| Research article - (2026)25, 627 - 636 DOI: https://doi.org/10.52082/jssm.2026.627 |
| The Influence of Structured Multisport Activities at Different Weekly Frequencies on the Gross Motor Development of Preschool Children: Evidence for a Dose–Response Relationship |
Fang Ren, Xing Zhao , Sha Qu |
| Key words: Preschool children, gross motor development, participation frequency, structured multisport activities |
| Key Points |
|
|
|
| Trial design |
This study employed a quasi-experimental pretest-posttest design to compare changes in gross motor development among preschool children participating in structured multisport activities at different weekly frequencies. A total of 63 preschool children were recruited for this study. The participants were categorized into four groups according to their frequency of participation in structured multisport activities: the low-frequency group (L), the medium-frequency group (M), the medium-high-frequency group (MH), and the high-frequency group (H). Participants were not randomly assigned to these groups; rather, they were classified according to their actual weekly participation frequency during the intervention period. The intervention lasted 12 weeks. Baseline data were collected one week before the start of the intervention, and post-intervention data were collected within one week after completion of the program. The study was approved by the Ethics Committee of Beijing Sport University (Approval No. 2024192H) and was conducted in accordance with the Declaration of Helsinki and relevant guidelines and regulations. |
| Participants |
A priori power analysis using G*Power (version 3.1; F tests, ANOVA: repeated measures, within-between interaction) for a mixed-design ANOVA (four groups × two time points; medium effect size f = 0.25, α = 0.05, 1-β = 0.80) indicated that a minimum total sample size of 48 participants was required. We ultimately enrolled 63 preschool children aged 3-6 years from an institution offering structured multisport activities, thereby exceeding the minimum required sample size. Strict inclusion criteria were applied at enrollment to control potential confounders and enhance between-group comparability. Eligibility criteria required that participants were healthy, with no contraindications to exercise and no hearing or vision impairments or learning disabilities; attended non-sports-focused kindergartens where physical activity primarily consisted of unstructured free play without specialized sports instruction; participated only in the program’s structured multisport activity sessions during the study and refrained from any additional off-campus organized sports programs; and had not received systematic sports instruction prior to the intervention. Only participants who maintained the weekly participation frequency required for their respective group throughout the intervention period were included in the final analysis. The participant recruitment, retention, and exclusion process across the intervention period is illustrated in Participants were classified into four groups according to their weekly frequency of participation in structured multisport activities: the low-frequency group (L; up to 1 session/week, with intermittent participation; n = 16), the medium-frequency group (M; fixed participation in 1 session/week, with occasional participation in a second session; n = 15), the medium-high-frequency group (MH; fixed participation in 2 sessions/week, with occasional participation in a third session; n = 18), and the high-frequency group (H; fixed participation in ≥ 3 sessions/week; n = 14). For children attending two or more sessions/week, at least one day was required between consecutive sessions to ensure adequate recovery. At baseline, height and weight were measured using an integrated height-and-weight measurement device, with one researcher guiding each child through the assessment and another recording the results. |
| Intervention |
Children in each group participated, at the prescribed frequencies, in a 12-week program of structured multisport activity sessions (60 minutes per session). The program adopted a circuit-based format involving a variety of gross motor tasks, a format that has also been used in structured physical activity interventions for preschool children in China and internationally (Jones et al., |
| Measurements |
Gross motor development was assessed before and after the intervention using the Test of Gross Motor Development-3 (TGMD-3). The TGMD-3 is designed for children aged 3-10 years and comprises two domains: locomotor movements (6 items: run, hop, gallop, skip, horizontal jump, and slide) and object control movements (7 items: overhand throw, underhand throw, kick a stationary ball, two hand catch, two-hand strike of a stationary ball, one hand stationary dribble, and forehand strike of self-bounced ball). For each skill, a trained examiner provided a verbal description and a visual demonstration. Each child then performed two trials, and all performances were video-recorded. Trained raters subsequently scored each trial using the process-oriented criteria specified in the TGMD-3 manual, evaluating each behavioral component as present (1) or absent (0). Scores from both trials were summed for each skill. Item scores were summed to obtain the total scores for locomotor movements and object control movements; these were then summed to yield the overall gross motor score. Before data collection, all raters received standardized scoring training. After training, the raters independently scored complete video recordings of all TGMD-3 test items performed by eight children aged 3-6 years to assess inter-rater agreement. Kendall’s coefficients of concordance (Kendall’s W) were all greater than 0.70, indicating good inter-rater reliability. To ensure scoring consistency, each participant was evaluated by the same rater across time points. As the children were identifiable during assessment, complete blinding to group allocation could not be ensured; standardized rater training and TGMD-3 scoring procedures were therefore applied to maintain scoring consistency. |
