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The Effect of Fundamental Training on General and Specific Functional Movements in Female Students | ||
Sport Sciences and Health Research | ||
مقاله 8، دوره 10، شماره 1، شهریور 2018، صفحه 131-145 اصل مقاله (995.27 K) | ||
نوع مقاله: Research Paper | ||
شناسه دیجیتال (DOI): 10.22059/jsmed.2019.257959.897 | ||
نویسندگان | ||
leili mahdieh1؛ vahid zolaktaf* 2؛ Mohammad taghi Karimi3 | ||
1PHD student, Department of Sport Injury and Corrective Exercise, School of Physical Education and Sports Sciences, University of Isfahan, Isfahan, Iran | ||
2Associate Professor, Department of Sport Injury and Corrective Exercise, School of Physical Education and Sports Sciences, University of Isfahan, Isfahan, Iran | ||
3Associate Professor, School of Rehabilitation Sciences, Shiraz University of Medical Sciences, Shiraz, Iran | ||
چکیده | ||
Disability to perform functional movements is known as one of the most crucial factors of musculoskeletal injuries. This study investigated to what extent fundamental movement training of dynamic neuromuscular stabilization (DNS) could improve various functional movements. The sample consisted of 34 female students who were randomly assigned to two groups. Their age, height and weight were 18.8±0.68, 160.4±5.63 cm and 61.4±14.41 kg for the experimental group and 18.9±0.91, 160.5±3.16 cm and 61.2±12.10 kg for the control group respectively. The experimental group followed a six-week training protocol 3 sessions and 50 minutes each session. Five movement tests were used as the indicators to measure training effectiveness. ANOVA with repeated measures indicated a significant interaction of all five movement tests in favor of the experimental group (F(1,32)≥4.13, P≤0.001 and ƞ2 ≥0.29). Based on Eta-square coefficients, the highest and lowest differences in the progress coefficient were observed in Y-balance test and functional movement screening test respectively. The findings support the hypothesis that fundamental movement training can be used to improve functional movements. Lower improvement of more specific functional movements reveals that they may require not only fundamental movements but also specific training of movement. | ||
کلیدواژهها | ||
Functional movements؛ fundamental movements؛ injury؛ neuromuscular disorder؛ neuromuscular stabilization | ||
مراجع | ||
1. Patel, D.R. and T.L. Nelson, Sports injuries in adolescents. Medical Clinics, 2000. 84(4): p. 983-1007.
2. De Loes, M., Epidemiology of sports injuries in the Swiss organization. International journal of sports medicine, 1995. 16(02): p. 134-138.
3. Louw, Q.A., J. Manilall, and K.A. Grimmer, Epidemiology of knee injuries among adolescents: a systematic review. British journal of sports medicine, 2008. 42(1): p. 2-10.
4. Boden, B.P., et al., Mechanisms of anterior cruciate ligament injury. Orthopedics, 2000. 23(6): p. 573-578.
5. Cook, G., Movement: Functional Movement Systems: Screening, Assessment and Corrective Strategies. 2010, California.
6. Sahrmann, S., Diagnosis and treatment of movement impairment syndromes. 2002: Elsevier Health Sciences.
7. Santana, J.C., Functional Training. 2016: human Kinetics
8. Ageberg, E., et al., Validity and inter-rater reliability of medio-lateral knee motion observed during a single-limb mini squat. BMC musculoskeletal disorders, 2010. 11(1): p. 265.
9. Kraus, K., et al., Efficacy of the functional movement screen: a review. The Journal of Strength & Conditioning Research, 2014. 28(12): p. 3571-3584.
10. Padua, D.A., et al., Reliability of the landing error scoring system-real time, a clinical assessment tool of jump-landing biomechanics. Journal of Sport Rehabilitation, 2011. 20(2): p. 145-156.
11. Padua, D.A., et al., The Landing Error Scoring System (LESS) is a valid and reliable clinical assessment tool of jump-landing biomechanics: the JUMP-ACL study. The American journal of sports medicine, 2009. 37(10): p. 1996-2002.
12. Shaffer, S.W., et al., Y-balance test: a reliability study involving multiple raters. Military medicine, 2013. 178(11): p. 1264-1270.
13. Bardenett, S.M., et al., Functional Movement Screen normative values and validity in high school athletes: can the FMSâ„¢ be used as a predictor of injury? International journal of sports physical therapy, 2015. 10(3): p. 303.
14. Chapman, R.F., A.S. Laymon, and T. Arnold, Functional movement scores and longitudinal performance outcomes in elite track and field athletes. International Journal of Sports Physiology & Performance, 2014. 9(2).
15. Hammes, D., et al., Injury prediction in veteran football players using the Functional Movement Screenâ„¢. Journal of sports sciences, 2016. 34(14): p. 1371-1379.
16. Kiesel, K., P.J. Plisky, and M.L. Voight, Can serious injury in professional football be predicted by a preseason functional movement screen. N Am J Sports Phys Ther, 2007. 2(3): p. 147-158.
17. Letafatkar, A., et al., Relationship between functional movement screening score and history of injury. International journal of sports physical therapy, 2014. 9(1): p. 21.
18. O Connor, F.G., et al., Functional movement screening: predicting injuries in officer candidates. Med Sci Sports Exerc, 2011. 43(12): p. 2224-30.
