Mitoxantrone is a parenteral, synthetic antineoplastic agent. Chemically, it is an anthracenedione and is structurally similar to the anthracyclines, doxorubicin, daunorubicin and idarubicin. Mitoxantrone is sometimes substituted for doxorubicin or daunorubicin because it has considerably less cardiotoxicity and mitoxantrone is not a vesicant as are the other anthracyclines. Mitoxantrone is indicated for the treatment of acute myelogenous leukemia in combination with other chemotherapy agents such as cytarabine. Response rates with this combination range 50-70%. Mitoxantrone is also active in other hematologic malignancies such as acute lymphocytic leukemia, chronic myelogenous leukemia, non-Hodgkin's lymphoma and pediatric leukemias. Mitoxantrone in combination with corticosteroids is indicated for the treatment of pain related to advanced, hormone-refractory prostate cancer. Mitoxantrone is active in various solid tumors including breast cancer, ovarian cancer, and various sarcomas. Mitoxantrone is not active in non-small cell lung, gastric, and advanced bladder cancers, malignant mesothelioma, germ cell tumors or Kaposi's sarcoma. The FDA initially approved mitoxantrone in 1987. In October 2000, the FDA approved the use of mitoxantrone to slow the worsening of neurologic disability and to reduce relapse rate in patients with clinically worsening forms of relapsing-remitting and secondary progressive multiple sclerosis.
General Administration Information
For storage information, see the specific product information within the How Supplied section.
Hazardous Drugs Classification
-NIOSH 2016 List: Group 1
-NIOSH (Draft) 2020 List: Table 1
-Observe and exercise appropriate precautions for handling, preparation, administration, and disposal of hazardous drugs.
-Use double chemotherapy gloves and a protective gown. Prepare in a biological safety cabinet or compounding aseptic containment isolator with a closed system drug transfer device. Eye/face and respiratory protection may be needed during preparation and administration.
Emetic Risk
Pediatrics:
-Doses 33 mg/m2 or lower: Low
Adults:
-Low
Administer routine antiemetic prophylaxis prior to treatment.
Extravasation Risk
-Usually classified as an irritant, but there are reports of both vesicant/irritant properties.
-Administer drug through a central venous line.
Route-Specific Administration
Injectable Administration
-Evaluation of left ventricular ejection fraction (LVEF) is recommended at baseline and in patients with evidence of heart failure. Mitoxantrone therapy should not be given to patients with multiple sclerosis and a LVEF < 50% or neutrophil counts < 1500/mm3 (see Contraindications).
-Women with multiple sclerosis who are able to have children should have a negative pregnancy test confirmed prior to treatment and before each mitoxantrone dose.
-Patients with multiple sclerosis should be provided with the Patient Package Insert with each dose of mitoxantrone.
-Visually inspect parenteral products for particulate matter and discoloration prior to administration whenever solution and container permit.
Intravenous Administration
-Mitoxantrone is administered by IV infusion. Avoid any contact with skin. Use Luer Lok fittings to prevent accidental leakage of mitoxantrone during administration. If spills occur, clean up with a solution containing 5.5 parts calcium hypochlorite in 13 parts water.
-If evidence of extravasation occurs during administration, the infusion should be stopped and completed via another vein, preferably in another limb.
Intravenous injection:
-Dilute to at least 50 ml with NS or D5W. Discard unused portion immediately.
-Do not mix mitoxantrone in the same infusion as heparin because a precipitate may form. Due to an absence of compatibility data, do not mix mitoxantrone with other drugs.
-Inject desired dose of the diluted injection slowly over at least 3 minutes into a free-flowing IV infusion of NS or D5W.
-Although mitoxantrone is not a vesicant, care should be taken to avoid extravasation because the drug may be irritating to extravascular tissue. Use of a large vein and avoidance of veins over joints or in extremities with compromised venous or lymphatic drainage is preferable.
Other Administration Route(s)
Intraperitoneal Administration*
NOTE: Mitoxantrone is not approved by the FDA for intraperitoneal administration.
-One method of intraperitoneal (IP) administration of mitoxantrone includes infusing 500 ml Ringer's solution IP over 30 minutes, followed by mitoxantrone diluted in 500 ml Ringer's solution and infused IP over 30 minutes, and then 1000 ml Ringer's solution infused IP over 60 minutes. Other methods include mitoxantrone diluted in 2 liters of 0.9% Sodium Chloride (NS) and given as an intraperitoneal infusion.
Intrapleural Administration*
NOTE: Mitoxantrone is not approved by the FDA for intrapleural administration.
-Dilute to at least 50 ml with NS or D5W. Discard unused portion immediately. Further dilution of a dose can be made with 50-100 ml of NS. The solution is sometimes warmed to body temperature before administration.
-Administer via a 16-20 char chest tube. Retain solution for about 48 hours.
-To maximize contact between the drug and the pleura the patient can be rotated into different positions for the first 2 hours after administration, followed by continuous mobilization.
Intraarterial Administration*
NOTE: Mitoxantrone is not approved by the FDA for intraarterial administration.
-Dilute to 1000 ml NS. Discard unused portion immediately.
-Administered via hepatic artery catheters placed at the time of laparotomy or by the percutaneous Seldinger technique.
