

Our findings suggest a need to focus on interventions and policies to increase the opportunities for higher intensity physical activity of mothers of younger or multiple children, as these mothers already undertake considerable amounts of LMVPA. LPA does provide health benefits, but in a study examining the association between device-assessed physical activity and mortality rates, greater reductions were achieved amongst those reaching a set physical activity energy expenditure through higher intensity physical activity than through more time spent in lower intensity activity [19]. Qualitative research may be helpful to identify means by which this change could be achieved. Large longitudinal studies using device-based assessment of physical activity are also required to build the evidence base relating to determinants of change in maternal physical activity, tracking changes in individuals as their children get older. Studies assessing physical activity through a combination of device-assessment and self-report would also be helpful to provide information on both amount and type of physical activity engaged in by mothers. Finally, research is needed to investigate the association between number and ages of children and paternal physical activity, to identify fathers more at risk of insufficient physical activity and to determine how this relates to both maternal and child activity.

Conclusions

Policies and interventions are needed to encourage mothers with younger or multiple children to engage in greater MVPA, ensuring they benefit from health gains associated with higher intensity activity.

Supporting information

S2 Appendix. DAG for number of children and maternal physical activity analyses.

https://doi.org/10.1371/journal.pone.0276964.s002

(PDF)

S3 Appendix. DAG for ages of children and maternal physical activity analyses.

https://doi.org/10.1371/journal.pone.0276964.s003

(PDF)

S4 Appendix. A comparison of descriptive characteristics.

https://doi.org/10.1371/journal.pone.0276964.s004

(DOCX)

S5 Appendix. Stratified associations between exposures and maternal LMVPA.

https://doi.org/10.1371/journal.pone.0276964.s005

(DOCX)

S6 Appendix. Associations between exposures and MVPA by time of the day.

https://doi.org/10.1371/journal.pone.0276964.s006

(DOCX)

S7 Appendix. Stratified associations between exposures and LMVPA by time of the day.

https://doi.org/10.1371/journal.pone.0276964.s007

(DOCX)

Acknowledgments

We thank the participants in the SWS for their commitment to and involvement in the study, and the dedicated team of research nurses and ancillary staff for their assistance in collecting and processing the data. The authors would also like to thank Stephanie Hollidge (MRC Epidemiology Unit) for her assistance in the processing of the physical activity data.

