Training-induced Changes in Development and Relaxation Electromechanical Delay (EMD)
Jenkins NDM, Housh TJ, Buckner SL et al (2016). Four weeks of high- versus low-load resistance training to failure on the rate of torque development, electrome-chanical delay, and contractile twitch properties. J Musculoskelet Neuronal Interact, 16(2):135-44.
Szpala A, Rutkowska-Kucharska A (2017). Electromechanical response times in the knee muscles in young and old women. Muscle Nerve,56(6):E147-E153.
Smith CM, Housh TJ, Hill EC, Keller JL, Johnson GO, Schmidt RJ (2017). Are there mode-specific and fatigue-related electromechanical delay responses for maximal isokinetic and isometric muscle actions? J Electromyogr Kinesiol, 37: 9-14.
Smith CM, Housh TJ, Hill EC, Keller JL, Johnson GO, Schmidt RJ (2017). Effects of fatigue and recovery on elec-tromechanical delay during isokinetic muscle actions. J Physiol Meas, 38(10):1837-1847.
Cè E, Rampichini S, Venturelli M, Limonta E, Veicsteinas A, Esposito F (2015). Electromechanical delay components during relaxation after voluntary contraction: reliability and effects of fatigue. Muscle Nerve, 51(6):907-15.
Koryak YA (2014). Influence of simulated microgravity on mechanical properties in the human triceps surae muscle in vivo. I: Effect of 120 days of bed rest without physical training on human muscle musculo tendinous stiffness and contractile properties in young women. Eur J Appl Physiol, 114:1025–36.