View clinical trials related to Hamstring Injury.
Filter by: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.
The aim of this study is to investigate the effects of blood flow restriction applied during nordic hamstring exercise on neuromuscular activation and endothelial function.
The sedentary lifestyle of today's world, prolonged time period of sitting during office hours and educational setups do have an effect on the flexibility of bi-articular muscles. Hamstring flexibility is a significant variable as decreased extensibility has been suggested as a prejudicing feature for injuries, poor posture and non-specific low back pain.Active Release Technique (ART) is a soft tissue method that focuses on relieving tissue tension via the removal of fibrosis/adhesions which can develop in tissues as a result of overload due to repetitive use. These disorders may lead to muscular weakness, numbness, aching, tingling and burning sensations. ART has been reported to be both a diagnostic and a treatment technique.Mulligan's bent leg raise (BLR) is a stretching technique which is a modern progression in the treatment of hamstring tightness. It is indicated in hamstring tightness patients with backache having restricted or painful straight leg raise (SLR), leg pain above knee and it is very beneficial in the patients having gross bilateral limitations of straight leg raise. It stretches the lower extremity muscles in combination of hamstring, adductors and rotators
The goal of this study is to explore the intervention effect of home-based neurodynamic slider program on hamstring flexibility. Fifty physically active male subjects will be randomly assigned to either performing a neurodynamic sliding technique (3x20 reps) or a static stretching protocol (3x30") on a daily basis for a 6-week period. Hamstring flexibility will be assessed by means of the Straight Leg Raise at baseline, immediately after the intervention and after 4 weeks follow up.
The invesitgators performed a randomized controlled trial on collegiate sprinters to explore the combined effect of the NHE and KT and randomly allocated the subjects into the experimental (NHE+KT) or control (NHE) group by an independent researcher using the sealed envelopes method. To calculate the sample size, a Cohen's d effect size of 0.4, an alpha level of 0.05, a test power of 0.95 were configured to G*Power software, at least 34 samples were computed. Considering the dropouts, 40 male collegiate sprinters were enrolled, explained the procedures of this study and voluntarily written informed consent. Inclusion criteria was that participants must be male, aged 18 years or older, training at the university level at least 4 times per week, with no history of lower limb injury within the last 6 months and no previous experience of the NHE or KT. Participants who had lower limb mobility limitation or injury especially HSI within 6 months and associated musculoskeletal, respiratory or cardiovascular diseases and was allergic to kinesio tape were excluded.
Despite the extensive research on prevention and prediction strategies, hamstrings strains injury (HSI) persists at a high rate in team sports and specifically in football. An initial injury increases the risk for re-injury and affects performance, whereas the financial cost for athletes and teams is crucial due to the time needed for appropriate rehabilitation. For that reason, it is critical to formulate better strategies in order to predict and prevent HSI. This study aims to develop a system dynamics (SD) model to evaluate HSI risk. First, a literature review will be carried out on the current approaches and identification of intrinsic and extrinsic risk factors of hamstrings strain injuries. Second, co-creation workshops based on the method of Group Modeling Building (GMB) will be applied to develop the SD for the HSI model. This co-creation process will involve stakeholders such as sports physiotherapists, doctors, and sports scientists. After creating the SD for HSI model, a one-year prospective cohort study will be performed to validate the model with real data and evaluate the ability of the model to predict HSIs. Sports teams will be invited to take part in the validation of the model. Multiple biomechanical parameters and other personal characteristics will be collected. Then, athletes will be monitored for the occurrence of injury and their exposure to injury risk during training and games. The factors' non-linear interaction will be assessed with the statistical method of structural equation modeling and factor analysis. In this way, the factors' interactions extracted for the qualitative phase of the study (group modeling building process) will be quantitatively evaluated. Validating the model with real data will provide a computer simulation platform to test plausible strategies for preventing hamstrings strain injuries prior to implementation and optimize intervention programs.
The purpose of this study is to examine the acute and chronic effects of high frequency electrical current transfer (frequently called "TECAR") on pain and functional movement in individuals with a musculoskeletal injury or pain. The participants will be assigned into an experimental or a control group and outcome measures will be measured prior to, after, 24 and 48 hours following a single intervention session (Acute effects) as well as 3 and 6 months after the intervention (chronic effects).
The investigators will combine state-of-the-art quantitative imaging, on-field biomechanics, and computational analytics into the largest-of-its-kind study to assess hamstring strain injury (HSI) risk and recovery in elite collegiate football players. The study will take place over 3 years and enroll up to 560 student athletes from Division I (D1) teams: University of Wisconsin-Madison, Brigham Young University and the University of North Carolina-Chapel Hill.
Ninety male subject will be divided into three group: a younger group (18-22y), an older group (30-40y) and a control group (18-40y). The study comprises 3 phases. PHASE 1: baseline strength and stiffness measurements of the hamstring muscles, PHASE 2: 12 week Nordic Hamstring strength training program (not for the control group) and PHASE 3: final strength and stiffness measurements. The aim of this study is twofold, namely to investigate (1) whether there is a difference in baseline stiffness of the hamstring muscle complex between different age categories and (2) the evolution of hamstring muscle stiffness during an eccentric strength training program within the different age groups. These two research questions could ultimately lead to a possible answer on the question if the higher probability of HSI (=hamstring strain injury) in the older age category with the lowest levels of eccentric hamstring strength could be due to an age-related difference in hamstring stiffness.
This project was a Randomized clinical trial conducted COMPARATIVE STUDY OF POST ISOMETRIC RELAXATION AND MULLIGAN BENT LEG RAISE ON HAMSTRING TIGHTNESS IN HIGH SCHOOL STUDENTS