View clinical trials related to Exercise.
Filter by:Aerobic endurance training has shown positive effects on symptoms, cognition, daily functioning, and the structure of the hippocampus in patients with schizophrenia. The study investigates genetic and epigenetic influences on neuroplastic changes following three months of endurance training. A control group performs flexibility, strength, and balance training. The main objective is to examine the association between a genetic risk score for schizophrenia and volume increase in the CA4/DG region of the hippocampus. Additional goals include examining changes in synapses, brain structure, function, and metabolism, as well as clinical symptoms and cognitive performance.
This is a study of the effects of acute, exhaustive exercise on pro-resolving and pro-inflammatory responses in healthy, trained and untrained adults.
Background and study aims: Nine out of ten women experience some negative effects due to their disease or its treatment such as anxiety, depression, weight gain and low quality of life. Research shows that exercise may help women overcome some of these effects. The investigators also know that most women become physically inactive after cancer treatment. Therefore, The investigators feel it is important that women get into a routine of doing regular exercise before they start their cancer treatment, this is called prehabilitation. The investigators believe that prehabilitation might help to build confidence and help women to continue exercising after their cancer treatment. The investigators are doing this study to find out if a remote (NHS Attend Anywhere), multimodal (aerobic, resistance and targeted exercise), behavioural change (Health Action Process Approach (HAPA), dyadic coping (the collective effort to dealing with the stress of breast cancer diagnosis and treatment), and wearable technology), multiphasic (pre- and post-surgery) intervention is feasible in the short time frame between diagnosis of breast cancer and surgery (less than 31 days). The investigators would also like to find out whether it is feasible for women to begin an exercise rehabilitation programme two weeks after their operation. If successful, the results will potentially enable us in the future to tailor the support gievn to women to help them prepare and recover from breast cancer treatment.
This clinical trial will collect heart rate (HR) data with the Fitbit Inspire 2 fitness tracker and Polar H10 chest strap with the aim of: - Goal 1. Optimising and validating our artefact removal procedure. - Goal 2. Developing a physical activity (PA) algorithm to follow and quantify day-to-day PA based on HR measurements. A pilot study will be conducted with a total of 46 cardiac patients (group 1), 46 coached sporters with 12-week training schedule (group 2) and 46 sporters without 12-week training schedule (group 3). The three groups all engage in controlled activities. The participants' HR will be monitored continuously for an average period of 13 weeks using 2 HR monitors, i.e. the Fitbit Inspire 2 fitness tracker and the Polar H10 chest strap. They will wear the Fitbit device continuously for the whole monitoring period, while they will wear the Polar chest strap continuously for the first 24 hours and after that only during exercise. To determine participants' exercise capacity (e.g. VO2max), cardiopulmonary exercise tests (CPETS) will be carried out. For group 1, 3 CPETS will take place during the CR programme: at the start, in the middle and at the end. For group 2 and group 3, 2 CPETS will be carried out at the start and the end of the study. The monitoring period with Fitbit and Polar will end at the last CPET. All participants will record their daily efforts in an activity diary during the first week of study. Moreover, two questionnaires will be conducted at the end of the study to evaluates usability and experiences with the HR monitors.
This project evaluates the feasibility of using custom wearable technology and associated procedures to increase activity of the more-involved upper extremity during the earliest stages of recovery from stroke by increasing the amount of therapeutic exercise during idle-time. The proposed research is relevant to public health because it takes steps to mitigate a significant problem in physical rehabilitation using low-cost technology to motivate and monitor idle-time exercise without adding significantly to clinician workloads. The project aligns with the NICHD / NCMRR Research Plan on Rehabilitation by exploiting a mobile health (mHealth) and sensor-based approach to promote health and wellness through participant-engaged, data-driven, individualized care.
In Spain, overweight and obesity prevalence is reaching 70% in men and 50% in women. Excess of triglycerides are usually stored in the subcutaneous adipose tissue (SAT), until a point where SAT is unable to expand further. Therefore, lipids are deposited in visceral and other peripheral organs and tissues that are not otherwise designed for adipose storage such as the liver, pancreas or the skeletal muscle, a process known as ectopic fat deposition. "Time-restricted eating" (TRE) is a recently emerged intermittent fasting approach which has the potential to maximize the beneficial metabolic effects extensively reported for energy intake restriction. Furthermore, exercise reduces hepatic steatosis and improves cardiometabolic health in humans. However, whether the effects of TRE combined with exercise on reducing hepatic steatosis are superior to TRE or exercise intervention alone remains unknown. The TEMPUS study will investigate the effects of a 12-week TRE combined with supervised exercise intervention, as compared with TRE or exercise alone, and usual-care control group, on hepatic fat (primary outcome) and cardiometabolic health (secondary outcomes) in adults with obesity; and to unveil the role of gut microbiota.
