Motor Behavior

The Effects of a Training Course with an Emphasis on Fine Motor Skills on Executive Functions of Children with Learning Disorder

Document Type : Research Paper

Authors

Shila Safavi 1
Nada Ghazinoor 2
Ahmad Abadi 3

1 Assistant Professor of Motor Behavior, University of Isfahan

2 M.Sc. of Motor Behavior, University of Isfahan

3 Associate Professor of Children with Special Needs, University of Isfahan

https://doi.org/10.22089/mbj.2018.3235.1396
Abstract
The purpose of the present study was to investigate the effect of 12 weeks of fine motor skills training on executive functions including working memory, problem solving,and inhibition control of 6-10 year old students with learning disorders. 30 students were randomly selected from a learning disorder center and were assigned into either a control (n=15) or experiment group (n=15) based on gender and academic grades. Intervention involved practicing of fine motor skills with emphasis on visual-motor coordination and visual-spatial integration skills based on Rini and Werner (1976) exercise package for 12 weeks, 24 one hour long sessions. London Tower, Digit Span subscale of Wechsler Intelligence Scale, and Stroop task software were used for collecting the data at pretest and posttest. Covariance analysis was used for comparing mean differences between groups. Results showed that practicing fine motor skills resulted in a significant improvement of all executive functions subscales including working memory, problem solving, and inhibition control of the participants of the experimental group. The findings indicate that requiring primary school children with learning disorder to exercise fine motor skills improves their executive functions.

