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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

An investigation into the mechanisms of acute effects of dynamic stretching on ankle joint mechanics and running economy

Pamboris, George Michael January 2018 (has links)
Warm-up routines commonly include stretching to increase flexibility (joint range of motion - ROM), optimise performance, and reduce the risk of injury. Literature suggests that static stretching as part of the warm-up routines decreases force and power production compared to an active warm-up or a warm-up including dynamic stretching, and therefore could be detrimental to performance. This has led to an increased interest in the use of dynamic stretching by many athletes while the benefits of such interventions and their potential mechanisms of action are not well understood. Studies presented in this thesis were conducted to examine the effects of acute dynamic stretching on aspects of performance (e.g. torque production capacity of the plantarflexors and running economy) and to identify possible neuromechanical mechanisms underpinning any potential changes. Furthermore, we attempted to examine whether altered pain tolerance/perception to stretch may be a contributing factor to the increased ROM using adaptations in the neural substrates involved by using functional magnetic resonance imaging (fMRI) technique. In the first study, both slow dynamic stretching and fast dynamic stretching increased ROM, and this was due to an increased tendon elongation. Importantly, dynamic stretching was not detrimental to the torque producing capacity of the ankle plantarflexors. Effects of dynamic stretching on the sensorimotor performance remained mainly unclear. Employment of shear wave elastography technique in the second study suggested an increase in muscle stiffness, a decrease in fascicle strain, and showed an increase in muscle thickness after dynamic stretching, supporting an increase in tendon compliance as a contributing factor to increased flexibility after dynamic stretching. In the third study, the improved running economy by dynamic stretching may be attributable to the decreased dynamic joint ankle and vertical stiffness. The fMRI study was not conclusive due to methodological issues. Present findings have practical implications for the use of dynamic stretching in sporting contexts.
2

Measuring dynamic hamstring flexibility: Dynamic versus static stretching in the warm-up

Rebello, Gayle, n/a January 2006 (has links)
The main purpose of this study was to compare the acute effects of static and dynamic stretching in the warm-up, on hamstring flexibility using a reliable set-up for measurement. Static and dynamic flexibility was measured using five modifications of the Straight Leg Raise (SLR) test to measure hip flexion range of motion (ROM). In the first part of the study (n = 33) hamstring flexibility was measured using a Static-passive, Static-active, Dynamic-supine and Dynamic-standing tests. The results of this study were used to calculate reliability statistics and to compare the various static and dynamic flexibility tests. There was a significant difference between Static-passive (SPH) and the Dynamic-supine (DSUH) tests (p less than .05). This was followed by an intervention study (n = 12) where participants were randomly assigned to three intervention treatments of 225 seconds on separate days: No stretching (Treatment I), Static stretching (Treatment 2) and Dynamic stretching (Treatment 3) in a cross-over study design. Static stretching had no impact on dynamic hamstring flexibility; however, dynamic stretching improved dynamic flexibility while simultaneously increasing static flexibility. This has implications for the specificity of stretching in sport.
3

THE EFFECTS OF STATIC AND DYNAMIC STRETCHING ON COMPETITIVE GYMNASTS’ SPLIT JUMP PERFORMANCE

Harper, Erin N. 10 August 2011 (has links)
No description available.
4

Static Versus Dynamic Stretching Effect on Agility Performance

Troumbley, Patrick 01 May 2010 (has links)
The purpose of this study was to compare effects of static and dynamic stretching on explosive agility movements, and to examine the effect of the interaction of dynamic and static stretching prior to explosive agility movements. Fourteen men and 10 women performed the different warm-up protocols, including no warm-up (NWU), static stretching (SS), dynamic stretching (DS), and dynamic stretching with static stretching (DS+SS). The T-Drill was used to assess agility. The results indicated no difference between the NWU and SS conditions (effect size = 0.40, p = 0.06), as well as no significant difference between the NWU and DS+SS conditions (effect size = 0.01, p = 0.48), and the SS and DS+SS conditions (effect size = 0.40, p = 0.06). Statistically significant differences were found between the NWU and DS conditions (effect size = 0.45, p = 0.03), the SS and DS conditions (effect size = 0.85, p < 0.001), and the DS and DS+SS conditions (effect size = 0.40, p = 0.03). Agility test times, in order from fastest to slowest, were (a) dynamic stretching (10.87 ± 1.07 s), (b) dynamic stretching + static stretching (11.41 ± 1.26 s), (c) no warm-up (11.42 ± 1.21 s), (d) static stretching (11.90 ±1.35 s). Dynamic stretching resulted in the fastest agility test time. Static stretching resulted in the slowest agility times. The benefits of dynamic stretching may have been diluted when followed by Static Stretching, and the agility test time was the same as if no form of stretching was completed. Static stretching prior to agility is not recommended as it has a negative effect on the stretch shortening cycle, and agility. The results support the use of dynamic stretching prior to agility performance.
5

