Authors: Yoon- Ho Shin, Jin-Seung Choi, Dong-Won Kang, Jeong-Woo Seo, Joo-Hack Lee, Ju-Young Kim, Dae-Hyeok Kim, Seung-Tae Yang, Gye-Rae Tack

Abstract:

It is difficult to study the effect of various variables on cycle fitting through actual experiment. To overcome such difficulty, the forward dynamics of a musculoskeletal model was applied to cycle fitting in this study. The measured EMG data weres compared with the muscle activities of the musculoskeletal model through forward dynamics. EMG data were measured from five cyclists who do not have musculoskeletal diseases during three minutes pedaling with a constant load (150 W) and cadence (90 RPM). The muscles used for the analysis were the Vastus Lateralis (VL), Tibialis Anterior (TA), Bicep Femoris (BF), and Gastrocnemius Medial (GM). Person’s correlation coefficients of the muscle activity patterns, the peak timing of the maximum muscle activities, and the total muscle activities were calculated and compared. BIKE3D model of AnyBody (Anybodytech, Denmark) was used for the musculoskeletal model simulation. The comparisons of the actual experiments with the simulation results showed significant correlations in the muscle activity patterns (VL: 0.789, TA: 0.503, BF: 0.468, GM: 0.670). The peak timings of the maximum muscle activities were distributed at particular phases. The total muscle activities were compared with the normalized muscle activities, and the comparison showed about 10% difference in the VL (+10%), TA (+9.7%), and BF (+10%), excluding the GM (+29.4%). Thus, it can be concluded that muscle activities of model & experiment showed similar results. The results of this study indicated that it was possible to apply the simulation of further improved musculoskeletal model to cycle fitting.

Keywords: Cycle fitting, EMG, Musculoskeletal modeling, Simulation.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1098110

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References:

[1] I. K. Kim, M. H. Jung, “The effect of ride a bicycle on the physical fitness of an old person,” Journal of Physical Education & Sports Science, vol. 14-1, 1996, pp. 115-124.
[2] J. H. Bae, J. S. Choi, D. W. Kang, J. W. Seo and G. R. Tack, “Technical Note: Development of electric riding machine for cycle fitting,” Korea Journal of Sport Biomechanics ,vol.22-3, 2012, pp. 373-378.
[3] B. R. Umberger, H. J. Scheuchenzuber and T. M. Manos, “Differences in power output during cycling at different seat tube angles,” Journal of Human Movement Studies, vol.35, 1998, pp. 021-036.
[4] R. Bini, P. A. Hume and J. I. Croft, “Effects of bicycle saddle height on knee injury risk and cycling performance,” Journal of Sports Medicine, vol. 41-6, 2011, pp. 463-476.
[5] J. S. Choi, D. W. Kang, J. W. Seo, J. H. Bae and G. R. Tack, “Effects of increased saddle height on length and activity pattern of Vastus Lateralis and Biceps Femoris muscle,” Korean Journal of Sport Biomechanics, vol. 22-4, 2012, pp. 413-419.
[6] P. W. Macdermid and A. M. Edwards, “Influence of crank length on cycle ergometer performance of well-trained female cross-country mountain bike athletes,” European Journal of Applied Physiology, vol. 108, 2010, pp. 177-182.
[7] J. Z. Wu, K. N. An, R. G. Cutlip and R.G. Dong, “A practical biomechanical model of the index finger simulating the kinematics of the muscle/tendon excursions,” Bio-Medical Materials and Engineering, vol. 20-2, 2010, pp. 89-97.
[8] S. L. Delp, A. S. Arnold and S. J. Piazza, “Graphics-based modeling and analysis of gait abnormalities,” Bio-Medical Materials and Engineering, vol. 8(3-4), 1998, pp. 227-240.
[9] W. R. Jeffery and R. R. Neptune, “A theoretical analysis of an optimal chain ring shape to maximize crank power during isokinetic pedaling,” Journal of Biomechanics, vol. 41, 2008, pp. 1494-1502
[10] Rasmussen, John, Michael Damsgaard, and Søren Tørholm Christensen, “Simulation of tendon energy storage in pedaling,” Mediterranean Conference on Medical and Biological Engineering and Computing. Pula, Croatia, 2001, pp. 4-7
[11] Y. S. Liu, T. S. Tsay and T. C. Wang, “Muscle force and joints load simulation of bicycle riding using multibody models,” Procedia Engineering, vol. 13, 2011, pp. 81-87.
[12] C. C. Raasch, F. E. Zajac, B. Ma and W. S. Levine, “Muscle coordination for maximum-speed pedaling,” Journal of Biomechanics, vol. 30-6 , 1997, pp. 595-602.
[13] Y. Albertus-Kajee, R. Tucker, W. Derman and M. Lambert, “Alternative methods for normalizing EMG during cycling,” Journal of Electromyography and Kinesiology, vol. 20-6, 2010, pp. 1036-1043.
[14] S. B. Brian and Li Li, “Lower extremity muscle activities during cycling are influenced by load and frequency,” Journal of Electromyography and Kinesiology, vol. 13-2, 2003, pp. 181-190.
[15] R. R. Neptune, S. A. Kautz, and F. E. Zajac, “Muscle contributions to specific biomechanical functions do not change in forward versus backward pedaling,” Journal of biomechanics, vol. 33-2, 2000, pp. 155-164.
[16] M. Damsgaard, J. Rasmussen, S. T. Christensen, E. Surma and M. de Zee, “Analysis of musculoskeletal systems in the AnyBody modeling system,” Simulation Modelling Practice and Theory, vol. 14-8, 2004, pp.1100-1111.
[17] R. Jacobs, M. F. Nobbert and J. van. I. S. Gerrit, “Function of mono- and biarticular muscles in running,” Medicine and Science in Sports and Exercise, vol. 25-10, 1993, pp. 1163-1173.
[18] Li Li and E. C. Graham, “Muscle coordination in cycling: effect of surface incline and posture,” Journal of Applied Physiology, vol. 85-3 1998, pp. 927-934.
[19] J. W. Rankin and R. R. Neptune, “The influence of seat configuration on maximal average crank power during pedaling: A simulation study,” Journal of Applied Biomechanics, vol. 26, 2010. pp. 493-500.