View clinical trials related to Muscular Atrophy.
Filter by:Patients with spinal muscular atrophy who are wheelchair users often experience lower back - and gluteal pain, reduced sleep quality, constipation and reduced quality of life - symptoms that regular exercise could potentially alleviate. However, only very little research has been done on exercise for patients who are wheelchair users. The aim of this study is to explore the impact of cycle exercise on patients with spinal muscular atrophy.
Skeletal muscle plays a critical role in supporting human health. Beyond its role in providing the force to move, skeletal muscle accounts for a large proportion of metabolic rate, glucose disposal, and amino acid storage. Skeletal muscle is dynamically regulated by environmental stimuli, such as loading (i.e., resistance training]) and unloading (i.e., disuse atrophy) as well as the intake of essential amino acids (EAAs). However, the precise mechanisms that regulate skeletal muscle mass in response to various conditions (e.g., EAA supplementation, resistance training, and unloading) are not completely understood. Therefore, concerted efforts to better understand the mechanisms regulating skeletal muscle size are needed that aid in the development of therapeutic interventions to combat age, disease, and disuse related muscular atrophy.
Substantial variability exists in the onset, and rate of degeneration across individuals with Motor Neurone Disease (MND) or Amyotrophic Lateral Sclerosis (ALS). This variability requires biomarkers that accurately classify and reliably track clinical subtypes as the disease progresses. Degeneration occurs in the brain and spinal cord, however, non-invasive diagnosis of spinal cord function remains highly challenging due to its unique alignment in spine. Disruption of complex spinal and cortical circuits that transmit and process neural signals for position sense and movement has not been adequately captured in the neurophysiological profiling of ALS patients. The overarching aim of this study is to reveal and quantify the extent of change in the sensorimotor integration and its potential contribution to network disruption in ALS.
Spinal muscular atrophy (SMA) is a group of disorders caused by the degeneration of the motor neuron cells of the anterior horn of the spinal cord and, in some subtypes, of the bulbar motor neurons. Almost all cases are genetically determined. Most SMAs are autosomal recessive diseases, caused by homozygous deletions of the survival motor neuron (SMN) gene located on the long arm of chromosome 5. The estimated incidence of recessive childhood and juvenile SMA linked to deletion of the SMN gene is 1 in 6000 to 10000 live births, with a carrier frequency of 1 in 35 in the general population, making it a major genetic cause of infant mortality. Up to 95-97% of all childhood cases are due to homozygous deletions of the survival motor neuron 1 (SMN1) gene, or telomeric SMN, located on chromosome 5q11.2-13.3. The remaining 3-5% of cases are due to small mutations in SMN1 (rather than complete deletions). Until a few years ago, the prognosis of type 1 SMA was poor. In the absence of therapies, the only measures were supportive (ventilation, nutrition) and the prospect, especially in the early forms, was to accompany them towards an early end of life. There are currently three treatment options available: nusinersen, risdiplam, and gene therapy with onasemnogene abeparvovec. The three options were found to be equally effective in reducing the symptoms of the disease, making it possible to reach or safeguard fundamental stages in a child's neuromotor development, starting from the ability to remain seated. At this moment, gene therapy is probably the preferred choice. To date, in Italy, there are approximately 100 patients undergoing gene therapy. To ensure maximum benefit for affected patients, it is essential that the therapy is administered as soon as possible. Literature shows how the administration of gene therapy in pre-symptomatic subjects made it possible to achieve a better neurological outcome compared to symptomatic patients. From this perspective, the inclusion of spinal muscular atrophy in neonatal screening is of fundamental relevance.
This study aims to determine, via skeletal muscle ultrasound (US), the extent, timing and relationship between skeletal muscle mass loss and outcomes after orthotropic heart transplantation (OHT) and left ventricular assist device (LVAD) implantation amongst patients with cardiogenic shock. Advanced therapies such as OHT and VADs in the heart failure (HF) population may promote skeletal muscle mass and subsequent quality of life, but there is a lack of literature assessing muscle mass changes in HF patients before and after advanced therapies using US imaging. Therefore this observational study will provide further insight into the 1) changes in lean body mass during critical illness and 2) the feasibility of using bedside US to assess lean body mass in the inpatient setting.
