No Access

EFFECTS OF FOOTWEAR VARIATIONS ON THREE-DIMENSIONAL KINEMATICS AND TIBIAL ACCELERATIONS OF SPECIFIC MOVEMENTS IN AMERICAN FOOTBALL

Division of Sport Exercise and Nutritional Sciences, School of Sport Tourism and Outdoors, University of Central Lancashire, Preston, Lancashire PR1 2HE, UK

E-mail Address: jksinclair@uclan.ac.uk

Corresponding author.

Search for more papers by this author

E ROONEY

Division of Sport Exercise and Nutritional Sciences, School of Sport Tourism and Outdoors, University of Central Lancashire, Preston, Lancashire PR1 2HE, UK

Search for more papers by this author

R NAEMI

Faculty of Health Sciences, Staffordshire University, College Road, Stoke-on-Trent, Staffordshire ST4 2DE, UK

Search for more papers by this author

S ATKINS

Division of Sport Exercise and Nutritional Sciences, School of Sport Tourism and Outdoors, University of Central Lancashire, Preston, Lancashire PR1 2HE, UK

Search for more papers by this author

, and

N CHOCKALINGAM

Faculty of Health Sciences, Staffordshire University, College Road, Stoke-on-Trent, Staffordshire ST4 2DE, UK

Search for more papers by this author

https://doi.org/10.1142/S0219519417500269Cited by:7 (Source: Crossref)

Abstract

American football is associated with a high rate of non-contact chronic injuries. Players are able to select from both high and low cut footwear. The aim of the current investigation was to examine the influence of high and low cut American football specific footwear on tibial accelerations and three-dimensional (3D) kinematics during three sport specific movements. Twelve male American football players performed three movements, run, cut and vertical jump whilst wearing both low and high cut footwear. 3D kinematics of the lower extremities were measured using an eight-camera motion analysis system alongside tibial acceleration parameters which were obtained using a shank mounted accelerometer. Tibial acceleration and 3D kinematic differences between the different footwear were examined using either repeated measures or Friedman’s ANOVA. Tibial accelerations were significantly greater in the low cut footwear in comparison to the high cut footwear for the run and cut movements. In addition, peak ankle eversion and tibial internal rotation parameters were shown to be significantly greater in the low cut footwear in the running and cutting movement conditions. The current study indicates that the utilization of low cut American football footwear for training/performance may place American footballers at increased risk from chronic injuries.

Keywords:

References

1. Wannop JW, Luo G and Stefanyshyn DJ, Footwear traction and lower extremity noncontact injury, Med Sci Sports Exerc 45 (2013) 2137–2143. Crossref, Web of Science, Google Scholar
2. Fernandez WG, Yard EE and Comstock RD, Epidemiology of lower extremity injuries among U.S. high school athletes, Acad Med 14 (2007) 641–645. Crossref, Web of Science, Google Scholar
3. Nelson AJ, Collins CL, Yard EE, Fields SK and Comstock RD, Ankle injuries among United States high school sports athletes, 2005–2006, J Athl Train 42 (2007) 381–387. Web of Science, Google Scholar
4. Fong DTP, Hong Y, Chan L-K, Yung PS and Chan KM, A systematic review on ankle injury and ankle sprain in sports, Sports Med 37 (2007) 73–94. Crossref, Web of Science, Google Scholar
5. Turbeville SD, Cowan LD, Owen WL, Asal NR and Anderson MA, Risk factors for injury in high school football players, Am J Sports Med 31 (2003) 974–980. Crossref, Web of Science, Google Scholar
6. Iacovelli JN, Yang J, Thomas G, Wu H, Schiltz T and Foster DT, The effect of field condition and shoe type on lower extremity injuries in American Football, Br J Sports Med 47 (2013) 789–793. Crossref, Web of Science, Google Scholar
7. Ekstrand J, Timpka T and Hagglund M, Risk of injury in elite football played on artificial turf versus national grass: a prospective two-cohort study, Br J Sports Med 40 (2006) 975–980. Crossref, Web of Science, Google Scholar
8. Meyers MC, Incidence, mechanisms, and severity of game-related college football injuries on Field-Turf versus natural grass: a 3 year prospective study, Am J Sports Med 38 (2010) 687–697. Crossref, Web of Science, Google Scholar
9. Hershman EB, Anderson R, Bergfeld JA, Bradley JP, Coughlin MJ, Johnson RJ and Tucker A, An analysis of specific lower extremity injury rates on grass and Field Turf playing surfaces in National Football League Games: 2000–2009 Seasons, Am J Sports Med 40 (2012) 2200–2205. Crossref, Web of Science, Google Scholar
10. Dragoo JL, Braun HJ and Harris AHS, The effect of playing surface on the incidence of ACL injuries in National Collegiate Athletic Association American Football, Knee 20 (2013) 191–195. Crossref, Web of Science, Google Scholar
11. Lambson RB, Barnhill BS and Higgins RW, Football Cleat Design and Its Effect on Anterior Cruciate Ligament Injuries A Three-Year Prospective Study, Am J Sports Med 24 (1996) 155–159. Crossref, Web of Science, Google Scholar
12. Faganel PP, Drake TC, Dahl-Miller AR and Senchina DS, Height variation in football shoes (cleats) for running backs and receivers may not alter ankle spatting effects in football field drills, J Undergrad Res 4 (2013) 6–10. Google Scholar
13. Ricard MD, Schulties SS and Saret JJ, Effects of high-top and low-top shoes on ankle inversion, J Athl Train 35 (2000) 38–43. Web of Science, Google Scholar
14. Barrett JR, Tanji JL, Drake C, Fuller D, Kawasaki RI and Fenton RM, High versus low-top shoes for the prevention of ankle sprains in basketball players. A prospective randomized study, Am J Sports Med 21 (1992) 582–585. Crossref, Web of Science, Google Scholar
15. Fu W, Fang Y, Liu Y and Hou J, The effect of high-top and low-top shoes on ankle inversion kinematics and muscle activation in landing on a tilted surface, J Foot Ankle Res 7 (2014) 14–24. Crossref, Web of Science, Google Scholar
16. Sinclair J, Chockalingam N, Naemi R and Vincent H, The effects of sport-specific and minimalist footwear on the kinetics and kinematics of three netball-specific movements, Footwear Sci 7 (2015) 31–36. Crossref, Web of Science, Google Scholar
17. Sinclair J, Bottoms L, Taylor K and Greenhalgh A, Tibial shock measured during the fencing lunge: the influence of footwear, Sports Biomech 9 (2010) 65–71. Crossref, Web of Science, Google Scholar
18. Lafortune MA and Hennig EM, Contribution of angular motion and gravity to tibial acceleration, Med Sci Sports Exerc 23 (1991) 360–363. Crossref, Web of Science, Google Scholar
19. Cappozzo A, Catani F, Leardini A, Benedeti MG and Della CU, Position and orientation in space of bones during movement: Anatomical frame definition and determination, Clin Biomech 10 (1995) 171–178. Crossref, Web of Science, Google Scholar
20. Sinclair J, Taylor PJ, Edmundson CJ, Brooks D and Hobbs SJ, Influence of the helical and six available Cardan sequences on 3D ankle joint kinematic parameters, Sp Biomech 11 (2013) 430–437. Crossref, Web of Science, Google Scholar
21. Sinclair J, Hebron J and Taylor PJ, The Test-retest Reliability of Knee Joint Center Location Techniques, J App Biomech 31 (2015) 117–121. Crossref, Web of Science, Google Scholar
22. Sinclair J, Taylor PJ, Currigan G and Hobbs SJ, The test-retest reliability of three different hip joint center location techniques, Movement Sport Sci 83 (2014) 31–39. Crossref, Google Scholar
23. Graydon R, Fewtrell D, Atkins S, Sinclair J, The test-retest reliability of different ankle joint center location techniques, FAOJ, in press. Google Scholar
24. Cappozzo A, Cappello A, Croce UD and Pensalfini F, Surface-marker cluster design criteria for 3-D bone movement reconstruction, IEEE Trans Biomed Eng 44 (1997) 1165–1174. Crossref, Web of Science, Google Scholar
25. Sinclair J, Hobbs SJ, Edmundson CJ and Brooks D, Evaluation of kinematic methods of identifying foot strike and toe-off during running, Int J Sp Sci Eng 5 (2011) 188–192. Google Scholar
26. McLean SG, Huang X, Su A and Van Den Bogert AJ, Sagittal plane biomechanics cannot injure the ACL during sidestep cutting, Clin Biomech 19 (2004) 828–838. Crossref, Web of Science, Google Scholar
27. Flanagan EP, Ebben W and Jensen RL, Reliability of the reactive strength index and time to stabilization during depth jumps, J Strength Condit Res 22 (2008) 1677–1682. Crossref, Web of Science, Google Scholar
28. Read MM and Cisar C, The influence of varied rest interval lengths on drop jump performance, J Strength Condit Res 15 (2001) 279–283. Web of Science, Google Scholar
29. Sinclair J, Taylor PJ and Hobbs SJ, Alpha level adjustments for multiple dependent variable analyses and their applicability – A review, Int J Sport Sci Eng 7 (2013) 17–20. Google Scholar
30. Whittle MW, The generation and attenuation of transient forces beneath the foot; a review, Gait Posture 10 (1999) 264–275. Crossref, Web of Science, Google Scholar
31. Taunton JE, Clement DB and McNicol K, Plantar fasciitis in runners, Can J Appl Sport Sci 7 (1982) 41–44. Google Scholar
32. Eslami M, Begon M, Farahpour N and Allard P, Forefoot rearfoot coupling patterns and tibial internal rotation during stance phase of barefoot versus shod running, Clin Biomech 22 (2007) 74–80. Crossref, Web of Science, Google Scholar
33. Markovic G, Does plyometric training improve vertical jump height? A meta-analytical review, Br J Sports Med 41 (2007) 349–355. Crossref, Web of Science, Google Scholar
34. Pearson KG, Proprioceptive regulation of locomotion, Curr Opin Neurobiol 5 (1995) 786–791. Crossref, Web of Science, Google Scholar
35. Ferber R, McClay DI and Williams DS III, Gender differences in lower extremity mechanics during running, Clin Biomech 18 (2003) 350–357. Crossref, Web of Science, Google Scholar
36. Sinclair J, Greenhalgh A, Edmundson CJ, Brooks D and Hobbs SJ, Gender Differences in the Kinetics and Kinematics of Distance Running: Implications for Footwear Design, Int J Sp Sci Eng 6 (2012) 118–128. Google Scholar
37. Black W and Roundy E, Comparisons of size, strength, speed and power in NCAA division I-A football players, J Strength Condit Res 8 (1994) 80–85. Google Scholar