References

  1. 1. Department of Health and Social Care. UK Chief Medical Officers’ Physical Activity Guidelines. London; 2019.
  2. 2. World Health Organisation. Physical activity [Internet]. World Health Organisation; 2020 [accessed 05 July 2022]. https://www.who.int/news-room/fact-sheets/detail/physical-activity.
  3. 3. Ekelund U, Steene-Johannessen J, Brown WJ, Fagerland MW, Owen N, Powell KE, et al. Does physical activity attenuate, or even eliminate, the detrimental association of sitting time with mortality? A harmonised meta-analysis of data from more than 1 million men and women. Lancet. 2016;388(10051):1302–10. pmid:27475271
  4. 4. Brown HE, Atkin AJ, Panter J, Wong G, Chinapaw MJ, van Sluijs EM. Family-based interventions to increase physical activity in children: a systematic review, meta-analysis and realist synthesis. Obes Rev. 2016;17(4):345–60. pmid:26756281
  5. 5. Hamilton K, White KM. Identifying parents’ perceptions about physical activity: a qualitative exploration of salient behavioural, normative and control beliefs among mothers and fathers of young children. J Health Psychol. 2010;15(8):1157–69. pmid:20472605
  6. 6. Yao CA, Rhodes RE. Parental correlates in child and adolescent physical activity: a meta-analysis. Int J Behav Nutr Phys Act. 2015;12:10. pmid:25890040
  7. 7. Petersen TL, Moller LB, Brond JC, Jepsen R, Grontved A. Association between parent and child physical activity: a systematic review. Int J Behav Nutr Phys Act. 2020;17(1):67. pmid:32423407
  8. 8. Bellows-Riecken KH, Rhodes RE. A birth of inactivity? A review of physical activity and parenthood. Prev Med. 2008;46(2):99–110. pmid:17919713
  9. 9. Rhodes RE, Downs DS, Riecken KH. Delivering inactivity? Transitions to motherhood and its effect on physical activity. In: Allerton LT, Rutherfode GP, editors. Exercise and Women’s Health: New Research. New York: Nova Science Publishers, Inc; 2008. p. 105–27.
  10. 10. Candelaria JI, Sallis JF, Conway TL, Saelens BE, Frank LD, Slymen DJ. Differences in physical activity among adults in households with and without children. J Phys Act Health. 2012;9(7):985–95. pmid:21953281
  11. 11. Adamo KB, Langlois KA, Brett KE, Colley RC. Young children and parental physical activity levels: Findings from the canadian health measures survey. Am J Prev Med. 2012;43(2):168–75. pmid:22813681
  12. 12. Gaston A, Edwards SA, Doelman A, Tober JA. The impact of parenthood on Canadians’ objectively measured physical activity: an examination of cross-sectional population-based data. BMC Public Health. 2014;14:1127. pmid:25363082
  13. 13. Hesketh K, Goodfellow L, Ekelund U, McMinn AM, Godfrey KM, Inskip HM, et al. Activity Levels in Mothers and Their Preschool Children. Pediatrics. 2014;133(4):e973–80. pmid:24664097
  14. 14. Government Digital Service. School admissions—school starting age [Internet] [accessed 24 May 2021]. https://www.gov.uk/schools-admissions/school-starting-age.
  15. 15. Hesketh KR, Brage S, Cooper C, Godfrey KM, Harvey NC, Inskip HM, et al. The association between maternal-child physical activity levels at the transition to formal schooling: cross-sectional and prospective data from the Southampton Women’s Survey. Int J Behav Nutr Phys Act. 2019;16(1):23. pmid:30786904
  16. 16. von Elm E, Altman DG, Egger MJ, Pocock SJ, Gotzsche PC, Vandenbroucke JP. Strengthening the Reporting of Observational Studies in Epidemiology (STROBE) Statement: guidelines for reporting observational studies. Ann Intern Med. 2007;147(8):573–7.
  17. 17. Inskip HM, Godfrey KM, Robinson SM, Law CM, Barker DJ, Cooper C, et al. Cohort profile: The Southampton Women’s Survey. Int J Epidemiol. 2006;35(1):42–8. pmid:16195252
  18. 18. Troiano RP, Berrigan D, Dodd KW, Masse LC, Tilert T, McDowell M. Physical activity in the United States measured by accelerometer. Med Sci Sports Exerc. 2008;40(1):181–8. pmid:18091006
  19. 19. Strain T, Wijndaele K, Dempsey PC, Sharp SJ, Pearce M, Jeon J, et al. Wearable-device-measured physical activity and future health risk. Nat Med. 2020;26(9):1385–91. pmid:32807930
  20. 20. Amagasa S, Machida M, Fukushima N, Kikuchi H, Takamiya T, Odagiri Y, et al. Is objectively measured light-intensity physical activity associated with health outcomes after adjustment for moderate-to-vigorous physical activity in adults? A systematic review. Int J Behav Nutr Phys Act. 2018;15(1):65. pmid:29986718
  21. 21. Ridgway CL, Brage S, Sharp SJ, Corder K, Westgate KL, van Sluijs EM, et al. Does birth weight influence physical activity in youth? A combined analysis of four studies using objectively measured physical activity. PLoS ONE. 2011;6(1):e16125. pmid:21264270
  22. 22. Corder K, Brage S, Mattocks CG, Ness A, Riddoch C, Wareham NJ, et al. Comparison of two methods to assess PAEE during six activities in children. Med Sci Sports Exerc. 2007;39(12):2180–8. pmid:18046189
  23. 23. Textor J, van der Zander B, Gilthorpe MS, Liskiewicz M, Ellison GT. Robust causal inference using directed acyclic graphs: the R package ’dagitty’. Int J Epidemiol. 2016;45(6):1887–94. pmid:28089956
  24. 24. World Health Organisation. BMI Classification. [Internet] [Accessed 25 November 2020]. http://apps.who.int/bmi/index.jsp?introPage=intro_3.html.
  25. 25. StataCorp. Stata Statistical Software: Release 16. College Station, TX: StataCorp LLC; 2019.
  26. 26. Goldstein H. Multilevel statistical models. 4th ed. Chichester, UK: Wiley-Blackwell; 2010.
  27. 27. Babić A, Humer JT, Sincek D. Physical activity and quality of life of mothers of preschool children. Coll Antropol. 2015;39(2):419–26. pmid:26753459
  28. 28. Lee RE, Kim Y, Cubbin C. Residence in unsafe neighborhoods is associated with active transportation among poor women: Geographic Research on Wellbeing (GROW) Study. J Transp Health. 2018;9:64–72.
  29. 29. Li K, Davison KK, Jurkowski JM. Mental health and family functioning as correlates of a sedentary lifestyle among low-income women with young children. Women Health. 2012;52(6):606–19. pmid:22860706
  30. 30. Goldberg AE, Smith JZ, McCormick NM, Overstreet NM. Health behaviors and outcomes of parents in same-sex couples: an exploratory study. Psychol Sex Orientat Gend Divers. 2019;6(3):318–35.
  31. 31. Collins BS, Miller YD, Marshall AL. Physical activity in women with young children: How can we assess "Anything that’s not sitting"? Women Health. 2007;45(2):95–116. pmid:18019288
  32. 32. Hamilton K, White KM. Understanding parental physical activity: meanings, habits, and social role influence. Psychol Sport Exerc. 2010;11(4):275–85.
  33. 33. MacKay LM, Schofield GM, Oliver M. Measuring physical activity and sedentary behaviors in women with young children: a systematic review. Women Health. 2011;51(4):400–21. pmid:21707341
  34. 34. Guthold R, Stevens GA, Riley LM, Bull FC. Worldwide trends in insufficient physical activity from 2001 to 2016: a pooled analysis of 358 population-based surveys with 1·9 million participants. Lancet Glob Health. 2018;6(10):e1077–e86. pmid:30193830