View clinical trials related to McArdle Disease.
Filter by:Previous studies have indicated that 13C-MRS in the ultra-high 7T magnetic resonance (MR) field is a potential non-invasive measurement method for assessing changes in muscle glycogen levels in PoD patients. However, in a single study, increases in glycogen intermediates were observed using the even more sensitive 31P-MRS technique in a mouse model of PoD and in glycogen storage disease III in humans. In fact, glycolytic intermediates such as phosphomonoesters (PME), measured by phosphorus-31P-MRS in PoD mouse models, were superior to 13C-MRS in monitoring disease progression and quantifying glycogen, indicating a significant clinical potential of 31P-MRS in humans. It has been shown that 31P-MRS can reliably quantify age- and weight-related differences as well as changes in thyroid function in human muscle metabolism. This study conducted by our institute demonstrates that the technique possesses the necessary sensitivity to measure these subtle muscular metabolic changes. However, there are currently no human 31P-MRS muscle data available for PoD. Therefore, we propose a proof-of-principle study to address this knowledge gap and contribute to establishing a new sensitive muscular biomarker that quantifies the primary disease mechanism, namely glycogen formation, for future longitudinal studies on PoD.
The project will use carbon-13 magnetic resonance spectroscopy to assess whether high glycogen levels in skeletal muscle of patients with Glycogen Storage Diseases is a prelude for muscle damage. Patients with Glycogen Storage Diseases will be examined using carbon-13 MR-spectroscopy to quantify the glycogen levels in lumbar, thigh and calf-muscles. The pattern of glycogen concentration will be compared to the pattern of muscle atrophy found in the literature.
The purpose of this survey is to report experiences with variants of a ketogenic diet in a group of individuals diagnosed with McArdle disease (glycogen storage disease type V). Further more the survey will report on physical activity, fatigue, sleep and quality of life in this cohort.
The purpose of the study is to explore the biomarker Fast Troponins response to exercise in patients with Becker muscular dystrophy, Limb-girdle muscular dystrophy and McArdle disease
The purpose of this study is to assess REN001 safety in subjects with McArdle Disease
McArdle disease, glycogen storage disease type V, is a rare metabolic disease. Affected individuals are unable to utilize sugar stored as glycogen in muscle. Investigators hypothesize that a modified ketogenic diet could be a potential treatment option, by providing ketones as alternative fuel substrates for working muscle. This blinded, placebo-controlled, cross-over study will investigate the potential effects of an optimal modified ketogenic diet found in part A (75% fat, 15%protein, 10%carbohydrates) in patients with McArdle disease compared with a healthy balanced placebo diet (>100grams of carbohydrates per day).
McArdle disease, glycogen storage disease type V, is a rare metabolic disease. Affected individuals are unable to utilize sugar stored as glycogen in muscle. Investigators hypothesize that ketones can be an alternative fuel substrate for skeletal muscle when muscle glycogenolysis is blocked as in McArdle disease. In this study investigators will investigate the immediate effects of an oral supplementation of exogenous ketone bodies (poly-hydroxybuturate) on exercise capacity in patients with metabolic myopathies, compared with a placebo drink.
McArdle disease, glycogen storage disease type V, is a rare metabolic disease. Affected individuals are unable to utilize sugar stored as glycogen in muscle. We hypothesize that a modified ketogenic diet could be a potential treatment option, by providing ketones as alternative fuel substrates for working muscle. In this open interventional pilot study we wish to investigate 3 different modified ketogenic diet regimes, to find an optimal composition of a modified ketogenic diet that ensures adequate degree of ketosis and at the same time is well tolerated for patients with McArdle disease.
The aim of this study is to quantify muscle relaxation properties of the finger flexor muscles in patients with different myopathies. The inhibiting effects of transcranial magnetic stimulation (TMS) on the cortical motor hand area are used to induce relaxation, which in turn will be monitored with handgrip dynamometry and EMG. The investigators will evaluate if this technique can be implemented as a diagnostic tool in clinical practice. Muscle relaxation is an often overlooked property of the muscle as compared to muscle strength or activation. Muscle relaxation is affected in different myopathies, such as myotonic dystrophy, non-dystrophic myotonias, and Brody myopathy. Therefore, a diagnostic tool to quantify muscle relaxation is of clinical and scientific importance. In this study, transcranial magnetic stimulation (TMS) is used, in combination with a dynamometer to quantify muscle relaxation properties. Transcranial magnetic stimulation (TMS) is a non-invasive technique that is commonly used to stimulate the brain. In practice, a circular coil is held directly above the scalp, upon which a strong current pulse induces a magnetic field that stimulates the underlying superficial brain areas. This stimulation can have both activating and inhibiting effects. When the motor cortex (i.e. the area of the brain that controls muscle contractions) is strongly stimulated with TMS during a voluntary muscle contraction, both excitatory and inhibitory effects can be observed in the muscle the targeted cortical area controls. The inhibitory effect entails a transient interruption of neural drive to the muscle. This interruption, called the "silent period", lasts for less than half a second and results in the relaxation of the muscle. Muscle activity and control quickly return to normal after the silent period. The elegance and main advantage of TMS-induced muscle relaxation lies in the fact that it excludes all voluntary influences on the relaxation process. Furthermore, the TMS pulse causes all muscle fibres involved in the contraction just prior to the onset of the silent period to relax simultaneously. This allows us to study muscle relaxation as only a property of the muscle, i.e. without voluntary influences. In this study, the investigators will measure muscle relaxation in several myopathies (McArdle disease, Nemaline myopathy type 6 and myotonic dystrophy type 2) and compare this to healthy controls and to controls with no myopathy but with similar complaints (myalgia, stiffness, cramps). The data from these two control groups has been gathered previously in a different study. The investigators will also compare this to patients suffering from Brody disease who were previously measured in a different study. Muscle relaxation will be evaluated in fresh and fatigued finger flexor muscles. The main outcome of this study is the peak relaxation rate normalized to the peak force preceding relaxation. The final outlook of this research is to evaluate whether muscle relaxation studied with TMS, can be used for different myopathies as a diagnostic tool, to monitor disease progression, and to study the effects of different interventions (e.g. medication, exercise).
McArdle disease is a metabolic myopathy characterised by the absence of glycogen phosphorylase in skeletal muscle. Sodium Valproate is part of a group of drugs known as histone deacetylase inhibitors, which have a direct effect on chromatin. Recently a drug trial in an animal model of McArdle disease showed that sodium valproate stimulated the expression of a different isoform of the missing enzyme in skeletal muscle. A safety and feasibility study of sodium valproate in people with McArdle disease has been carried out in London (UK) and Copenhagen (DK) since January 2015. Participants will receive 20mg/Kg/day of sodium valproate for 6 months. The primary outcome measure is exercise performance assessed by cycle ergometry. Pre and post-treatment skeletal muscle biopsies will be performed to assess for glycogen phosphorylase. Together with blood analyses for safety. Additional functional exercise tests will be performed.