Drug Interaction Report

MONITOR CLOSELY: Coadministration of ketamine with other central nervous system (CNS) depressants, including alcohol, may result in profound sedation, respiratory depression, coma, and death. In addition, opioid analgesics, barbiturates, and benzodiazepines may prolong the time to complete recovery from anesthesia.

MANAGEMENT: During concomitant use of ketamine with other CNS depressants, including alcohol, close monitoring of neurologic status and respiratory parameters, including respiratory rate and pulse oximetry, is recommended. Dosage adjustments should be considered according to the patient's clinical situation. Ambulatory patients should be counseled to avoid hazardous activities requiring mental alertness and motor coordination until they know how these agents affect them, and to notify their physician if they experience excessive or prolonged CNS effects that interfere with their normal activities.

MONITOR: Coadministration with ranolazine may increase the plasma concentrations of drugs that are primarily metabolized by the CYP450 3A4 isoenzyme. The mechanism is reduced clearance due to inhibition of CYP450 3A4 by ranolazine. The interaction may be significant for sensitive CYP450 3A4 substrates or those that demonstrate a narrow therapeutic index.

MANAGEMENT: Caution is advised if ranolazine is used in combination with sensitive CYP450 3A4 substrates or those that demonstrate a narrow therapeutic index (e.g., ergot alkaloids, colchicine, fentanyl, macrolide immunosuppressants, midazolam, triazolam, vinca alkaloids). Dosage adjustments as well as clinical and laboratory monitoring may be appropriate whenever ranolazine is added to or withdrawn from therapy.

MONITOR: Ranolazine can cause dose-related prolongation of the QT interval. Theoretically, coadministration with other agents that can prolong the QT interval may result in additive effects and increased risk of ventricular arrhythmias including torsade de pointes and sudden death, although there is little experience in this setting. At Tmax following repeat dosing of 1000 mg twice daily, the mean effect of ranolazine on QTc is approximately 6 msec. However, in 5% of the population with the highest plasma concentrations, the prolongation of QTc is 15 msec or more. The relationship between ranolazine plasma level and QTc remains linear over a concentration range up to 4-fold greater than the concentrations produced by a dosage of 1000 mg twice a day, and this relationship is not significantly affected by age, weight, gender, race, heart rate, congestive heart failure, diabetes, or renal impairment. However, the apparent linear relationship is much steeper in cirrhotic subjects with mild or moderate hepatic impairment. Ranolazine did not induce torsade de pointes or other arrhythmias in several in vitro and animal models. There have also been no reported cases of torsade de pointes in clinical studies of ranolazine comprising 3,669 patient-years of treatment. In fact, ranolazine was found to be antiarrhythmic in Study CVT 3036 (MERLIN-TIMI 36), which was a Phase 3, randomized, double-blind, parallel-group, placebo-controlled clinical trial designed to evaluate the efficacy and safety of ranolazine as chronic therapy in patients with non-ST elevation acute coronary syndromes (ACS) treated with other standard therapy. No proarrhythmic effects were observed on 7-day Holter recordings in 3,162 ACS patients treated with ranolazine. There was a significantly lower incidence of arrhythmias (ventricular tachycardia, bradycardia, supraventricular tachycardia, and new atrial fibrillation) in patients treated with ranolazine (80%) versus placebo (87%), including ventricular tachycardia >= 3 beats (52% versus 61%). In general, the risk of an individual agent or a combination of agents causing ventricular arrhythmia in association with QT prolongation is largely unpredictable but may be increased by certain underlying risk factors such as congenital long QT syndrome, cardiac disease, and electrolyte disturbances (e.g., hypokalemia, hypomagnesemia). In addition, the extent of drug-induced QT prolongation is dependent on the particular drug(s) involved and dosage(s) of the drug(s).

MANAGEMENT: Caution is recommended if ranolazine is used in combination with other drugs that can prolong the QT interval. Since the magnitude of QTc prolongation increases with increasing plasma concentrations of ranolazine, the maximum recommended dosage of 1000 mg twice daily should not be exceeded. Patients should be advised to seek prompt medical attention if they experience symptoms that could indicate the occurrence of torsade de pointes such as dizziness, lightheadedness, fainting, palpitation, irregular heart rhythm, shortness of breath, or syncope. Ranolazine is contraindicated in patients with liver cirrhosis because of the profound effect on QT prolongation in this population.