| Statistical analysis |
Data were entered in Excel 2019 and analyzed using SPSS 26.0. Data screening indicated that there were no missing values or outliers. Examination of Q-Q plots indicated that the variables were approximately normally distributed, and Levene’s test indicated that the assumption of homogeneity of variances was satisfied. To assess baseline equivalence across groups, one-way ANOVA was performed on the pre-test scores for each gross motor development outcome. A 2 (Time: pre-test vs. post-test) × 4 (Group: L / M / MH / H) mixed-design ANOVA was performed for each gross motor development outcome to examine differences associated with participation frequency. The total score of gross motor development was considered the primary outcome, whereas the domain scores and individual movement scores were treated as exploratory outcomes to provide a more detailed description of the observed changes. When a significant Time × Group interaction was identified, simple-effects comparisons were conducted to examine changes within each group and between-group differences at each time point. When a significant group main effect was identified without a significant interaction, post-hoc pairwise comparisons were conducted. The Bonferroni correction was applied to pairwise comparisons to control for Type I error. Effect sizes for baseline comparisons and for all main and interaction effects in the mixed-design ANOVA were reported as partial eta squared (η2p). According to Cohen’s guidelines, values of 0.01, 0.06, and 0.14 represent small, medium, and large effects, respectively (Cohen, |
|
|
| Baseline comparisons, pre- and post-test descriptive statistics, and ANOVA results |
| Baseline data comparison |
As shown in |
| Overall gross motor development |
The total scores (gross motor) demonstrated a significant Time × Group interaction (p < 0.01, η2p = 0.280). Within-group analyses showed significant pre- to post-test improvements in all groups (p < 0.01). Between-group analyses showed no differences at pre-test, whereas post-test scores diverged: H and MH > L (both p < 0.01) and M > L (p < 0.05) ( |
| Locomotor movements |
The total score of locomotor movements showed a significant Time × Group interaction (p < 0.01, η2p = 0.205). Within-group analyses indicated significant pre- to post-test improvements in all groups (p < 0.01) ( The horizontal jump score showed a significant Time × Group interaction (p < 0.05, η2p = 0.143). Within-group analyses indicated significant pre- to post-test improvements in all groups (p < 0.01) ( |
| Object control movements |
The total score of object control movements showed a significant Time × Group interaction (p < 0.01, η2p = 0.183). Within-group analyses indicated significant pre- to post-test improvements in all groups (p < 0.01) ( For two-hand strike of a stationary ball, a significant Time × Group interaction was observed (p < 0.05, η2p = 0.124). Within-group analyses showed significant improvements in all groups (p < 0.01) ( |
|
|
Participants in all four frequency groups showed improvements in overall gross motor development after the 12-week program. A basic premise of motor development is that children need opportunities to perform and practice movement tasks in an appropriate environment (Payne et al., Compared with the L group, the groups participating at least twice per week showed greater improvements in horizontal jump, two-hand strike of a stationary ball, and one hand stationary dribble. Similar patterns were found for the overall gross motor, locomotor, and object control total scores. Previous studies have also suggested that more frequent opportunities for physical activity or movement practice may support motor skill development in children (Lopes et al., The findings can also be understood through Newell’s constraints model, which proposes that motor development results from the interaction among the individual, the task, and the environment (Newell, Although the H group generally showed high post-test scores, no statistically significant differences were found between the MH and H groups in either total scores or individual movement outcomes. This indicates that the present study did not detect an additional advantage of the H participation pattern over the MH pattern. However, because the H group included children attending three or more sessions per week, the data do not allow conclusions about whether gains plateau beyond three sessions per week. Further studies with clearly defined higher-frequency groups and larger samples are needed to examine this question. Overall, this exploratory study examined how different weekly frequencies of participation in structured multisport activities were associated with gross motor development in preschool children. The primary outcome showed greater