Drug Interaction Report

MONITOR CLOSELY: Coadministration of lomitapide with other agents known to induce hepatotoxicity may potentiate the risk of liver injury. Lomitapide can cause elevations in serum transaminases and hepatic steatosis. In a premarketing clinical trial, 34% (10/29) of patients treated with lomitapide had at least one elevation in alanine aminotransferase (ALT) or aspartate aminotransferase (AST) 3 times the upper limit of normal (ULN) or greater, and 14% (4/29) had at least one elevation in ALT or AST 5 times ULN or greater. There were no concomitant clinically meaningful elevations of total bilirubin, international normalized ratio (INR), or alkaline phosphatase. Lomitapide also increases hepatic fat, with or without concomitant increases in transaminases. In the same study, the median absolute increase in hepatic fat was 6% after both 26 and 78 weeks of treatment, from 1% at baseline, measured by magnetic resonance spectroscopy. Hepatic steatosis associated with lomitapide may be a risk factor for progressive liver disease, including steatohepatitis and cirrhosis. Clinical data suggest that hepatic fat accumulation is reversible after stopping treatment with lomitapide, although the long-term consequences are unknown.

MANAGEMENT: Caution is advised if lomitapide is used with other potentially hepatotoxic agents (e.g., acetaminophen; alcohol; amiodarone; androgens and anabolic steroids; antituberculous agents; azole antifungal agents; ACE inhibitors; cyclosporine (high dosages); disulfiram; endothelin receptor antagonists; interferons; ketolide and macrolide antibiotics; kinase inhibitors; methotrexate; nonsteroidal anti-inflammatory agents; nucleoside reverse transcriptase inhibitors; proteasome inhibitors; retinoids; tamoxifen; tetracyclines; thiazolidinediones; tolvaptan; vincristine; zileuton; anticonvulsants such as carbamazepine, hydantoins, felbamate, and valproic acid; other lipid-lowering medications such as fenofibrate, mipomersen, niacin, and statins; herbals and nutritional supplements such as black cohosh, chaparral, comfrey, DHEA, kava, pennyroyal oil, and red yeast rice). Patients treated with lomitapide should have serum ALT, AST, alkaline phosphatase, and total bilirubin measured prior to initiation of treatment and regularly during treatment in accordance with the product labeling, and the dosing adjusted or interrupted as necessary. Since alcohol may increase levels of hepatic fat and induce or exacerbate liver injury, the manufacturer recommends that patients taking lomitapide not consume more than one alcoholic drink per day. Patients should be advised to seek medical attention if they experience potential signs and symptoms of hepatotoxicity such as fever, rash, itching, anorexia, nausea, vomiting, fatigue, malaise, right upper quadrant pain, dark urine, pale stools, and jaundice.

ADJUST DOSING INTERVAL: Administration of lomitapide with food may increase the risk of common gastrointestinal adverse reactions such as diarrhea, nausea, vomiting, dyspepsia, abdominal pain or discomfort, abdominal distension, constipation, and flatulence. Absorption of concomitant oral medications may be affected in patients who develop diarrhea or vomiting.

GENERALLY AVOID: Grapefruit juice may significantly increase the plasma concentrations of lomitapide. The proposed mechanism is inhibition of CYP450 3A4-mediated first-pass metabolism in the gut wall by certain compounds present in grapefruit. Weak CYP450 3A4 inhibitors can increase lomitapide exposure (AUC) by approximately 2-fold according to the product labeling. Ketoconazole, a potent CYP450 3A4 inhibitor, has been shown to increase lomitapide AUC by 27-fold .

GENERALLY AVOID: Coadministration with alcohol may increase the risk of hepatotoxicity associated with the use of lomitapide. In a premarketing clinical trial, 34% (10/29) of patients treated with lomitapide had at least one elevation in alanine aminotransferase (ALT) or aspartate aminotransferase (AST) 3 times the upper limit of normal (ULN) or greater, and 14% (4/29) had at least one elevation in ALT or AST 5 times ULN or greater. There were no concomitant clinically meaningful elevations of total bilirubin, international normalized ratio (INR), or alkaline phosphatase. Lomitapide also increases hepatic fat, with or without concomitant increases in transaminases. In the same study, the median absolute increase in hepatic fat was 6% after both 26 and 78 weeks of treatment, from 1% at baseline, measured by magnetic resonance spectroscopy. Hepatic steatosis associated with lomitapide may be a risk factor for progressive liver disease, including steatohepatitis and cirrhosis. Clinical data suggest that hepatic fat accumulation is reversible after stopping treatment with lomitapide, although the long-term consequences are unknown.

