Procainamide Lidocaine

Concurrent administration of propafenone with digoxin, warfarin, propranolol, or metoprolol increases the serum concentrations of the latter four drugs. Cimetidine slightly increases the propafenone serum concentrations. Additive pharmacological effects can occur when lidocaine, procainamide, and quinidine are combined with propafenone. [Pg.181]

LIDOCAINE PROCAINAMIDE Case report of neurotoxicity when intravenous lidocaine administered with procainamide. No significant interaction expected when lidocaine is used for local anaesthetic infiltration Likely to be an additive effect both may cause neurotoxicity in overdose Care should be taken when administering lidocaine as an infusion for patients taking procainamide... [Pg.499]

For refractory cases consider additional pharmacological agents aminodarone. lidocaine, procainamide or sotalol ... [Pg.511]

Pharmacokinetic parameters of digoxin and other cardioactive drugs are summarized in Table 33-2. Digoxin, disopyra-mide, lidocaine, procainamide, and quinidine are usually quantified by immunoassay. HPLC methods to quantify the other cardioactive drugs are reviewed in a previous edition of this chapter. ... [Pg.1256]

For PVCs of purely cardiac origin drugs to suppress ventricular irritability, such as amiodarone, lidocaine, procainamide... [Pg.59]

Lldoc ine. Lidocaine hydrochloride, an anilide, was originally introduced as a local anesthetic in 1943 and found to be a potent antiarrhythmic in 1960. The compound is a reverse amide of procainamide. Lidocaine is generally considered to be the dmg of choice in the treatment of ventricular arrhythmias and those originating from digitalis glycoside toxicity (1,2,15—17). [Pg.113]

Propranolol may increase procainamide plasma levels. Additive cholinergic effects may occur when procainamide is administered with other drugp with anticholinergic effects. There is the potential of additive cardiodepressant effects when procainamide is administered with lidocaine. When a beta blocker, such as Inderal, is administered with lidocaine, there is an increased risk of lidocaine toxicity. [Pg.373]

It will be recalled that certain local anesthetic amides, such as procainamide and lidocaine, are active antiarrythmic agents. Annelation of a second aromatic ring is consistent with bioactivity. Bunaftine (21) is such an agent, prepared simply from reaction of the acid chloride of 1-naphthoic acid and... [Pg.211]

The answer is e. (Hardman, pp 858-874.) Because verapamil, a Ca channel blocker, has a selective depressing action on AV nodal tissue, it is an ideal drug for both immediate and prophylactic therapy of supraventricular tachycardia (SVT). Nifedipine, another Ca channel blocker, has little effect on SAT Lidocaine and adenosine are parenteral drugs with short ha If-lives and, thus, are not suitable for prophylactic therapy. Procainamide is more suitable for ventricular arrhythmias and has the potential for serious adverse reactions with long-term use. [Pg.121]

Patients with mild or no symptoms can be treated initially with antiarrhythmic drugs. IV amiodarone is now recommended as first-line therapy in this situation. Procainamide or lidocaine given IV is a suitable alternative. Synchronized DCC should be delivered if the patient s status deteriorates, VT degenerates to VF, or drug therapy fails. [Pg.84]

Like procainamide, lidocaine is an amide with local anesthetizing action. Lidocaine is usually administered intravenously for short-term therapy of ventricular extrasystole, tachycardia, especially in the severe phase of myocardial infarction, arrhythmia of natural cause, and for arrhythmia that can originate in the heart during surgical manipulations. Synonyms of this drug are lidopen, xylocaine, xylocard, and others. [Pg.249]

Digitalis intoxication Exercise caution in the use of procainamide in arrhythmias associated with digitalis intoxication. Procainamide can suppress digitalis-induced arrhythmias however, if there is concomitant marked disturbance of AV conduction, additional depression of conduction and ventricular asystole or fibrillation may result. Consider use of procainamide only if discontinuation of digitalis, and therapy with potassium, lidocaine, or phenytoin are ineffective. [Pg.433]

Drugs that may affect lidocaine include beta-blockers, cimetidine, procainamide, tocainide, and succinylcholine. [Pg.446]

Unlabeled uses Bretylium is a second-line agent following lidocaine in the protocol for advanced cardiac life support during CPR. For resistant VF and VT (after lidocaine, defibrillation, and procainamide failures), give bretylium 5 to 10 mg/kg IV repeat as needed up to 30 mg/kg use a bolus every 15 to 30 minutes, infusion 1 to 2 mg/min. For life-threatening arrhythmia use an undiluted infusion of 1 g/250 mL. [Pg.462]

Drugs that may affect amiodarone include hydantoins, cholestyramine, fluoroquinolones, rifamycins, ritonavir, and cimetidine. Drugs that may be affected by amiodarone include anticoagulants, beta-blockers, calcium channel blockers, cyclosporine, dextromethorphan, digoxin, disopyramide, fentanyl, flecainide, hydantoins, lidocaine, methotrexate, procainamide, quinidine, and theophylline. Drug/Lab test interactions Amiodarone alters the results of thyroid function tests, causing an increase in serum T4 and serum reverse T3 levels and a decline in... [Pg.473]

According to recent ACC/AHA/ESC Guidelines (see Zipes et al., 2006), in patients with sutained VT, direct-current cardioversion is appropriate and most effective, and also intravenous procainamide (or ajmaline in some European countries) is recommended as a reasonable choice for initial treatment for sustained monomorphic VT in patients with acute coronary syndrome. Intravenous amiodarone or lidocaine may be reasonable chose as alternative treatment. [Pg.605]

Early after-depolarizations and the associated ventricular arrhythmia can be prevented or suppressed by the appropriate adjustment of plasma potassium and/or magnesium concentrations. Lidocaine or procainamide may be effective for termination of the arrhythmia. [Pg.166]

The electrophysiological properties of lidocaine in atrial muscle resemble those produced by quinidine. Membrane responsiveness, action potential amplitude, and atrial muscle excitability are all decreased. These changes result in a decrease in conduction velocity. However, the depression of conduction velocity is less marked than that caused by quinidine or procainamide. Action potential duration of atrial muscle fibers is not altered by lidocaine at either normal or subnormal extracellular K+ levels. The ERP of atrial myocardium either remains the same or increases slightly after lidocaine administration. [Pg.176]

Procainamide and lidocaine are two of the primary drugs for treating cardiac arrhythmias. Since lidocaine has a short duration of action, it is common to administer it by continuous infusion. Procainamide, because of its amide linkage, has longer action than does its precursor, procaine. Orally active analogues of local anesthetics (e.g., mexiletine) also are used as antiarrhyth-mics (see Chapter 16). [Pg.333]

Lidocaine Morphine Ondansetron Pravastatin Procainamide Ranitidine Sumatriptan Vigabatrin ... [Pg.18]

It is a cleavage of drug molecule by taking up a molecule of water. The most hydrolytic enzymes are found outside the endoplasmic reticulum, and in higher concentrations in liver, kidney and plasma. The metabolism of an ester by an enzyme esterase results in the formation of an acid and alcohol. The examples are meperidine, procaina-mide, pethidine and lidocaine etc. Meperidine is catalyzed by esterases to be changed into meperidinic acid and procainamide is catalyzed by amidases. [Pg.32]

Amides RCONHR1 - RCOOH + R,NH2 Procainamide, lidocaine, indomethacin... [Pg.81]

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