Erika Zemková¹, Michal Jeleň², Ludmila Zapletalová³, Dusan Hamar⁴

¹Comenius University in Bratislava, Department of Sports Kinanthropology, Faculty of Physical Education and Sport, Bratislava, Slovakia; Slovak University of Technology, Sports Technology Institute, Faculty of Electrical Engineering and Information Technology, Bratislava, Slovakia
²Slovak University of Technology, Sports Technology Institute, Faculty of Electrical Engineering and Information Technology, Bratislava, Slovakia
³Comenius University in Bratislava, Department of Sports Games, Faculty of Physical Education and Sport, Bratislava, Slovakia
⁴Comenius University in Bratislava, Department of Sports Kinanthropology, Faculty of Physical Education and Sport, Bratislava, Slovakia

Muscle Power during Standing and Seated Trunk Rotations with Different Weights

Sport Mont 2017, 15(3), 17-23 | DOI: 10.26773/smj.2017.10.003

Abstract

This study compares peak and mean power during standing and seated trunk rotations with different weights. Twenty seven fit men completed four trials of trunk rotations in both standing and seated positions with a bar weight of 5.5, 10.5, 15.5, and 20 kg placed on the shoulders. The FiTRO Torso Premium was used to monitor basic biomechanical parameters throughout the movement. Results showed significantly higher peak power during standing than seated trunk rotations at weights of 20 kg (274.4±63.5 vs. 206.4±54.6 W, p=0.004), 15.5 kg (371.2±93.9 vs. 313.5±72.3 W, p=0.007), and 10.5 kg (336.9±77.8 vs. 286.3±66.0 W, p=0.009) but not at 5.5 kg (191.6±46.2 vs. 166.0±37.0 W, p=0.061). Similarly, mean power in the acceleration phase of trunk rotations was significantly higher when performed in standing than seated position at weights of 20 kg (143.2±32.1 vs. 101.9±23.7 W, p=0.008), 15.5 kg (185.1±42.3 vs. 150.4±36.5 W, p=0.019), and 10.5 kg (169.8±40.7 vs. 139.7±31.6 W, p=0.024) but not at 5.5 kg (107.4±29.4 vs. 86.5±21.1 W, p=0.111). Furthermore, peak and mean power during standing trunk rotations significantly correlated with values achieved in the seated position at the weight of 5.5 kg (r=0.684, p=0.027; r=0.676, p=0.033) but not at 10.5 kg (r=0.589, p=0.089; r=0.552, p=0.143), 15.5 kg (r=0.493, p=0.243; r=0.436, p=0.298), and 20 kg (r=0.357, p=0.361; r=0.333, p=0.417). In conclusion, power production is greater during standing as compared to seated trunk rotations, with more pronounced differences at higher weights. This fact has to be taken into account when training and testing the trunk rotational power.

Keywords

additional load, rotational power, standing/sitting positions, trunk movement

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References

Andre, M.J., Fry, A.C., Heyrman, M.A., Hudy, A., Holt, B., Roberts, C., Vardiman, J.P., & Gallagher, P.M. (2012). A reliable method for assessing rotational power. Journal of Strength and Conditioning Research, 26(3), 720–724.

Earp, J.E. & Kraemer, W.J. (2010). Medicine ball training implications for rotational power sports. Strength and Conditioning Journal, 32(4), 20–25.

Keogh, J.W., Aickin, S.E., & Oldham, A.R. (2010). Can common measures of core stability distinguish performance in a shoulder pressing task under stable and unstable conditions? Journal of Strength and Conditioning Research, 24(2), 422–429.

Kohmura, Y., Aoki, K., Yoshigi, H., Sakuraba, K., & Yanagiya, T. (2008). Development of a baseball-specific battery of tests and a testing protocol for college baseball players. Journal of Strength and Conditioning Research, 22(4), 1051–1058.

Kumar, S., Dufresne, R.M., & Van Schoor, T. (1995). Human trunk strength profile in lateral flexion and axial rotation. Spine, 20(2), 169–177.

