ABSTRACT
The Vaughn Williams classification divides antiarrhythmic agents into four groups according to their effects on various ion channels. Class I agents block sodium channels and are subdivided into three groups. The use of class Ia agents is gradually on the decline, secondary to lack of a favorable risk/benefit ratio. Class Ib agents include lidocaine, which is extensively used for the acute treatment of ventricular tachyarrhythmias. Class Ic drugs are not advisable for patients with structural cardiac abnormalities secondary to a high risk of proarrhythmia. They are mainly used for supraventricular tachyarrhythmias. beta blockers form class II. Class III agents, such as amiodarone and sotalol, prolong action potential duration and repolarization and are among the most widely used antiarrhythmics. They are the subject of active research, and newer agents are being developed. Calcium-channel blockers are grouped under class IV. Digoxin and adenosine have unique antiarrhythmic properties, which can be useful in the management of selected patients. All antiarrhythmic drugs have the potential to provoke arrhythmias and, therefore, should be used with caution. The risk of proarrhythmia is increased in patients with abnormal cardiac substrate, with electrolyte abnormalities, and during drug initiation. Correction of electrolyte imbalance and prevention of bradycardia while the drug is metabolized and/or excreted are the cornerstones of proarrhythmia management.
Subject(s)
Anti-Arrhythmia Agents/pharmacology , Heart Conduction System/drug effects , Amiodarone/pharmacology , Amiodarone/therapeutic use , Anti-Arrhythmia Agents/adverse effects , Anti-Arrhythmia Agents/classification , Anti-Arrhythmia Agents/therapeutic use , Humans , Procainamide/pharmacology , Procainamide/therapeutic use , Sodium Channel BlockersABSTRACT
In vitro studies suggest that vascular endothelial growth factor/vascular permeability factor (VEGF/VPF) may stimulate release of nitric oxide (NO) from endothelial cells. To investigate the hemodynamic consequences of recombinant VEGF/VPF administered in vivo, recombinant human VEGF/VPF was administered as a bolus dose of 500 micrograms to anesthetized (n = 6) or conscious (n = 5) New Zealand White rabbits, as well as anesthetized rabbits with diet-induced hypercholesterolemia (HC; n = 7). Anesthetized Yorkshire farm pigs (no specific dietary pretreatment) were studied before and after receiving 500 micrograms intravenous (IV; n = 5) or intracoronary (IC; n = 5) VEGF/VPF. In anesthetized, normal rabbits, mean arterial pressure (MAP) fell by 20.5 +/- 1.4% (P < .05 versus baseline) within 3 minutes after IV VEGF/VPF. Pretreatment with N omega-nitro-L-arginine caused a significant inhibition of VEGF/VPF-induced hypotension. In conscious, normal rabbits, VEGF/VPF produced a consistent though lesser reduction in MAP. The fall in MAP induced by VEGF/VPF in anesthetized, HC rabbits (21.5 +/- 2.5% from baseline) was no different from that observed in normal anesthetized rabbits. In pigs, both IV and IC administration of VEGF/VPF produced a prompt reduction in MAP. Heart rate increased, while cardiac output, stroke volume, left atrial pressure, and total peripheral resistance all declined to a similar, statistically significant degree in both IV and IC groups. Epicardial echocardiography disclosed neither global nor segmental wall motion abnormalities in response to VEGF/VPF. We conclude that (1) VEGF/VPF-stimulated release of NO, previously suggested in vitro, occurs in vivo; (2) this finding suggests that functional VEGF/VPF receptors are present on quiescent adult endothelium, consistent with a maintenance function for VEGF/VPF, which may include regulation of NO; and (3) the preserved response of HC rabbits suggests that endothelial cell receptors for VEGF/VPF are spared in the setting of hypercholesterolemia.