19. Chorba, R.S., et al., Use of a Functional Movement Screening Tool to Determine Injury Risk in Female Collegiate Athletes. North American Journal of Sports Physical Therapy, 2010. 5(2): p. 47.
20. Warren, M., C.A. Smith, and N.J. Chimera, Association of the Functional Movement Screen with injuries in division I athletes. Journal of sport rehabilitation, 2015. 24(2).
21. Wieczorkowski, M.P., Functional movement screening as a predictor of injury in high school basketball athletes. 2010.
22. Bell, D.R., et al., Jump-landing mechanics after anterior cruciate ligament reconstruction: a landing error scoring system study. Journal of athletic training, 2014. 49(4): p. 435-441.
23. Chimera, N.J., C.A. Smith, and M. Warren, Injury history, sex, and performance on the functional movement screen and Y balance test. Journal of athletic training, 2015. 50(5): p. 475-485.
24. Padua, D.A., et al., The landing error scoring system as a screening tool for an anterior cruciate ligament injury–prevention program in elite-youth soccer athletes. Journal of athletic training, 2015. 50(6): p. 589-595.
25. Ugalde, V., et al., Single leg squat test and its relationship to dynamic knee valgus and injury risk screening. PM&R, 2015. 7(3): p. 229-235.
26. Frank, C., A. Kobesova, and P. Kolar, Dynamic neuromuscular stabilization & sports rehabilitation. International journal of sports physical therapy, 2013. 8(1): p. 62.
27. Kolar, P. and A. Kobesova, Postural-locomotion function in the diagnosis and treatment of movement disorders. Clinical Chiropractic, 2010. 13(1): p. 58-68.
28. Harris, B.A. and D.A. Dyrek, A model of orthopaedic dysfunction for clinical decision making in physical therapy practice. Physical therapy, 1989. 69(7): p. 548-553.
29. Rose, S.J., Description and classification—The cornerstones of pathokinesiological research. Physical therapy, 1986. 66(3): p. 379-381.
30. Yoon, H.S. and J.S.H. You, Reflex-mediated dynamic neuromuscular stabilization in stroke patients: EMG processing and ultrasound imaging. Technology and Health Care, 2017(Preprint): p. 1-8.
31. Oppelt, M., et al., A case study utilizing spinal manipulation and dynamic neuromuscular stabilization care to enhance function of a post cerebrovascular accident patient. Journal of bodywork and movement therapies, 2014. 18(1): p. 17-22.
32. Juehring, D.D. and M.R. Barber, A case study utilizing Vojta/Dynamic Neuromuscular Stabilization therapy to control symptoms of a chronic migraine sufferer. Journal of bodywork and movement therapies, 2011. 15(4): p. 538-541.
33. Bokarius, V., Long-term efficacy of dynamic neuromuscular stabilization in treatment of chronic musculoskeletal pain. Age, 2008. 18(25): p. 3.
34. Kobesova, A., et al., Effects of shoulder girdle dynamic stabilization exercise on hand muscle strength. Isokinetics and exercise Science, 2015. 23(1): p. 21-32.
35. Thomas, J.R., W. Salazar, and D.M. Landers, What is missing in p<. 05? Effect size. Research quarterly for exercise and sport, 1991. 62(3): p. 344-348.
36. Clark, M.A., NASM Essentials of Corrective Exercise Training. 2011.
37. Plisky, P.J., et al., The reliability of an instrumented device for measuring components of the star excursion balance test. North American journal of sports physical therapy: NAJSPT, 2009. 4(2): p. 92.
38. Phillips, A., Dynamic Neuromuscular Stabilization, Sport I: Review and Recap. 2012, pikeathletics.com.
39. Field, A.P., Eta and eta squared. Wiley StatsRef: Statistics Reference Online, 2005.
40. Bell, D.R., et al., Two-and 3-dimensional knee valgus are reduced after an exercise intervention in young adults with demonstrable valgus during squatting. Journal of athletic training, 2013. 48(4): p. 442-449.
41. Kiesel, K., P. Plisky, and R. Butler, Functional movement test scores improve following a standardized offâ€season intervention program in professional football players. Scandinavian journal of medicine & science in sports, 2011. 21(2): p. 287-292.
42. Wright, M.D., et al., The effectiveness of 4 weeks of fundamental movement training on functional movement screen and physiological performance in physically active children. The Journal of Strength & Conditioning Research, 2015. 29(1): p. 254-261.
43. Frost, D.M., et al., Using the Functional Movement Screenâ„¢ to evaluate the effectiveness of training. The Journal of Strength & Conditioning Research, 2012. 26(6): p. 1620-1630.
44. Elphinston, J. and S.L. Hardman, Effect of an integrated functional stability program on injury rates in an international netball squad. Journal of science and medicine in sport, 2006. 9(1): p. 169-176.
45. Oliver, J.L., R.S. Lloyd, and R.W. Meyers, Training elite child athletes: Promoting welfare and well-being. Strength & Conditioning Journal, 2011. 33(4): p. 73-79.
46. Deli, E., I. Bakle, and E. Zachopoulou, Implementing intervention movement programs for kindergarten children. Journal of Early Childhood Research, 2006. 4(1): p. 5-18. | ||
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