Effect of foot pronation during distance running on the lower limb impact acceleration and dynamic stability

• Autorzy: Xiang Liangliang , Gu Yaodong , Wang Alan , Mei Qichang , Yu Peimin , Shim Vickie , Fernandez Justin

Identyfikatory

DOI

10.37190/ABB-02165-2022-02

• Języki publikacji: EN

Abstrakty

EN

Foot pronation is not an isolated factor influencing lower limb functions. Exploring gait variability and impact loading associated with the foot posture are crucial for understanding foot pronation-related injury mechanisms. This study aimed to evaluate how foot posture affects impact loading and running variability during running. Methods: Twenty-five male participants were recruited into this study. Pressure under the foot arch, acceleration and marker trajectory were recorded in the right limb for each runner after 1, 4, 7 and 10 km running, respectively. Linear mixed effects models were used to analyze the statistical difference of the data. Results: FPI-6 has significantly increased after the 10 km running ( p < 0.01). For the tibial acceleration, peak resultant acceleration after 10 km running was significantly increased than after 4 km running ( p = 0.02). At the dorsum of the foot, the short-time largest Lyapunov exponent (LyE) after 10 km running decreased 0.28 bit/s compared with LyE after 7 km running ( p = 0.03). In the tibia, LyE after 4 km and 10 km running was decreased significantly ( p < 0.01 and p = 0.01). Conclusions: The foot was significantly pronated at the middle and at the end of running. Foot pronation during distance running increased the distal tibia peak impact acceleration but did not increase running instability.

Słowa kluczowe

EN

foot pronation; running; impact loading; tibial acceleration; local dynamic stability; LDS

• Wydawca: Oficyna Wydawnicza Politechniki Wrocławskiej
• Czasopismo: Acta of Bioengineering and Biomechanics
• Rocznik: 2022
• Tom: Vol. 24, no. 4
• Strony: 21--30
• Opis fizyczny: Bibliogr. 43 poz., rys., tab., wykr.

Twórcy

autor

Xiang Liangliang

• Faculty of Sports Science, Ningbo University, Ningbo, China.
• Research Academy of Grand Health, Ningbo University, Ningbo, China.
• Auckland Bioengineering Institute, The University of Auckland, Auckland, New Zealand.

autor

Gu Yaodong

• Faculty of Sports Science, Ningbo University, Ningbo, China.
• Research Academy of Grand Health, Ningbo University, Ningbo, China.
• Auckland Bioengineering Institute, The University of Auckland, Auckland, New Zealand.

autor

Wang Alan

• Auckland Bioengineering Institute, The University of Auckland, Auckland, New Zealand.
• Faculty of Medical and Health Sciences, The University of Auckland, Auckland, New Zealand.

autor

Mei Qichang

• Faculty of Sports Science, Ningbo University, Ningbo, China.
• Research Academy of Grand Health, Ningbo University, Ningbo, China.

autor

Yu Peimin

• Faculty of Sports Science, Ningbo University, Ningbo, China.
• Research Academy of Grand Health, Ningbo University, Ningbo, China.
• Auckland Bioengineering Institute, The University of Auckland, Auckland, New Zealand.

autor

Shim Vickie

• Auckland Bioengineering Institute, The University of Auckland, Auckland, New Zealand.

autor

Fernandez Justin

• Research Academy of Grand Health, Ningbo University, Ningbo, China.
• Auckland Bioengineering Institute, The University of Auckland, Auckland, New Zealand.
• Department of Engineering Science, The University of Auckland, Auckland, New Zealand.

