A cross-sectional, exploratory survey on health-relevant free-time activities and body mass index in preschool children in urban and rural settings of Austria
verfasst von:
J. Robatsch, P. Voitl, Susanne C. Diesner-Treiber
The increasing prevalence of obesity is among the most relevant healthcare issues in Europe. The number of overweight people rises due to lifestyle changes, increased sitting activities, and less physical activity. Prevention in early childhood is paramount to stop this alarming trend.
Aim
This study primarily aimed to evaluate the average time children (3-5 years) from rural and urban Austrian regions spent engaging in physical activity and sedentary behaviors in their free-time. Additionally, we investigated the potential correlation between duration and habits of free-time activity or place of residence and age- and sex-specific body mass index (BMI). The potential impact of socio-economic factors on BMI was examined.
Methods
Urban (Vienna) and rural (Carinthia) regions of Austria were chosen for this observational cross-sectional study. Preschool children (n=130) attending nurseries in these regions were included. Weight and height were measured and BMI calculated. Free-time activity and socio-economic data were asked using a self-administered questionnaire. Data on sedentary behavior time (sedentary activity and media consumption) and physical activity time (defined as organized or spontaneous exercise) were analyzed using non-parametric tests.
Results
Preschool children spent approximately as many hours of their free-time engaged in physical activity as in sedentary behaviors. Time trend in media consumption amounts to one-third of the cumulative time spent engaging in sedentary behaviors. Preschoolers from the urban area spent fewer hours practicing organized exercise and more in sedentary behaviors than peers in the rural area. In the selected areas, 7 % of preschoolers were overweight, 3.9 % were obese. BMI was not associated with free-time activities but showed a trendwise negative correlation with organized exercise. A positive correlation of age and organized exercise was observed but not with physical activity per se.
Conclusions
Our results confirm the necessity of preventive interventions among Austrian preschoolers and lead to a better understanding of their free-time activities. Further investigations with larger study populations are needed to promote effective childhood obesity prevention and examine the differences regarding obesity prevalence and leisure-time activity between rural and urban areas.
J. Robatsch and P. Voitl contributed equally to this work.
Publisher’s Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Abkürzungen
BMI
Body mass index
WHO
World health
organization
Background
Overweight and obesity are among the major health problems of the 21st century [1, 2]. The WHO classifies the nutritional status based on the body mass index into underweight (BMI <18.5 kg/m2), normal weight (18.5-24.9 kg/m2), overweight (BMI ≥25 kg/m2) and obesity (BMI ≥30 kg/m2) in adults [3]. BMI values for children and adolescents are expressed as sex- and age-specific percentiles, as a standard deviation score (SD-score) or relative BMI (rBMI) [2‐4]. Due to the statistical distribution of BMI values in German-speaking countries, the overweight limit for children and adolescents between 0 and 18 years is a BMI >90th percentile (approx. +1 SD-score), the obesity value exceeds the 97th percentile (approx. +2 SD-score) and extreme obesity 99.5th, while the cut-off for underweight is the 10th BMI-percentile [4‐6]. Normal weight lies between the 10th and 90th BMI-percentile. At the age of 18, percentiles switch to the corresponding risk-related BMI limit values for adults as a transition to definitions for different age groups [5, 7].
According to the World Health Organization (WHO) in 2016, 18 % of children and adolescents between 5 and 19 worldwide were overweight, 6 % of girls and 8 % of boys were obese [1]. The increasing prevalence of overweight in children and adults around the world continually presents our healthcare systems with new economic, prevention, and therapeutic challenges.
Anzeige
The multifactorial causes of the rising prevalence of obesity in the last decades involve a lifestyle with insufficient physical activity and excessive consumption of high-caloric food. Several socio-economic factors, as well as pre- and perinatal determinants, increase the risk of obesity [8‐12].
