Many attempts have been made to classify antiarrhythmic agents. Many of the antiarrhythmic agents have multiple modes of action, which makes any classification imprecise.
The cardiac myocyte has two general types of action potentials: conduction system and working myocardium. The action potential is divided into 5 phases and shown in the diagram. The sharp rise in voltage ("0") corresponds to the influx of sodium ions, whereas the two decays ("1" and "3", respectively) correspond to the sodium-channel inactivation and the repolarizing efflux of potassium ions. The characteristic plateau ("2") results from the opening of voltage-sensitive calcium channels. Each phase utilizes different channels and it is useful to compare these phases to the most common classification system — Vaughan Williams — described below.
Vaughan Williams was a pharmacology tutor at Hertford College, Oxford. One of his students, Bramah N. Singh,[3] contributed to the development of the classification system. The system is therefore sometimes known as the Singh-Vaughan Williams classification.
The five main classes in the Vaughan Williams classification of antiarrhythmic agents are:
Class I agents interfere with the sodium (Na+) channel.
Class IV agents affect calcium channels and the AV node.
Class V agents work by other or unknown mechanisms.
With regard to management of atrial fibrillation, classes I and III are used in rhythm control as medical cardioversion agents, while classes II and IV are used as rate-control agents.
Class Ib drugs shorten the action potential of myocardial cell and has a weak effect on the initiation of phase 0 of depolarization
Treat and prevent ventricular arrhythmia during and immediately after myocardial infarction, though this is now discouraged given the increased risk of asystole
Class I agents are called membrane-stabilizing agents, "stabilizing" referring to the decrease of excitogenicity of the plasma membrane which is brought about by these agents. (Also noteworthy is that a few class II agents like propranolol also have a membrane stabilizing effect.)
Class I agents are divided into three groups (Ia, Ib, and Ic) based upon their effect on the length of the action potential.[10][11]
Class Ia drugs lengthen the action potential (right shift)
Class Ib drugs shorten the action potential (left shift)
Class Ic drugs do not significantly affect the action potential (no shift)
Class II agents are conventional beta blockers. They act by blocking the effects of catecholamines at the β1-adrenergic receptors, thereby decreasing sympathetic activity on the heart, which reduces intracellular cAMP levels and hence reduces Ca2+ influx. These agents are particularly useful in the treatment of supraventricular tachycardias. They decrease conduction through the AV node.
Effect of class III drugs on length of action potential
Class III agents predominantly block the potassium channels, thereby prolonging repolarization.[12] Since these agents do not affect the sodium channel, conduction velocity is not decreased. The prolongation of the action potential duration and refractory period, combined with the maintenance of normal conduction velocity, prevent re-entrant arrhythmias. (The re-entrant rhythm is less likely to interact with tissue that has become refractory). The class III agents exhibit reverse-use dependence (their potency increases with slower heart rates, and therefore improves maintenance of sinus rhythm). Inhibiting potassium channels results in slowed atrial-ventricular myocyte repolarization. Class III agents have the potential to prolong the QT interval of the EKG, and may be proarrhythmic (more associated with development of polymorphic VT).
Class IV agents are slow non-dihydropyridinecalcium channel blockers. They decrease conduction through the AV node, and shorten phase two (the plateau) of the cardiac action potential. They thus reduce the contractility of the heart, so may be inappropriate in heart failure. However, in contrast to beta blockers, they allow the body to retain adrenergic control of heart rate and contractility.[citation needed]
Since the development of the original Vaughan Williams classification system, additional agents have been used that do not fit cleanly into categories I through IV. Such agents include:
Digoxin decreases conduction of electrical impulses through the AV node and increases vagal activity via its action on the central nervous system. Via indirect action, it leads to an increase in acetylcholine production, stimulating M2 receptors on AV node leading to an overall decrease in speed of conduction.
The initial classification system had 4 classes, although their definitions different from the modern classification. Those proposed in 1970 were:[2]
Drugs with a direct membrane action: the prototype was quinidine, and lignocaine was a key example. Differing from other authors, Vaughan-Williams describe the main action as a slowing of the rising phase of the action potential.
Compounds that prolong the action potential: matching the modern classification, with the key drug example being amiodarone, and a surgical example being thyroidectomy. This was not a defining characteristic in an earlier review by Charlier et al. (1968),[17] but was supported by experimental data presented by Vaughan Williams (1970).[2]: 461 The figure illustrating these findings was also published in the same year by Singh and Vaughan Williams.[18]
Drugs acting like diphenylhydantoin (DPH): mechanism of action unknown, but others had attributed its cardiac action to an indirect action on the brain;[19] this drug is better known as antiepileptic drug phenytoin.