Infection (5-81%) has been reported with mitoxantrone use in clinical studies. Infection occurred in 81% of multiple sclerosis patients who received mitoxantrone 12 mg/m2 IV every 3 months for 2 years (n = 62) compared with 67% of patients who received placebo (n = 64) in a randomized study. Infections that occurred more often in patients treated with mitoxantrone compared with placebo include upper respiratory tract infection (URI) (53% vs 52%), urinary tract infection (UTI) (32% vs 13%), and sinusitis (6% vs 2%). In patients with acute nonlymphocytic leukemia, infection was reported in 66% of patients who received mitoxantrone plus cytarabine as induction therapy (n = 102) and in 60% of patients who received mitoxantrone plus cytarabine as consolidation therapy (n = 55) in a randomized, comparative study. Infections reported with induction and consolidation therapy in this study include UTI (7% and 7%), pneumonia (9% and 9%), sepsis (34% and 31%), and fungal infections (15% and 9%). In men with advanced hormone-refractory prostate cancer (HRPC), systemic infection (10% vs 7%), skin infection (5% vs 3%), and UTI (9% vs 4%) were reported more often in patients who received mitoxantrone 12 mg/m2 IV every 3 weeks plus prednisone (n = 80) compared with prednisone alone (n = 81) in a randomized, phase III study. Additionally, infection occurred in 17% of men with advanced HRPC who received mitoxantrone 14 mg/m2 IV every 3 weeks plus hydrocortisone (n = 112) compared with 4% of men treated with hydrocortisone alone (n = 113) in another randomized, phase III study. In these 2 prostate cancer studies, febrile neutropenia/infection occurred in 11% and 10% of patients receiving mitoxantrone plus corticosteroids. Monitor complete blood counts more frequently if signs and symptoms of infection develop.
Bone marrow suppression such as anemia, lymphopenia, neutropenia, and thrombocytopenia has been reported with mitoxantrone use in clinical studies; severe myelosuppression will occur with a high dosage of mitoxantrone (e.g., 14 mg/m2 IV for 3 days). Myelosuppression is the dose-limiting toxicity of mitoxantrone. In a randomized study, hematologic adverse events that occurred more often in patients with multiple sclerosis who received mitoxantrone 12 mg/m2 IV every 3 months for 2 years (n = 62) compared with placebo (n = 64) include leukopenia (4000 cells/mm3) (19% vs 0%), granulocytopenia (2000 cells/mm3) (6% vs 2%), and anemia (6% vs 2%). Therapy-related myelosuppression and significant marrow hypoplasia (pancytopenia) occurred in patients with acute nonlymphocytic leukemia who received mitoxantrone plus cytarabine as induction (n = 102) and consolidation (n = 55) therapy in a randomized study. In men with advanced hormone-refractory prostate cancer (HRPC), anemia was reported in 5% of patients who received mitoxantrone 12 mg/m2 IV every 3 weeks plus prednisone (n = 80) compared with 3% of patients treated with prednisone alone (n = 81) in a randomized, phase III study. Grade 4 neutropenia (absolute neutrophil count < 500/mm3) occurred in 54% of mitoxantrone-treated patients in this study. Additionally, decreased white blood cell count (87% vs 4%), abnormal granulocytes/bands (79% vs 3%), decreased hemoglobin (75% vs 39%), abnormal lymphocytes count (72% vs 25%), and abnormal platelet count (39% vs 7%) occurred more often in men with advanced HRPC who received mitoxantrone 14 mg/m2 IV every 3 weeks plus hydrocortisone (n = 112) compared with hydrocortisone alone (n = 113) in another randomized, phase III study. Grade 4 neutropenia was reported in 23% of mitoxantrone-treated patients in this study. In these 2 prostate cancer studies, decreased platelets (< 50,000/mm3) occurred in 4% and 3% of patients receiving mitoxantrone plus corticosteroids. Monitor complete blood counts and platelets prior to each course of mitoxantrone and more frequently if signs and symptoms of infection develop. In patients with multiple sclerosis, the mitoxantrone dose is usually not given if the neutrophil count is less than 1500 cells/mm3.
Cardiotoxicity (e.g., cardiomyopathy, congestive heart failure (CHF), decreased left ventricular ejection fraction (LVEF), sinus tachycardia, hypotension, and chest pain (unspecified)) has been reported with IV mitoxantrone therapy. In cancer patients who receive a cumulative mitoxantrone dose greater than 140 mg/m2 (with or without other chemotherapy agents), the risk of CHF is about 2.6% and the probability of moderate to severe decreased LVEF is 13%. In a randomized study, cardiac adverse events that occurred more often in patients with multiple sclerosis who received mitoxantrone 12 mg/m2 IV every 3 months for 2 years (n = 62) compared with placebo (n = 64) include arrhythmias (18% vs 8%) and abnormal electrocardiogram (ECG) (11% vs 3%). Two patients treated in the mitoxantrone 12 mg/m2 arm experienced cardiac dysfunction, one patient had LVEF values that decreased to below 50% and one patient had a LVEF decrease measured on echocardiogram. In patients with acute nonlymphocytic leukemia, cardiovascular toxicity was reported in 26% of patients who received mitoxantrone plus cytarabine as induction therapy (n = 102) and in 11% of patients who received mitoxantrone plus cytarabine as consolidation therapy (n = 55) in a randomized, comparative study. Cardiac toxicities reported with induction and consolidation therapy in this study include CHF (5% and 0%) and arrhythmias (3% and 4%). In men with advanced hormone-refractory prostate cancer (HRPC), decreased LVEF was reported in 5% of patients who received mitoxantrone 12 mg/m2 IV every 3 weeks plus prednisone (n = 80) compared with 0% of patients treated with prednisone alone (n = 81) in a randomized, phase III study. In the 128 patients who received mitoxantrone (range, 48 to 212 mg/m2) in this study (48 patients crossed over to the mitoxantrone/prednisone arm), 5.5% of patients had a cardiac event defined as any decrease in LVEF below the normal range, CHF (n = 3; 2.3%), or myocardial ischemia. Additionally, abnormal cardiac function (18% vs 0%), arrhythmias (7% vs 3%), and cardiac ischemia (5% vs 1%) occurred more often in men with advanced HRPC who received mitoxantrone 14 mg/m2 IV every 3 weeks plus hydrocortisone (n = 112) compared with hydrocortisone alone (n = 113) in another randomized, phase III study. Obtain a baseline ECG and a quantitative evaluation of LVEF prior to starting mitoxantrone therapy. In patients with multiple sclerosis, obtain an ECG and an LVEF evaluation prior to each mitoxantrone dose; do not give the mitoxantrone dose if there is a decrease in LVEF to below the lower limit of normal or a clinically significant reduction in LVEF during therapy. In multiple sclerosis patients, do not exceed a cumulative mitoxantrone dose greater than 140 mg/m2 and assess LVEF yearly after therapy completion to evaluate for late cardiotoxicity.