GENERALLY AVOID: Grapefruit and grapefruit juice may significantly increase the plasma concentrations of orally administered ranolazine. The proposed mechanism is inhibition of CYP450 3A4-mediated first-pass metabolism in the gut wall by certain compounds present in grapefruit. Because ranolazine prolongs QT interval in a dose-dependent manner, high plasma levels of ranolazine may increase the risk of ventricular arrhythmias such as ventricular tachycardia, ventricular fibrillation, and torsade de pointes.

MANAGEMENT: Patients treated with ranolazine should avoid consumption of grapefruit juice and other grapefruit products if possible. Otherwise, the dosage of ranolazine should be limited to 500 mg twice a day.

MONITOR CLOSELY: Coadministration of ketamine with other central nervous system (CNS) depressants, including alcohol, may result in profound sedation, respiratory depression, coma, and death. In addition, opioid analgesics, barbiturates, and benzodiazepines may prolong the time to complete recovery from anesthesia.

MANAGEMENT: During concomitant use of ketamine with other CNS depressants, including alcohol, close monitoring of neurologic status and respiratory parameters, including respiratory rate and pulse oximetry, is recommended. Dosage adjustments should be considered according to the patient's clinical situation. Ambulatory patients should be counseled to avoid hazardous activities requiring mental alertness and motor coordination until they know how these agents affect them, and to notify their physician if they experience excessive or prolonged CNS effects that interfere with their normal activities.

GENERALLY AVOID: Alcohol may potentiate some of the pharmacologic effects of ketamine. Use in combination may result in additive central nervous system (CNS) depression and/or impairment of judgment, thinking, and psychomotor skills.

GENERALLY AVOID: Coadministration of oral ketamine with grapefruit juice may significantly increase the plasma concentrations of S(+) ketamine, the dextrorotatory enantiomer of ketamine. The proposed mechanism is inhibition of CYP450 3A4-mediated first-pass metabolism in the gut wall by certain compounds present in grapefruit. Inhibition of hepatic CYP450 3A4 may also contribute. When a single 0.2 mg/kg dose of S(+) ketamine was administered orally on study day 5 with grapefruit juice (200 mL three times daily for 5 days) in 12 healthy volunteers, mean S(+) ketamine peak plasma concentration (Cmax) and systemic exposure (AUC) increased by 2.1- and 3.0-fold, respectively, compared to administration with water. In addition, the elimination half-life of S(+) ketamine increased by 24% with grapefruit juice, and the ratio of the main metabolite norketamine to ketamine was decreased by 57%. The pharmacodynamics of ketamine were also altered by grapefruit juice. Specifically, self-rated relaxation was decreased and performance in the digit symbol substitution test was increased with grapefruit juice, but other behavioral or analgesic effects were not affected.

MANAGEMENT: Patients receiving ketamine should not drink alcohol. Caution is advised when ketamine is used in patients with acute alcohol intoxication or a history of chronic alcoholism. Following anesthesia with ketamine, patients should be counseled to avoid hazardous activities requiring complete mental alertness and motor coordination, such as driving or operating hazardous machinery, for at least 24 hours and until they know how the medication affects them. Patients treated with oral ketamine should also avoid consumption of grapefruit and grapefruit juice during treatment. Otherwise, dosage reductions of oral ketamine should be considered.

GENERALLY AVOID: The pharmacologic activity of oral midazolam, triazolam, and alprazolam may be increased if taken after drinking grapefruit juice. The proposed mechanism is CYP450 3A4 enzyme inhibition. In addition, acute alcohol ingestion may potentiate CNS depression and other CNS effects of many benzodiazepines. Tolerance may develop with chronic ethanol use. The mechanism may be decreased clearance of the benzodiazepines because of CYP450 hepatic enzyme inhibition. Also, it has been suggested that the cognitive deficits induced by benzodiazepines may be increased in patients who chronically consume large amounts of alcohol.

MANAGEMENT: The manufacturer recommends that grapefruit juice should not be taken with oral midazolam. Patients taking triazolam or alprazolam should be monitored for excessive sedation. Alternatively, the patient could consume orange juice which does not interact with these drugs. Patients should be advised to avoid alcohol during benzodiazepine therapy.