Bibliografia

• [1] BEHLING A.V., MANZ S., VON TSCHARNER V., NIGG B.M., Pronation or foot movement – what is important, J. Sci. Med. Sport, 2020, 23 (4), 366–371.
• [2] BEHLING A.V., NIGG B.M., Relationships between the foot posture index and static as well as dynamic rear foot and arch variables, J. Biomech., 2020, 98, 109448.
• [3] COHEN J., Statistical Power Analysis for the Behavioral Sciences, 2nd ed., Routledge, 2013.
• [4] COLAPIETRO M., FRASER J.J., RESCH J.E., HERTEL J., Running mechanics during 1600 meter track runs in young adults with and without chronic ankle instability, Phys. Ther. Sport, 2020, 42, 16–25.
• [5] COWLEY E., MARSDEN J., The effects of prolonged running on foot posture: a repeated measures study of half marathon runners using the foot posture index and navicular height, J. Foot Ankle Res., 2013, 6 (20), DOI: 10.1186/1757-1146-6-20.
• [6] DINGWELL J.B., CUSUMANO J.P., CAVANAGH P.R., STERNAD D., Local dynamic stability versus kinematic variability of continuous overground and treadmill walking, J. Biomech. Eng., 2001, 123, 27–32.
• [7] DOS SANTOS J.O.L., GOMES A.L.R., LIMA A.B., DE PAIVA VIEIRA E., BEZERRA E.D.S., ROSSATO M., Effect of linear running velocity on the increase on foot pronation, Foot, 2019, 41, 74–78.
• [8] EKIZOS A., SANTUZ A., ARAMPATZIS A., Transition from shod to barefoot alters dynamic stability during running, Gait Posture, 2017, 56, 31–36.
• [9] FRANK N.S., PRENTICE S.D., CALLAGHAN J.P., Local dynamic stability of the lower extremity in novice and trained runners while running in traditional and minimal footwear, Gait Posture, 2019, 68, 50–54.
• [10] FRASER A.M., SWINNEY H.L., Independent coordinates for strange attractors from mutual information, Phys. Rev. A., 1986, 33, 1137–1140.
• [11] GLASSBROOK D.J., FULLER J.T., ALDERSON J.A., DOYLE T.L.A., Foot accelerations are larger than tibia accelerations during sprinting when measured with inertial measurement units, J. Sports Sci., 2020, 38 (3), 248–255.
• [12] HINTERMANN B., NIGG B.M., Pronation in runners, Sport. Med., 1998, 26 (3), 169–176.
• [13] HOENIG T., HAMACHER D., BRAUMANN K.M., ZECH A., HOLLANDER K., Analysis of running stability during 5000 m running, Eur. J. Sport Sci., 2019, 19 (4), 413–421.
• [14] HOLLANDER K., HAMACHER D., ZECH A., Running barefoot leads to lower running stability compared to shod running – results from a randomized controlled study, Sci. Rep., 2021, 11, 4376.
• [15] HORWOOD A.M., CHOCKALINGAM N., Defining excessive, over, or hyper-pronation: a quandary, Foot, 2017, 31, 49–55.
• [16] JANDOVÁ S., VOLF P., VAVERKA F., The influence of minimalist and conventional sports shoes and lower limbs dominance on running gait, Acta Bioeng. Biomech., 2018, 20 (3), 3–9.
• [17] KENNEL M.B., BROWN R., ABARBANEL H.D.I., Determining embedding dimension for phase-space reconstruction using a geometrical construction, Phys. Rev. A., 1992, 45 (6), 3403–3411.
• [18] LAI C.H.Y., LI-TSANG C.W.P., Validation of the Pliance X System in measuring interface pressure generated by pressure garment, Burns, 2009, 35, 845–851.
• [19] MALISOUX L., CHAMBON N., DELATTRE N., GUEGUEN N., URHAUSEN, A., THEISEN D., Injury risk in runners using standard or motion control shoes: a randomised controlled trial with participant and assessor blinding, Br. J. Sports Med., 2016, 50 (8), 481–487.
• [20] MEHDIZADEH S., The largest lyapunov exponent of gait in young and elderly individuals: a systematic review, Gait Posture, 2018, 60, 241–250.
• [21] MEI Q., GU Y., XIANG L., BAKER J.S., FERNANDEZ J., Foot pronation contributes to altered lower extremity loading after long distance running, Front. Physiol., 2019, 10, 573.
• [22] MIZRAHI J., VERBITSKY O., ISAKOV E., Fatigue-related loading imbalance on the shank in running: a possible factor in stress fractures, Ann. Biomed. Eng., 2000, 28 (4), 463–469.
• [23] MO S., CHOW D.H.K., Accuracy of three methods in gait event detection during overground running, Gait Posture, 2018, 59, 93–98.