Keywords

Learning Disorder
Fine Motor Skills‚ Executive Function
Children

Subjects

  1. Hallahan P. Basic concepts. Learning disabilities : Foundations, Characteristics, and Effective teaching. Alizadeh H .5.Tehran: Arasbaran؛ 2011.245.(In Persian).
  2. Seidman L J. Neuropsychological functioningin people with ADHD across the lifespan. J Clin Psychol. 2006;26:466-85.
  3. Kirk S A, Gallagher J J, Anastasiow N J & Coleman M R. Educating exceptional children. Boston: Houghton Mifflin; 2006.
  4. Hughes C, Graham A. Measuring executive functions in childhood: Problems and solutions? Child Adol Psychol Cl. 2002;7(3):131-42.
  5. Zelazo P D, Muller U, Marcovitch S, Argitis G R ‚Sultherland A. The development of Executive Functions in early chidhood. J Learn Disabil. 2002;36(3):230-46.
  6. Diamond A. Executive functions. Annual review of psychology. 2013;64:135-68.
  7. Blair C, Zelazo P D, Greenberg M T. The measurement of executive function in early childhood. Dev Neuropsychol. 2005;28(2):561-71.
  8. Denckla M B. ADHD: Topic update. J Brain Res. 2003;25(2):383-9.
  9. Lehto JE JP, Kooistra L, Pulkkinen L. Dimensions of executive functioning: evidence from children. Devl Psychol. 2003;21:59-80.
  10. Dawson P, Guare R. Executive skills in children and adolescents. A practical guide to assessment and intervention. New York: Guilford Press; 2004.
  11. Avila C, Parcet M A. Personality and inhibitory deficits in the stop-signal task: The mediating role of Gray’s anxiety and impulsivity. Pers and Indiv Differ. 2001;31(6):975-86.
  12. Sternberg R J, Sternberg K. Cognitive psychology: Nelson Education; 2015.
  13. Kirk S, Gallagher J J, Coleman M R, Anastasiow N J. Educating exceptional children: Cengage Learning; 2011.
  14. Ridler K, Veijola J M, Tanskanen P, Miettunen J, Chitnis X, Suckling J, et al. Fronto-cerebellar systems are associated with infant motor and adult executive functions in healthy adults but not in schizophrenia. P Nati Acad Sci. 2006;103(42):15651-6.
  15. Piek J P, Dawson L, Smith LM, Gasson N. The role of early fine and gross motor development on later motor and cognitive ability. Hum Movement Sci. 2008;27(5):668-81.
  16. Murray G, Veijola J, Moilanen K, Miettunen J, Glahn D C, Cannon T, et al. Infant motor development is associated with adult cognitive categorisation in a longitudinal birth cohort study. J Child Psychol Psych. 2006;47(1):25-9.
  17. Burns Y, O'Callaghan M, Mcdonell B, Rogers Y. Movement and motor development in ELBW infants at 1 year is related to cognitive and motor abilities at 4 years. Early Hum Dev. 2004;80(1):19-29.
  18. Bushnell E W, Boudreau J P. Motor development and the mind: The potential role of motor abilities as a determinant of aspects of perceptual development. Child dev. 1993;64(4):1005-21.
  19. Son S H, Meisels S J. The relationship of young children's motor skills to later school achievement. Merrill-Palmer Quart. 2006;52(4):755-78.
  20. Viholainen H, Ahonen T, Lyytinen P, Cantell M, LicSSc A T, Lyytinen H. Early motor development and later language and reading skills in children at risk of familial dyslexia. Dev Med Child Neurol. 2006;48(5):367-73.
  21. Westendorp M, Hartman E, Houwen S, Smith J, Visscher C. Specific associations between gross motor skills and executive functioning in children with learning disorders: a longitudinal study. Movement and Cognition.Phd Thesis.University Medical Center Groning.Netherland. 2014:59.
  22. Stöckel T, Hughes C M. The relation between measures of cognitive and motor functioning in 5-to 6-year-old children. Psychol Rev. 2015:1-12.
  23. Rigoli D, Piek J P, Kane R, Oosterlaan J. An examination of the relationship between motor coordination and executive functions in adolescents. Dev Med Child Neurol. 2012;54(11):1025-31.
  24. Rigoli D, Piek J P, Kane R, Whillier A, Baxter C, Wilson P. An 18-month follow-up investigation of motor coordination and working memory in primary school children. Hum Movement Sci. 2013;32(5):1116-26.
  25. Ploughman M. Exercise is brain food: the effects of physical activity on cognitive function. J Neurorl Rehabil. 2008;11(3):236-40.
  26. Tomporowski P D, Davis C L, Miller P H, Naglieri J A. Exercise and children’s intelligence, cognition, and academic achievement. Edu Psychol Rev. 2008;20(2):111-31.
  27. Hillman C H, Castelli D M, Buck S M. Aerobic fitness and neurocognitive function in healthy preadolescent children. Med Sci sports Exer. 2005;37(11):1967.
  28. Lakes K D, Hoyt W T. Promoting self-regulation through school-based martial arts training. J Appl Devl Psychol. 2004;25(3):283-302.
  29. Scudder M R, Lambourne K, Drollette E S, Herrmann S, Washburn R, Donnelly J E, et al. Aerobic capacity and cognitive control in elementary school-age children. Med Sci Sports Exercise. 2014;46(5):1025.
  30. Sibley B A, Etnier J L. The relationship between physical activity and cognition in children: a meta-analysis. Pediatr Exerc Sci. 2003;15(3):243-56.
  31. Coe D P, Pivarnik J M, Womack C J, Reeves M J, Malina R M. Effect of physical education and activity levels on academic achievement in children. Med Sci sports Exer. 2006;38(8):1515.
