View clinical trials related to Muscle Loss.
Filter by:ICUacquired weakness is a common complication of critical illness, particularly in patients receiving mechanical ventilation and/or suffering from conditions leading to the systemic inflammatory response syndrome.
Patients suffering from cancer often experience a loss of muscle mass and strength during disease and its therapy. Muscle wasting is the main characteristic of the so-called cancer cachexia syndrome and responsible for many therapy-related complications and a poorer prognosis of the patient. Stabilizing muscle mass should therefore be a great goal in cancer care. Physical exercise and nutrition are promising measures to combat cancer-related muscle atrophy but conventional exercise programs may not always be suitable for physical-weakened patients and increased catabolic processes are difficult to overcome by normal Nutrition - especially in advanced cancer. Therefore, the present study aims to test a combined approach of specific nutritional supplementation and exercise using the novel strength training method of Whole-Body electromyostimulation (WB-EMS). The study investigates the effect of a 12-week WB-EMS training combined with a dietary supplementation of β-hydroxy-β-methylbutyrate (HMB), L-carnitine (LC) or the omega-3-fatty acid eicosapentaenoic acid (EPA) on skeletal muscle mass, body composition, physical function, nutritional and inflammatory status, fatigue and quality of life in cancer patients undergoing oncological treatment. The results of this study may help to clarify the effectiveness of those combined interventions to counteract muscle wasting and other symptoms of cancer cachexia.
The aim of this study is evaluate the effect of whey protein supplementation on muscle mass preservation, improvement of strength and quality of life, and inflammatory parameters in patients with heart failure NYHA I or II followed by a cardiac rehabilitation program.
In this study, we aimed to examine the effect of whey protein supplementation given before night sleep on Fat Free Mass (FFM) preservation during a 4 wk period on Very Low Caloric Diet (VLCD). Half of the participants underwent a 4 week VLCD and walking program, while the other half underwent a 4 week VLCD, walking program and had an additional protein supplement before each night sleep.
The purposes of this study are 1) to determine whether neuromuscular electrical stimulation (NMES) is effective in preventing loss of muscle mass and strength and 2) to observe the time variation of MLT and strength from preoperative day to hospital discharge.
This study evaluates the effects of a 12-week whole-body electromyostimulation (WB-EMS) training combined with individualized nutritional support on body composition, muscle strength and function and quality of life of patients with malignant disease undergoing curative or palliative anti-cancer treatment
A minimum of 450 healthy individuals (62-70 years old) will be recruited. Each individual will be randomized into one of three groups stratified according to gender (M/F), BMI (≤28/>28), and 30 sec chair stand (≤11/>11). The three groups are Heavy resistance training (n=150), moderate intensity training (n=150), and control (n=150, no training). Assessments will be performed at baseline, after 12 months of intervention. Furthermore, follow up will be performed after 2,4,7, and 10 years. The primary outcome is change in leg extensor power after the intervention and during follow up. The primary hypothesis is that by applying the intention-to-treat analysis, the moderate intensity training group will increase leg extensor power just as much as the heavy resistance training group. The two training groups will increase muscle power more than the control group.
Up to 66 healthy elderly individuals (at least 65 years old) are recruited as subjects. They will be recruited as a subgroup to protocol ID: H-4-2013-070. Upon inclusion, each individual will be randomized into one of the five groups stratified according to gender (M/F) and 30s chair stand (<16 OR ≥16). The five groups are: Heavy Resistance Training (N=12), Light Intensity Training (N=12), Protein Whey (N=15), Protein Collagen (N=15) and Carbohydrate (N=12). The individuals randomized into one of the supplementation groups (Protein Whey, Protein Collagen or Carbohydrate) will be blinded to the supplement content. Assessments will be performed at Baseline (before intervention start) and after 12 months of intervention. The primary outcomes are measures of muscle protein synthesis rate measured as the fractional synthesis rate from Baseline to 12 months of intervention. The hypotheses are i) that basal and protein-stimulated muscle protein synthesis rates are elevated in the exercise training groups after 12 months of intervention. ii) prolonged intake of protein of different quality will improve the muscle protein synthetic response to protein intake after 12 months of intervention.
From 3 interventiongroups in the project with ClinicalTrials.gov ID NCT02034760, namely: HRTW: Heavy Strength Training x3/week & 20g whey protein twice daily. LITW: Light Intensity Training x3-5/week & 20g whey protein twice daily. WHEY: 20g whey protein twice daily. 15 subjects from each group will be recruited and tested after 3 months of intervention. Tests will include muscle cross sectional area (MRi), muscle biopsies (fiber types, size, cell- and capillary count), functional- and strength measurements, plasma lipids, HbA1c. Tests are to be compared with Project ID NCT01997320.
Up to approximately 205 (dependent on drop-out rate) healthy elderly individuals (at least 65 years old) are recruited as subjects. Upon inclusion, each individual will be randomized into one of the five groups stratified according to gender (M/F) and 30s chair stand (<16 OR ≥16). The five groups are: Heavy Resistance Training (N=30-35), Light Intensity Training (N=30-35), Protein Whey (N=40-50), Protein Collagen (N=40-50) and Carbohydrate (N=30-35). The individuals randomized into one of the supplementation groups (Protein Whey, Protein Collagen or Carbohydrate) will be blinded to the supplement content. Assessments will be performed at Baseline (before intervention start), and after 6 and 12 months of intervention and again at 18 months (after 6 months of follow up). The primary outcome is change in quadriceps muscle cross sectional area from Baseline to 12 months of intervention. The primary hypothesis is that by applying the intension-to-treat analysis, the Light Intensity Training group will increase quadriceps muscle cross sectional area just as much as the Heavy Resistance Training group. The two training groups will gain more muscle mass than the Protein Whey group, which will gain more than the Protein Collagen and the Carbohydrate groups that will loose quadriceps muscle cross sectional areas.