Visual Motor Integration

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Introduction[edit | edit source]

The concept of visual-motor integration (VMI) is complex and influenced by various factors, including visual receptive functions, visual cognitive functions, fine motor ability and the coordination of visual, cognitive and motor processess[1].

Background[edit | edit source]

The integration of visual and motor skills holds significance in the development of children. The developmental milestones for VMI commence at three months of age, marked by an infants's ability to visually track an object while lying on their back (supine position)[2]. It is closely linked to various functional abilities and the capacity to engage in daily tasks[3]. For instance, visual-motor integration plays a crucial role in the acquisition of handwriting skills[4][5]. Approximately 10% to 30% of school-aged children are estimated to encounter difficulties with handwriting[6].Various research has noted that visual-motor integration is a significant predictor of handwriting performance[1][4][7][8][9][10][11].This is especially in the early grades, as younger students often depend more on visual feedback and motor information to guide their movements when forming and replicating letters[12][13]. Beyond its impact on the development of handwriting, difficulties in visual-motor integration are likely to have repercussions on academic performance in areas such as reading and mathematics[14][15][16]. VMI also plays an indirect role in extracurricular activities, sports and recreational performance[17]. Impairments in VMI skills are diverse, leading to negative consequences on both participation and self-concept[18][19].

Clinical Presentation[edit | edit source]

There are different diagnosis that may influence the visual-motor integration:

  • Children born preterm: several reports have shown that children born preterm have poor VMI and motor function[20][21][22][23][24]
  • Children with Cerebral Palsy (CP): several studies were at a consensus that CP negatively impacts VMI skills[25][26][27][28]. There is an increased risk for having VMI deficits due to dyspraxia and motor coordination limitations[29].
  • Children with Brachial Plexus Injury: several studies were at consensus that brachial plexus injury may have a negative impact on VMI skills[28][30][31]. The extent of impairment in Brachial Plexus Injury is associated with adverse effects on physical functioning, particularly affecting tasks related to VMI[32]. There is an increased risk for having VMI deficits due to dyspraxia and motor coordination limitations[29].
  • Children and adults with Autism Spectrum Disorder (ASD): studies are at consensus that ASD negatively impacts VMI skills[28][33][34][35]. There is an increased risk for having VMI deficits due to dyspraxia and motor coordination limitations[29].
  • Children with Attention Deficit Hyperactivity Disorder (ADHD): Children with ADHD exhibited significantly lower visual-motor integration[36]

Gender[edit | edit source]

In general, gender might influence visual-motor integration skills in children; however, conclusive findings cannot be drawn at this time[37][17][38][39][40]. Notably, one study indicated that females exhibited superior VMI abilities compared to males[11], while another study suggested that males were at a higher risk for VMI deficits[41].

Age[edit | edit source]

All studies unanimously agreed that age had an impact on visual-motor integration scores[42][43][44][45][46][47].

Diagnostic Procedures[edit | edit source]

add text here relating to diagnostic tests for the condition

Diagnostic instruments[edit | edit source]

add links to outcome measures here (see Outcome Measures Database)

Therapy interventions[edit | edit source]

Early implementation of interventions targeting a child's visual-motor intergration skills is crucial. Addressing deficits in VMI skills before formal schooling begins is essential, as these deficits can impact a child's academic journey. By practicing, enhancing, or remediating these skills early on, children can cope better with school-related challenges, preventing potential delays compared to their peers[48][49]. Interventions designed to enhance the VMI skills of children should incorporate activities and exercises that engage their visual senses[15]. Tasks involving visual stimuli, such as objects, encouraged children to actively engage with what they observed[50]. This facilitates the development of Gross Motor Skills through activities involving object manipulation, as well as enhancing the VMI skills. This is because children needed to interpret their visual environment to execute appropriate motor responses while interacting with the objects[50].

  • Early interventions can improve VMI in general school populations[51]and in children born preterm[52]
  • Several studies suggest that occupational therapy intervention improves VMI skills in children with disabilities[53][54][55]
  • The utilization of visual perception exercises, whether motor-independent or motor-dependent, can serve as an effective intervention to enhance the visual-motor integration of children with ADHD[56]
  • Engaging in visual perceptual interventions positively impacted the VMI skills and performance in daily activities for children with Cerebral Palsy[25][26][27]
  • A graphomotor intervention program can significantly change children's visual-motor integration scores[57]

Differential Diagnosis
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add text here relating to the differential diagnosis of this condition

Resources
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add appropriate resources here

References[edit | edit source]

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  2. Scharf RJ, Scharf GJ, Stroustrup A. Developmental milestones. Pediatrics in Review. 2016; 37(1): 25-38
  3. Marr D, Cermak S. Predicting handwriting performance of early elementary students with the developmental test of visual-motor integration. Perceptual and Motor Skills. 2002; 95(1): 661-669
  4. 4.0 4.1 Volman MJM, van Schendel B, Jongmans MJ. Handwriting difficulties in primary school children: A search for underlying mechanisms. American Journal of Occupational Therapy. 2006; 60(4): 451-460
  5. Capellini SA, Giaconi C, Germano GD. Relation between visual motor integration and handwriting in students of elementary school. Psychology. 2017; 8(2): 258-270
  6. Karlsdottir R, Stefansson T. Problems in developing functional handwriting. Perceptual and Motor Skills. 2002; 94(2): 623-662
  7. Feder KP, Majnemer A. Handwriting development, competency, and intervention. Developmental Medicine & Child Neurology. 2007; 49(4): 312-317
  8. Taverna L, Tremolada M, Sabattini F. Drawing and Writing. Learning of Graphical Representational Systems in Early Childhood. In Proceedings of the 2nd International and Interdisciplinary Conference on Image and Imagination; Cicalo. Springer Nature: Cham, Switzerland, 2020; 216-229
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  10. Chow S, Tseng M. Perceptual-motor function of school-aged children with slow handwriting speed. The American Journal of Occupational Therapy. 2000; 54: 83-88
  11. 11.0 11.1 Coallier M, Rouleau N, Bara F, Morin M. Visual-motor skills performance on the Beery-VMI: a study of Canadian kindergarten children. The Open Journal of Occupational Therapy. 2014; 2(2): 1-10
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  13. Overvelde A, Hulstijn W. Handwriting development in grade 2 and grade 3 primary school children with normal, at risk, or dysgraphic characteristics. Research in Developmental Disabilities. 2011; 32(2): 540-548
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  20. Pereira FL, Gaspardo CM. Neonatal pain and developmental outcomes in children born preterm: An updated systematic review. Psychology & Neuroscience. 2024; 17(1):1-15
  21. Geldof CJ, van Wassenaer AG, de Kieviet JF, Kok JH, Oosterlaan J. Visual perception and visual-motor integration in very preterm and/or very low birth weight children: a meta-analysis. Research in Developmental Disabilities. 2011; 33(2): 726-36
  22. Williams J, Lee KJ, Anderson PJ. Prevalence of motor-skill impairment in preterm children who do not develop cerebral palsy: a systematic review. Developmental Medicine & Child Neurology. 2009; 52(3): 232-7
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  56. Sherejini NA, Molanorouzi K, Vakili S. Comparison of the Effect of Motor Independent/Dependent Visual Perception Practice on Visual-Motor Activity Disorder. Journal of Medical Council. 2023; 41(2): 152-159
  57. Taverna L, Tremolada M, Tosetto B, Dozza L, Renata ZS. Impact of Psycho-Educational Activities on Visual-Motor Integration, Fine Motor Skills and Name Writing among First Graders: A Kinematic Pilot Study. Children. 2020; 7(4): 27
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