Active clinical trials for "Sarcopenia"

This study aims to 1) develop a strength-building lifestyle-integrated intervention for sarcopenic CAD patients and to 2) examine the feasibility and 3) preliminary effects of this intervention on skeletal muscle mass, muscle strength, physical performance, cardiac-related functional status and health-related quality of life (HRQoL), psychological distress, major adverse cardiovascular and cerebral events (MACCE) and hospital readmission rates

We are conducting a study in different centers in Spain in elderly people, in order to assess the effectiveness of a physical exercise intervention program in people in a situation of frailty. Frailty in an elderly person is a situation in which, although there are no major differences in their usual abilities, the person presents a certain decrease in their capacities. This slight decrease is usually accompanied by a progressive deterioration.

This clinical trial is intended to evaluate the effects of protein intake graded to resistance training volume over a 10-week period on macroscopic skeletal muscle adaptations and body composition. Briefly, all participants will complete a progressive resistance training protocol for 10 weeks, with one group consuming a constant amount of total daily protein (RDA of 0.8g/kg/day) to serve as an active comparator. The alternative group will consume total daily protein and protein supplement in a graded manner designed to increase as overall training volume increases. Protein intake and resistance training protocols are described in full elsewhere. The investigators hypothesize that the graded protein intake group will see larger benefits to skeletal muscle function, size, and body composition than the active comparator.

Protein-energy malnutrition (PEM) occurs in 65-90% of patients with liver cirrhosis. Severity of malnutrition correlates with progression of liver disease and leads to sarcopenia in 30-70% of cirrhotic patients. Malnutrition and sarcopenia are associated with an increased risk of complications and mortality. In cirrhosis the gut microbiome is altered leading to increased gut permeability, bacterial translocation and inflammation. Since the microbiome is involved in nutrient uptake and metabolism, it is hypothesized that microbiome alterations contribute to sarcopenia. A prospective controlled cohort study to investigate the interrelation of microbiome changes and sarcopenia in cirrhosis will be conducted. Furthermore the effect of nutritional interventions on the microbiome in cirrhosis will be studied. From this study information on how the gut microbiome composition and sarcopenia are associated in cirrhosis and if modulation of the gut microbiome by nutritional interventions is feasible will be collected.

The goal of this interventional study is to learn about the role of mitochondrial function in healthy aging, and then go on and assess the role of a home-based exercise program on the changes seen. The main question[s] it aims to answer are: What alterations in skeletal muscle mitochondrial function are seen in healthy aging? Can a short-term exercise program alter these alterations seen? The older participants will be invited to take part in a home-based 4 week exercise intervention involving either: High intensity interval training Resistance based training (resistance bands will be provided) Researchers will compare the two exercise groups to see if it alters mitochondrial function.

Aim: to analyse the effects of microcurrent treatment alone, and combined with a resistance exercise programme, on muscle strength, body composition and physical functional capacity in middle-aged adults. Methods Randomised, balanced, double-blind parallel-group between-participants design. Participants - non-regularly trained adults (people who do not engage regularly in physical sessions), aged 40 to 65 years old. All participants will be invited to take part in a 6-week supervised resistance training programme that will be combined with microcurrent (MC) or sham (SH) intervention. The participants who do not accept to undergo the resistance training programme will integrate a non-exercise group involving a 6-week intervention period using the microcurrent (MC) or the sham (SH) device. The devices will be provided by Arc4Health (ARC Microtech Ltd, UK; https://arcmicrotech.com/arc4health/). The device Arc4Health has regulatory approval as a Class IIa medical device in the areas of pain management and tissue repair. The following will be analysed: Microcurrent alone (MC) Microcurrent with exercise (MC + RT) Sham alone (SH) Sham with exercise (SH + RT) The participants who agree to take part in the training programme will have 2 sessions a week for a period of 6 weeks. The training programme involves elastic bands and is designed to increase strength and muscle mass. Measurements of body composition (via plethysmography BodPod), strength, functional capacity, muscular structure (via non-invasive ultrasound), and immunological blood markers will be undertaken at baseline and after the 6-week intervention period.

The purpose of this study is to assess the impact of 3-days reduced physical activity (<1500 steps/day) with/without 'exercise snacks' (15 chair stands with calf raises every 30 min) on skeletal muscle metabolic health.

