Cognitive Development and Neurodevelopment

Motor Skills and Cognitive Development in Children

Sensorimotor Variability Influences Early Cognition in Toddlers with Autism
Published: September 21, 2024 · Last reviewed:
📖1,719 words⏱7 min read📚5 references cited

For a long time motor development and cognitive development were treated as parallel but mostly independent strands of children’s growth: motor skills tracked through pediatric milestones, cognitive skills tracked through psychometric assessments, and the two domains analyzed by separate researchers using separate frameworks. The past two decades of research have made that separation untenable. Motor skill proficiency, executive function, and cognitive development emerge together, share neural substrates, and predict each other across the early years of childhood. The empirical literature now consistently treats motor and cognitive development as components of an integrated system, with implications for how children should be assessed, supported, and educated.

Two recent meta-analytic and contributory studies have consolidated the case. Bao, Wade, Leahy, and Owen (2024), in Sports Medicine, meta-analyzed the relationship between motor competence and executive functions across childhood and adolescence and reported substantial cross-domain associations supported by shared cortical and subcortical neurobiology. Capio, Mendoza, Jones, and Masters (2024), in Scientific Reports, examined the contributions of motor skill proficiency to cognitive and social development in early childhood and identified specific motor skills (object control, balance, locomotor) that drive different cognitive and social outcomes. Together with longitudinal research like Adolph and colleagues’ work on infant locomotor learning and Iverson’s (2010) motor-language coupling research, these studies establish that motor and cognitive development are not parallel — they are interleaved processes that mutually scaffold one another.

Why motor and cognitive development are linked

The neurobiological case is the simplest entry point. The cerebellum, the prefrontal cortex, the basal ganglia, and the parietal regions all participate in both motor control and cognitive function. Movement learning recruits the same brain networks that support attention, working memory, and inhibitory control. When a child practices a complex motor skill — coordinating fine motor sequences in a Lego construction, learning the rhythm of skipping, threading beads onto a string — they are also practicing cognitive control, sustained attention, and goal maintenance. The motor task is the surface; the underlying cognitive infrastructure is being trained simultaneously.

Bao and colleagues (2024) reviewed this neurobiological evidence alongside the behavioral correlations, noting that improvements in motor competence often co-occur with improvements in executive function. The relationship is bidirectional: better motor skill supports better executive function (presumably through shared neural development), and better executive function supports faster motor learning (presumably through more efficient practice and attention to feedback). The implication is that motor skill assessment is not just a measure of physical competence; it is also a window onto cognitive development.

Iverson’s (2010) work on motor-language coupling in infants illustrates the same principle at an earlier developmental stage. The acquisition of independent sitting, reaching, and crawling each precedes language milestones in characteristic ways: babies who reach a motor milestone are subsequently more likely to reach a language milestone in the months following. The two developmental trajectories are not independent. Motor advances reorganize the infant’s perceptual and learning environment — a sitting baby sees the world differently from a lying baby, a crawler explores objects differently from a sitter — and the cognitive consequences are real.

What motor skills predict

Capio and colleagues (2024) examined which specific motor skills contribute to which specific cognitive and social outcomes in early childhood, using a large sample of preschool-aged children. The differentiated findings:

  • Object control skills (catching, throwing, kicking with intent) showed the strongest associations with executive function — particularly inhibitory control and working memory. These skills involve goal-directed prediction and timing under uncertainty, which recruits the same cognitive resources that classical EF tasks measure.
  • Locomotor skills (running, jumping, hopping) showed broader but more diffuse associations across executive function and social outcomes, consistent with the general physical-activity literature on cognition.
  • Balance and stability showed associations with attention regulation, particularly the kind of postural attention that supports academic seat-work in classrooms.

The differentiated pattern matters because it argues against a single “motor-cognitive correlation” story. Different motor skill clusters tap different cognitive substrates, and intervention design that targets specific motor skills is more defensible than generic “more physical activity” prescriptions when specific cognitive targets are the goal.

Diamond (2011), in Science, made a closely related point at the intervention level. Reviewing the evidence on what works to improve executive function development in children, she identified specific intervention modalities — including martial arts, yoga, and traditional games requiring rule-based motor coordination — that produce measurable cognitive gains. The unifying principle: interventions that combine motor demand with cognitive demand outperform interventions that target either domain alone.

Atypical development and motor variability

The motor-cognitive link has particular relevance for understanding atypical development. Denisova and Wolpert (2024), in iScience, examined sensorimotor variability in over 1,000 toddlers with autism spectrum disorder and found that the pattern of variability tracked cognitive ability levels. Higher-IQ toddlers with ASD showed sensorimotor patterns similar to typically developing children, while lower-IQ toddlers exhibited significantly altered sensorimotor functions.

The finding has two substantive implications. First, sensorimotor variability is not a uniform feature of autism — it varies systematically with cognitive ability, suggesting that motor and cognitive subdomains share underlying mechanisms that are differentially affected across the ASD population. Second, sensorimotor measures may be useful as early markers of cognitive risk in ASD, potentially supplementing or complementing the standard cognitive assessments that are typically administered later in development.

The same logic applies more broadly to atypical development. Children with developmental coordination disorder show elevated rates of executive-function difficulty; children with ADHD show motor-coordination differences; children born prematurely show coupled motor and cognitive trajectories. The motor and cognitive systems develop together, and disruptions in one tend to manifest in the other.