Gastrointestinal (GI) adverse events such as nausea (26-76%), vomiting (9-72%), stomatitis (8-29%), and diarrhea (14-47%) have been reported with IV mitoxantrone use in clinical studies. Most patients experience an acute episode of nausea and vomiting which can lead to dehydration; symptoms are usually mild to moderate in severity and can be controlled with antiemetic use. Stomatitis/mucositis generally occurs within 1 week of starting mitoxantrone therapy. In a randomized study, GI adverse events that occurred more often in patients with multiple sclerosis who received mitoxantrone 12 mg/m2 IV every 3 months for 2 years (n = 62) compared with placebo (n = 64) include nausea (76% vs 20%), stomatitis (19% vs 8%), diarrhea (16% vs 11%), and constipation (10% vs 6%). In patients with acute nonlymphocytic leukemia, GI adverse events were reported in 88% of patients who received mitoxantrone plus cytarabine as induction therapy (n = 102) and in 58% of patients who received mitoxantrone plus cytarabine as consolidation therapy (n = 55) in a randomized, comparative study. GI adverse events reported with induction and consolidation therapy in this study include nausea/vomiting (72% and 31%), diarrhea (47% and 18%), abdominal pain (15% and 9%), and mucositis/stomatitis (29% and 18%). In men with advanced hormone-refractory prostate cancer (HRPC), nausea (61% vs 35%), anorexia (25% vs 6%), constipation (16% vs 14%), mucositis (10% vs 0%), and vomiting (9% vs 5%) were reported more often in patients who received mitoxantrone 12 mg/m2 IV every 3 weeks plus prednisone (n = 80) compared with prednisone alone (n = 81) in a randomized, phase III study. Additionally, nausea (26% vs 8%), anorexia (22% vs 14%), diarrhea (14% vs 4%), vomiting (11% vs 5%), stomatitis (8% vs 1%), and other GI toxicity (14% vs 11%) occurred more often in men with advanced HRPC who received mitoxantrone 14 mg/m2 IV every 3 weeks plus hydrocortisone (n = 112) compared with hydrocortisone alone (n = 113) in another randomized, phase III study.
Alopecia has been reported commonly (20-61%) with IV mitoxantrone use in clinical studies. Alopecia occurred in 61% of multiple sclerosis patients who received mitoxantrone 12 mg/m2 IV every 3 months for 2 years (n = 62) compared with 31% of patients who received placebo (n = 64) in a randomized study. In patients with acute nonlymphocytic leukemia, alopecia was reported in 37% of patients who received mitoxantrone plus cytarabine as induction therapy (n = 102) and in 22% of patients who received mitoxantrone plus cytarabine as consolidation therapy (n = 55) in a randomized, comparative study. In men with advanced hormone-refractory prostate cancer (HRPC), alopecia was reported in 29% of patients who received mitoxantrone 12 mg/m2 IV every 3 weeks plus prednisone (n = 80) compared with 0% of patients treated with prednisone alone (n = 81) in a randomized, phase III study. Additionally, alopecia occurred in 20% of men with advanced HRPC who received mitoxantrone 14 mg/m2 IV every 3 weeks plus hydrocortisone (n = 112) compared with 1% of men treated with hydrocortisone alone (n = 113) in another randomized, phase III study.
Ophthalmic adverse effects including bluish discoloration of the sclera have been reported with IV mitoxantrone use. In patients with acute nonlymphocytic leukemia, eye adverse events were reported in 7% of patients who received mitoxantrone plus cytarabine as induction therapy (n = 102) and in 2% of patients who received mitoxantrone plus cytarabine as consolidation therapy (n = 55) in a randomized, comparative study. Conjunctivitis occurred in 5% of patients during induction and in no patients during consolidation therapy.
Injection site reaction (e.g., erythema, swelling, pain, burning, skin discoloration (blue skin), and phlebitis) and rash (unspecified) has been reported with IV mitoxantrone use. Extravasation resulting in skin ulcer and tissue necrosis may occur and skin debridement and grafting may be necessary. Monitor for local reactions during mitoxantrone therapy. If signs or symptoms of extravasation occur, stop the mitoxantrone infusion and restart in another vein. Elevate the affected extremity and apply intermittent ice packs at the subcutaneous extravasation site.
Urine discoloration (blue-green urine for up to 24 hours) has been reported with IV mitoxantrone use. Abnormal urine occurred in 11% of patients with multiple sclerosis who received mitoxantrone 12 mg/m2 IV every 3 months for 2 years (n = 62) compared with 6% of patients who received placebo (n = 64) in a randomized study. Renal failure (unspecified) was reported in 8% of patients with acute nonlymphocytic leukemia who received mitoxantrone plus cytarabine as induction therapy (n = 102) in a randomized, comparative study. Increased BUN (22% vs 20%) and creatinine (13% vs 10%) levels, hematuria (11% vs 6%), proteinuria (6% vs 3%), and other kidney or bladder adverse events (5% vs 3%) occurred more often in men with advanced hormone-refractory prostate cancer who received mitoxantrone 14 mg/m2 IV every 3 weeks plus hydrocortisone (n = 112) compared with hydrocortisone alone (n = 113) in a randomized, phase III study.
A new primary malignancy, such as acute myeloid leukemia (AML) and acute promyelocytic leukemia (APL), has been reported with mitoxantrone use. In a study in men with prostate cancer, AML was reported in 1% of patients who received mitoxantrone (n = 487) compared with no patients in the control arm (n = 496) at a follow-up of 4.7 years. Leukemia occurred in 0.6% of multiple sclerosis patients who received mitoxantrone for a median of 2.8 years in a prospective, open-label study. The risk of AML or PML was 0.25% to 2.8% in mitoxantrone-treated multiple sclerosis patients in other literature reports. The cumulative risk of developing treatment-related AML at 5 and 10 years was 1.1% and 1.6%, respectively, in breast cancer patients who received mitoxantrone in combination with other chemotherapeutic agents and radiotherapy (n = 1,774).