• [24] NEAL B.S., GRIFFITHS I.B., DOWLING G.J., MURLEY G.S., MUNTEANU S.E., FRANETTOVICH SMITH M.M., COLLINS N.J., BARTON C.J., Foot posture as a risk factor for lower limb overuse injury: a systematic review and meta-analysis, J. Foot Ankle Res., 2014, 7(55), DOI: 10.1186/s13047-014-0053-6.
• [25] NIELSEN R.O., BUIST I., PARNER E.T., NOHR E.A., SØRENSEN H., LIND M., RASMUSSEN S., Foot pronation is not associated with increased injury risk in novice runners wearing a neutral shoe: a 1-year prospective cohort study, Br. J. Sports Med., 2014, 48, 440–447.
• [26] NIGG B., BEHLING A., HAMILL J., Foot pronation, Footwear Sci., 2019, 11 (3), 131–134.
• [27] NIGG B.M., BALTICH J., HOERZER S., ENDERS H., Running shoes and running injuries: mythbusting and a proposal for two new paradigms:“preferred movement path”and “comfort filter”, Br. J. Sports Med., 2015, 49 (20), 1290–1294.
• [28] NOVACHECK T.F., The biomechanics of running, Gait Posture, 1998, 7, 77–95.
• [29] PATERSON K.L., CLARK R.A., MULLINS A., BRYANT A.L., MENTIPLAY B.F., Predicting dynamic foot function from static foot posture: comparison between visual assessment, motion analysis, and a commercially available depth camera, J. Orthop. Sport. Phys. Ther., 2015, 45 (10), 789–798.
• [30] RABIEI M., ESLAMI M., MOVAGHAR A.F., The assessment of three-dimensional foot pronation using a principal component analysis method in the stance phase of running, Foot, 2016, 29, 11–17.
• [31] REDMOND A.C., CRANE Y.Z., MENZ H.B., Normative values for the foot posture index, J. Foot Ankle Res., 2008, 1 (1), DOI: 10.1186/1757-1146-1-6.
• [32] REDMOND A.C., CROSBIE J., OUVRIER R.A., Development and validation of a novel rating system for scoring standing foot posture: the foot posture index, Clin. Biomech., 2006, 21, 89–98.
• [33] RESENDE R.A., PINHEIRO L.S.P., OCARINO J.M., Effects of foot pronation on the lower limb sagittal plane biomechanics during gait, Gait Posture, 2019, 68, 130–135.
• [34] ROSENSTEIN M.T., COLLINS J.J., DE LUCA C.J., A practical method for calculating largest lyapunov exponents from small data sets, Phys. D Nonlinear Phenom., 1993, 65, 117–134.
• [35] SCHÜTTE K.H., SEERDEN S., VENTER R., VANWANSEELE B., Influence of outdoor running fatigue and medial tibial stress syndrome on accelerometer-based loading and stability, Gait Posture, 2018, 59, 222–228.
• [36] SHEERIN K.R., BESIER T.F., REID D., The influence of running velocity on resultant tibial acceleration in runners, Sport. Biomech., 2018, DOI: 10.1080/14763141.2018.1546890.
• [37] SINCLAIR J., FAU-GOODWIN J., RICHARDS J., SHORE H., The influence of minimalist and maximalist footwear on patellofemoral kinetics during running, J. Appl. Biomech., 2016, 32 (4), 359–364.
• [38] STENUM J., BRUIJN S.M., JENSEN B.R., The effect of walking speed on local dynamic stability is sensitive to calculation methods, J. Biomech., 2014, 47, 3776–3779.
• [39] TANSEY P.A., BRIGGS P.J., Active and passive mechanisms in the control of heel supination, Foot ankle Surg., 2001, 7 (3), 131–136.
• [40] TENFORDE A.S., HAYANO T., JAMISON S.T., OUTERLEYS J., DAVIS I.S., Tibial acceleration measured from wearable sensors is associated with loading rates in injured runners, PM R, 2020, 12 (7), 679–684.
• [41] VARGHESE M.A., SAHA P.N., ATREYA N., A rapid appraisal of occupational workload from a modified scale of perceived exertion, Ergonomics, 1994, 37 (3), 485–491.
• [42] XIANG L., GU Y., RONG M., GAO Z., YANG T., WANG A., SHIM V., FERNANDEZ J., Shock acceleration and attenuation during running with minimalist and maximalist shoes: a timeand frequency-domain analysis of tibial acceleration, Bioengineering, 2022, 9, 322.
• [43] XIANG L., WANG A., GU Y., ZHAO L., SHIM V., FERNANDEZ J., Recent machine learning progress in lower limb running biomechanics with wearable technology: a systematic review, Front. Neurorobot., 2022, 16, 913052.