Drug Interactions between Decadron with Xylocaine and fosamprenavir

MONITOR CLOSELY: Coadministration with amprenavir or its prodrug, fosamprenavir, may significantly increase the plasma concentrations of antiarrhythmic agents that are primarily metabolized by CYP450 3A4 such as amiodarone, bepridil, systemic lidocaine, and quinidine. The proposed mechanism is decreased clearance due to inhibition of CYP450 3A4 activity by amprenavir. The interaction has not been specifically studied, but could conceivably lead to serious and/or life-threatening reactions including cardiac arrhythmias and other toxicities if levels are substantially increased. The use of amiodarone, bepridil, and quinidine has been associated with dose-related prolongation of the QT interval, thus elevated plasma levels may potentiate the risk of ventricular arrhythmias such as ventricular tachycardia and torsade de pointes as well as cardiac arrest and sudden death.

MANAGEMENT: Caution is advised if amprenavir or fosamprenavir must be used with antiarrhythmic agents that are substrates of CYP450 3A4. Pharmacologic response and plasma antiarrhythmic drug levels should be monitored more closely whenever amprenavir or fosamprenavir is added to or withdrawn from therapy, and the antiarrhythmic dosage adjusted as necessary. Concomitant use with amiodarone, bepridil, lidocaine, or quinidine is specifically contraindicated according to Canadian and European labeling.

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GENERALLY AVOID: Coadministration with protease inhibitors may increase the plasma concentration and pharmacologic effects of dexamethasone. The proposed mechanism is protease inhibitor-mediated inhibition of CYP450 3A4, the isoenzyme involved in the metabolic clearance of dexamethasone. Ritonavir has been reported to increase dexamethasone systemic exposure (AUC) by more than threefold. In one case report, an HIV patient who had been receiving long-term dexamethasone therapy for thrombotic thrombocytopenia purpura developed spinal epidural lipomatosis four months following the initiation of ritonavir. Although the patient was already cushingoid as a result of chronic dexamethasone administration, he did not have symptoms of myelopathy until after ritonavir was added. The effect of dexamethasone on the clearance of protease inhibitors has not been established. Theoretically, plasma levels of protease inhibitors may decrease due to dexamethasone induction of their metabolism by CYP450 3A4. This may lead to a loss of therapeutic effect and development of resistance to protease inhibitor-containing antiretroviral regimens; however, data are not available. These interactions may also be seen with cobicistat, a potent CYP450 3A4 inhibitor that solely acts as a pharmacokinetic booster in antiretroviral treatment regimen; however, data are not available.

MONITOR: Corticosteroids such as dexamethasone may cause hypokalemia and potentiate the risk of QT and/or PR interval prolongation associated with the use of certain protease inhibitors such as atazanavir, lopinavir-ritonavir, and saquinavir-ritonavir. The risk of torsade de pointes arrhythmia, bradycardia, and heart block may be increased.

MANAGEMENT: Caution is advised if dexamethasone must be used concomitantly with protease inhibitors or cobicistat. Some authorities advise against concomitant use unless the potential benefit outweighs the risk. Adrenal function should be monitored regularly during chronic use of these agents, and dexamethasone dosage adjusted as necessary. Patients should be monitored for symptoms of hypercorticism (e.g., acne, easy bruising, moon face, edema, hirsutism, buffalo hump, skin striae, glucose intolerance, and irregular menstruations), immunosuppression, and osteoporosis. In addition, it may be appropriate to monitor patients for potentially reduced antiretroviral response following initiation or any dosage increase of dexamethasone. Serum potassium and ECG monitoring should also be considered during coadministration of dexamethasone with certain protease inhibitors in accordance with the product labeling.

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Coadministration with inducers of CYP450 1A2 and/or 3A4 may decrease the plasma concentrations of lidocaine, which is primarily metabolized by these isoenzymes. In four healthy volunteers (2 smokers and 2 nonsmokers), administration of a single 400 mg oral dose of lidocaine following pretreatment with the CYP450 inducer phenobarbital (15 mg/day for 4 weeks, followed by 30 mg/day for 4 weeks) decreased lidocaine systemic exposure (AUC) by 37% and increased its oral clearance by 56% compared to administration of lidocaine alone. In another study, the mean bioavailability of a single 750 mg oral dose of lidocaine in six patients receiving chronic antiepileptic drug therapy (consisting of one or more of the following enzyme-inducing anticonvulsants: phenobarbital, primidone, phenytoin, carbamazepine) was approximately 2.5-fold lower than that reported for six healthy control subjects, while intrinsic clearance was nearly threefold higher. By contrast, the interaction was modest for lidocaine administered intravenously, suggesting induction of primarily hepatic first-pass rather than systemic metabolism of lidocaine. When a single 100 mg dose of lidocaine was given intravenously, mean lidocaine AUC was reduced by less than 10% and serum clearance increased by just 17% in the epileptic patients compared to controls. These changes were not statistically significant. Likewise, mean lidocaine AUC decreased by approximately 11% and plasma clearance increased by 15% when a single 50 mg intravenous dose of lidocaine was administered following pretreatment with the potent CYP450 inducer rifampin (600 mg/day for six days) in ten healthy, nonsmoking male volunteers. Another pharmacokinetic study found that cigarette smoke, an inducer of CYP450 1A2, reduced the bioavailability of lidocaine when administered orally, but had only minor effects on lidocaine administered intravenously. When 4 smokers and 5 non-smokers received 2 doses of lidocaine (100 mg IV followed by 100 mg orally after a 2-day washout period), the smoker's systemic exposure (AUC) of oral lidocaine was 68% lower than non-smokers. The AUC of IV lidocaine was only 9% lower in smokers compared with non-smokers. The clinical impact of smoking on lidocaine has not been studied, however, a loss of efficacy may occur.

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