[1] Bateman, J.E., 1962. Athletic injuries about the shoulder in throwing and body-contact sports. Clinical Orthopaedics and Related Research®, 23, pp.75-83.
[2] Bernstein, N., 1966. The co-ordination and regulation of movements. The co-ordination and regulation of movements.
[3] Giszter, S., Patil, V. and Hart, C., 2007. Primitives, premotor drives, and pattern generation: a combined computational and neuroethological perspective. Progress in brain research, 165, pp.323-346.
[4] Chhabra, M. and Jacobs, R.A., 2006. Properties of synergies arising from a theory of optimal motor behavior. Neural computation, 18(10), pp.2320-2342.
[5] Todorov, E. and Jordan, M.I., 2002. Optimal feedback control as a theory of motor coordination. Nature neuroscience, 5(11), p.1226.
[6] Scholz, J.P. and Schöner, G., 1999. The uncontrolled manifold concept: identifying control variables for a functional task. Experimental brain research, 126(3), pp.289-306.
[7] Moghadam, M.N., Aminian, K., Asghari, M. and Parnianpour, M., 2013. How well do the muscular synergies extracted via non-negative matrix factorisation explain the variation of torque at shoulder joint?. Computer methods in biomechanics and biomedical engineering, 16(3), pp.291-301.
[8] Eskandari, A.H., Sedaghat-Nejad, E., Rashedi, E., Sedighi, A., Arjmand, N. and Parnianpour, M., 2016. The effect of parameters of equilibrium-based 3-D biomechanical models on extracted muscle synergies during isometric lumbar exertion. Journal of biomechanics, 49(6), pp.967-973.
[9] Sedaghat-Nejad, E., Mousavi, S.J., Hadizadeh, M., Narimani, R., Khalaf, K., Campbell-Kyureghyan, N. and Parnianpour, M., 2015. Is there a reliable and invariant set of muscle synergy during isometric biaxial trunk exertion in the sagittal and transverse planes by healthy subjects? Journal of biomechanics, 48(12), pp.3234-3241.
[10]Eskandari, A.H., Sedaghat-Nejad, E., Mousavi, S.J., Asghari, M. and Parnianpour, M., 2011. Employing muscular and stability synergies to perform a desired task. Iran. J. Biomed. Eng, 5, pp.257-274.
[11]Tresch, M.C., Cheung, V.C. and d'Avella, A., 2006. Matrix factorization algorithms for the identification of muscle synergies: evaluation on simulated and experimental data sets. Journal of neurophysiology, 95(4), pp.2199-2212.
[12]d'Avella, A. and Tresch, M.C., 2002. Modularity in the motor system: decomposition of muscle patterns as combinations of time-varying synergies. In Advances in neural information processing systems (pp. 141-148).
[13]Krouchev, N., Kalaska, J.F. and Drew, T., 2006. Sequential activation of muscle synergies during locomotion in the intact cat as revealed by cluster analysis and direct decomposition. Journal of neurophysiology, 96(4), pp.1991-2010.
[14]Berniker, M., Jarc, A., Bizzi, E. and Tresch, M.C., 2009. Simplified and effective motor control based on muscle synergies to exploit musculoskeletal dynamics. Proceedings of the National Academy of Sciences, pp.pnas-0901512106.
[15]d'Avella, A. and Bizzi, E., 2005. Shared and specific muscle synergies in natural motor behaviors. Proceedings of the National Academy of Sciences, 102(8), pp.3076-3081.
[16]d'Avella, A., Fernandez, L., Portone, A. and Lacquaniti, F., 2008. Modulation of phasic and tonic muscle synergies with reaching direction and speed. Journal of neurophysiology, 100(3), pp.1433-1454.
[17]d'Avella, A., Portone, A., Fernandez, L. and Lacquaniti, F., 2006. Control of fast-reaching movements by muscle synergy combinations. Journal of Neuroscience, 26(30), pp.7791-7810.