Obesity is not only a risk factor and contributor to increase morbidity and mortality in adults but affects already the children’s wellbeing [2, 5, 13]. Common obesity-related diseases, such as hypertension, lipid metabolism disorders, type 2 diabetes mellitus, or musculoskeletal system disorders, can affect children and adolescents and are associated with increased morbidity and mortality in the long term [2, 7]. Asthma, obstructive sleep apnea, infertility, polycystic ovary syndrome, and psychiatric disorders are also associated with an elevated BMI [14]. Discrimination and bullying, social isolation, and low self-esteem deriving from the stigma around obesity, along with body consciousness as early as in childhood, contribute significantly to severe psychological issues: anxiety, mood disorders, or disturbed eating behaviors such as binge eating [15‐17].
As overweight children are more likely to become overweight adults [18, 19] lifestyle habits, such as insufficient physical activity or dietary patterns, which are shaped at a young age, might be maintained later in life [19]. Therefore, it is necessary to understand that overweight and obesity are mostly preventable but early life preventive measures are needed. Nursery coincides with a critical window- thus the importance of a better understanding of preschoolers’ free-time activities as a potential target of obesity prevention is important, as confirmed by other results showing after-school time to play an essential role in establishing health-promoting activities in everyday life [20, 21].
Data on the correlation between physical activity and weight in children and adolescents is mostly incongruent [22‐25]. Not all children and adolescents accumulate the physical activity time recommended by the WHO being (60 min per day for children aged 5-17) [1]. Sedentary behavior and extensive screen media are unhealthy and represent a challenging habit for parents to break. Sedentary behaviors remain undoubtedly associated with obesity in many studies [25], while the effect of media exposure on BMI are discussed controversially in the corresponding literature [26‐30].
Anzeige
The prevalence of obesity increases regardless of the age groups and might have some association with the place of residency as according to international data the prevalence of overweight and obesity is differently distributed in rural and urban regions [1, 2, 31‐36].
In our opinion healthy early life free-time activities are a prerequisite for a healthy development and BMI not only at that age but also later in life. Thus, in this descriptive cross-sectional study we aimed to evaluate the average time children aged 3-5 years from rural and urban Austrian regions spent engaging in physical activity and sedentary behaviors in their free-time. We then analyzed if the duration of free-time activities was associated with age- and sex-specific BMI. The potential correlation of socio-economic factors, such as education level, the parents’ employment, the residence (urban or rural region) on BMI was examined.
The results might contribute to a better understanding of preschoolers’ free-time activities in these examined regions and can be the basis for further studies to provide indispensable insights into obesity prevention and healthy life style habits early in life.
Methods
Study design and setting
The current study is a cross-sectional exploratory survey, aiming to primarily compare free-time activities and collect data on BMI and socio-economic factors of preschool children in chosen rural and urban areas of Austria. Due to the exploratory design, sample size calculation was not performed.
This study considers cities with more than 100.000 inhabitants as urban areas and communities with 5.000 inhabitants or less as rural areas. In Austria big cities are defined as >100.000 inhabitants while a clear definition for rural areas does not exist. We defined rural areas as described by the Food and Agriculture Organization of the United Nations, indicating that 5.000 or less inhabitants come form rural clusters [37, 38].
We have chosen 4 nurseries located in different districts of Vienna, representing urban regions, and 6 nurseries in several communities in Carinthia, representing rural areas.
Study population
The study population includes apparently healthy children aged 3 to 5 years, attending one of the addressed nurseries, as well as their parents or legal guardians. Infants born prematurely and children with known chronic diseases were excluded.
Questionnaire
After consenting to participate, the parents or legal guardians filled in a self-administered questionnaire at the respective nurseries to provide demographic and socio-economic data of their preschool children (Supplementary data questionnaire). The study team collected data during visits to the preschools where a trained study member measured weight (kg) and height (cm) of the children in light clothes, without shoes [39], upright position and with the same instruments (digital scale brand AICOK, model no. YHF1431; measuring tape fixated on portable stadiometer). The weight and height were measured with an accuracy of one decimal number.
Anzeige
The Ethics Committee of the Medical University of Vienna approved this study (EK Nr. 1544/2017). Participation was voluntary and anonymous. Written informed consent to participate in this study was provided by the participants’ legal guardian / next of kin.
Measures
Although the questionnaire was developed by the authors themselves the choice of questions were based on validated study designs [40‐43]. Parents reported the following parameters (1+2) and estimated their preschool children’s time performing different free-time activities. The BMI (3) was calculated from the measured height and weight values. The detailed questions are listed in the supplementary file (Supplementary data questionnaire).