Hepatotoxicity including elevated hepatic enzymes (5-20%) has been reported with IV mitoxantrone use. In a randomized study, hepatic adverse events that occurred more often in patients with multiple sclerosis who received mitoxantrone 12 mg/m2 IV every 3 months for 2 years (n = 62) compared with placebo (n = 64) include increased gamma-glutamyl transpeptidase (15% vs 3%) and ALT (5% vs 3%) levels. In patients with acute nonlymphocytic leukemia, hepatic adverse reactions were reported in 10% of patients who received mitoxantrone plus cytarabine as induction therapy (n = 102) and in 14% of patients who received mitoxantrone plus cytarabine as consolidation therapy (n = 55) in a randomized, comparative study. Jaundice was reported with induction (3%) and consolidation (7%) therapy in this study. Elevated transaminase levels occurred in 20% of men with advanced hormone-refractory prostate cancer who received mitoxantrone 14 mg/m2 IV every 3 weeks plus hydrocortisone (n = 112) compared with 14% of patients treated with hydrocortisone alone (n = 113) in a randomized, phase III study. Obtain liver function tests should also be performed prior to each course of therapy. In general, mitoxantrone is not recommended in patients with multiple sclerosis who have hepatic impairment.
In a randomized study, menstrual disorder (61% vs 26%) and amenorrhea (43% vs 3%) occurred more often in female patients with multiple sclerosis who received mitoxantrone 12 mg/m2 IV every 3 months for 2 years (n = 62) compared with placebo (n = 64). Impotence (erectile dysfunction)/libido decrease (7% vs 3%) and sterility (infertility) (5% vs 3%) occurred more often in men with advanced hormone-refractory prostate cancer who received mitoxantrone 14 mg/m2 IV every 3 weeks plus hydrocortisone (n = 112) compared with hydrocortisone alone (n = 113) in a randomized, phase III study.
Hyperuricemia and tumor lysis syndrome (TLS) may occur with mitoxantrone therapy due to a rapid lysis of tumor cells. Monitor serum uric acid levels and take precautionary measures (e.g., allopurinol, hydration) prior to the initiation of antileukemic therapy.
Pulmonary adverse events such as cough (9-13%) and dyspnea (5-18%) have been reported with IV mitoxantrone use in clinical studies. Interstitial pneumonitis has been reported in cancer patients who received mitoxantrone in combination with other chemotherapy agents. In patients with acute nonlymphocytic leukemia, pulmonary adverse reactions were reported in 43% of patients who received mitoxantrone plus cytarabine as induction therapy (n = 102) and in 24% of patients who received mitoxantrone plus cytarabine as consolidation therapy (n = 55) in a randomized, comparative study. Pulmonary adverse reactions reported with induction and consolidation therapy in this study include cough (13% and 9%) and dyspnea (18% and 6%). In men with advanced hormone-refractory prostate cancer (HRPC), cough (11% vs 5%) and dyspnea (5% vs 0%) were reported more often in patients who received mitoxantrone 12 mg/m2 IV every 3 weeks plus prednisone (n = 80) compared with prednisone alone (n = 81) in a randomized, phase III study. Additionally, dyspnea (15% vs 8%) and other pulmonary toxicity (5% vs 3%) occurred more often in men with advanced HRPC who received mitoxantrone 14 mg/m2 IV every 3 weeks plus hydrocortisone (n = 112) compared with hydrocortisone alone (n = 113) in another randomized, phase III study; 2% of men treated with mitoxantrone and hydrocortisone developed pulmonary edema.
Urticaria has been reported occasionally and anaphylaxis/anaphylactoid reactions have been reported rarely with IV mitoxantrone therapy.
Back pain occurred in 8% of patients with multiple sclerosis who received mitoxantrone 12 mg/m2 IV every 3 months for 2 years (n = 62) compared with 5% of patients who received placebo (n = 64) in a randomized study. Myalgia/arthralgia occurred in 5% of men with advanced hormone-refractory prostate cancer who received mitoxantrone 14 mg/m2 IV every 3 weeks plus hydrocortisone (n = 112) compared with 3% of patients treated with hydrocortisone alone (n = 113) in a randomized, phase III study.
Bleeding (5-37%) has been reported with IV mitoxantrone use in clinical studies. In patients with acute nonlymphocytic leukemia, bleeding was reported in 37% of patients who received mitoxantrone plus cytarabine as induction therapy (n = 102) and in 20% of patients who received mitoxantrone plus cytarabine as consolidation therapy (n = 55) in a randomized, comparative study. Bleeding events reported with induction and consolidation therapy in this study include GI bleeding (16% and 2%) and petechiae/ecchymosis (7% and 11%). In men with advanced hormone-refractory prostate cancer (HRPC), bleeding/bruise was reported in 6% of patients who received mitoxantrone 12 mg/m2 IV every 3 weeks plus prednisone (n = 80) compared with 1% of patients treated with prednisone alone (n = 81) in a randomized, phase III study. Additionally, bleeding occurred in 5% of men with advanced hormone-refractory prostate cancer who received mitoxantrone 14 mg/m2 IV every 3 weeks plus hydrocortisone (n = 112) compared with 3% of patients treated with hydrocortisone alone (n = 113) in another randomized, phase III study. One patient died in the mitoxantrone plus hydrocortisone due to intracranial bleeding after a fall.
Fever (6-78%) has been reported with IV mitoxantrone use in clinical studies. In patients with acute nonlymphocytic leukemia, fever was reported in 78% of patients who received mitoxantrone plus cytarabine as induction therapy (n = 102) and in 24% of patients who received mitoxantrone plus cytarabine as consolidation therapy (n = 55) in a randomized, comparative study. In men with advanced hormone-refractory prostate cancer (HRPC), fever was reported in 6% of patients who received mitoxantrone 12 mg/m2 IV every 3 weeks plus prednisone (n = 80) compared with 3% of patients treated with prednisone alone (n = 81) in a randomized, phase III study. Additionally, fever in absence of infection (14% vs 6%) and chills (5% vs 0%) occurred more often in men with advanced HRPC who received mitoxantrone 14 mg/m2 IV every 3 weeks plus hydrocortisone (n = 112) compared with hydrocortisone alone (n = 113) in another randomized, phase III study.
