Drug Interactions between ibuprofen / oxycodone and isoniazid / rifampin

MONITOR CLOSELY: The risk of hepatotoxicity is greater when rifampin and isoniazid (INH) are given concomitantly, than when either drug is given alone. The proposed mechanism is rifampin's induction of isoniazid hydrolase, an enzyme involved in the conversion of INH to isonicotinic acid and hydrazine. Hydrazine is the proposed toxic metabolite of INH, which has been shown in animal studies to cause steatosis, hepatocyte vacuolation and glutathione depletion. Some studies have also shown that slow acetylators have a two-fold increased risk of developing antituberculosis drug-induced hepatotoxicity (ATDH) as compared with fast acetylators due to more available INH for direct hydrolysis to hydrazine. Theoretically, a similar reaction may occur with rifabutin and isoniazid. Additional risk factors for developing hepatotoxicity include patients with advanced age, malnutrition, existing hepatic impairment, daily alcohol consumption, female gender, HIV infection, extra-pulmonary tuberculosis and/or patients who are taking other potent CYP450-inducing agents.

MANAGEMENT: Caution and close monitoring should be considered if isoniazid (INH) is coadministered with rifampin or rifabutin. In cases where coadministration is required, careful monitoring of liver function, especially ALT and AST, should be done at baseline and then every 2 to 4 weeks during therapy, or in accordance with individual product labeling. Some manufacturers of INH recommend strongly considering its discontinuation if serum aminotransferase concentrations (AST or SGOT, ALT or SGPT) exceed 3 to 5 times the upper limit of normal. Product labeling for rifampin also recommends the immediate discontinuation of therapy if hepatic damage is suspected. INH product labeling suggests alternate drugs be used if hepatitis is attributed to INH in patients with tuberculosis. However, if INH must be used, it should only be resumed after the patient's symptoms and laboratory abnormalities have cleared. It should also be restarted in very small, gradually increasing doses and immediately withdrawn if there is any indication of recurrent liver involvement. Patients should be counseled to immediately report signs or symptoms consistent with liver damage and notified that prodromal symptoms usually consist of fatigue, weakness, malaise, anorexia, nausea, and/or vomiting.

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MONITOR CLOSELY: Coadministration with inducers of CYP450 3A4 may decrease the plasma concentrations of opioids that are primarily metabolized by the isoenzyme such as butorphanol, fentanyl, hydrocodone, and oxycodone. Reduced efficacy or withdrawal symptoms may occur in patients maintained on their narcotic pain regimen following the addition of a CYP450 3A4 inducer. Conversely, discontinuation of the inducer may increase opioid plasma concentrations and potentiate the risk of overdose and fatal respiratory depression.

MANAGEMENT: Pharmacologic response to the opioid should be monitored more closely whenever a CYP450 3A4 inducer is added to or withdrawn from therapy, and the opioid dosage adjusted as necessary.

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MONITOR: Coadministration of rifampin with agents known to induce hepatotoxicity may potentiate the risk of liver injury. There are various possible mechanisms related to rifampin-associated hepatotoxicity described in product labeling and medical literature, however no consensus has been made. These include increased mitochondrial oxidative stress, apoptotic liver cell injury (in rodent studies), the development of cholestasis, hepatic lipid accumulation, and elevated toxic metabolites caused by rifampin-mediated induction of cytochrome P450 enzymes. Cases of drug-induced liver injury (including fatal cases) have been reported within the first few days to months following rifampin treatment initiation. Additional data suggests that 1-2% of patients receiving rifampin monotherapy for tuberculosis prophylaxis experience hepatotoxicity. The severity of hepatotoxicity from rifampin ranges from asymptomatic elevations in liver enzymes, jaundice and/or hyperbilirubinemia, and symptomatic self-limiting hepatitis to fulminant liver failure and death. In most cases, liver function recovers upon on discontinuation of rifampin treatment, however, progression to acute liver failure requiring liver transplantation is possible. Known risk factors that may predispose the patient to rifampin related hepatotoxicity include: coadministration with other hepatotoxic agents, alcoholism, existing liver disease, malnutrition, extensive liver tuberculosis, liver adenocarcinoma and biliary tract neoplasm. Clinical data have been reported with concurrent use of rifampin with other antituberculosis agents (e.g. isoniazid, pyrazinamide), acetaminophen, antiretroviral agents (e.g., saquinavir/ritonavir) and halothane. Data with other hepatotoxic agents are limited.

MANAGEMENT: Caution and close clinical monitoring should be considered if rifampin is coadministered with other hepatotoxic medications. In addition, the manufacturer recommends patients with impaired liver function only be given rifampin in cases of necessity and then under strict medical supervision. Some authorities consider rifampin treatment in patients with existing liver injury contraindicated (Canada). In cases where coadministration of rifampin with hepatotoxic agents is required, careful monitoring of liver function, especially ALT and AST, should be done prior to therapy and then every 2 to 4 weeks during therapy. If hepatic damage is suspected, rifampin should be immediately discontinued. Furthermore, if hepatitis is attributed to rifampin in patients with tuberculosis, alternative agents should be considered. Patients should be instructed to contact their physician immediately if they experience symptoms such as itching, weakness, loss of appetite, nausea, vomiting, abdominal pain, yellowing of the eyes or skin or dark urine.