Implications for parents and educators

The practical implications distill to three points:

  • Motor skill development is cognitive development. Time spent in deliberate motor practice — building, sport, dance, instrument playing — is also time spent in cognitive practice. The dichotomy between “physical” and “intellectual” activities for children does not match how children’s brains develop.
  • Specificity matters. Different motor skills support different cognitive abilities. Object-control activities (catch, throw, target sports) appear particularly potent for executive function development; balance and proprioception activities support attention regulation; rhythm and bilateral coordination support working memory and language. Diversified motor exposure broadens the cognitive scaffolding.
  • Motor delays warrant cognitive attention. A child showing significant motor coordination difficulties is more likely to show executive-function or attention difficulties than a typically-developing peer. Comprehensive assessment should include both domains rather than treating them as separate referral pathways.

For early-childhood education contexts, the research argues for embedding cognitive challenge into motor activities and motor demand into cognitive activities. Children at the early ages of learning are particularly responsive to integrated motor-cognitive curricula, with documented gains across both domains relative to single-domain curricula.

What remains contested

The motor-cognitive link is empirically well-established, but causal direction and intervention efficacy continue to attract methodological debate. Cross-sectional and longitudinal correlations cannot fully distinguish whether motor skills cause cognitive development, whether shared neurobiology produces the correlation without direct causation, or whether environmental factors that promote both domains drive the association. Randomized controlled trials of motor interventions on cognitive outcomes have yielded mixed results, with effect sizes typically smaller in RCTs than in observational studies — a pattern common in cognitive intervention research.

The honest reading is that motor experience is one input among several to cognitive development, and that integrated motor-cognitive activities are more likely to produce measurable cognitive gains than either domain alone. Strong claims about specific motor regimens producing specific cognitive benefits should be discounted; the substantive case is the broader integration story rather than a recipe for cognitive enhancement through motor training.

Frequently Asked Questions

Does physical activity make children smarter?

The honest answer is “it can, modestly, when combined with cognitive demand”. Physical activity that engages both motor and cognitive systems — coordinated sports, martial arts, dance with sequence learning — is more strongly associated with cognitive gains than purely aerobic activity alone (Diamond, 2011; Bao et al., 2024). The effect sizes are real but modest; physical activity is a useful component of cognitive development rather than a single-lever solution.

Are motor and cognitive development really linked, or is the correlation due to other factors?

Both. The neurobiological substrate for motor and executive function overlaps substantially (cerebellum, prefrontal cortex, basal ganglia), which produces a genuine link. Family socioeconomic factors, home environment, and parental investment also independently support both domains. The two effects are difficult to fully disentangle in non-experimental research, but the link is robust across study designs.

What does it mean if my child has motor coordination difficulties?

It is more likely than not that some executive-function or attention demand is also affected, even if the cognitive symptoms are subtle. Children with documented motor coordination disorder show elevated rates of executive-function difficulty, and comprehensive assessment is warranted. The motor difficulty itself is not a cause for alarm in isolation; the cognitive co-occurrence is what makes broader assessment useful.

Are motor differences in autism a sign of cognitive differences?

Denisova and Wolpert (2024) found that sensorimotor variability tracks cognitive ability in toddlers with ASD: higher-IQ ASD toddlers show motor patterns more similar to typically developing peers, while lower-IQ ASD toddlers show distinctive motor differences. This suggests motor and cognitive subdomains are coupled in ASD rather than independent, and motor measurements may be useful as early indicators of cognitive trajectory.

Should I prioritize motor or cognitive activities for my child?

The framing is wrong. Children’s brains develop through integrated motor-cognitive experience, and prioritizing one domain over the other misses the point that they develop together. Diversified, deliberately challenging activities that demand both motor and cognitive engagement — building, music, sport with strategy, dance with sequence learning — support both domains better than activities that target either alone.

References

  • Bao, R., Wade, L., Leahy, A. A., & Owen, K. B. (2024). Associations between motor competence and executive functions in children and adolescents: A systematic review and meta-analysis. Sports Medicine. https://doi.org/10.1007/s40279-024-02040-1
  • Capio, C. M., Mendoza, N. B., Jones, R. A., & Masters, R. S. W. (2024). The contributions of motor skill proficiency to cognitive and social development in early childhood. Scientific Reports. https://doi.org/10.1038/s41598-024-79538-1
  • Denisova, K., & Wolpert, D. M. (2024). Sensorimotor variability distinguishes early features of cognition in toddlers with autism. iScience, 27(9), 110685. https://doi.org/10.1016/j.isci.2024.110685
  • Diamond, A. (2011). Interventions shown to aid executive function development in children. Science, 333(6045), 959–964. https://doi.org/10.1126/science.1204529
  • Iverson, J. M. (2010). Developing language in a developing body: The relationship between motor development and language development. Journal of Child Language, 37(2), 229–261. https://doi.org/10.1017/S0305000909990432

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Why motor and cognitive development are linked?

The neurobiological case is the simplest entry point. The cerebellum, the prefrontal cortex, the basal ganglia, and the parietal regions all participate in both motor control and cognitive function. Movement learning recruits the same brain networks that support attention, working memory, and inhibitory control. When a child practices a complex motor skill — coordinating fine motor sequences in a Lego construction, learning the rhythm of skipping, threading beads onto a string — they are also practicing cognitive control, sustained attention, and goal maintenance. The motor task is the surface; the underlying cognitive infrastructure is being trained simultaneously.

What motor skills predict?

Capio and colleagues (2024) examined which specific motor skills contribute to which specific cognitive and social outcomes in early childhood, using a large sample of preschool-aged children. The differentiated findings: The differentiated pattern matters because it argues against a single "motor-cognitive correlation" story. Different motor skill clusters tap different cognitive substrates, and intervention design that targets specific motor skills is more defensible than generic "more physical activity" prescriptions when specific cognitive targets are the goal.

📋 Cite This Article

Sharma, P. (2024, September 21). Motor Skills and Cognitive Development in Children. PsychoLogic. https://www.psychologic.online/motor-skills-cognition/

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