Nervous system adverse events such as headache (6-13%) have been reported with IV mitoxantrone in clinical studies. Headache occurred in 6% of patients with multiple sclerosis who received mitoxantrone 12 mg/m2 IV every 3 months for 2 years (n = 62) compared with 5% of patients who received placebo (n = 64) in a randomized study. In patients with acute nonlymphocytic leukemia, central nervous system (CNS) adverse events were reported in 30% of patients who received mitoxantrone plus cytarabine as induction therapy (n = 102) and in 34% of patients who received mitoxantrone plus cytarabine as consolidation therapy (n = 55) in a randomized, comparative study. CNS events reported with induction and consolidation therapy in this study include seizures (4% and 2%) and headache (10% and 13%). Neurologic constipation (7% vs 2%), motor disorder (7% vs 3%), and mood disorder (6% vs 2%), and other neurologic adverse events (11% vs 5%) occurred more often in men with advanced hormone-refractory prostate cancer who received mitoxantrone 14 mg/m2 IV every 3 weeks plus hydrocortisone (n = 112) compared with hydrocortisone alone (n = 113) in a randomized, phase III study.
In men with advanced hormone-refractory prostate cancer (HRPC), fatigue was reported in 39% of patients who received mitoxantrone 12 mg/m2 IV every 3 weeks plus prednisone (n = 80) compared with 14% of patients treated with prednisone alone (n = 81) in a randomized, phase III study. Additionally, malaise/fatigue occurred in 34% of men with advanced HRPC who received mitoxantrone 14 mg/m2 IV every 3 weeks plus hydrocortisone (n = 112) compared with 14% of men treated with hydrocortisone alone (n = 113) in another randomized, phase III study.
In men with advanced hormone-refractory prostate cancer (HRPC), nail bed changes (onycholysis) was reported in 11% of patients who received mitoxantrone 12 mg/m2 IV every 3 weeks plus prednisone (n = 80) compared with 0% of patients treated with prednisone alone (n = 81) in a randomized, phase III study.
In men with advanced hormone-refractory prostate cancer (HRPC), edema was reported in 10% of patients who received mitoxantrone 12 mg/m2 IV every 3 weeks plus prednisone (n = 80) compared with 4% of patients treated with prednisone alone (n = 81) in a randomized, phase III study. Additionally, edema occurred in 30% of men with advanced HRPC who received mitoxantrone 14 mg/m2 IV every 3 weeks plus hydrocortisone (n = 112) compared with 14% of men treated with hydrocortisone alone (n = 113) in another randomized, phase III study.
In men with advanced hormone-refractory prostate cancer (HRPC), anxiety/depression was reported in 5% of patients who received mitoxantrone 12 mg/m2 IV every 3 weeks plus prednisone (n = 80) compared with 3% of patients treated with prednisone alone (n = 81) in a randomized, phase III study.
Sweats (hyperhidrosis) occurred in 9% of men with advanced hormone-refractory prostate cancer who received mitoxantrone 14 mg/m2 IV every 3 weeks plus hydrocortisone (n = 112) compared with 2% of patients treated with hydrocortisone alone (n = 113) in a randomized, phase III study.
Weight loss occurred in 17% of men with advanced hormone-refractory prostate cancer who received mitoxantrone 14 mg/m2 IV every 3 weeks plus hydrocortisone (n = 112) compared with 12% of patients treated with hydrocortisone alone (n = 113) in a randomized, phase III study.
Hyperglycemia (31% vs 30%) and other endocrine adverse events (6% vs 4%) occurred in men with advanced hormone-refractory prostate cancer who received mitoxantrone 14 mg/m2 IV every 3 weeks plus hydrocortisone (n = 112) compared with 30% of patients treated with hydrocortisone alone (n = 113) in a randomized, phase III study.
Hypocalcemia (10% vs 5%), hyponatremia (9% vs 3%), and hypokalemia (7% vs 4%) occurred more often in men with advanced hormone-refractory prostate cancer who received mitoxantrone 14 mg/m2 IV every 3 weeks plus hydrocortisone (n = 112) compared with hydrocortisone alone (n = 113) in a randomized, phase III study.
Severe cardiotoxicity including fatal congestive heart failure and severe left ventricular dysfunction may occur during mitoxantrone therapy or months to years after discontinuing therapy. The risk of cardiotoxicity is dose related; the maximum cumulative lifetime dose is 140 mg/m2 IV. Additionally, patients with cardiac disease, a history of prior radiation therapy to the mediastinal/pericardial area, prior therapy with anthracycline or anthracenedione agents, or who are receiving concurrent cardiotoxic agents may also be at increased risk for cardiotoxicity. Perform a cardiac history assessment and physical examination and obtain an electrocardiogram (ECG) and a quantitative evaluation of left ventricular ejection fraction (LVEF) prior to starting mitoxantrone therapy. In patients with multiple sclerosis, obtain an ECG and an LVEF evaluation prior to each mitoxantrone dose; assess LVEF yearly after therapy completion to evaluate for late cardiotoxicity. Do not give the mitoxantrone dose if there is a decrease in LVEF to below the lower limit of normal or a clinically significant reduction in LVEF during therapy.
Mitoxantrone may cause a new primary malignancy. Patients with either multiple sclerosis or cancer who received mitoxantrone may develop acute myelogenous leukemia (AML). The most commonly reported types were acute promyelocytic leukemia and acute myelocytic leukemia. Secondary AML has been reported in patients with cancer treated with anthracyclines, and mitoxantrone is an anthracenedione, which is a related drug. The occurrence of refractory secondary leukemia is more common when anthracyclines are given in combination with DNA-damaging antineoplastic agents, when patients have been heavily pretreated with cytotoxic drugs, or when doses of anthracyclines have been escalated.