The Acute Effects of Various Stretching Modalities on Performance across a Time Spectrum in NCAA Division I Volleyball Players

Kruse, Nicholas T. January 2010 (has links)
No description available.
6

Dynamické rozcvičení u závodních hráčů tenisu / Dynamic warm-up race for tennis players

Koskuba, Jakub January 2012 (has links)
Title: Dynamic warm-up race for tennis players Subject: Male and female tennis players from tennis club Tj Lokomotiva Plzen Objective: Compare immediate influence of static and dynamic stretching on performance level during particular movement tests using device Myotest PRO Methods: To meet the objective quantitative comparison was used by performance parameters using load accelerometer. Quantitative stress parameters were evaluated for individual tests as the mean value from a large amount of repetition in individually evaluation. Results: Tests proved it is not possible to confirm acute positive influence of dynamic stretching on all assesed parameters in different tests. In terms of average values of different tests a noticeable lower limbs improvement has been emerged at two out of three tests. Keywords: dynamic stretching, warm up, sport, injuries, regeneration, tennis
7

Akutní vliv statického a dynamického strečinku na výskok / Acute effect of static and dynamic stretching on vertical jump

Dostálová, Anna January 2017 (has links)
Title Acute effect of static and dynamic stretching on vertical jump. Objectives The aim of this thesis is to assess whether it is better to warm up by static or dynamic stretching in order to improve performance in the vertical jump. Methods The first part of this thesis is theoretical and is the basis for measurement, which is described in the second part. The tested set consists of ten women volleyball players. Each player underwent three vertical jump measurements on power plates Kistler, which recorded flight time of the player over the plates. All measurements were evaluated afterwards. Five attempts were recorded in each measurement. Measurements were carried out without stretching, after dynamic stretching and after static stretching. The thesis includes a survey that monitors the perception of the players` performance. Results Results of the total tested set measurement show that inclusion of dynamic stretching during the warm up leads to a slight decline in the physical performance. This decrease presents about 0.92%. Another conclusion of this research is that the inclusion of static stretching to the warm up also results in a slight decrease in the athletic performance. In this case the decrease is about 1.72%. In a direct comparison of these two types of stretching, the inclusion of...
8

Komparace efektivity rozcvičení florbalistů / Comparasion of effectiveness of florball warm-ups

Řehulka, Filip January 2017 (has links)
Názevpráce Komparace efektivity rozcvičení florbalistů Cíle práce Zjistit, které z vybraných druhů rozcvičení má největší vliv na rychlostní výkon florbalisty. Metoda Data pro komparaci efektivity rozcvičení budou dosažena pomocí srovnávací studie, kdy probandi podstoupí různé druhy rozcvičení. Probandi budou testováni testovou baterií, která je součástí kondičních testů české reprezentace. Využity budou fotobuňky zapůjčené od České florbalové unie. Výsledky Zobrazují efektivitu jednotlivých druhů rozcvičení florbalistů. Klíčová slova Rozcvičení, dynamický strečink, florbal, experiment, komparace
9

Dynamic Warm-Up Improves Mean Power Output Compared to a Warm-Up With Static Stretching

Rucker, Timothy A. January 2011 (has links)
No description available.
10

Vliv rozcvičení na sílu úderu / Acute effect of warm-up on the force of a punch

Rudolf, Jan January 2020 (has links)
Title: Acute effect of a warm-up on the force of a punch Objectives: The aim of this diploma thesis is to test whether a warm-up before a performance affects the force of a punch at a sample participants practicing full-contact combat sports. Further goal is to analyze a change in the force of a punch depending on elapsed time after warming up. Methods: Each participant in this experimental study with intra-subject design went through all phases of the measurement, where the force of a punch was tested in four specified times (before a warm-up and then 4, 10 and 25 minutes after the warm-up). Results: No statistically significant effect of a warm-up on the force of a punch was observed, nor was there a statistically significant change in the force of a punch during the time following a warm-up. However, a warm-up did have a significant effect on change in heart rate and body temperature. Keywords: Combat sports, performance, fight, dynamic stretching, explosive power, punch sensor

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