How many hours per week were devoted on average to the following free-time activities: Physical activity defined as organized exercise (such as sport programs with consistent attendance, i.e., dance class, or gymnastics, hours per week) and spontaneous exercise (such as additional physical exertion like running, biking, playground activities, hours per week). Sedentary behaviors defined as sedentary activity (such as playing with toys, drawing, hours per week) and screen media consumption (i.e., “screen-time”: TV, computer, tablet, smartphone, hours per week) (Supplementary Fig. 1);
Socio-economic factors: region (rural/urban; i.e. Carinthia/Vienna), age (years), gender (male, female), birth order (firstborn; middle child; lastborn), age of parents (years), parental occupational status (yes/no), highest parental education (less than high school completion; high school diploma; university degree).
Body-mass-index (calculated from measured height (cm) and weight (kg) values): raw values and weight classes (underweight BMI ≤10th percentile; normal weight 10th < BMI <90th percentile; overweight without obesity 90th ≤ BMI < 97th percentile; obesity BMI ≥97th percentile) grouped according to percentiles after Kromeyer-Hauschild et al. 2001 [4].
.
Statistical analysis
Data analysis was performed using Microsoft Excel and IBM SPSS® software. Kolmogorov-Smirnov-Test and Shapiro-Wilk-Test were used to test normal distribution, absent in most of the tested variables. Analysis of categorial variables included frequencies in absolute numbers and percentages for the total study population and regions separately and for all categories of ordinal variables, as well as Fisher’s Exact Test. Descriptive analysis of quantitative variables included median values, minimum and maximum for the total study population and regions separately. Two-sided p-values of Wilcoxon-Mann-Whitney-U-Test were calculated to test the differences of free-time activities between the rural and urban regions. Wilcoxon signed-rank test was performed to assess the differences between physical activity and sedentary behavior within a region. Kruskal-Wallis-Test was used to determine the variations concerning activities among weight classes. Correlations between age and free-time activities were calculated using the non-parametric coefficient of Spearman-Rho.
Anzeige
Non-parametric data were transformed using the Johnson transformation a method for achieving normal distribution [44]. These data were then used for linear regression analysis with BMI as the dependent variable. Normal distribution of residuals was confirmed. Regression analysis was conducted to test the correlation of socio-economic factors and BMI. Strength, direction and significance of the effects are shown as regression coefficient B (95 % CI), Beta and p-value (Supplementary Table 1). Bonferroni correction was performed for multiple comparisons. P-values <0.05 were considered statistically significant.
The study was conducted according to the STROBE-Statement on observational studies for evidence-based medicine [45].
Results
Cohort characterization
This cross-sectional observational study involved four nurseries in four different municipal districts of Vienna (urban area) and six nurseries in six municipalities of Carinthia (rural area). This pilot study is conceived as a guide for future large-scale analyses to address questions that were not thoroughly answered here. Opening hours had to be similar (6:30 or 7:00 a.m. - 4:00 p.m. and 5:30 p.m., Vienna, on average 10.88 h / day vs. Carinthia 9.66 h / Open every day), to ensure comparability of marginal conditions.
Out of 130 children included in the study, 58 were from Vienna, 72 were from Carinthia, 65 were female, and 65 were male. No significant sex differences between participants from rural and urban nurseries were observed.
Anzeige
The characteristics of the study cohorts can be found in Tables 1 and 2.