The objective of this multicenter randomized controlled trial is to compare a 6-month exercise and nutrition intervention (intervention group, IG) aimed at maintaining or improving physical functioning and quality of life with usual care (control group, CG) in ovarian cancer patients. The main question it aims to answer is: • Can an exercise and nutrition program improve physical performance during and after active treatment for ovarian cancer? Participants of the IG will undergo: - Weeks 1-18: approximately 15-30 minutes of daily exercise (cardio, resistance, and balance exercises); nutritional counseling focusing on malnutrition (protein-energy malnutrition). - Weeks 19-25: More intense daily training; nutritional counseling focusing on the Mediterranean diet. The study design includes 3 survey time points: - Baseline: After surgery and before starting chemotherapy - T1: After chemotherapy (week 19) - T2: After intervention (week 26) The primary outcome is: • 6-minute walk test, 6 months after enrollment (T2)
Post-intensive care syndrome (PICS) encompasses persistent physical, cognitive, and psychiatric symptoms following ICU discharge, commonly triggered by serious conditions such as respiratory failure, sepsis, and mechanical ventilation. PICS prevalence is reported to be as high as 84% up to 12 months in patients with at least 2 days spent in the ICU or with mechanical ventilatory support. As a consequence, many patients do not return to they former level of function for weeks, months and even years. Muscular affection manifested by muscle weakness is particularly seen and is provoked by a combination of damage to the nerves or directly the muscles fibers. This affection is referred to as CU-Acquired Weakness (ICUAW). One third of the time, lower extremities are affected, often due to prolonged immobilization or sedation. Evidence suggests that early mobilization reduces the incidence of ICUAW at discharge and improves the number of patients able of stand. However achieving this early intervention is not always feasible due to time or personnel constraints. The purpose of the study is to examine the effectiveness of lower extremity neuromodulation for prevention of muscle deconditioning in patients admitted to the ICU.
Muscle wasting occurs rapidly in critically ill patients and impacts both short and long term outcomes. Altered protein metabolism drives muscle loss in ICU patients, with muscle protein breakdown exceeding muscle protein synthesis (MPS). Interventions aimed at attenuating muscle loss by stimulating MPS rates are hampered by a lack of knowledge on altered muscle protein turnover rates during critical illness. Only a few studies have specifically assessed muscle protein synthesis by using contemporary intravenous stable isotope infusions, which allows the assessment of MPS over a short (<9 hours) period of time. Results from such acute studies can be difficult to extend or translate into long-term clinical practice and outcomes. Oral deuterated water (2H2O) dosing provides an alternative method that can be utilized to extend the measurement of muscle protein synthesis over a period of several days or weeks. It could therefore provide a valuable tool to study muscle protein synthesis during ICU admission and the impact of different anabolic interventions. Although multiple studies using the deuterated water methodology have been performed in both healthy volunteers and patients, it has not yet been performed in critically ill patients. In this prospective study the investigators aim to assess fractional rates of muscle protein synthesis over a period of (maximal) 7 days in critically ill patients admitted to the intensive care unit. Secondly, the investigators aim to assess mechanisms of acute muscle wasting on an microscopic, ultrastructural and molecular level. Furthermore, the investigators aim to investigate to what extent muscle fibre size is recovered 3 months after ICU discharge.
Loss of skeletal muscle mass (atrophy) and strength in the lower limb are consequences of elective knee surgery as result of prolonged disuse from limb immobilization and impaired mobility, as well as pathophysiological trauma. The highest rates of skeletal muscle mass and strength loss occur during the 2-week post-surgery period, considered the early phase of outpatient recovery. Alternative to resistance exercise and pharmacology, nutritional intervention represents one strategy to combat skeletal muscle disuse atrophy. Essential amino acids (EAA) and omega-3 fatty acids are known to independently potentiate rates of skeletal muscle protein synthesis and attenuate skeletal muscle atrophy in humans. However, the combined actions these nutritional strategies on skeletal muscle have not been explored in a pathophysiological context, such as surgery. With the ultimate goal to test the efficacy of the combined nutritional strategy to attenuate skeletal muscle disuse atrophy in the future, the aim of this present pilot study is to explore the feasibility of recruitment and retention of anterior cruciate ligament reconstruction (ACLR) outpatients from a single centre across 18 months for a 6-week nutritional intervention. Participants will consume either an intervention of omega-3 fatty acids and EAAs, or a placebo control of safflower oil and non-essential amino acids (NEAA), for 4 weeks before and 2 weeks after elective ACLR surgery. Furthermore, this pilot will characterize secondary outcomes of skeletal muscle mass, strength, and power, and integrated rates of muscle protein synthesis, as well as report participant adherence to protocols and incidence of adverse events.
This study will characterize intramuscular molecular mechanisms underlying anabolic resistance to protein ingestion during muscle disuse. Adults (n=12) will be studied using a unilateral leg immobilization model in which one leg will be randomly assigned to immobilization and the contralateral, active leg used as a within-subjects control. Immobilization will be implemented for five days using a rigid knee brace, during which time participants will ambulate using crutches. Integrated ribonucleic acid (RNA) synthesis will be determined during immobilization in the immobilized and non-immobilized legs using ingested deuterium oxide, salivary and blood sampling, and muscle biopsies. Immediately after immobilization, muscle biopsies will be collected before and 90 mins after consuming 25 g of whey protein from the immobilized and non-immobilized legs to characterize the intramuscular molecular response to protein feeding. Serial blood samples will be collected during that time to characterize the circulating metabolic response to protein ingestion. Knowledge generated from this effort will inform the development of targeted interventions for mitigating anabolic resistance to protein ingestion that develops during periods of muscle disuse.