Rhabdomyolysis Linked to a Hereditary Disease of Metabolism Clinical Trial
Official title:
Study of the Correlation Between the Effort Test, With the Assessment of Peripheral Oxygen Consumption and Cardiac Output in Patients With Acute Rhabdomyolysis Related to a Hereditary Disease of Metabolism, and the Biochemical Flux on Myoblasts: Evaluate the Effort Test as a Therapeutic Monitoring Tool in Acute Rhabdomyolyses
The prognosis of rhabdomyolyses related to hereditary diseases of metabolism is poor and treatments are only symptomatic. Rhabdomyolysis outbreaks are frequently precipitated by fever and fasting. They are unpredictable. In spite of the care of patient in an intensive care unit, the occurrence of renal failure and heart rhythm disorders explains a significant acute-phase mortality rate. There is an urgent need to understand the pathophysiological mechanisms of rhabdomyolyses related to hereditary diseases of metabolism, in order to identify specific treatments. Patients with rhabdomyolyses have few clinical signs outside of access. So there is a methodological difficulty in following a treatment test. There is an urgency to identify follow-up parameters in anticipation of new therapies. The objective of this study is to validate the hypothesis that effort test and cardiac function parameters are usable in the treatment monitoring for patients with acute rhabdomyolysis linked to a hereditary disease of metabolism and thus propose the effort test as an assessment tool for future clinical trials. In order to do so, the correlation between the results of the effort tests, performed to each patient with rhabdomyolysis related to a hereditary disease of metabolism, with the severity of the disease will be evaluated. This study is original because it opens up innovative prospects for monitoring in the field of hereditary diseases of metabolism, with the identification of new monitoring tools.
Rhabdomyolysis is a poorly known symptom associated with the destruction of skeletal muscle cells. The diagnosis of rhabdomyolyses is carried when the dosage of muscle enzymes, in particular creatine phosphate kinase (KPC), is greater than 1000 U/L (normal < 160 U/L). Rhabdomyolyses may be of viral origin, but fever and viruses are also triggers of genetic diseases. Also, the incidence of genetic rhabdomyolyses, representing 10 to 15% of all rhabdomyolyses, is underestimated. Genetic causes are heterogeneous. They are mainly attributed to hereditary diseases of metabolism, in particular fatty acid oxidation defects, Lipin-1 deficiency, muscle glycogenoses, TANGO2 deficiency, mitochondrial cytopathies and calcium channels anomalies of in particular RYR1. Whatever the cause, traumatic, infectious or genetic, the rhabdomyolyses cause an alteration of the metabolism of adenosine triphosphate and a deregulation of the ionic channels, with the consequences of an intracytoplasmic calcium release and the destruction of muscle cells. The prognosis of rhabdomyolyses related to hereditary diseases of metabolism is poor and treatments are only symptomatic. Rhabdomyolysis outbreaks are frequently precipitated by fever and fasting. They are unpredictable. In spite of the care of patient in an intensive care unit, the occurrence of renal failure and heart rhythm disorders explains a significant acute-phase mortality rate. There is an urgent need to understand the pathophysiological mechanisms of rhabdomyolyses related to hereditary diseases of metabolism, in order to identify specific treatments. The pathophysiological mechanism of rhabdomyolyses related to Lipin-1 deficiency has been identified. Two patients with Lipin-1 deficiency treated in vivo by Hydroxychloroquine (Plaquenil ®, 6 mg/kg/day by one oral intake) rapidly standardized their serum inflammatory profile and corrected their clinical phenotype: Plasma creatine phosphokinase levels, Amount of mitochondrial DNA in plasma, number of myolyses, muscular pain, quality of life. One of these two patients, suffering from cardiac dysfunction already reported in Lipin-1 deficiency (left ventricular ejection fraction or LVEF 45%), significantly and durably improved cardiac function after one month of treatment (LVEF 62%). In addition, his fatigability and sleep disturbances have dramatically improved. Disruption of mitophagy and immunity could be a common denominator for rhabdomyolyses linked to hereditary diseases of metabolism, which could, despite their heterogeneity, benefit from a common therapeutic approach, Now non-existent. There could be a role of inflammation in rhabdomyolyses outbreaks of metabolic origin and new therapeutic approaches could be imagined as in the Lipin-1 deficiency. Patients with rhabdomyolyses have few clinical signs outside of access. So there is a methodological difficulty in following a treatment test. There is an urgency to identify follow-up parameters in anticipation of new therapies. In the Lipin deficiency, an anomaly of the effort tests with measurement of oxygen consumption and cardiac output was characterized. These effort tests were carried out in the context of care, in order to recognize for a given patient whether the practice of sport is a factor triggering rhabdomyolysis. The objective of this study is to validate the hypothesis that effort test and cardiac function parameters are usable in the treatment monitoring for patients with acute rhabdomyolysis linked to a hereditary disease of metabolism and thus propose the effort test as an assessment tool for future clinical trials. To date, no tests are available for clinical trials. In order to do so, the correlation between the results of the effort tests, performed to each patient with rhabdomyolysis related to a hereditary disease of metabolism, with the severity of the disease will be assessed, including: 1) Metabolic flux on myoblasts, 2) clinical severity (onset of disease, number of rhabdomyolyses, cardiomyopathy), 3) genotype. This study is original because it opens up innovative prospects for monitoring in the field of hereditary diseases of metabolism, with the identification of new monitoring tools. ;