improvement in the more regularly participating groups than in the low-frequency group. Exploratory analyses further indicated frequency-related differences in several specific skills. These results suggest that regular participation may support gross motor development, while the detailed patterns across skill categories require further study. For practice, the findings support providing preschool children with regular opportunities to participate in structured multisport activities that include diverse movement tasks. One session per week may still provide meaningful movement experiences, while more frequent participation may be associated with greater improvements in some skills. Because the study was exploratory and did not include a non-intervention control group, specific frequency recommendations should be examined further in future studies. Limitations and future directions: First, participants were recruited from institutions offering structured multisport activities, and participant attrition resulted in a relatively small final sample. Future studies should recruit larger samples from different regions, institutions, and kindergartens to improve the generalizability of the findings. Second, although this study included only children attending non-sports-focused kindergartens, where physical activity primarily consisted of unstructured free play without specialized sports instruction, children’s actual physical activity during kindergarten hours could not be fully controlled or monitored. Differences in daily movement opportunities within kindergarten may therefore have influenced the observed between-group differences. Future studies could monitor children’s whole-day physical activity to better examine the relationship between participation in structured multisport activities and gross motor development. Third, this study lacked a non-intervention control group. Therefore, the observed between-group differences and pre- to post-test improvements cannot be fully separated from changes related to natural maturation. Future studies should include a non-intervention control group to more clearly evaluate changes associated with the activity program. Fourth, sex information was unavailable in the final analytical dataset and could not be reconstructed retrospectively. As a result, this potentially important confounding variable could not be controlled or examined in the analyses, and unequal sex distributions across groups may have influenced the observed outcomes. Future studies should ensure the collection and retention of key demographic information to allow adjustment for potential confounding factors. Fifth, participants were classified according to their actual participation frequency rather than through random assignment. Although baseline comparisons indicated no significant differences among groups before the intervention, non-random grouping may still have introduced selection bias and influenced the observed results. Future studies should employ randomized allocation procedures whenever feasible to further strengthen internal validity. Sixth, complete blinding could not be guaranteed throughout the study process, which may have influenced the study findings. Future studies should adopt more rigorous blinding procedures where possible to further reduce potential sources of bias. Finally, this study examined only one type of structured preschool activity program: structured multisport activities organized in a circuit-based format involving a variety of gross motor tasks. The findings may not apply to other types of structured activity programs. Future studies should examine other program types, such as ball games and dance activities, and further explore whether participation frequency influences locomotor and object control skills differently. |
|
|
After three months of intervention, preschool children participating in structured multisport activities showed improvements in overall gross motor development. Regular participation (once a week or more) was associated with improvement across all assessed gross motor skills. More frequent participation (at least twice per week) was associated with greater improvements in specific skills, including horizontal jump, two-hand strike of a stationary ball, and one hand stationary dribble. Although gross motor development generally tended to improve as participation frequency increased, no statistically significant additional advantage of the high-frequency group over the medium-high-frequency group was detected. These findings should be interpreted cautiously, given the absence of a non-intervention control group and the relatively limited sample size. |
| ACKNOWLEDGEMENTS |
The authors declare that financial support was received for the research and publication of this article. This study was funded by a grant from the National Social Science Foundation of China General Education Project: “Scientific Development of Body Composition and Mechanisms of Precision Exercise Promotion in Preschool Children Based on Accelerated Tracking Design” (grant number BLA220235). All experiments were performed in compliance with the applicable laws of the country where they were conducted. The authors declare no conflicts of interest. Owing to the unique nature of the study population, the data will not be made publicly available. Nevertheless, data may be obtained from the corresponding author upon reasonable request. |
| AUTHOR BIOGRAPHY |
|
| REFERENCES |
|