Functional movement is negatively associated with weight status and positively associated with physical activity in british primary school children

Michael J Duncan, Michelle Stanley, Michael J Duncan, Michelle Stanley

Abstract

Although prior studies have suggested that overweight and obesity in childhood are associated with poorer functional movement performance, no study appears to have examined this issue in a pediatric population. The relations between BMI, ambulatory physical activity and functional movement screen (FMS) performance were compared in 58, 10-11-year-old children. Total FMS score was significantly, negatively correlated with BMI (P = .0001) and positively related to PA (P = .029). Normal weight children scored significantly better for total FMS score compared to children classified as overweight/obese (P = .0001). Mean ± S.D. of FMS scores were 15.5 ± 2.2 and 10.6 ± 2.1 in normal weight and overweight/obese children, respectively. BMI and PA were also significant predictors of functional movement (P = .0001, Adjusted R(2) = .602) with BMI and PA predicting 52.9% and 7.3% of the variance in total FMS score, respectively. The results of this study highlight that ambulatory physical activity and weight status are significant predictors of functional movement in British children. Scientists and practitioners therefore need to consider interventions which develop functional movement skills alongside physical activity and weight management strategies in children in order to reduce the risks of orthopaedic abnormality arising from suboptimal movement patterns in later life.

Figures

Figure 1
Figure 1
Scattergraph illustrating the relationship between; (a) FMS score and BMI and (b) FMS score and physical activity in British children.
Figure 2
Figure 2
Mean ± S.D. of total FMS score between children classified as normal weight and overweight/obese according to IOTF criteria (*P = .0001).

References

    1. Duncan MJ, Nevill A, Woodfield L, Al-Nakeeb Y. The relationship between pedometer-determined physical activity, body mass index and lean body mass index in children. International Journal of Pediatric Obesity. 2010;5(5):445–450.
    1. Hills AP, Hennig EM, Byrne NM, Steele JR. The biomechanics of adiposity—structural and functional limitations of obesity and implications for movement. Obesity Reviews. 2002;3(1):35–43.
    1. Wearing SC, Hennig EM, Byrne NM, Steele JR, Hills AP. The biomechanics of restricted movement in adult obesity. Obesity Reviews. 2006;7(1):13–24.
    1. Nantel J, Mathieu M-E, Prince F. Physical activity and obesity: biomechancial and physiological key concepts. Journal of Obesity. 2011;2011:10 pages. Article ID 650230.
    1. Rozendal RH. Biomechanics of standing and walking. In: Bles W, Brandt T, editors. Disorders of Gait and Posture. Amsterdam, The Netherlands: Elsevier Scientific; 1986. pp. 3–18.
    1. Cole TJ, Bellizzi MC, Flegal KM, Dietz WH. Establishing a standard definition for child overweight and obesity worldwide: international survey. British Medical Journal. 2000;320(7244):1240–1243.
    1. Trost SG. Objective measurement of physical activity in youth: current issues, future directions. Exercise and Sport Sciences Reviews. 2001;29(1):32–36.
    1. Tudor-Locke C, Pangrazi RP, Corbin CB, et al. BMI-referenced standards for recommended pedometer-determined steps/day in children. Preventive Medicine. 2004;38(6):857–864.
    1. Cook G, Burton L, Hoogenboom B. Pre-participation screening: the use of fundamental movements as an assessment of function—part 1. North American Journal of Sports Physical Therapy. 2006;1:62–72.
    1. Cook G, Burton L, Hoogenboom B. Pre-participation screening: the use of fundamental movements as an assessment of function—part 2. North American Journal of Sports Physical Therapy. 2006;1:132–139.
    1. Schneiders AG, Davidsson A, Horman E, Sullivan JS. Functional Movement Screen Normative values in a young active population. International Journal of Sports Physical Therapy. 2011;6:75–82.
    1. Messier SP, Loeser RF, Mitchell MN, et al. Exercise and weight loss in obese older adults with knee osteoarthritis: a preliminary study. Journal of the American Geriatrics Society. 2000;48(9):1062–1072.
    1. Riddiford-Harland DL, Steele JR, Storlien LH. Does obesity influence foot structure in prepubescent children? International Journal of Obesity. 2000;24(5):541–544.
    1. Dowling AM, Steele JR, Baur LA. What are the effects of obesity in children on plantar pressure distributions? International Journal of Obesity. 2004;28(11):1514–1519.
    1. Zoico E, Di Francesco V, Guralnik JM, et al. Physical disability and muscular strength in relation to obesity and different body composition indexes in a sample of healthy elderly women. International Journal of Obesity. 2004;28(2):234–241.
    1. Stenholm S, Alley D, Bandinelli S, et al. The effect of obesity combined with low muscle strength on decline in mobility in older persons: results from the InCHIANTI Study. International Journal of Obesity. 2009;33(6):635–644.
    1. Burton R, Elkins K, Kiesel KB, Plisky PJ. Gender differences in functional movement screen and Y-balance test scores in middle aged school children. Medicine & Science in Sports & Exercise. 2009;41:p. 183.

Source: PubMed

Спонсоры и соавторы

Заболевания

Медикаментозные вмешательства

Подписаться