Procainamide

Medical uses

Procainamide is used for treating ventricular arrhythmias: ventricular ectopy and tachycardia and supraventricular arrhythmias: atrial fibrillation, and re-entrant and automatic supraventricular tachycardia. For example, it can be used to convert new-onset atrial fibrillation, though it is suboptimal for this purpose.

It is administered by mouth, by intramuscular injection, or intravenously.

Side effects

There are many side effects following the induction of procainamide. These adverse effects are ventricular dysrhythmia, bradycardia, hypotension and shock. The adverse effects occur even more often if the daily doses is increased. Procainamide may also lead to drug fever and other allergic responses. There is also a chance that systemic lupus erythematosus occurs, which at the same time leads to polyarthralgia, myalgia and pleurisy. Most of these side effects may occur due to the acetylation of procainamide.

Toxicity

There is just a close line between the plasma concentrations of the therapeutic and toxic effect, therefore a high risk for toxicity. Many symptoms resemble systemic lupus erythematosus because procainamide reactivates hydroxylamine and nitroso metabolites, which bind to histone proteins and are toxic to lymphocytes. The hydroxylamine and nitroso metabolites are also toxic to bone marrow cells and can cause agranulocytosis. These metabolites are formed due to the activation of polymorphonuclear leukocytes. These leukocytes release myeloperoxidase and hydrogen peroxide, which oxidize the primary aromatic amine of procainamide to form procainamide hydroxylamine. The release of hydrogen peroxide is also called a respiratory burst, which occurs for procainamide in monocytes but not in lymphocytes. Furthermore, the metabolites can be formed by activated neutrophils. These metabolites could then bind to their cell membranes and cause a release of autoantibodies which would react with the neutrophils. Procainamide hydroxylamine has more cytotoxicity by hindering the response of lymphocytes to T- and B-cell mitogens. Hydroxylamine can also generate methemoglobin, a protein that could hinder further oxygen exchange.

It was also detected that the antiarrhythmic drug procainamide interferes with pacemakers. Because a toxic level of procainamide leads to decrease in ventricular conduction velocity and increase of the ventricular refractory period. This results in a disturbance in the artificial membrane potential and leads to a supraventricular tachycardia which induces failure of the pacemaker and death. Thus, it prolongs QT interval of action potential and increases the risk of torsade de points.

Procainamide could initiate leukopenia and/or agranulocytosis, which are serious hematologic disorders, and is also known for causing gastrointestinal disturbances and aggravating pre-existing abnormalities in impulse initiation and propagation.

Mechanism of action

Procainamide works as an anti-arrhythmic agent and is used to treat cardiac arrhythmia. It induces rapid block of the batrachotoxin (BTX)-activated sodium channels of the heart muscle and acts as antagonist to long gating closures. The block is voltage dependent and can occur from both sides; either from the intracellular or the extracellular side. Blocking from the extracellular side is weaker than from the intracellular side because it occurs via the hydrophobic pathway. Procainamide is present in charged form and probably requires a direct hydrophobic access to the binding site for blocking of the channel. Furthermore, blocking of the channel shows a decreased voltage sensitivity, which may result from the loss of voltage dependence of the blocking rate. Due to its charged and hydrophilic form, procainamide has its effect from the internal side, where it causes blockage of voltage-dependent open channels. With increasing concentration of procainamide, the frequency of long blockage becomes less without the duration of blockage being affected. The rate of fast blocking is determined by the membrane depolarization. Membrane depolarization leads to increased blocking and decreased unblocking of the channels. Procainamide slows the conduction velocity and increases the refractory period, such that the maximal rate of depolarization is reduced.

Metabolism

Procainamide is metabolized via different pathways. The most common one is the acetylation of procainamide to the less toxic N-acetylprocainamide. The rate of acetylation is genetically determined. There are two phenotypes that result from the acetylation process, namely the slow and rapid acetylator. Procainamide can also be oxidized by the cytochrome P-450 to a reactive oxide metabolite. But it seems that acetylation of the nitrogen group of procainamide decrease the amount of the chemical that would be available for the oxidative route. Other metabolites of procainamide include desethyl-N-acetylprocainamide, desethylprocainamide, p-aminobenzoic acid, which are excreted via the urine. N-acetyl-4-aminobenzoic acid as well as N-acetyl-3-hydroxyprocainamide, N-acetylprocainamide-N-oxide and N-acetyl-4-aminohippuric acid are also metabolites of procainamide.

Chemistry

4-amino-N-2-(diethylamino)ethyl-benzamide (also known as para-amino-N-2-(diethylamino)ethyl-benzamide because the amino substituent is attached to the para-position Arene substitution patterns of the benzene ring) is a synthetic organic compound with the chemical formula C13-H21-N3-O.

Procainamide is structurally similar to procaine but in place of an ester group contains procainamide an amide group. This substitution is the reason why procainamide exhibit a longer half-life time than procaine.

Procainamide belongs to the aminobenzamides. These are aromatic carboxylic acid derivatives consisting of an amide with a benzamide moiety and a triethylamine attached to the amide nitrogen.

History

Procainamide was approved by the US FDA on June 2, 1950, under the brand name Pronestyl. It was launched by Bristol-Myers Squibb in 1951.
Due to the loss of Indonesia in World War II, the source for cinchona alkaloids, a precursor of quinidine, was strongly diminished. This led to research for a new antiarrhythmic drug. As a result, procaine was discovered, which has similar cardiac effects as quinidine. In 1936 it was found by Mautz that by applying it directly on the myocardium, the ventricular threshold for electrical stimulation was elevated. This mechanism is responsible for the antiarrhythmic effect. However, due to the short duration of action, caused by rapid enzymatic hydrolysis, its therapeutic applications were limited. In addition, procaine also caused tremors and respiratory depression. All these adverse features stimulated the search for an alternative to procaine. Studies were done on various congeners and metabolites and this ultimately led to the discovery of procainamide by Mark et al. It was found that procainamide was effective for treating ventricular arrhythmias, but it had the same toxicity profile as quinidine and it could cause systemic lupus erythematosus like syndrome. These negative characteristics slowed down the search for new antiarrhythmics based on the chemical structure of procainamide. In 1970 only five drugs were reported. These were the cardiac glycosides, quinidine, lidocainem propranolol and diphenylhydantoin. In January 1996, Procainamide hydrochloride (procanbid extended-release tablets) were approved by the FDA.