The hand is important to perform activities of daily living (ADL). However, many people experience a loss of hand function as result of a traumatic brain injury, spinal cord injury, stroke or orthopedic problems, or due to ageing. To improve hand function, or reduce its decline, one can benefit from exercise therapy or use of assistive aids to improve ADL independence. A promising innovative approach combining both is a wearable soft-robotic glove that supports hand grip. With this glove, performance of functional activities can be supported directly, while also facilitating repeated use of the affected arm and hand during functional daily activities. One of our previous studies showed that besides a direct support effect, a therapeutic effect on performance was found after several weeks of using the soft-robotic glove as support during ADL. However, several participants reported complaints of increased pain and/or overload, mainly at the beginning of the trial. Clinicians suspect that a (too) high intensity of hand use compared to normal is contributing to this observation. This might be related to more fatigue experienced when using the glove in high-demand tasks, due to a larger movement capacity (faster, further, more repetitions) and can be associated with decreased blood perfusion/lower saturation levels at muscular level and altered muscle activation and movement coordination. Therefore, the primary objective is to examine the effect of use of the assistive soft-robotic glove during strenuous ADL tasks on the kinematic movement profile, compared to not using the soft-robotic glove. Secondary objectives are to examine whether pain or discomfort is experienced in strenuous activities with the soft-robotic glove as well as the characteristics and locations of such pain/discomfort, and to examine whether use of the glove is associated with increased handgrip strength, larger number of ADL task repetitions, diminished blood perfusion / reduced tissue saturation at the muscle and/or changes in muscle activity.

In modern society with an increasing aging population, recent literature has defined sarcopenia as a significant reduced mass and function of skeletal muscle with physical limitations due to aging. Clinically and experimentally, the foot often plays a crucial role in sensorimotor control and movement performance in standing, walking, and running. Apparently, previous literature has shown that the intrinsic and extrinsic foot muscles have significantly reduced muscle morphology and muscle strength in the elderly compared to that of young healthy controls. How to effectively increase foot muscles using muscle-strengthening exercises will be a crucial issue for further research and clinical intervention in this population. The intrinsic foot muscles (IFM) are the primary local stabilizer to provide static and dynamic stability in the foot, which are part of the active and neural subsystems to constitute the foot core system. The intrinsic foot muscles (IFMs) may play a key role in supporting foot arches (e.g., the medial longitudinal arch, MLA), providing flexibility, stability, shock absorption to the foot, and partially controlling foot pronation. Due to the difficulties in teaching and learning the plantar intrinsic foot muscle (IFM) exercise, the accuracy and follow-up after learning this exercise could be questioned following this exercise program. Physiologically, the effects of integrated exercise intervention may be achieved following more than 4-week intensive exercise intervention at least. How to learn and activate this kind of exercise efficiently and effectively is a key issue for employing these exercise interventions in the elderly with and without sarcopenia. In this project, we will aim to employ the novel intrinsic foot muscle strengthening device using 3-D printing techniques and to examine the feasibility and reliability of the morphology in intrinsic and extrinsic foot muscles and foot posture before and after exercise intervention using sonographic imaging and foot posture index in the elderly with and without sarcopenia; second, we will investigate whether the immediate and persistent increase in balance control and level-walking after this therapeutic exercise with novel 3-D printing foot core exerciser.

Dietary proteins potently augment muscle protein synthesis. Because of poorer anabolic sensitivity with ageing, studies and guidelines recommend higher dietary protein intake for older adults. Although higher doses would benefit skeletal muscle remodelling, large protein consumption is not feasible for many older adults. To circumvent, high-protein quality which possesses a high amino acid profile and digestibility appears to have an emergent role for supporting anabolism. Since currently the best line of defence against age related muscle loss is resistance exercise training and regular protein consumption, emphasising high-quality protein ingestion, such as whey protein, within meals may be feasible and efficacious in supporting musculoskeletal remodelling in older adults, without requirement for large protein doses. The investigators propose that at low doses, high quality protein will have additive benefit to muscle protein synthesis compared to low-quality protein. Further, combining high-quality protein diets with resistance exercise training will have more profound benefits for muscle protein synthesis and muscle remodelling more so than low-quality protein diets.