Pharmacology
DrugBankDescription
Methimazole is a thionamide antithyroid agent that inhibits the synthesis of thyroid hormones. It was first introduced as an antithyroid agent in 1949 and is now commonly used in the management of hyperthyroidism, particularly in those for whom more aggressive options such as surgery or radioactive iodine therapy are inappropriate. On a weight basis, methimazole is 10 times more potent than the other major antithyroid thionamide used in North America, propylthiouracil, and is the active metabolite of the pro-drug carbimazole, which is an antithyroid medication used in the United Kingdom and parts of the former British Commonwealth. Traditionally, methimazole has been preferentially used over propylthiouracil due to the risk of fulminant hepatotoxicity carried by the latter, with propylthiouracil being preferred in pregnancy due to a perceived lower risk of teratogenic effects. Despite documented teratogenic effects in its published labels, the true teratogenicity of methimazole appears to be unclear and its place in therapy may change in the future.
Mechanism of Action
Methimazole's primary mechanism of action appears to be interference in an early step in thyroid hormone synthesis involving thyroid peroxidase (TPO), however the exact method through which methimazole inhibits this step is unclear. TPO, along with hydrogen peroxide, normally catalyzes the conversion of iodide to iodine and then further catalyzes the incorporation of this iodine onto the 3 and/or 5 positions of the phenol rings of tyrosine residues in thyroglobulin. These thyroglobulin molecules then degrade within thyroid follicular cells to form either thyroxine (T4) or tri-iodothyronine (T3), which are the main hormones produced by the thyroid gland. Methimazole may directly inhibit TPO, but has been shown in vivo to instead act as a competitive substrate for TPO, thus becoming iodinated itself and interfering with the iodination of thyroglobulin. Another proposed theory is that methimazole’s sulfur moiety may interact directly with the iron atom at the centre of TPO’s heme molecule, thus inhibiting its ability to iodinate tyrosine residues. Other proposed mechanisms with weaker evidence include methimazole binding directly to thyroglobulin or direct inhibition of thyroglobulin itself.
Pharmacodynamics
Methimazole inhibits the synthesis of thyroid hormones resulting in an alleviation of hyperthyroidism. Onset of action occurs within 12 to 18 hours, and its duration of action is 36 to 72 hours, likely due to concentration of methimazole and some metabolites within the thyroid gland after administration. The most serious potential side effect of methimazole therapy is agranulocytosis, and patients should be instructed to monitor for, and report, any signs or symptoms of agranulocytosis such as fever or sore throat. Other cytopenias may also occur during methimazole therapy. There also exists the potential for severe hepatic toxicity with the use of methimazole, and monitoring for signs and symptoms of hepatic dysfunction, such as jaundice, anorexia, pruritus, and elevation in liver transaminases, is prudent in patients using this therapy.
Metabolism
Methimazole is rapidly and extensively metabolized by the liver, mainly via the CYP450 and FMO enzyme systems. Several metabolites have been identified, though the specific enzyme isoforms responsible for their formation are not entirely clear. One of the first methimazole metabolites identified, 3-methyl-2-thiohydantoin, may contribute to antithyroid activity - its antithyroid activity has been demonstrated in rats and may explain the prolonged duration of iodination inhibition following administration despite methimazole's relatively short half-life. A number of metabolites have been investigated as being the culprits behind methimazole-induced hepatotoxicity. Both glyoxal and N-methylthiourea have established cytotoxicity and are known metabolic products of methimazole's dihydrodiol intermediate. Sulfenic and sulfinic acid derivatives of methimazole are thought to be the ultimate toxicants responsible for hepatotoxicity, though their origin is unclear - they may arise from direct oxidation of methimazole via FMO, or from oxidation of N-methylthiourea further downstream in the metabolic process.
Absorption
Absorption of methimazole after oral administration is rapid and extensive, with an absolute bioavailability of approximately 0.93 and a Tmax ranging from 0.25 to 4.0 hours. Cmax is slightly, but not significantly, higher in hyperthyroid patients, and both Cmax and AUC are significantly affected by the oral dose administered.
Toxicity
The oral LD50 of methimazole in rats is 2250 mg/kg. Signs and symptoms of methimazole overdose may include gastrointestinal distress, headache, fever, joint pain, pruritus, and edema. More serious adverse effects, such as aplastic anemia or agranulocytosis, may manifest within hours to days. Hepatitis, nephrotic syndrome, exfoliative dermatitis, and CNS effects such as neuropathy or CNS depression/stimulation are also potential, albeit less frequent, results of overdose. Management of overdose involves supportive treatment as dictated by the patient's status. This may involve monitoring of the patient's vital signs, blood gases, serum electrolytes, or bone marrow function as indicated.
Indication
In the United States, methimazole is indicated for the treatment of hyperthyroidism in patients with Graves' disease or toxic multinodular goiter for whom thyroidectomy or radioactive iodine therapy are not appropriate treatment options. Methimazole is also indicated for the amelioration of hyperthyroid symptoms in preparation for thyroidectomy or radioactive iodine therapy. In Canada, methimazole carries the above indications and is also indicated for the medical treatment of hyperthyroidism regardless of other available treatment options.
Half-life
Following a single intravenous bolus injection of 10mg of methimazole, the t1/2 of the distribution phase was 0.17 hours and the t1/2 of the elimination phase was 5.3 hours. Methimazole's primary active metabolite, 3-methyl-2-thiohydantoin, has a half-life approximately 3 times longer than its parent drug. Renal impairment does not appear to alter the half-life of methimazole, but patients with hepatic impairment showed an increase in half-life roughly proportional to the severity of their impairment - moderate insufficiency resulted in a elimination t1/2 of 7.1 hours, while severe insufficiency resulted in an elimination t1/2 of 22.1 hours. There does not appear to be any significant differences in half-life based on thyroid status (i.e. no difference between euthyroid and hyperthyroid patients).
Protein Binding
Methimazole exhibits little-to-no protein binding, existing primarily as free drug in the serum.
Elimination
Urinary excretion of unchanged methimazole has been reported to be between 7% and 12%. Elimination via feces appears to be limited, with a cumulative fecal excretion of 3% after administration of methimazole. Enterohepatic circulation also appears to play a role in the elimination of methimazole and its metabolites, as significant amounts of these substances are found in the bile post-administration.
Volume of Distribution
The apparent volume of distribution of methimazole has been reported as roughly 20 L. Following oral administration, methimazole is highly concentrated in the thyroid gland - intrathyroidal methimazole levels are approximately 2 to 5 times higher than peak plasma levels, and remain high for 20 hours after ingestion.
Clearance
Following a single intravenous bolus injection of 10mg of methimazole, clearance was found to be 5.70 L/h. Renal impairment does not appear to alter clearance of methimazole, but patients with hepatic impairment showed a reduction in clearance roughly proportional to the severity of their impairment - moderate insufficiency resulted in a clearance of 3.49 L/h, while severe insufficiency resulted in a clearance of 0.83 L/h. There does not appear to be any significant differences in clearance based on thyroid status (i.e. no difference between euthyroid and hyperthyroid patients).
Effect Profile
CuratedStrong euphoria with moderate itching/nausea, mild sedation