Side effects include
malignant hyperthermia, muscle pains, acute
rhabdomyolysis with
high blood levels of potassium, and changes in cardiac rhythm, including
slow heart rate, and
cardiac arrest. In people with neuromuscular disease or
burns, an injection of suxamethonium can lead to a large release of
potassium from
skeletal muscles, potentially resulting in cardiac arrest. Conditions having susceptibility to suxamethonium-induced high blood potassium are burns,
closed head injury,
acidosis,
Guillain–Barré syndrome, cerebral
stroke,
drowning, severe intra-abdominal
sepsis, massive
trauma,
myopathy, and
tetanus. Suxamethonium does not produce
unconsciousness or
anesthesia, and its effects may cause considerable psychological distress while simultaneously making it impossible for a patient to communicate. Therefore, administration of the drug to a conscious patient is contraindicated.
Hyperkalemia The side effect of high blood potassium may occur because the acetylcholine
receptor is propped open, allowing continued flow of potassium ions into the
extracellular fluid. A typical increase of potassium ion serum concentration on administration of suxamethonium is 0.5
mmol per
liter.The increase is transient in otherwise healthy patients. The normal range of potassium is 3.5 to 5 mEq per liter. High blood potassium does not generally result in adverse effects below a concentration of 6.5 to 7
mEq per liter. Therefore, the increase in serum potassium level is usually not catastrophic in otherwise healthy patients. Severely high blood levels of potassium can cause changes in
cardiac electrophysiology, which, if severe, can result in
arrhythmias and even
cardiac arrest.
Malignant hyperthermia Administering suxamethonium and certain other anesthetics can result in a drastic and uncontrolled increase in skeletal muscle
oxidative metabolism. This overwhelms the body's capacity to supply
oxygen, remove
carbon dioxide, and regulate body temperature, eventually leading to circulatory collapse and death if not treated quickly. Susceptibility to malignant hyperthermia is often inherited as an
autosomal dominant disorder, for which there are at least six
genetic loci of interest, the most prominent being the
ryanodine receptor gene (RYR1). MH susceptibility is
phenotype and genetically related to
central core disease (CCD), an autosomal dominant disorder characterized both by MH symptoms and by
myopathy. MH is usually unmasked by
anesthesia, or when a family member develops the symptoms. There is no simple, straightforward test to diagnose the condition. When MH develops during a procedure, treatment with
dantrolene sodium is usually initiated; dantrolene and the avoidance of suxamethonium administration in susceptible people have markedly reduced the mortality from this condition.
Apnea The normal short duration of action of suxamethonium is due to the rapid metabolism of the drug by non-specific plasma cholinesterases. However, plasma cholinesterase activity is reduced in some people due to either genetic variation or acquired conditions, which results in a prolonged duration of neuromuscular block. Genetically, ninety six percent of the population have a normal (Eu:Eu) genotype and block duration; however, some people have atypical genes (Ea, Es, Ef) which can be found in varying combinations with the Eu gene, or other atypical genes (see
Pseudocholinesterase deficiency). Such genes will result in a longer duration of action of the drug, ranging from 20 minutes up to several hours. Acquired factors that affect plasma cholinesterase activity include pregnancy, liver disease, kidney failure,
heart failure,
thyrotoxicosis, and cancer, as well as a number of other drugs. If unrecognized by a clinician it could lead to awareness if anesthesia is discontinued whilst still paralyzed or hypoxemia (and potentially fatal consequences) if artificial ventilation is not maintained. Normal treatment is to maintain sedation and ventilate the patient on an intensive care unit until muscle function has returned. Blood testing for cholinesterase function can be performed.
Mivacurium, a non-depolarizing neuromuscular blocking drug, is also metabolized via the same route with a similar clinical effect in patients deficient in plasma cholinesterase activity. Deliberate induction of conscious apnea using this drug led to its use as a form of
aversion therapy in the 1960s and 1970s in some prison and institutional settings. This use was discontinued after negative publicity concerning the terrifying effects on subjects of this treatment and ethical questions about the punitive use of painful aversion. ==Mechanism of action==