Table 1
Descriptive data analysis I: Child
Total
Urban
Rural
p
p-adjust
(n = 130)
(n = 58)
(n = 72)
Gender
male
50% (65)
51.7% (30)
48.6% (35)
0.7284
1
female
50% (65)
48.3% (28)
51.4% (37)
Age
years
4.5 (3-5.5)
4 (3-5.5)
4.5 (3-5.5)
0.059
0.649
Birth order
firstborn
48.5% (63)
50% (39)
47.2% (34)
0.3288
1
lastborn
41.5% (54)
43.1% (25)
40.3% (29)
other
10% (13)
6.9% (4)
12.5% (9)
Weight
kilogramm
18 (11.9-30.3)
16.5 (12.9-25.8)
18.7 (11.9-30.3)
0.149
1
Height
meters
1.07 (0.9-1.23)
1.05 (0.9-1.22)
1.1 (0.92-1.23)
0.435
1
BMI
kg/m2
15.82 (12.42-20.83)
15.83 (12.42-20.83)
15.81 (13.06-20.34)
0.535
1
Weight class
underweight
4.7% (6)
7% (4)
2.8% (2)
0.4558
1
normalweight
84.5% (109)
86% (49)
83.3% (60)
overweight w/o obesity
7% (9)
5.3% (3)
8.3% (6)
obesity
3.9% (5)
1.8% (1)
5.6% (4)
Physical activity
hours/week
12 (0-40)
12 (4-40)
12 (0-32)
0.746
1
Organized exercise
hours/week
0 (0-10)
0 (0-5)
1 (0-10)
0.001*
0.016*
Spontaneous exercise
hours/week
10 (2-40)
11 (3-40)
10 (2-30)
0.381
1
Sedentary behaviors
hours/week
13 (1-34)
14.5 (4-34)
10.75 (1-30)
0.010*
0.13
Sedentary activity
hours/week
7 (0-28)
10 (0-21)
7 (1-28)
0.030*
0.36
Media consumption
hours/week
4 (0-16)
5 (0-16)
4 (0-10)
0.007*
0.098
Categorial data: frequency in%, (absolute number); 2-sided p-value Fisher’s Exact Test; Quantitative data: median (min - max); 2-sided p-value Wilcoxon-Mann-Whitney U test; * p-value <0.05. p-adjust value after Bonferroni correction. Urban n = 58, rural n = 72, except for Physical activity: rural n = 81
Table 2
Descriptive data analysis II: Parents
Total
Urban
Rural
p
p-adjust
(n = 130)
(n = 58)
(n = 72)
Age mother
years
34 (22-51)
34 (22-47)
34 (25-51)
0.576
1
Age father
years
36 (24-62)
36 (24-55)
36 (24-62)
0.596
1
Employment mother
no
18% (23)
15.8% (9)
19.7% (14)
0.647
1
yes
82% (105)
84.2% (48)
80.3% (57)
Employment father
no
5.6% (7)
7.1% (4)
4.4% (3)
0.7
1
yes
94.4% (117)
92.9% (52)
95.6% (65)
Highest education level mother
< high school diploma
40.6% (52)
32.8% (19)
47.1% (33)
0.249
1
high school diploma
31.3% (40)
36.2% (21)
27.1% (19)
university
28.1% (36)
31.0% (18)
25.7% (18)
Highest education level father
< high school diploma
43.5% (54)
25.9% (15)
59.1% (39)
0.001*
0.006*
high-school diploma
26.6% (33)
32.8% (19)
21.2% (14)
university
29.8% (37)
41.4% (24)
19.7% (13)
Categorial data: frequency in % (absolute number); 2-sided p-value Fisher’s Exact Test; Quantitative data: median (min – max); 2-sided p-value Wilcoxon-Mann-Whitney U test; * p-value <0.05, p-adjust value after Bonferroni correction
Prevalence of overweight and obesity in selected Austrian cohorts
In the Austrian regions selected for this study, 84.5 % of preschoolers are a healthy weight (between 10th and 90th percentiles), 4.7 % are underweight (definition BMI <= 10th percentile), 7 % overweight not obese (90th ≤ BMI < 97th percentile) and 3.9 % of the preschoolers fall within the obesity range (BMI ≥97th percentile). No significant differences were observed between the considered rural and urban regions regarding overweight and obesity (p=0.456, see Table 1).
Time spent on physical activity and sedentary behaviors
The amount of free-time preschoolers spend performing physical activity is statistically comparable to the time dedicated to sedentary behavior (Wilcoxon sign test, p=0.778).
As it turns out, spontaneous exercise (such as additional physical exertion like running, biking, playground activities) is more customary among preschoolers than organized exercise (such as club sports, soccer, gymnastics, dance lessons). According to their parents, preschoolers devote about twice as many hours of their weekly free-time to sedentary activities (such as drawing, playing with toys) than to media consumption.