Kumar, S. (1997). Axial rotation strength in seated neutral and pre-rotated postures of young adults. Spine, 22(19), 2213–2221.

Kumar, S. & Narayan, Y. (1998). Spectral parameters of trunk muscles during fatiguing isometric axial rotation in neutral posture. Journal of Electromyography and Kinesiology, 8(4), 257–267.

Lehman, G.J. (2006). Resistance training for performance and injury prevention in golf. The Journal of the Canadian Chiropractic Association, 50(1), 27–42.

Lehman, G., Drinkwater, E.J., & Behm, D.G. (2013). Correlation of throwing velocity to the results of lower-body field tests in male college baseball players. Journal of Strength and Conditioning Research, 27(4):902–908.

Lindsay, D.M. & Horton, J.F. (2006). Trunk rotation strength and endurance in healthy normals and elite male golfers with and without low back pain. North American Journal of Sports Physical Therapy, 1(2), 80–88.

McGill, S.M. (1991). Electromyographic activity of the abdominal and low back musculature during the generation of isometric and dynamic axial trunk torque: Implications for lumbar mechanics. Journal of Orthopaedic Research, 9(1), 91–103.

Newton, M., Thow, M., Somerville, D., Henderson, I., & Waddell, G. (1993). Trunk strength testing with iso-machines. Part 2: Experimental evaluation of the Cybex II Back Testing System in normal subjects and patients with chronic low back pain. Spine, 18(7), 812–824.

Palmer, T.G., & Uhl, T.L. (2011). Interday reliability of peak muscular power outputs on an isotonic dynamometer and assessment of active trunk control using the chop and lift tests. Journal of Athletic Training, 46(2):150–159.

Pope, M.H., Andersson, G.B., Broman, H., Svensson, M., & Zetterberg, C. (1986). Electromyographic studies of the lumbar trunk musculature during the development of axial torques. Journal of Orthopaedic Research, 4(3), 288–297.

Putnam, C.A. (1993). Sequential motions of body segments in striking and throwing skills: descriptions and explanations. Journal of Biomechanics, 26(Suppl 1), 125–135.

Rivilla-García, J., Martínez I, Grande, I., & Sampedro-Molinuevo, J. (2011). Relation between general throwing tests with a medicine ball and specific tests to evaluate throwing velocity with and without opposition in handball. Journal of Human Sport & Exercise, 6(2), 414–426.

Sahrmann, A.S. (2002). Diagnosis and treatment of movement impairment syndrome. St Louis, Missouri: Mosby Inc.

Shinkle, J., Nesser, T.W., Demchak, T.J., & McMannus, D.M. (2012). Effect of core strength on the measure of power in the extremities. Journal of Strength and Conditioning Research, 26(2), 373–380.

Suter, E. & Lindsay, D.M. (2001). Back muscle fatigability is associated with knee extensor inhibition in subjects with low back pain. Spine, 26(16), E361–E366.

Talukdar, K., Cronin, J., Zois, J., & Sharp, A.P. (2015). The role of rotational mobility and power on throwing velocity. Journal of Strength and Conditioning Research, 29(4):905–911.

Tihanyi, J., Apor, P., & Fekete, G. (1982). Force-velocity-power characteristics and fiber composition in human knee extensor muscles. European Journal of Applied Physiology and Occupational Physiology, 48(3), 331–343.

Watkins, R.G., Uppal, G.S., Perry, J., Pink, M., & Dinsay, J.M. (1996). Dynamic electromyographic analysis of trunk musculature in professional golfers. The American Journal of Sports Medicine, 24(4), 535–538.

Willson, J.D., Dougherty, C.P., Ireland, M.L., & Davis, I.M. (2005). Core stability and its relationship to lower extremity function and injury. The Journal of the American Academy of Orthopaedic Surgeons, 13(5), 316–325.

Zemková, E., Cepková, A., Uvaček, M., & Šooš, Ľ. (2016). A novel method for assessing muscle power during the standing cable wood chop exercise. Journal of Strength and Conditioning Research [Epub ahead of print].