Development of Circuit-Based Games According to Fundamental Motor Skill Activities for Dyspraxia Children

Ramadhan, N.; Nurhasan, N.; Indahwati, N.; Baqiyudin, G.; Saifuddin, H.; Mustaqim, S.; Perdanawati, F.

doi:10.58209/hehp.11.3.471

All

Webpages

Books

Journals

Tarbiat Modares University Press

Health Education and Health Promotion

Volume 11, Issue 3 (2023) Health Educ Health Promot 2023, 11(3): 471-476 | Back to browse issues page

‎ 10.58209/hehp.11.3.471

Mendeley

Zotero

RefWorks

Ramadhan N, Nurhasan N, Indahwati N, Baqiyudin G, Saifuddin H, Mustaqim S et al . Development of Circuit-Based Games According to Fundamental Motor Skill Activities for Dyspraxia Children. Health Educ Health Promot 2023; 11 (3) :471-476
URL: http://hehp.modares.ac.ir/article-5-71082-en.html

Development of Circuit-Based Games According to Fundamental Motor Skill Activities for Dyspraxia Children

N. Ramadhan¹, N. Nurhasan ^*¹, N. Indahwati¹, G. Baqiyudin¹, H. Saifuddin², S. Mustaqim³, F. Perdanawati²

1- Department of Sport and Health Sciences, Postgraduate School of Sport Science, State University Negeri Surabaya, Surabaya, Indonesia
2- Department of Physical Education, Sport, Health and Recreation, Faculty of Educational Sciences, University Nahdlatul Ulama Sunan Giri, Bojonegoro, Indonesia
3- Department of Tarbiyah Education, College of Science Tarbiyah Nahdlatul Ulama, Mojokerto, East Java, Indonesia

Abstract: (579 Views)

Aims: This study aimed to develop fundamental motor skill activities based on game circuits that aim to improve the motor skills of children with dyspraxia.
Instrument & Methods: This research involved instrument development, initial revision, and field trials. Instruments in-game circuits were designed with various motor challenges specifically designed to facilitate the development of basic motor skills. In the initial trial phase, activities were implemented with the participation of several children with dyspraxia. Then, instruments and activities were adjusted based on feedback and findings from the initial trials. Field trials were conducted through the participation of larger groups of children with dyspraxia to evaluate the effectiveness and efficiency of the activities developed.
Findings: The development of fundamental motor skill activity based on the game circuit has a CVR value of 0.5, greater than the threshold limit of 0.62. Hence, it had good content validity in measuring the desired construct. The correlation calculation results showed a positive and significant relationship between the scores of assessors 1, 2, and 3 with a total score of assessors on aspects of movement skills, cognitive aspects, fun aspects, and attention focus. The ICC test results showed the instrument's reliability.
Conclusion: Developing fundamental motor skill activities through the game circuit approach can effectively improve the motor skills of children with dyspraxia.

Keywords: Activity Fundamentals [MeSH], Circuit Games [MeSH], Motor Skills [MeSH], Children's Dyspraxia [MeSH]

Full-Text [PDF 590 kb] (571 Downloads) | | Full-Text (HTML) (258 Views)

Article Type: Descriptive & Survey | Subject: Health Education and Health Behavior
Received: 2023/08/1 | Accepted: 2023/09/14 | Published: 2023/10/18

* Corresponding Author Address: Jalan Lidah Wetan, Kec. Lakarsantri, Surabaya, East Java, Indonesia. Postal Code: 60213 (nurhasan007@unesa.ac.id)

References

1. Ningsih RW, Suyanto S, Fahmi F. A development of number circuit game based learning strategy to introduce numeral symbols for children aged 4-5 years. Mitra Ash-Shibyan J. Pendidik. Dan Konseling. 2021;4(1):47-58. [Link] [DOI:10.46963/mash.v4i01.231]

2. Mylsidayu A, Tangkudung J, Hanif AS. Effectiveness of physical activity circuit model on endurance of elementary school students. Dordrecht: Atlantis Press; 2020. [Link] [DOI:10.2991/assehr.k.200824.048]

3. Astuti Y, Bakhtiar S, Barlian E, Gistituati N. Development of mental training and playing circuit-based training programs on volleyball materials. J. High. Educ. Theory Pract. 2022;22(12):244. [Link]

4. Endrawan IB, Aliriad H. Problem-based collaborative learning model improves physical education learning outcomes for elementary school students. 2023;11(1):9-17. [Link]

5. Khasanah I, Sutapa P. Development of teaching model through circuit game to increasing children's gross motor ability. Dordrecht: Atlantis Press; 2018. pp. 138-146. [Link] [DOI:10.2991/secret-18.2018.22]

6. Bakhtiar S. Fundamental motor skill among 6-year-old children in Padang, West Sumatera, Indonesia. Asian Soc. Sci. 2014;10(5):155-8. [Link] [DOI:10.5539/ass.v10n5p155]

7. Endrawan IB, Aliriad H, Apriyanto R, Da'I M, Adi S, Cahyani OD, et al. The relationship between sports and mental health: literature analysis and empirical study. Heal Educ Heal Promot. 2023;11(2);1001-11. [Link]

8. Edmonds C. Why teachers need to hear the voice and experience of the child with dyspraxia. Res Teach Educ. 2013;3(1):5-10. [Link]