Free-time activities in urban and rural regions of Austria
In Vienna, hours spent on sedentary behaviors per week are significantly more than physical activity (Wilcoxon sign test, p=0.042). In Carinthia, on the other hand, the time for sedentary behaviors and physical activity is comparable (Wilcoxon sign test, p=0.128) (Fig. 1).
The median duration of sedentary behaviors is significantly longer in Vienna (14.5 h (4- 34) than in Carinthia (10.75 h (4-30) (p=0.01), while there are no differences as for physical activity (p=0.746) (Table 1).
Fig. 1
Physical activity and sedentary behaviors. Weekly hours preschoolers spend for physical activity and sedentary behaviors in selected rural and urban regions in Austria, * p <0.05 Wilcoxon sign test or Wilcoxon-Mann-Whitney-U test, (survey in Carinthia n = 72, and Vienna n = 58)
×
Preschoolers who live in the urban area spend more time engaging in sedentary activities (p=0.03) and media consumption (p=0.007) than rural preschoolers. On the other hand, preschoolers from the rural area practice more organized exercise (p=0.001) Fig. 2.
Fig. 2
Distribution of free-time activities. Preschoolers’ free-time spent on organized exercise, spontaneous exercise, sedentary activity, and media consumption in weekly hours in selected rural and urban regions of Austria (survey in Carinthia n = 72, and Vienna n = 58), * p <0.05 Wilcoxon-Mann-Whitney -U test
×
Free-time activities among the weight classes
To analyze possible associations between physical activity (organized and spontaneous exercise) or sedentary behaviors (sedentary activity and media consumption) and BMI, preschoolers were categorized according to their weight status, i.e. underweight, normal weight, overweight and obese.
Our data show no significant association between BMI and physical activity (p=0.187) or BMI and sedentary behaviors (p=0.722) (Table 3). An increasing BMI determines a trendwise decrease in the weekly hours of spontaneous exercise (p=0.105). There is no association between organized exercise and BMI (p=0.308), presumably because of the small number of cases per group (Table 3). Preschoolers of all weight classes spend, on average, twice as much time engaging in sedentary activities than in media consumption (Table 3).
Table 3
Weight class and free-time activity in (h/week)
Underweight
Normalweight
Overweight w/o obesity
Obesity
p
p-adjust
(n = 6)
(n = 108)
(n = 9)
(n = 5)
Physical activity
19 (7-25)
12 (0-40)
9 (6-21)
7 (5-13)
0.187
0.935
Organized exercise
0 (0-3)
0 (0-10)
1 (0-3)
1 (0-3)
0.308
1
Spontaneous exercise
17.5 (7-25)
10 (2-40)
8 (4-20)
7 (4-10)
0.105
0.63
Sedentary behaviors
14.75 (4-18)
13 (1-34)
16.5 (4-30)
8 (6-16)
0.722
1
Sedentary activity
10 (3-15)
7 (0-21)
10 (2-28)
5 (4-15)
0.702
1
Media consumption
3 (1-7)
4 (0-16)
4 (2-10)
3 (1-8)
0.622
1
median (min-max); p-value calculated using the Kruskal-Wallis test; p-adjust value after Bonferroni correction
Relationship between BMI and socio-economic factors
As socioeconomic factors might influence the BMI, we addressed this aspect using a linear regression model. After Johnson transformation, linear regression analysis for the dependency of BMI of preschoolers on the explanatory socioeconomic variables such as employment, education level, and age of the father; employment, education level, and age of the mother, as well as age, gender and federal state residency did not show a significant correlation (p≤0.05) for any explanatory variables (see Supplementary Table 1).
As a next step we investigated a possible age-specific effect on free-time activities using the Spearman correlation analysis. Age had no significant association with free-time activities per se. A correlation, however, was observed between age and weekly hours dedicated to organized exercise (correlation coefficient Spearman-Rho = 0.387), the two being directly proportional (p <0.001, Fig. 3).
Fig. 3
Age dependent time for organized exercise. Correlation of the age of Austrian preschoolers to the amount of free-time spent in organized exercise in a week (survey in Vienna and Carinthia, n = 129)
×
Discussion
In this observational cross-sectional study, we investigated the free-time of preschoolers (time outside of nursery hours) from the urban area of Vienna and the rural area of Carinthia.