Myelosuppressive drugs, such as mitoxantrone, can cause an increased incidence of bacterial, viral, and fungal infection, bleeding, and fatigue due to neutropenia, thrombocytopenia, and anemia. Because these adverse effects can be fatal, the patient must be warned to promptly report any signs such as fever, sore throat, or abnormal pain. Severe bone marrow suppression is a relative contraindication to mitoxantrone depending upon the etiology of the suppression. In general, reserve use only for the treatment of acute nonlymphocytic leukemia in patients who have a baseline neutrophil count < 1500/mm3. Mitoxantrone should be used cautiously in patients with bone marrow suppression, coagulopathy, or in those who have received previous myelosuppressive therapy such as chemotherapy or radiotherapy. Therefore, this drug requires an experienced clinician knowledgeable in the use of cancer chemotherapy. Frequent peripheral blood cell count monitoring is recommended for all patients. Patients with preexisting marrow suppression including neutropenia and/or thrombocytopenia should be allowed to recover their counts prior to mitoxantrone administration. Patients with an active infection should be treated prior to receiving mitoxantrone. Patients with a history of varicella zoster, other herpes infection (e.g., herpes simplex), or other viral infection are at risk for reactivation the infection when treated with chemotherapy.
Myelosuppressive effects of mitoxantrone can increase the risk of infection or bleeding; therefore, dental work should be delayed until blood counts have returned to normal. Patients, especially those with dental disease, should be instructed in proper oral hygiene, including caution in use of regular toothbrushes, dental floss, and toothpicks.
Intrathecal administration of mitoxantrone is not recommended. Neuropathy and neurotoxicity including seizures, paralysis, and bowel and bladder dysfunction have been reported after intrathecal injection; severe injury with permanent sequelae can occur. Intraarterial administration of mitoxantrone has been associated with reversible and irreversible local/regional neuropathy and should not be used.
Intramuscular injections should not be administered to patients receiving mitoxantrone with platelet counts < 50,000/mm3. IM injections may cause bleeding, bruising, or hematomas when administered to patients with mitoxantrone-induced thrombocytopenia.
Mitoxantrone should be given slowly into a freely flowing intravenous infusion. Intramuscular administration and subcutaneous administration of mitoxantrone are not recommended due to the potential for severe local reactions. Take care to avoid extravasation when administering mitoxantrone. Although, mitoxantrone has not been traditionally considered a vesicant, cases of skin necrosis requiring debridement and skin grafting have been reported following extravasation of mitoxantrone into tissues.
Hyperkalemia, hyperphosphatemia, hyperuricemia, hypocalcemia, and decreased urine output may be indicative of mitoxantrone-induced tumor lysis syndrome (TLS). Appropriate measures (e.g. aggressive hydration and allopurinol) must be taken to prevent severe electrolyte imbalances and renal toxicity during and following chemotherapy administration in patients with large chemosensitive tumors.
The safety of mitoxantrone use in patients with hepatic insufficiency has not been established. Patients with multiple sclerosis and hepatic impairment, in general, should not receive mitoxantrone. Mitoxantrone should be used with caution in other patients with hepatic disease, especially in patients with jaundice or hyperbilirubinemia. Mitoxantrone is eliminated hepatically, and clearance may be decreased with hepatic dysfunction. Dosage adjustments may be necessary (see Dosage).
Mitoxantrone should not be administered during pregnancy because of the possibility of teratogenic effects (FDA pregnancy risk category D). There are no adequate and well-controlled trials in pregnant women. Females who may become pregnant should use appropriate contraception. Women with multiple sclerosis who are of childbearing potential should have a pregnancy test prior to each dose of mitoxantrone, and the results should be known prior to administering the drug. If mitoxantrone is used during pregnancy or a woman becomes pregnant while taking this drug, the patient should be apprised of the potential risk to the fetus.
Mitoxantrone is excreted in breast milk and significant concentrations (18 ng/ml) have been reported for up to 28 days after the last dose. Breast-feeding should be discontinued before beginning mitoxantrone therapy because of the possibility of severe adverse reactions to the infant.
Caution is recommended during the preparation, handling, and administration of mitoxantrone solution to avoid accidental exposure. Following cutaneous and ocular exposure, eyes and skin should be thoroughly rinsed. The use of protective gowns, gloves, and goggles during preparation and administration is recommended.
Vaccination during chemotherapy or radiation therapy, such as with mitoxantrone, should be avoided because the antibody response is suboptimal. When chemotherapy is being planned, vaccination should precede the initiation of chemotherapy by >= 2 weeks. The administration of live vaccines to immunocompromised patients should be avoided. Those undergoing chemotherapy should not be exposed to others who have recently received the oral poliovirus vaccine (OPV). Measles-mumps-rubella (MMR) vaccination is not contraindicated for the close contacts, including health care professionals, of immunocompromised patients. Passive immunoprophylaxis with immune globulins may be indicated for immunocompromised persons instead of, or in addition to, vaccination. When exposed to a vaccine-preventable disease such as measles, severely immunocompromised children should be considered susceptible regardless of their vaccination history.
For the treatment of acute myelogenous leukemia (AML):
NOTE: Mitoxantrone has been designated an orphan drug by the FDA for this indication.
NOTE: If used, consolidation therapy is recommended to be withheld until full hematologic recovery occurs.
-for the treatment of acute myelogenous leukemia in combination with cytarabine:
Intravenous dosage:
Adults: For induction, 12 mg/m2/day IV on days 1 to 3 in combination with cytarabine on days 1 to 7. A second induction course of mitoxantrone 12 mg/m2/day IV for 2 days in combination with cytarabine for 5 days may be given for an incomplete antileukemic response once any severe nonhematologic toxicity, if present, is resolved. The first consolidation course is given approximately 6 weeks after the final induction course and consists of mitoxantrone 12 mg/m2/day IV for 2 days with cytarabine for 5 days. The second consolidation therapy course is generally given 4 weeks after the first consolidation course.
