View clinical trials related to Stretching.
Filter by:The primary objective of this study is to determine the immediate efficiency of stretching intensity on regional and distant pain sensitivity in healthy subjects. It is hypothesized that the analgesic effect of stretching may be linked with the intensity of stretching in a dose-response relationship.
To assess the immediate effects of hamstring stretching alone or combined with myofascial release of the hamstring muscle on masseter muscle activity, pressure pain threshold, active mouth opening, hamstring flexibility, and forward head flexed posture in recreationally active participants. The young, healthy, recreationally active adults aged 18-25 years were included in the study. The participants were randomly separated into two groups of equal number. Static stretching alone was applied to one group and this was combined with myofascial release techniques (SSMR) for the other group. Masseter muscle activity was assessed using a NORAXON® surface electromyography device. Both pre-and post-intervention, mechanical pressure algometer was used to measure the pressure pain threshold, hamstring flexibility was evaluated using the maximum hip flexion and active knee extension test, the maximum mouth opening (MMO) was measured with the millimetric ruler, and forward flexed posture was evaluated using the tragus to wall distance test.
Maintaining an adequate state of vascular function is an important element for the maintenance of cardiovascular well-being. Several training plans involving both active and passive engagement by the muscles have been proposed with the aim of improving vascular function. At local level, i.e., at the level of the arteries that supply the muscles directly involved in training, significant improvements in vascular function have been found. These improvements are more noticeable after active training than with a passive training regimen, such as passive static stretching. On the contrary, at the systemic level the effects of active or passive training are less clear and, above all, it is not evident whether there is a difference in the effects induced at the level of vascular function in arteries supplying muscles not directly involved in training. The aim of the study is to clarify the local and systemic effect of an active training protocol (single leg knee extension, SLKE) and of a passive training protocol (passive static stretching training, PST) applied to the lower limbs lasting 8 weeks on the local (femoral artery) and systemic (brachial artery) vascular function.
Muscular flexibility is believed to prevent injuries and improve movement therefore most coaches include stretching exercises in their pre-competition and pre-exercise warm-up routines. One question arises here, should sports persons avoid stretching exercises prior to sporting events thereby exposing themselves to musculoskeletal injuries, or should they continue stretching exercises prior to sporting events and risk losing the maximal performance? The aim of this study is to compare the effects of 2, 4, and 8 min of static stretching (SS) on isometric maximum voluntary contraction (MVCF) force between proximal (Hamstrings) and distal group (Calf) of muscles.
Recent research suggests that the skeletal muscles and the fibrous connective tissue form a body-wide network of myofascial chains. A systematic analysis of dissection studies suggests that fascia links at least a variety of muscles to myofascial chains (Wilke et al. 2015). As fascia can modify its stiffness, strain transmission along these meridians is supposable (Norton-Old et al. 2013). Tensile transmission along myofascial chains might contribute to the proper functioning of the movement system. However, despite solid evidence from in vitro studies, scarce data is available concerning the in vivo behavior of the meridians. The present study is conducted to resolve this research deficit and to elucidate whether stretching of the lower limb muscles increases neck mobility. Healthy subjects (n = 3 x 20) participate in the randomized controlled trial. One group performs three 30 s bouts of static stretching for the gastrocnemius and the hamstrings respectively. A control group remains inactive for the same time. Participants of the third group perform 6x30 s bouts of static stretching of the cervical spine in zhe sagittal plane (flexion only). Pre and post intervention as well as 5 min after the intervention, maximal cervical range of motion (ROM) in flexion/extension, lateral flexion and rotation was assessed using an ultrasonic movement analysis system.
Stretching is frequently used in clinical practice to manage musculoskeletal discomfort and to prevent sports injuries. It is not known if stretching affects pain sensitivity. The purpose of this study is to investigate if a 4 week daily stretching protocol alters pain sensitivity. The investigators hypothesize that stretching reduces pain sensitivity.
This two-site (Southern Methodist University (SMU) and Boston University (BU)) study aims to examine the effectiveness of exercise interventions for the treatment of generalized anxiety disorder (GAD). If effective, the use of exercise as a component of treatment for GAD would have a significant public health impact. In addition to improving GAD treatment outcome, exercise is expected to offer health benefits and promote further lifestyle changes. The present study involves the randomization of 52 adults with GAD to either a 12-week combined supervised- home-based moderate-intensity aerobic exercise protocol (EX) or a 12-week combined supervised- home-based stretching protocol (CTRL). The investigators hypothesize that participants in the EX intervention will evidence greater improvements in anxiety symptoms and quality of life relative to individuals receiving the control intervention.