This study aims to investigate the effectiveness of various recovery strategies (such as longer recovery periods or reduced exercise intensity) in optimizing both physical performance and overall health status. Furthermore, the study will explore the potential of using changes in blood and urinary markers as indicators for assessing recovery status. This study will assess whether extending recovery periods between exercise sessions and reducing the volume of exercise training can enhance the recovery process and enhance performance and health-related markers, relative to a control group. One hundred-fifth young males will be recruited to participate in a single-center, parallel-group, randomized, well-controlled, superiority trial for 8 weeks of high-volume exercise training. A single-center, parallel-group, randomized, well-controlled, superiority trial will be conducted among 150 physically active young males. Participants will undergo an 8-week high-volume exercise during base training program, which they will be randomly assigned to one of three groups: (1) a control group, which will follow the standard exercise regimen of 35 hours/week (n = 50); (2) a less exercise volume group, which will reduce exercise volume by 15% to 30 hours/week (n = 50); and (3) an extended recovery group, which will perform the same volume of exercise as the control group (35 hours/week), but with longer recovery intervals between exercises (n = 50). The intervention will take place at the Ministry of Defense training platform. All study measurements will be taken at baseline and throughout the study. Body composition will be assessed using multichannel bioelectrical impedance (Seca). Continuously monitor (Garmin) will be used to evaluate heart rate and heart rate variability. Fasting blood samples will be used to examine inflammatory, lipid, glycemic, and endocrine markers. Physical performance will be assessed by several validated assessments, including handgrip, maximal voluntary contraction, Wingate test, Isometric Mid-Thigh Pull (IMTP), counter movement jump (CMJ) and maximal oxygen consumption (VO2max).
Spinal muscular atrophy (SMA) is a serious neuromuscular disease characterized by the degeneration of alpha motor neurons in the spinal cord, resulting in progressive proximal muscle atrophy and denervation. The main problems are posture disorders, scoliosis, pelvic curvature, contracture, hip dislocation, foot and chest deformities. In this study, examining the effectiveness of trunk support used to alleviate the progression of scoliosis in children diagnosed with SMA Type I will contribute to the current literature.In addition to Individualized Trunk Exercises (ITE), Individualized Pulmonary Rehabilitation (IPR) and Chest Care (CC) Programme, the use of thoracolumbosacral spinal orthosis in Type I children will be used for the first time in our country and in the world literature. SMA. Our aim in the project is to examine the effectiveness of this treatment program on the motor functions, scoliosis Cobb angle, pelvic curvature and chest deformity of children with Type I SMA.The project is planned to be carried out with children diagnosed with Type I SMA who are followed up at Medipol Mega University Hospital Pediatric Chest Diseases Polyclinic.In evaluating the development of scoliosis as the primary outcome measure; Radiological evaluation (Cobb Angle) and examination of chest deformity; Lung X-ray (Basal Chest Wall Upper-Lower Ratio Measurement) will be used. As secondary outcome measures, the Children's Hospital of Philadelphia Infant Test for Neuromuscular Disorders and the Hammersmith Functional Motor Scale Expanded were used to assess motor functions and examine the level of motor development; In the World Health Organization Motor Development Scale body posture assessment; Supine Trunk Rotation Angle Test and Pelvic Curvature Test, pulse oximetry to assess oxygenation; In determining the level of satisfaction with orthosis use; Children/families' information will be questioned through the Quebec Assistive Technology User Satisfaction Evaluation Survey and Personal Information Form.The active control group will receive the ITE, IPR and CC program as a home program and once a week in the outpatient clinic for 8 weeks, 7 days a week, once a day, each session being 50-60 minutes. In the ITE-IPR-CC + spine orthosis group, in addition to the control group program, a thoracolumbosacral spine orthosis specially designed for the child will be used every day of the week and 8 hours a day for 8 weeks. Evaluations will be made at baseline and at week 8.