-for the treatment of refractory acute myelogenous leukemia in combination with etoposide and cytarabine*:
Intravenous dosage:
Adults, Adolescents, and Children >= 5 years: Etoposide 80 mg/m2 IV over 1 hour, then cytarabine 1 g/m2 IV over 6 hours, then 3 hours later, mitoxantrone 6 mg/m2 IV bolus. All should be given daily for 6 days.
Children <= 5 years old: Safety and efficacy not established.
-for the treatment of relapsed or refractory acute myelogenous leukemia in combination with cladribine, cytarabine, and filgrastim*:
Intravenous dosage:
Adults: 10 mg/m2/day IV on days 1 to 3 in combination with cladribine 5 mg/m2/day IV over 2 hours on days 1 to 5, cytarabine 2 g/m2/day IV over 4 hours, starting 2 hours after cladribine, on days 1 to 5, and G-CSF 300 mcg subcutaneously on days 0 to 5 (starting 24 hours prior to chemotherapy) (CLAG-M regimen). Patients who achieved a complete response progressed to consolidation therapy. Patients who achieved a partial response could receive a second course of CLAG-M induction therapy.
For the treatment of relapsed or refractory acute lymphocytic leukemia (ALL)* in combination with ifosfamide and etoposide:
Intravenous dosage:
Adults: 8 mg/m2/day IV over 1 hour for 3 days in combination with ifosfamide 1.5 g/m2/day IV over 30 minutes for 5 days and etoposide 100 mg/m2/day IV over 90 minutes for 5 days. All patients received mesna 120 mg/m2 IV administered immediately prior to the first ifosfamide dose and then received mesna 1 g/m2/day as a continuous IV infusion for 6 days. If patients achieved a complete remission, they were eligible to repeat a second cycle of chemotherapy as consolidation treatment.
For the treatment of malignant pleural effusion*:
Intrapleural dosage*:
Adults: 30 mg in 100 mL NS instilled in the intrapleural cavity. Thoracostomy tube was then closed for 24 hours, allowing action of the drug. It was opened and the drainage continued until the end of effusion or the manifestation of a side effect. Thoracostomy and tube drainage were also performed prior to instillation of mitoxantrone. Chest radiographs were taken immediately before and after the thoracostomy tube procedure and during the follow-up period.
For the treatment of previously treated metastatic breast cancer*:
Intravenous dosage:
Adults: 14 mg/m2 IV on day 1, every 21 days.
For the palliative treatment of severe pain related to advanced hormone-refractory prostate cancer in combination with corticosteroids:
NOTE: Mitoxantrone has been designated an orphan drug by the FDA for this indication.
Intravenous infusion dosage:
Adults: 12 to 14 mg/m2 IV every 21 days in combination with either prednisone or hydrocortisone. In randomized, controlled trials, patients who received mitoxantrone in combination with either hydrocortisone or prednisone had decreased pain intensity and decreased analgesic use. In addition, the prostate specific antigen (PSA) concentration decreased in some patients who received mitoxantrone and corticosteroids. The clinical significance of the decreased PSA is not clear as the changes in PSA did not correlate to palliative response and the studies were not designed to evaluate changes in PSA.
For autologous stem cell transplant preparation* in patients with relapsed/refractory lymphoma, in combination with melphalan:
Intravenous dosage:
Adults: Mitoxantrone 60 mg/m2 IV divided in 3 doses (each administered over 1 hour) at 1 hour intervals on day -4, in combination with melphalan 180 mg/m2 IV divided in 2 doses (each administered over 1 hour) at 1 hour intervals on day -1, followed by peripheral blood stem cell infusion on day 0.
For the treatment of metastatic hepatocellular cancer* in combination with 5-fluorouracil and cisplatin:
Intravenous dosage:
Adults: 6 mg/m2 IV on day 1 in combination with 5-fluorouracil 450 mg/m2/day continuous IV infusion on days 1 to 5 and cisplatin 80 mg/m2 IV over 2 hours on day 1; in a phase II study, the regimen was repeated every 4 weeks for a maximum of 6 cycles.
For the treatment of secondary (chronic) progressive, progressive relapsing, or worsening relapsing-remitting multiple sclerosis to reduce neurologic disability and/or frequency of clinical relapses:
NOTE: Mitoxantrone is not indicated in the treatment of primary progressive multiple sclerosis.
NOTE: Mitoxantrone has been designated an orphan drug by the FDA for this indication.
NOTE: Patients with LVEF less than 50%, a clinically significant reduction in LVEF during mitoxantrone therapy, neutrophil count less than 1500/mm3, or a cumulative lifetime dose of 140 mg/m2 should not be treated with mitoxantrone. Further, in July 2008, the FDA issued a MedWatch alerting clinicians to the possibility of decreased LVEF and frank congestive heart failure in patients who had received a cumulative lifetime mitoxantrone dose less than 100 mg/m2. LVEF should be evaluated before initiating treatment with mitoxantrone, prior to administration of each dose, and at yearly intervals after completion of treatment.
Intravenous infusion dosage:
Adults: 12 mg/m2 IV every 3 months.
For the treatment of chronic lymphocytic leukemia (CLL)*, in combination with cladribine and cyclophosphamide:
Intravenous dosage:
Adults: 10 mg/m2 IV on day 1 in combination with cyclophosphamide 650 mg/m2 IV on day 1 and cladribine 0.12 mg/kg/day IV over 2 hours on days 1 to 3 repeated every 28 days for up to 6 cycles (median, 3 cycles) has been evaluated in a randomized, phase III trial.
For the treatment of non-Hodgkin's lymphoma (NHL)*:
-for the treatment of relapsed or refractory NHL in combination with rituximab, ifosfamide, and etoposide*:
Intravenous dosage:
Adults: 8 mg/m2 IV on day 1 in combination with ifosfamide 2g/m2/day IV on days 1 to 3, etoposide 100 mg/m2/day IV on days 1 to 3, and rituximab 375 mg/m2 IV on the day prior to each chemotherapy cycle and on day 7 of cycle 3 prior to stem cell collection. The regimen was repeated for 3 cycles.
