View clinical trials related to Postoperative Myalgia.
Filter by:For more than 60 years, succinylcholine is still being administered as the selective relaxant for rapid sequence intubation by anesthesiologists in many countries. It has been shown to possess unique features such as low cost, fast-acting, short half-life, safe metabolites, and causing excellent muscle relaxation for intubation. However, it has many side effects as well. Postoperative myalgia (POM), with an incidence rate of about 41%-92%, is one of the most common side effects of this drug and can take several days to cause significant discomfort in patients. However, its effect is felt more in the throat, neck, shoulder, and abdominal muscles and is common among patients with outpatient surgery. Due to its unknown real context of pathogenesis and in an effort to reduce the incidence and severity of succinylcholine-induced myalgia, various medications including non-depolarizing muscle relaxants, benzodiazepines, magnesium sulfate, opioids, gabapentin, pregabalin and nonsteroidal anti-inflammatory drugs have been tested, with varying degrees of success. Free radicals are created as a consequence of ATP (adenosine triphosphate) production by the mitochondria. These by-products are generally reactive oxygen species (ROS) as well as reactive nitrogen species (RNS) that result from the cellular redox process. These species play a dual role as both toxic and beneficial compounds. The delicate balance between their two antagonistic effects is clearly an important aspect of life. At low or moderate levels, ROS and RNS exert beneficial effects on cellular responses and immune function. At high concentrations, they generate oxidative stress, a deleterious process that can damage all cell structures. Muscle injuries might lead to the production of free radicals and further cellular damage, triggered by lipid peroxidation and protein oxidation. Peroxidation of membrane lipids leads to loss of membrane fluidity and elasticity, impaired cellular functioning, and even cell rupture. The various direct products of lipid peroxidation, such as malondialdehyde (MDA), isoprostanes, and 4-hydroxynonenal are considered among the most important biomarkers of oxidative stress in tissues. Malondialdehyde is a reactive carbonyl compound and is both mutagenic and carcinogenic. It reacts with DNA to form DNA adducts that are believed to contribute significantly to cancers linked to lifestyle and dietary factors. Protein oxidation can cause fragmentation at amino acid residues, formation of protein-protein cross-linkages, and oxidation of the protein backbone which ultimately leads to loss of function. Damaged proteins affect intracellular pathways and are contributing factors to different disorders and diseases. Protein carbonyl (CO) groups are produced on protein side chains during oxidation. High levels of protein CO groups have been observed in rheumatoid arthritis, Alzheimer's disease, diabetes, sepsis and chronic renal failure. Selenium is a well-recognized antioxidant which act s as a cofactor of antioxidant enzymes. This essential element helps protect the body against free radicals causing damage to the cells. Substantial evidence suggests that free radical production leads to increased oxygen uptake over time. The indirect though significant impact of selenium supplements is to protect the cells against oxidative stress and free radical production. Nature-made selenium contains 200 mg of this element with a natural origin, high absorption capacity, and prolonged retention. Selenium exerts its antioxidant effects through glutathione peroxidase. Glutathione peroxidase is an enzyme containing four selenium-cofactors that catalyze the breakdown of hydrogen peroxide and organic hydroperoxides. There are at least four different glutathione peroxidase isozymes in animals. Glutathione peroxidase 1 is the most abundant and is a very efficient scavenger of hydrogen peroxide, while glutathione peroxidase 4 is most active with lipid hydroperoxides. The glutathione S-transferases show high activity with lipid peroxides. These enzymes are at particularly high levels in the liver and serve in detoxification metabolism.
For >60 years, succinylcholine is still being administered as a selective relaxant for rapid sequence intubation by anesthesiologists in many countries. It has been shown to possess unique features such as low cost, fast-acting, short half-life, safe metabolites, and causing excellent muscle relaxation for intubation. It has many side effects as well. Postoperative myalgia (POM), with an incidence rate of ~41%-92%, is one of the most common side effects of this drug and can take several days to cause significant discomfort in patients. However, its effect is felt more in the throat, neck, shoulder, and abdominal muscles and is common among patients with outpatient surgery. Due to its unknown real context of pathogenesis and in an effort to reduce the incidence and severity of succinylcholine-induced myalgia, various medications including nondepolarizing muscle relaxants, benzodiazepines, magnesium sulfate, opioids, gabapentin, and nonsteroidal anti-inflammatory drugs have been tested, with varying degrees of success. Duloxetine is an US Food and Drug Administration-approved analgesic used for various pain syndromes, including diabetic peripheral neuropathy and fibromyalgia. The underlying mechanism for duloxetine against these pain syndromes remains unclear, but it may involve three major central nervous system (CNS) targets: (1) serotonin transporter (Ki, 4.6 nM), (2) norepinephrine transporter (Ki, 16 nM), and (3) dopamine transporter (Ki, 370 nM). In the past, the antidepressant action was often thought to be the primary mechanism for its analgesic efficacy. This theory was addressed later by "Path Analysis," and the result showed that duloxetine affects pain directly rather than indirectly through mood improvement. In addition to these multiple CNS targets, duloxetine, like the antidepressant amitriptyline and the local anesthetic bupivacaine, blocks voltage-gated Na+ channels. Because neuronal Na+ channels are present in both CNS and peripheral nervous systems, such a finding expands the possible analgesic action and locus of duloxetine.
Succinylcholine is commonly used for neuromuscular relaxation for short procedures such as rigid bronchoscopy. A more modern alternative is the application aof rocuronium, reversed by sugammadex. The investigators compare the intubating conditions, incidence of postoperative myalgia (POM) as well as patient satisfaction for these two muscle relaxants.
Succinylcholine is commonly used for neuromuscular relaxation for short procedures such as rigid bronchoscopy. A alternative is the application of low dose mivacurium, reversed with neostigmine. The investigators compare the intubating conditions, incidence of postoperative myalgia (POM), patient satisfaction and the postoperative performance with respiration exercise device for these two muscle relaxants.
Succinylcholine is commonly used for neuromuscular relaxation for short procedures such as rigid bronchoscopy. A more modern alternative is the application of low-dose rocuronium, reversed by low-dose sugammadex. The investigators compare the intubating conditions, incidence of postoperative myalgia (POM), as well as patient satisfaction for these two muscle relaxants.