MANAGEMENT: Lomitapide should be taken once daily with a glass of water, without food, at least 2 hours after the evening meal. Strict adherence to a low-fat diet (<20% of total calories from fat) and gradual dosage titration may also help to reduce gastrointestinal intolerance. Patients should avoid consumption of grapefruit, grapefruit juice, and any supplement containing grapefruit extract during treatment with lomitapide. Since alcohol may increase levels of hepatic fat and induce or exacerbate liver injury, the manufacturer recommends that patients taking lomitapide not consume more than one alcoholic drink per day.

ADJUST DOSING INTERVAL: The oral bioavailability of mercaptopurine (6-MP) is highly variable and may be affected by administration with food or dairy products. The mechanism by which food may impact the absorption of 6-MP has not been fully established, but cow's milk specifically has been found to contain a high concentration of xanthine oxidase, the enzyme responsible for first-pass metabolism of 6-MP to the inactive metabolite 6-thiouric acid. Incubation with cow's milk at 37 C induced a 30% catabolism of 6-MP within 30 minutes in one investigation. However, food or dairy intake with 6-MP in study patients has yielded variable results. In a study conducted in 17 children with acute lymphoblastic leukemia (ALL), oral 6-MP 75 mg/m2 administered 15 minutes after a standardized breakfast including 250 mL of milk resulted in a prolonged Tmax and a lower Cmax and AUC compared with 6-MP administration in the fasting state (mean Tmax: 2.3 hours vs. 1.2 hours; mean Cmax: 0.63 uM vs. 0.98 uM; mean AUC: 105 uM vs. 143 uM, respectively). In a different study, oral 6-MP 31.2 to 81.1 mg/m2 administered to 7 subjects with ALL 15 minutes after a standard breakfast consisting of orange juice, cereal, and toast also trended towards longer Tmax and lower Cmax values compared to 6-MP administration after an overnight fast, although the differences were not statistically significant. Two subjects had blood samples that were all below the limit of detection (20 ng/mL) following administration in the fed state. Likewise, a study of 15 pediatric patients reported non-significant 20% to 22% decreases in the Cmax and AUC of 6-MP when administered after a standardized breakfast containing both milk and cheese compared to administration after fasting, but in contrast to the two earlier studies, Tmax was decreased from 1.8 to 1.1 hours. Another study of 10 children with ALL or non-Hodgkin's lymphoma given an average oral 6-MP dose of 63 mg/m2 revealed substantial interpatient variations in the effect of food intake on 6-MP plasma levels, with Cmax changes ranging from 67% decrease to 81% increase and AUC changes ranging from 53% decrease to 86% increase relative to administration following fasting. Collectively for the group, however, there was no statistically significant difference in mean Tmax, Cmax, or AUC between the fed and fasting states. In this study, patients were fed what they normally ate at home rather than a standardized breakfast, which may have contributed to the inconsistent results. The clinical significance of the data and observations from these studies has not been determined. An interaction with milk was suspected in a four-year-old male with ALL who experienced persistent elevations of peripheral blood counts during maintenance with 6-MP and methotrexate despite increasing doses of 6-MP up to 160% of the calculated dosage for his body surface area (75 mg/m2). Cessation of concomitant milk ingestion allowed for the 6-MP dosage to return to 75 mg/m2 and resulted in control of peripheral blood counts within a week. Other data do not support a clinically relevant interaction with food or dairy products. In a prospective study of 441 patients aged 2 to 20 years receiving 6-MP for ALL maintenance, investigators found no significant association between relapse risk and 6-MP ingestion habits including administration with food versus never with food and administration with milk/dairy versus never with milk/dairy. Among the 56.2% of patients who were considered adherent by the study, there was also no significant association between red cell thioguanine nucleotide (active metabolite) levels and taking 6-MP with food versus without or taking with milk/dairy versus without. However, taking 6-MP with milk/dairy was associated with a 1.9-fold increased risk for nonadherence. These results suggest that taking 6-MP with food or milk/dairy products may not influence clinical outcome but may hinder patient adherence. Poor 6-MP adherence has been associated with an increased risk of childhood ALL relapse.

MANAGEMENT: To minimize variability in absorption and systemic exposure, the timing of mercaptopurine administration should be standardized in relation to food intake (i.e., always with food or always on an empty stomach). Some authorities suggest avoiding concomitant administration with milk or dairy products, although the clinical relevance of their effects on mercaptopurine bioavailability has not been established. As a precaution, patients may consider taking mercaptopurine at least 1 hour before or 2 hours after milk or dairy ingestion if they are able to do so without compromising treatment adherence.