  32. Alexander R, Hay J A, Liu J, Faught B E, Engemann J, Cairney J. The influence of aerobic fitness on the relationship between academic performance and motor proficiency. J Public Heal. 2015;3(4):145-52.
  33. Wolff P H, Gunnoe C, Cohen C. Neuromotor maturation and psychological performance: a developmental study. Dev Med Child Neurol. 1985;27(3):344-54.
  34. Luo Z, Jose P E, Huntsinger C S, Pigott T D. Fine motor skills and mathematics achievement in East Asian American and European American kindergartners and first graders. Brit J Dev Psychol. 2007;25(4):595-614.
  35. Grissmer D, Grimm K J, Aiyer S M, Murrah W M, Steele J S. Fine motor skills and early comprehension of the world: two new school readiness indicators. Devl Psychol. 2010;46(5):1008.
  36. Carlson A G. Kindergarten fine motor skills and executive function: Two non-academic predictors of academic achievement.Phd Thesis: George Mason University; 2013.
  37. Westendorp M, Houwen S, Hartman E, Mombarg R, Smith J, Visscher C. Effect of a ball skill intervention on children’s ball skills and cognitive functions. Med Sci Sport Exer. 2014;46(2):414-22.
  38. Hajiloo N, Rezaei Sharif A. Psychometric properties of Colorado Learning Difficulties Questionnaire (CLDQ). J Learn Disabi. 2011;1(1):24-43. (In Persian).
  39. Khodadadi M, Mashhadi A, Amman H. Stroop test software. Tehran: Sina Research Institute of Behavioral Sciences. 2009.
  40. MacLeod CM. Half a century of research on the Stroop effect: an integrative review. Psychol Bull. 1991;109(2):163.
  41. 41.  Lezak M D. Neuropsychological assessment.15: USA: Oxford University Press; 2004.
  42. Khodadadi M, Mashadi A, Amani H. Stroop task software. 2014. Sina Cognitive Behavioral studies science Institue. (In Persian).
  43. Abedi M R, Sadeghi A, Rabeei M. Normalization of Wechsler Intelligence scale for children Fourth edition. Pers Indiv Differ. 2013;2(3):138-58. (In Persian).
  44. Rini L, Werner PH. Perceptual-motor development equipment: inexpensive ideas and activities: New York: Wiley; 1976.
  45. Dehghani M, Taghipour-Javan A, Hasan- Nataj-Jelodar F, Zeid Abadi F. The effectiveness of rhythmic movement games (weighted) on the rate of executive function in children with neuropsychological learning disabilities. J Learn Disabil. 2012;2(1):33-77. (In Persian).
  46. Garoosi-Farshi M, Ashayeri H, Moghimi A, Ghanaei-Chaman Abad A. The effect of rhythmic movement exercises on the function of visual memory in children with special learning disabilitie. Studies in Education Psychology. 2009;2:149-66.              (In Persian)
  47. Baddeley A D. Developments in the concept of working memor. Neuropsychology. 1994;8:485-93.
  48. Smith E E. Storage and executive processes in the frontal lobes. Science. 1999;283:1657-61
  49. Livesey D, Keen J, Rouse J, White F. The relationship between measures of executive function, motor performance and externalising behaviour in 5-and 6-year-old children. Hum Movement Sci. 2006;25(1):50-64.
  50. Roebers C M, Kauer M. Motor and cognitive control in a normative sample of 7‐year‐olds. Developmental Science. 2009;12(1):175-81.
  51. Diamond A. Close interrelation of motor development and cognitive development
  52. and of the cerebellum and prefrontal cortex.Child Dev. 2000;71:44-56.
  53. Willingham D B. The neural basis of motor-skill learning. Curr Dir Psychol Sci. 1999;8(6):178-82.
  54. kargar shoraki G.Study of Effectiveness of Instruction of Fine Motor Skills on Mathematics Concepts Learning in Pupils Having Mathematics Learning Disabilities in Third to Fifth Grades in Meybod City. Quarterly Journal of Education leadership.2010;3:105-26
  55. Colcombe S, Kramer A F. Fitness effects on the cognitive function of older adults a meta-analytic study. PsycholSci. 2003;14(2):125-30.
  56. Timinkul A, Kato M, Omori T, Deocaris CC, Ito A, Kizuka T, et al. Enhancing effect of cerebral blood volume by mild exercise in healthy young men: a near-infrared spectroscopy study. Neurosci Res. 2008;61(3):242-8.
  57. Jorgensen LG, Perko G, Secher N H. Regional cerebral artery mean flow velocity and blood flow during dynamic exercise in humans. J Appl Physiol. 1992;73(5):1825-30.
  58. Suzuki M, Miyai I, Ono T, Oda I, Konishi I, Kochiyama T, et al. Prefrontal and premotor cortices are involved in adapting walking and running speed on the treadmill: an optical imaging study. Neuroimage. 2004;23(3):1020-6.
  59. Barenberg J, Berse T, Dutke S. Executive functions in learning processes: do they benefit from physical activity? Educ Res. 2011;6(3):208-22.
  60. Budde H, Voelcker-Rehage C, Pietraßyk-Kendziorra S, Ribeiro P, Tidow G. Acute coordinative exercise improves attentional performance in adolescents. Neurosci Lett. 2008;441(2):219-23.
  61. Lakes K D, Hoyt W T.Promoting self-regulation through school-based martial art training.J Appl Dev Psychol. 2004;25:283-302.
Motor Behavior
Volume 9, Issue 30
Winter 2018
February 2018
Pages 37-56

  • Receive Date 26 October 2016
  • Revise Date 18 January 2017
  • Accept Date 06 February 2017

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