View clinical trials related to Motor Imagery.
Filter by:Plyometric training (PT) is training consisting of exercises that enable the muscles to reach maximum strength in minimum time. PE improves lower extremity muscle strength, jumping performance, agility, reaction time. Although plyometric exercises contribute greatly to increasing athlete performance, athletes cannot apply PE due to loading procedures at all times of the season. PEs in the literature generally involve active application of exercises. The definition of exercise includes not only physical exercise but also mental exercise. Athletes can use mental exercises as complementary training methods that can complement or add to physical training to compensate for their deficiencies. When mental exercises are examined, we often encounter two concepts. These are action observation (AO) and motor imagery (MI). MI imagines a task without actually performing it. AO is when a person watches a certain action being performed by another third party or while the video is being played back. There are studies showing that training on MI and AO methods creates more activation in the brain when applied together. Although the definition of motor imagery has been broadly separated from action, more recent imagery theories have led to the concept of dynamic motor imagery (DMI), the practice of athletes adopting a harmonious body position and embodying the spatial and temporal properties of movement without performing the entire movement. To the best of our knowledge, no study has been found in which PT based on MI and AO was performed on female volleyball players. Additionally, to our knowledge, the effectiveness of DMI on female volleyball players has not been investigated. Therefore, the aim of our study is; PT based on MI and AO is applied to female volleyball players in two different ways; The aim is to investigate the effects of balance, jumping, agility and reaction time and to compare the effectiveness of these two methods.
Both motor imagery and action observation training, either alone or in combination with physical practice, have been shown to improve some clinical variables of interest such as strength and motor control. However, this has not yet been investigated in the pelvic floor musculature.
Mental practice (both in isolation and also in combination with real practice) has been shown to improve somatosensory and motor variables but so far no study has taken it into the study of women's health. Through this study we want to offer some interesting data regarding the effectiveness of mental practice combined with physical practice.
The aim of this study is to examine the investigation of the effects of motor imagery to facilitate sensorimotor re-learning training on performance and heart rate variability in adolescent basketball players.
About 50% of stroke patients are unable to live independently because of residual disability. Brain-computer interface (BCI) is based on closed-loop theory, which facilitates neurological remodeling by establishing a bridge between central and peripheral connections. Studies have confirmed that BCI real-time neurofeedback training system based on motor imagery alone can effectively improve patients' motor function. So, is the benefit greater if motor imagery is combined with motor execution? Current conclusions are mixed. In addition, previous studies and our preliminary study found that prefrontal Fp1 and Fp2 areas play an important role in motor recovery after stroke, and they are involved in motor imagery, motor execution, attention and other behavioral processes. Therefore, we designed a BCI training system based on motor imagery and motor execution with prefrontal electroencephalogram (EEG) signals as the modulatory target. This was a randomized placebo-controlled double-blinded clinical trial. Patients in the test group performed BCI-controlled upper extremity motor imagery + upper extremity pedaling training. The control group had the same equipment and training scenario, and patients were also asked to imagine the upper extremity pedaling movement with effort, and patients also wore EEG caps, but the EEG signals were only recorded without controlling the pedaling equipment. After 3 weeks of treatment, we observed the changes of motor and cognitive functions as well as fNIRS-related brain network characteristics in both groups.
This study will investigate if the use of motor imagery to practice a balance task is as effective as physically practicing balance tasks as measured by the Berg Balance Scale (BBS) in persons with MS. A secondary purpose is to investigate if using a motor imagery balance intervention will limit fatigue typically experienced with physical movement in this population.
The primary aim of this study is to investigate the effect of motor imagery training as an additional tool in the rehabilitation after anterior cruciate ligament reconstruction (ACLR). Therefore, ACLR patients will be recruited and randomly assigned into one of following groups: - Experimental group: Classic rehabilitation + Motor imagery training - Control group: Classic rehabilitation Both, the control and experimental group, will be submitted to a routine physiotherapy program after ACLR. In addition, the intervention group will be exposed to motor imagery training at three different time periods during the rehabilitation process (MI 1: immediately postoperative; MI 2: return to run; MI 3: change of direction). All participants will be invited for a preoperative screening, several postoperative screenings at 4-week time intervals and a final return to sport screening. At these test moments, participants will be subjected to a specific test battery consisting of subjective and objective clinical parameters. The subjective outcomes imply the patient's perception of pain and discomfort, level of participation, psychosocial well-being and overall quality of life. The objective clinical outcome measures relate to knee mobility and muscle strength, level of functioning/performance capacity and the detection of brain areas and networks involved in the processes of anxiety and worrying using EEG.
Low back pain is a common problem in society and causes loss of workforce. Its lifetime prevalence reaches 80% and annual hospital admission rates in the adult population reach 15%.Most studies on motor imagery suggested the effects of motor imagery are related to neuroplastic changes in the brain. Studies have shown that similar brain regions are activated during motor imagery and real movement. However, the level of evidence about the effect of motor imagery on autonomic functions is limited. Today, interest in telerehabilitation has increased due to the Covid-19 pandemic. The aim of this study is to examine the effects of telerehabilitation-based motor imagery training in patients with non-specific low back pain.