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MONITOR: Coadministration of isoniazid (INH) with other agents known to induce hepatotoxicity may potentiate the risk of liver injury. INH-associated hepatotoxicity is believed to be due to an accumulation of toxic metabolites and may also be partly immune mediated, though the exact mechanisms are not universally agreed upon. INH is metabolized by N-acetyltransferase and CYP450 2E1. The rate of INH's acetylation is genetically determined and generally classified as slow or rapid, with slow acetylators characterized by a relative lack of N-acetyltransferase. While the rate of acetylation does not significantly alter INH's effectiveness, it can lead to higher blood levels of INH and an increase of adverse reactions. In addition, INH is an in vitro inhibitor of several CYP450 isoenzymes (2C9, 2C19, 2E1, and 3A4). Coadministration of hepatotoxic drugs eliminated by one or more of these pathways may lead to elevated concentrations of the concomitant drug and increase the risk of hepatotoxicity. Most of the INH-associated hepatitis cases occur during the first 3 months of treatment, but may occur at any time and have been reported to be severe or even fatal. INH is reported in medical literature to cause clinically apparent acute liver injury with jaundice in 0.5% to 1% and fatality in 0.05% to 0.1% of recipients. A United States Public Health Service Surveillance Study of 13,838 people taking INH reported 8 deaths among 174 cases of hepatitis. Risk factors for INH related liver injury may include: age > 35 years, female gender, postpartum period, daily consumption of alcohol, injection drug user, slow acetylator phenotype, malnutrition, HIV infection, pre-existing liver disease, extra-pulmonary tuberculosis, and concomitant use of hepatotoxic medications. Clinical data have been reported with concurrent use of acetaminophen, alcohol, carbamazepine, phenobarbital, phenytoin, and rifampin.

MANAGEMENT: Coadministration of isoniazid (INH) with other hepatotoxic medications should be done with caution and close clinical monitoring. Some authorities recommend avoiding concurrent use when possible. If coadministration is needed, baseline and monthly liver function testing as well as monthly interviewing of the patient to check for signs and symptoms of adverse effects is recommended. More frequent testing may be advisable in patients at increased risk of INH-associated liver injury. Some manufacturers of INH recommend strongly considering its discontinuation if serum aminotransferase concentrations (AST or SGOT, ALT or SGPT) exceed 3 to 5 times the upper limit of normal. Patients should be counseled to immediately report signs or symptoms consistent with liver damage and notified that prodromal symptoms usually consist of fatigue, weakness, malaise, anorexia, nausea, and/or vomiting. If hepatic damage is suspected, INH should be immediately discontinued as continuation may lead to more severe damage. If hepatitis is attributed to INH in patients with tuberculosis, alternative drugs should be used. However, if INH must be used, it should only be resumed after the patient's symptoms and laboratory abnormalities have cleared. It should also be restarted in very small, gradually increasing doses and immediately withdrawn if there is any indication of recurrent liver involvement. Consultation with product labeling and relevant guidelines is advisable.

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MONITOR: Coadministration with inhibitors of CYP450 3A4 may increase the plasma concentrations of oxycodone, which is primarily metabolized by the isoenzyme. Increased oxycodone concentrations could increase or prolong adverse drug effects and may cause potentially fatal respiratory depression. According to some manufacturers, oxycodone systemic exposure (AUC) was, on average, approximately 2.4-times higher (range 1.5 to 3.4) during coadministration with itraconazole (200 mg orally for 5 days); 1.8 times higher (range 1.3 to 2.3) during coadministration with telithromycin (800 mg orally for 4 days); 3.6 times higher (range 2.7 to 5.6) during coadministration with voriconazole (200 mg twice daily for 4 days); and 1.7 times higher (range 1.1 - 2.1) during coadministration with grapefruit juice (200 mL three times daily for 5 days). Itraconazole, telithromycin and voriconazole are considered potent inhibitors of CYP450 3A4, while grapefruit juice may be a moderate or potent inhibitor depending on strength and brand of juice. It is not known to what extent oxycodone may interact with weak CYP450 3A4 inhibitors. Because oxycodone is also partially metabolized by CYP450 2D6, the magnitude of interaction may be increased with concomitant use of a CYP450 3A4 and a CYP450 2D6 inhibitor, or concomitant use of a drug that is a dual inhibitor of both isoenzymes.

MANAGEMENT: Caution may be advisable when oxycodone is prescribed with weak CYP450 3A4 inhibitors. The risk of overdose may be increased following the initiation of a CYP450 3A4 inhibitor in patients already receiving oxycodone. Patients should be closely monitored for signs and symptoms of sedation, respiratory depression, and hypotension. Following discontinuation of the CYP450 3A4 inhibitor, patients should be monitored for reduced efficacy of oxycodone or development of withdrawal symptoms due to reduced plasma oxycodone levels.

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