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Filter by:This study is to explore the effects of unilateral, bilateral and combined resistance training on the serve speed and accuracy of amateur youth tennis players in China. The subjects were young male tennis players aged 16-20 years from four universities in Gansu Province. The experiment was divided into control group (CG), experiment group 1 (EG1-unilateral group), experiment group 2 (EG2-bilateral group) and experiment group 3 (EG3-combined group). Used to compare the effects of different forms of resistance training on serve speed and accuracy. Previous studies have shown that unilateral and bilateral resistance training can effectively improve strength, power, and speed in athletes (Speirs, et al., 2016; Davo, Jimenez, & Solana,. , 2018), there is still controversy when comparing the advantages and disadvantages of two forms of resistance training (Ramirez-Campillo et al., 2015; Donab and Wall. The results of this study will be expected to be updated in 2022. Unilateral resistance training, bilateral resistance training, and combined unilateral and bilateral resistance training were used as intervention models in this study. Based on the literature review, the training frequency of this experiment was arranged as 2 times/week, and the total training time was 6 weeks, with a fixed duration of each training session. Each training session lasted a maximum of 60 minutes. In this experiment, the interval between the two weekly training sessions was at least 24 h to prevent subjects from being in a fatigued state in the relevant muscle groups of the body and affecting the experimental level.
Tendons are essential structures for transmitting muscle forces to skeletal structures. A stiffer tendon will transmit muscle force faster, and then allow faster movement. Moreover, tendons are a living tissue and respond to mechanical forces by changing their metabolism as well as their structural and mechanical properties. The aim of the present study is to answer essential questions remaining unanswered that are necessary in order to optimize physical activity with ageing in humans, and thus improve quality of life in elderly. The main questions are: What is the minimal training intensity leading to tendon adaptations? What is the time-course of tendon adaptations? Does the same loading protocol lead to similar tendon adaptations for different tendons (Achilles vs Patellar) and does the same training program lead to identical tendon adaptations with age (25yrs vs 75yrs)? To answer these questions, tendon architecture and mechanical properties will be investigated in humans of different age and applying different training intensities. The kinematic of the tendon adaptations due to these different training characteristics will also be investigated. The training protocol will be applied on plantar flexors and knee extensors. MRI and ultrasound techniques as well as the use of ankle and knee ergometers will allow the quantification of possible modifications in tendon architecture and mechanical properties (tendon stiffness and Young's Modulus). This will be assessed in vivo, using ultrasound images to assess tendon displacement during an incremental maximal contraction.