Abstract
The effect of different strength training regimes, and in particular training utilizing brief explosive contractions, on tendinous tissue properties is poorly understood. This study compared the efficacy of 12 weeks of knee extensor explosive-contraction (ECT; n = 14) vs. sustained-contraction (SCT; n = 15) strength training vs. a non-training control (n = 13) to induce changes in patellar tendon and knee extensor tendon–aponeurosis stiffness and size (patellar tendon, vastus-lateralis aponeurosis, quadriceps femoris muscle) in healthy young men. Training involved 40 isometric knee extension contractions (three times/week): gradually increasing to 75% of maximum voluntary torque (MVT) before holding for 3 s (SCT), or briefly contracting as fast as possible to ∼80% MVT (ECT). Changes in patellar tendon stiffness and Young’s modulus, tendon–aponeurosis complex stiffness, as well as quadriceps femoris muscle volume, vastus-lateralis aponeurosis area and patellar tendon cross-sectional area were quantified with ultrasonography, dynamometry, and magnetic resonance imaging. ECT and SCT similarly increased patellar tendon stiffness (20% vs. 16%, both p < 0.05 vs. control) and Young’s modulus (22% vs. 16%, both p < 0.05 vs. control). Tendon–aponeurosis complex high-force stiffness increased only after SCT (21%; p < 0.02), while ECT resulted in greater overall elongation of the tendon–aponeurosis complex. Quadriceps muscle volume only increased after sustained-contraction training (8%; p = 0.001), with unclear effects of strength training on aponeurosis area. The changes in patellar tendon cross-sectional area after strength training were not appreciably different to control. Our results suggest brief high force muscle contractions can induce increased free tendon stiffness, though SCT is needed to increase tendon–aponeurosis complex stiffness and muscle hypertrophy.
Highlights
The mechanical stiffness of muscle tendinous tissues is integral to the effectiveness of these tissues to transmit skeletal muscle force to the bone and generate movement
There were no differences in maximum voluntary torque (MVT) (p = 0.304), tendon– aponeurosis complex stiffness (p = 0.328), patellar tendon stiffness (p = 0.215), Young’s modulus (p = 0.184), quadriceps muscle volume (p = 0.508), and vastus lateralis aponeurosis area (p = 0.815), though a tendency existed for patellar tendon mean cross-sectional area (CSA) (p = 0.073)
The reproducibility of pre and post measures for the CON group over the 12-week intervention period was excellent for MVT (CVw 2.9%) and tendon–aponeurosis complex stiffness (3.9%), and very good for patellar tendon stiffness (7.2%) and Young’s modulus (6.8%)
Summary
The mechanical stiffness (resistance to deformation) of muscle tendinous tissues (aponeurosis and extramuscular free tendon) is integral to the effectiveness of these tissues to transmit skeletal muscle force to the bone and generate movement. Stiffer tissues may limit injury risk by providing greater joint stability and by perhaps reducing the loading imposed on passive joint tissue structures (meniscus, cartilage, ligaments), (Lipps et al, 2014). A particular concern is that traumatic joint injuries predispose to degenerative disease (e.g., anterior cruciate ligament) and the increased risk of knee osteoarthritis, which contributes to a reduced quality of life (Salaffi et al, 2005). Increased tendinous tissue stiffness could have functional and clinical implications, identifying effective interventions to stimulate tendinous tissue adaptations is warranted
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