[18]d'Avella, A., Saltiel, P. and Bizzi, E., 2003. Combinations of muscle synergies in the construction of a natural motor behavior. Nature neuroscience, 6(3), p.300.
[19]Flanders, M.A.R.T.H.A. and Herrmann, U., 1992. Two components of muscle activation: scaling with the speed of arm movement. Journal of neurophysiology, 67(4), pp.931-943.
[20]Buneo, C.A., Soechting, J.F. and Flanders, M.A.R.T.H.A., 1994. Muscle activation patterns for reaching: the representation of distance and time. Journal of Neurophysiology, 71(4), pp.1546-1558.
[21]Bagheri Rouchi, M., 2013. ‘Evaluation of Trunk Movement System Strategies through the Concept of Muscle Synergies’, M.Sc Thesis, Department of Mechanical Engineering Sharif University of Technology, Tehran, Iran.
[22]Abdollahi, M., Nikkhoo, M., Ashouri, S., Asghari, M., Parnianpour, M. and Khalaf, K., 2016. A model for flexi-bar to evaluate intervertebral disc and muscle forces in exercises. Medical engineering & physics, 38(10), pp.1076-1082.
[23]Khalaf, K., Abdollahi, M., Nikkhoo, M., Hoviattalab, M., Asghari, M., Ashouri, S., Nikpour, S., Kahrizi, S. and Parnianpour, M., 2015, August. A Mechanical model for flexible exercise bars to study the influence of the initial position of the bar on lumbar discs and muscles forces. In Engineering in Medicine and Biology Society (EMBC), 2015 37th Annual International Conference of the IEEE (pp. 3917-3920). IEEE.
[24]Anders, C., Wenzel, B. and Scholle, H.C., 2008. Activation characteristics of trunk muscles during cyclic upper-body perturbations caused by an oscillating pole. Archives of physical medicine and rehabilitation, 89(7), pp.1314-1322.
[25]Gonçalves, M., Marques, N.R., Hallal, C.Z. and van Dieen, J.H., 2011. Electromyographic activity of trunk muscles during exercises with flexible and non-flexible poles. Journal of Back and Musculoskeletal Rehabilitation, 24(4), pp.209-214.
[26]Hallal, C.Z., Marques, N.R. and Gonçalves, M., 2011. Electromyographic ratio of shoulder stabilizer muscles during performance of exercises with oscillatory poles. Revista Brasileira de Medicina do Esporte, 17(1), pp.31-35.
[27]Ting, L.H. and Macpherson, J.M., 2005. A limited set of muscle synergies for force control during a postural task. Journal of neurophysiology, 93(1), pp.609-613.
[28]Chang, Y.W., Su, F.C., Wu, H.W. and An, K.N., 1999. Optimum length of muscle contraction. Clinical Biomechanics, 14(8), pp.537-542.
[29]Tresch, M.C., Saltiel, P. and Bizzi, E., 1999. The construction of movement by the spinal cord. Nature neuroscience, 2(2), p.162.
[30]Ivanenko, Y.P., Poppele, R.E. and Lacquaniti, F., 2004. Five basic muscle activation patterns account for muscle activity during human locomotion. The Journal of physiology, 556(1), pp.267-282.
[31]Gottlieb, G.L., Song, Q., Almeida, G.L., Hong, D.A. and Corcos, D., 1997. Directional control of planar human arm movement. Journal of Neurophysiology, 78(6), pp.2985-2998.
[32]Wood, J.E., Meek, S.G. and Jacobsen, S.C., 1989. Quantitation of human shoulder anatomy for prosthetic arm control—II. Anatomy matrices. Journal of biomechanics, 22(4), pp.309-325.
[33]Van der Helm, F.C., 1994. Analysis of the kinematic and dynamic behavior of the shoulder mechanism. Journal of biomechanics, 27(5), pp.527-550.
[34]Buneo, C.A., Soechting, J.F. and Flanders, M., 1997. Postural dependence of muscle actions: implications for neural control. Journal of Neuroscience, 17(6), pp.2128-2142.