Another approach, known as the "Sicilian gambit", placed a greater approach on the underlying mechanism.[20][21][22]
It presents the drugs on two axes, instead of one, and is presented in tabular form. On the Y axis, each drug is listed, in roughly the Singh-Vaughan Williams order. On the X axis, the channels, receptors, pumps, and clinical effects are listed for each drug, with the results listed in a grid. It is, therefore, not a true classification in that it does not aggregate drugs into categories.[23]
Modernized Oxford classification by Lei, Huang, Wu, and Terrar[edit]
Common anti-arrhythmic drugs under the modernized classification according to Lei et al. 2018
A recent publication (2018) has now emerged with a fully modernised drug classification.[24] This preserves the simplicity of the original Vaughan Williams framework while capturing subsequent discoveries of sarcolemmal, sarcoplasmic reticular and cytosolic biomolecules. The result is an expanded but pragmatic classification that encompasses approved and potential anti-arrhythmic drugs. This will aid our understanding and clinical management of cardiac arrhythmias and facilitate future therapeutic developments. It starts by considering the range of pharmacological targets, and tracks these to their particular cellular electrophysiological effects. It retains but expands the original Vaughan Williams classes I to IV, respectively covering actions on Na+ current components, autonomic signalling, K+ channel subspecies, and molecular targets related to Ca2+ homeostasis. It now introduces new classes incorporating additional targets, including:
Class 0: ion channels involved in automaticity
Class V: mechanically sensitive ion channels
Class VI: connexins controlling electrotonic cell coupling
Class VII: molecules underlying longer term signalling processes affecting structural remodeling.
It also allows for multiple drug targets/actions and adverse pro-arrhythmic effects. The new scheme will additionally aid development of novel drugs under development and is illustrated here.
^Rang, Humphrey P.; Ritter, James M.; Flower, Rod J.; Henderson, Graeme (2012). Rang and Dale's pharmacology (7th ed.). Elsevier. p. 255. ISBN9780702034718.
^ abcVaughan Williams, EM (1970) "Classification of antiarrhythmic drugs". In Symposium on Cardiac Arrhythmias (Eds. Sandoe E; Flensted-Jensen E; Olsen KH). Astra, Elsinore. Denmark (1970)[ISBN missing]
^Milne JR, Hellestrand KJ, Bexton RS, Burnett PJ, Debbas NM, Camm AJ (February 1984). "Class 1 antiarrhythmic drugs – characteristic electrocardiographic differences when assessed by atrial and ventricular pacing". Eur. Heart J. 5 (2): 99–107. doi:10.1093/oxfordjournals.eurheartj.a061633. PMID6723689.
^Trevor, Anthony J.; Katzung, Bertram G. (2003). Pharmacology. New York: Lange Medical Books/McGraw-Hill, Medical Publishing Division. p. 43. ISBN978-0-07-139930-2.
^Hoshino K, Ogawa K, Hishitani T, Isobe T, Eto Y (October 2004). "Optimal administration dosage of magnesium sulfate for torsades de pointes in children with long QT syndrome". J Am Coll Nutr. 23 (5): 497S–500S. doi:10.1080/07315724.2004.10719388. PMID15466950. S2CID30146333.
^Hoshino K, Ogawa K, Hishitani T, Isobe T, Etoh Y (April 2006). "Successful uses of magnesium sulfate for torsades de pointes in children with long QT syndrome". Pediatr Int. 48 (2): 112–117. doi:10.1111/j.1442-200X.2006.02177.x. PMID16635167. S2CID24904388.
^Charlier, R; Deltour, G; Baudine, A; Chaillet, F (November 1968). "Pharmacology of amiodarone, and anti-anginal drug with a new biological profile". Arzneimittel-Forschung. 18 (11): 1408–1417. PMID5755904.
^Damato, Anthony N. (1 July 1969). "Diphenylhydantoin: Pharmacological and clinical use". Progress in Cardiovascular Diseases. 12 (1): 1–15. doi:10.1016/0033-0620(69)90032-2. PMID5807584.
^"The 'Sicilian Gambit'. A new approach to the classification of antiarrhythmic drugs based on their actions on arrhythmogenic mechanisms. The Task Force of the Working Group on Arrhythmias of the European Society of Cardiology". Eur. Heart J. 12 (10): 1112–1131. October 1991. PMID1723682.