TITLE: Exergaming with Immersive Virtual Reality for people with Multiple Sclerosis INTRO: Multiple Sclerosis (MS) is an autoimmune and chronic neurodegenerative pathology caused by loss of the myelin sheath in the nervous system, causing motor, cognitive, behavioral and sensory symptoms. Conventional physiotherapy often includes exercise therapies, based on repetitive performances that can sometimes be unmotivating for patients. Immersive Virtual Reality could offer programs based on exercise (exergames) that are motivating, as well as appropriate to the therapeutic objectives of the target group. This tool has already been successfully tested in other groups (post stroke, Parkinson's,...) with promising results. Our ExeRVIEM project (Exergaming with Immersive Virtual Reality in Multiple Sclerosis) represents a new strategy to improve functionality in people with MS, using an exercise program with Virtual Reality glasses. HYPOTHESIS: The practice of the ExeRVIEM protocol based on physical function training in people with MS contributes to the maintenance and improvement of functional capacities, reducing the number of falls and increasing their personal autonomy. GENERAL OBJECTIVES: 1.1 Design and implement an ExeRVIEM exercise program/protocol to improve balance in older people 1.2 Analyze the effects of this ExeRVIEM program/protocol, in the short and medium term in people who attend an Association of patients. 1.3 Identify if there is a relationship between the variables that induce frailty and functional dependence and the ExeRVIEM protocol. SPECIFIC OBJECTIVES: 2.1 Determine and apply the ExeRVIEM protocol to explore differential effects for 6 minutes a day (2 days a week for 8 weeks). 2.1.1 Improving the functional independence and mobility of people by improving balance, reducing the risk of falls and the correct development of activities of daily living. 2.1.2 Gait improvement. 2.1.3 Improved functionality. 2.1.4 Improving grip strength. 2.1.5 Improving reaction times. 2.1.6 Improving the perception of fatigue 2.2 Determine the influence of parameters related to exposure to RVI. 2.2.1 Safety of the virtual reality exhibition 2.2.2 Usability of the virtual reality exhibition 2.2.3 Personal experiences and satisfaction of the virtual reality exhibition METHODS: Design: Randomized controlled trial. People diagnosed with MS who attend the AVEMPO VIGO center in Spain on a regular basis will be invited to participate in the study. After they meet the selection criteria, they will be assigned to an experimental group and a control group. Information on the sociodemographic characteristics and a clinical history of the participants will be collected. Intervention: Two groups (experimental and control). The experimental group will carry out the ExeRVIEM protocol sessions (6 min) focused on the upper and lower limbs. (2 sessions per week for 8 weeks). All sessions will begin with a warm-up focused on stimulating coordination and joint mobilization, so that the body is predisposed both centrally and peripherally to carry out the session and will end with a stretching routine accompanied by breathing calm and controlled cycles. The session will be supervised by the center's physiotherapist or occupational therapist. The control group will continue with the usual activities proposed by the center team. Evaluations: 3 evaluations will be carried out: initial, final (at 8 weeks) and follow-up (one month after the end of the program). The contents of the evaluations will be: Patient characteristics: "Ad hoc" record sheet that will include data on age, sex, years since diagnosis, MS subtype, and drug treatment. 1. ExeRVIEM protocol. Safety (Simulator Sickness Questionnaire), Usability (System Usability Scale) and personal experiences (Game Experience Questionnaire and "ad hoc" interview notebook) 2. Balance, gait and risk of falling (Tinetti Test) 3. Functional mobility and lower limb strength (Five times sit to stand test) 4. Functional autonomy (Timed Up and Go Test- simple and cognitive) 5. Fatigue (Fatigue Severity Scale) 6 Handgrip (dynamometer) 7. Reaction time (Rezzil Software) Hypothesis: Our findings aim to support the use of new health technologies in the field of rehabilitation and medical care for people with MS, achieving a feasible and safe Immersive Virtual Reality exergaming program.
The goal of this clinical trial is to investigate the effects of kinesthetic motor imagery training and dual-task training on cognitive and motor functions in healthy young people. The main question[s] it aims to answer are: - Kinesthetic motor imagery training and dual-task training do not affect cognitive and motor functions in healthy young people. - Kinesthetic motor imagery training and dual-task training affect cognitive and motor functions in healthy youth. - In healthy young people, kinesthetic motor imagery training is more effective on cognitive functions than dual-task training. - In healthy young people, dual task training is more effective on motor functions than kinesthetic motor imagery training. Participants will be divided into 3 groups, taking into account the inclusion and exclusion criteria. Participants in each group will be asked to fill out the sociodemographic form before starting the training. Then, initial assessments were the Motion Image Questionnaire-3 to measure motor imagery ability, and the Box and Block Test for mental stopwatch; Stroop Test to measure cognitive functions; In order to evaluate the dual-task performance, the measurement of the dual-task effect and the Berg Balance scale, which evaluates balance as a motor function, and the Y test, which is frequently used in healthy individuals, will be applied. In the balance exercises group, the participants will do the determined balance exercises 3 days a week for 6 weeks, accompanied by a physiotherapist. In the double-task training group, the participants will perform the cognitive tasks in addition to the determined balance exercises, 3 days a week for 6 weeks, accompanied by a physiotherapist. In kinesthetic motor imagery group, the participants will do the physically determined balance exercises in the first session. Participants will participate in imagery exercises, 3 sessions a week for 6 weeks. Visualization studies will be performed in a quiet environment with the eyes closed, accompanied by a physiotherapist, and whether the participants perform a real motor imagery will be examined by evaluating their autonomic functions. At the end of 6 weeks, initial evaluations will be repeated in all groups. The investigators will compare dual-task training group, kinesthetic motor imagery training group and balance exercises group to see if changes in cognitive and motor function.