According to parents’ reports, preschoolers spent approximately as many hours of their free-time doing physical activity as engaging in sedentary behaviors. Media consumption amounts to one-third of the time dedicated to sedentary activities. Preschoolers’ free-time activities in Vienna significantly differ in the fewer hours dedicated to organized exercise and the more extended period reserved for sedentary activity and watching screen-based entertainment. In our study cohort, 7 % of preschoolers in selected areas of Austria were overweight, 3.9 % were obese. No differences regarding the prevalence of overweight and obesity could be found among said regions. No differences were noted in the free-time activities among the weight classes, which might be due to the small sample size. However, organized exercise seems to be trendwise negatively correlated with BMI and might depend on the age of the child. No other socio-economic factors influenced BMI in our cohort.
Obesity rates among preschoolers differ worldwide, with the lowest numbers in developing countries [46] and the highest prevalence among 2- to 5-year-olds (13 %) in the US according to the CDC [47]. A comparison of our data on the prevalence of overweight and obesity with the results of the study by Mayer et al. 2015 [48], focusing on children and adolescents aged 4 to 19, reveals a similar proportion of obesity in children (between 3 % and 5 %). In contrast, our data showed a lower proportion of overweight children, 9 % of boys, 4 % of girls vs. 18 % of boys, 12 % of girls [48]. In our study, the rate of overweight girls was substantially lower. A remark about the discrepancy in our results and the apparent overweight rates decline would be purely speculative but, as parents of obese children might have refused to participate in our study, we consider a selection bias a possible explanation.
As shown in various studies, urban-rural-specific trends of overweight prevalence differ worldwide [32‐36]. According to Johnson et al., rural areas of the United States in 2015 were associated with 1.26 higher odds of obesity for 2-19-year-olds compared to urban children [35]. The Austrian participation in the COSI 2017 (8-9 years), however, showed an increased risk in cities [49].
Data on the prevalence of obesity among preschoolers in specific parts of Austria are rare. A Tirolean study revealed 7.6 % of preschoolers to be overweight and 5.5 % to be obese with no differences between mountainous and non-mountainous areas [50]. Despite the results of the Statistics Austria 2014 health survey on adults ranking Carinthia as the region with the second-highest prevalence of overweight and Vienna as the area with the lowest overweight prevalence [51], our study on preschoolers aged 3 to 5 shows no notable contrasts between the two regions being in line with the Tirolean study. This might be explained by the fact that our selected regions are not representative or that being overweight is less common at an early age and rather occurs later in life. This hypothesis is consistent with US data showing obesity to be more common in adolescence (20 % of 12- to 19-year-olds) [47]. Evidence in our study on the degree of urbanization as a risk factor for obesity remains inconclusive and needs to be addressed with a more representative study cohort.
Free-time activities are part of those lifestyle habits that are shaped at a young age and likely maintained later in life, determining a higher or lower BMI development. However, data on the correlation between physical activity and weight in children and adolescents are partially contradictory. According to a review by Prentice-Dunn et al. 2012, sedentary behaviors are positively associated with obesity in most studies [25]. Our findings are in line with other results showing no differences in active leisure habits between obese first-grade children compared to controls [52, 53]. Overweight children might favor sedentary behavior due to poorer motor abilities such as endurance, strength, coordination and balance [54].
Even though the association of physical activity with BMI in preschoolers is evident, further studies are needed. It is equally advisable to encourage an active lifestyle since childhood to prevent unhealthy lifestyle habits, as physical activity often reduces with age [24]. Our results reveal that preschoolers spend an average of 12 h/week (720 min/week, i.e. 102.86 min/day) engaging in physical activity and therefore exceed the 60 min daily minimum suggested by the WHO [55]. However, our findings should be interpreted with caution, as self-report questionnaires might tend to provide overestimations of actual behaviors. According to a systematic review, only 54 % of preschoolers are sufficiently active and meet the recommendations of the WHO [56].