9. Waber DP, Boiselle EC, Yakut AD, Peek CP, Strand KE, Bernstein JH. Developmental dyspraxia in children with learning disorders: Four-year experience in a referred sample. J Child Neurol. 2021;36(3):210-21. [Link] [DOI:10.1177/0883073820966913]

10. Pedro A, Goldschmidt T, Daniels L. Parent-carer awareness and understanding of dyspraxia: Implications for child development support practices. J Psychol Africa. 2019;29(1):87-91. [Link] [DOI:10.1080/14330237.2019.1568092]

11. Carballo‐Fazanes A, Díaz‐Pereira MP, Fernández‐Villarino MA, Abelairas‐Gómez C, Rey E. Physical activity in kindergarten, fundamental movement skills, and screen time in Spanish preschool children. Psychol Sch. 2023;60(9):3318-28. [Link] [DOI:10.1002/pits.22925]

12. Jariono G, Yunita P, Gontara SY, Nugroho H, Maslikah U. Strategies to improve children's motor skills with special needs through circuit method based inclusion education. Kinestetik J Ilm. Pendidik. Jasm. 2023;7(2):434-40. [Link] [DOI:10.33369/jk.v7i2.27485]

13. Murray E, McCabe P, Ballard KJ. A randomized controlled trial for children with childhood apraxia of speech comparing rapid syllable transition treatment and the Nuffield Dyspraxia Programme-Third edition. J Speech Lang Hear Res. 2015;58(3):669-86. [Link] [DOI:10.1044/2015_JSLHR-S-13-0179]

14. Avila-Pesantez D, Vaca-Cardenas L, Rivera LA, Zuniga L, Avila LM. Athynos: Helping children with dyspraxia through an augmented reality serious game. 2018 International Conference on eDemocracy & eGovernment (ICEDEG); 2018 Apr 14-16; IEEE Xplor. p. 286-90. [Link] [DOI:10.1109/ICEDEG.2018.8372351]

15. Bodison SC. Developmental dyspraxia and the play skills of children with autism. Am J Occup Ther. 2015;69(5):6905185060. [Link] [DOI:10.5014/ajot.2015.017954]

16. van der Fels IMJ, Hartman E, Bosker RJ, de Greeff JW, de Bruijn AGM, Meijer A, et al. Effects of aerobic exercise and cognitively engaging exercise on cardiorespiratory fitness and motor skills in primary school children: A cluster randomized controlled trial. J Sports Sci. 2020;38(17):1975-83. [Link] [DOI:10.1080/02640414.2020.1765464]

17. Kareem J. Effectiveness of activity based program in enhancing fine motor skills of children with dyspraxia. Sch Int J Multidiscip Allied Stud. 2015;5(2). [Link]

18. Miller M, Chukoskie L, Zinni M, Townsend J, Trauner D. Dyspraxia, motor function and visual-motor integration in autism. Behav Brain Res. 2014;269:95-102. [Link] [DOI:10.1016/j.bbr.2014.04.011]

19. Kesumawati SA, Fakhruddin, Fahritsani H. Learning model of fundamental movement skills (FMS) for children with mild intellectual disability. Int J Hum Mov Sport Sci. 2021;9(1):71-80. [Link] [DOI:10.13189/saj.2021.090110]

20. Satria MH, Aliriad H, Kesumawati SA, Fahritsani H, Endrawan IB, Adi S. Model pengembangan keterampilan motorik my home environment terhadap anak disabilitas intelektual. J Obs J Pendidik Anak Usia Dini. 2023;7(2):2336-47. [Link] [DOI:10.31004/obsesi.v7i2.4415]

21. Menescardi C, Villarrasa-Sapiña I, Lander N, Estevan I. Canadian agility movement skill assessment (CAMSA) in a Spanish context: evidences of reliability and validity. Meas Phys Educ Exerc Sci. 2022;26(3):245-255. [Link] [DOI:10.1080/1091367X.2021.2020794]

22. Castaño PRL, Suárez DPM, González ER, Robledo-Castro C, Hederich-Martínez C, Cadena HPG, et al. Effects of physical exercise on gross motor skills in children with autism spectrum disorder. J Autism Dev Disord. 2023; pp. 1-10, 2023. [Link] [DOI:10.1007/s10803-023-06031-5]

23. Masteller B. Feasibiity and efficacy of a movement-training program on physical fitness, fundamental movement skills, and physical activity in third and fourth grade students. Massachusetts: University of Massachusetts Amherst; 2018. [Link]

24. Hill P. Evaluating the developmental trajectories of fundamental movement skills across late childhood and adolescence. Swansea: Swansea University; 2022. [Link]

25. Spies TG, Lyons C, Huerta M, Garza T, Reding C. Beyond professional development: factors influencing early childhood educators' beliefs and practices working with dual language learners. Catesol J. 2017;29(1):23-50. [Link]

26. Sameroff AJ, Seifer R, Baldwin A, Baldwin C. Stability of intelligence from preschool to adolescence: The influence of social and family risk factors. Child Dev. 1993;64(1):80-97. [Link] [DOI:10.2307/1131438]

27. Collins WA, Maccoby EE, Steinberg L, Hetherington EM, Bornstein MH. Contemporary research on parenting: The case for nature and nurture. Am Psychol. 2000;55(2):218-32. [Link] [DOI:10.1037/0003-066X.55.2.218]

Rights and permissions
	This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.