Preschoolers in Austria spend 13 h/week (780 min/week, i.e. 111.43 min/day) engaging in sedentary behaviors. Outside nursery hours, they favor spontaneous exercise and sedentary activities such as painting, handicrafts, and games. According to the parents’ reports their preschool children meet the WHO recommendations of not exceeding 60 min of sedentary screen time per day (median of 4 h per week, 34 min/day) [55]. Therefore, media consumption for children this age amounts to about half of the time allotted for other sedentary activities (median 7 h/w).
With regard to the effects of socioeconomic factors such as residency, recreational activities have significantly different durations in rural and urban areas. In the United States, Euler et al. 2019 observed that teenagers in cities spend less time practicing physical activity and more in sedentary behaviors [34]. We remarked the same pattern in urban areas of Austria where preschoolers engage more in sedentary activities and media consumption, but no significant difference in physical activity were reported. Although our data indicate that preschoolers spend enough time engaging in physical activity in their free-time, the influencing factors such as urban versus rural residency or socio-economic status must be taken into account. Children from disadvantaged homes participate less frequently in free-time physical activity than those from higher-income families [57], and are more likely to do so in adulthood [58]. Thus, the relevance of early life preventive measures and the focus on influencing factors.
Limitations
Our study is an exploratory analysis and has some limitations. The selection bias, inadequate randomization, and the insufficient sample size from only two of the nine federal states make our results non-representative of the whole country. Accordingly, it is impossible to draw definitive conclusions. Sample size calculation was not performed due to the design of the study and the limited number of nurseries that were willing to participate. One of the limitations might be the questionnaire, which was self-administered, although based on validated study designs. Furthermore, presumably, parents of obese preschoolers did not consent to participate in the study. Also, evaluations on free-time activities are based on the parents’ subjective assessment and could be susceptible to inaccuracy. Due to the small sample size some of the effects might be statistically insignificant. Nonetheless, our efforts lay the foundation for future research to focus on more representative cohorts and provide indispensable insights into this topic.
Conclusions
Despite the limitations of this study, our results proved that, in urban areas, the duration of sedentary behaviors is significantly longer than physical activity, exposing preschoolers to an unhealthy life-style. Rural preschoolers might follow healthier life style habits as they participate more in organized sports (facilitating weight control) and less sedentary activities. As overweight and obesity affect preschool children, it is compelling to consecrate the utmost attention to obesity prevention at a young age and promote physical activity to tackle obesity and its onset later in life. Future studies could build on our outcomes to address obesity prevention and children’s free-time activities in more representative settings.
Acknowledgements
Not applicable.
Declarations
Ethics approval and consent to participate
The Ethics Commission of the Medical University of Vienna in July 2017 (1544/2017) approved this study. Participation was entirely voluntary and anonymous at all times. Nurseries participated upon management approval only. The participant information sheet and the questionnaire were handed and explained individually. Written informed consent to participate in this study was provided by the participants’ legal guardian / next of kin.
Consent for publication
Not applicable.
Competing interests
The authors declare that they have no conflict of interest.
Open AccessThis article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/. 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 in a credit line to the data.
Publisher’s Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
A cross-sectional, exploratory survey on health-relevant free-time activities and body mass index in preschool children in urban and rural settings of Austria
Wenn Kinder an Werktagen zum Arzt gehen, werden neu auftretender Typ-1-Diabetes und diabetische Ketoazidosen häufiger erkannt als bei Arztbesuchen an Wochenenden oder Feiertagen.
Augentropfen mit niedrig dosiertem Atropin können helfen, das Fortschreiten einer Kurzsichtigkeit bei Kindern zumindest zu verlangsamen, wie die Ergebnisse einer aktuellen Studie mit verschiedenen Dosierungen zeigen.
Seit 2021 ist die Untersuchung auf spinale Muskelatrophie Teil des Neugeborenen-Screenings in Deutschland. Eine Studie liefert weitere Evidenz für den Nutzen der Maßnahme.
Im Choosing-Wisely-Programm, das für die deutsche Initiative „Klug entscheiden“ Pate gestanden hat, sind erstmals Empfehlungen zum Umgang mit Notfällen von Kindern erschienen. Fünf Dinge gilt es demnach zu vermeiden.
Update Pädiatrie
Bestellen Sie unseren Fach-Newsletter und bleiben Sie gut informiert.