-for the treatment of intermediate or high-grade NHL in combination with cyclophosphamide, vincristine, and prednisone*:
Intravenous dosage:
Adults: 10 mg/m2 IV on day 1 in combination with cyclophosphamide 600 mg/m2 IV on day 1, vincristine 1 mg IV on day 1, and prednisolone 20 mg PO daily on days 1 to 5, repeated every 21 days for up to 6 cycles.
-for the treatment of previously untreated follicular NHL in combination with fludarabine and rituximab*:
Intravenous dosage:
Adults: 10 mg/m2 IV on day 1 in combination with fludarabine 25 mg/m2 IV daily on days 1, 2, and 3 and rituximab 375 mg/m2 IV on day 1 repeated every 21 days for 6 cycles followed by 2 additional rituximab 375 mg/m2 IV doses given at 21-day intervals has been evaluated in patients with previously untreated follicular lymphoma in a randomized, phase III trial.
Maximum Dosage Limits:
-Adults
The maximum cumulative lifetime dose of mitoxantrone is 140 mg/m2 IV.
Patients with Hepatic Impairment Dosing
Specific guidelines for dosage adjustments in hepatic impairment are not available; however, mitoxantrone clearance is reduced in patients with hepatic impairment (see Pharmacokinetics). Multiple sclerosis patients with hepatic impairment, in general, should not receive mitoxantrone. Mitoxantrone should be used cautiously and potentially in lower doses in other patients with hepatic impairment; however, specific adjustment guidelines are not available from the manufacturer.
Patients with Renal Impairment Dosing
Specific guidelines for dosage adjustments in renal impairment are not available; it appears that no dosage adjustments are needed.
*non-FDA-approved indication
Acalabrutinib: (Moderate) Coadministration of acalabrutinib and mitoxantrone may increase mitoxantrone exposure and increase the risk of mitoxantrone toxicity. Acalabrutinib is a substrate and inhibitor of the breast cancer resistance protein (BCRP) transporter in vitro; it may inhibit intestinal BCRP. Mitoxantrone is a BCRP subtrate.
Acetaminophen; Ibuprofen: (Major) Due to the thrombocytopenic effects of mitoxantrone, an additive risk of bleeding may be seen in patients receiving concomitant anticoagulants, NSAIDs, platelet inhibitors, including aspirin, strontium-89 chloride, and thrombolytic agents. In addition, large doses of salicylates (>= 3-4 g/day) can cause hypoprothrombinemia, an additional risk factor for bleeding.
Albuterol; Budesonide: (Minor) Because systemically administered corticosteroids exhibit immunosuppressive effects when given in high doses and/or for extended periods, additive effects may be seen with other immunosuppressives or antineoplastic agents.
Alemtuzumab: (Major) Concomitant use of mitoxantrone with alemtuzumab may increase the risk of immunosuppression. Avoid the use of these drugs together.
Alpha interferons: (Moderate) Additive myelosuppressive effects may be seen when alpha interferons are given concurrently with other myelosuppressive agents, such as antineoplastic agents or immunosuppressives.
Amlodipine; Celecoxib: (Major) Due to the thrombocytopenic effects of mitoxantrone, an additive risk of bleeding may be seen in patients receiving concomitant anticoagulants, NSAIDs, platelet inhibitors, including aspirin, strontium-89 chloride, and thrombolytic agents. In addition, large doses of salicylates (>= 3-4 g/day) can cause hypoprothrombinemia, an additional risk factor for bleeding.
Azelastine; Fluticasone: (Minor) Because systemically administered corticosteroids exhibit immunosuppressive effects when given in high doses and/or for extended periods, additive effects may be seen with other immunosuppressives or antineoplastic agents.
Bacillus Calmette-Guerin Vaccine, BCG: (Contraindicated) Do not administer live vaccines to mitoxantrone recipients; no data are available regarding the risk of secondary transmission of infection by live vaccines in patients receiving mitoxantrone. At least 2 weeks before initiation of mitoxantrone therapy, consider completion of all age appropriate vaccinations per current immunization guidelines. Mitoxantrone recipients may receive inactivated vaccines, but the immune response to vaccines or toxoids may be decreased.
Beclomethasone: (Minor) Because systemically administered corticosteroids exhibit immunosuppressive effects when given in high doses and/or for extended periods, additive effects may be seen with other immunosuppressives or antineoplastic agents.
Betamethasone: (Minor) Because systemically administered corticosteroids exhibit immunosuppressive effects when given in high doses and/or for extended periods, additive effects may be seen with other immunosuppressives or antineoplastic agents.
Budesonide: (Minor) Because systemically administered corticosteroids exhibit immunosuppressive effects when given in high doses and/or for extended periods, additive effects may be seen with other immunosuppressives or antineoplastic agents.
Budesonide; Formoterol: (Minor) Because systemically administered corticosteroids exhibit immunosuppressive effects when given in high doses and/or for extended periods, additive effects may be seen with other immunosuppressives or antineoplastic agents.
Budesonide; Glycopyrrolate; Formoterol: (Minor) Because systemically administered corticosteroids exhibit immunosuppressive effects when given in high doses and/or for extended periods, additive effects may be seen with other immunosuppressives or antineoplastic agents.
Bupivacaine; Meloxicam: (Major) Due to the thrombocytopenic effects of mitoxantrone, an additive risk of bleeding may be seen in patients receiving concomitant anticoagulants, NSAIDs, platelet inhibitors, including aspirin, strontium-89 chloride, and thrombolytic agents. In addition, large doses of salicylates (>= 3-4 g/day) can cause hypoprothrombinemia, an additional risk factor for bleeding.
Celecoxib: (Major) Due to the thrombocytopenic effects of mitoxantrone, an additive risk of bleeding may be seen in patients receiving concomitant anticoagulants, NSAIDs, platelet inhibitors, including aspirin, strontium-89 chloride, and thrombolytic agents. In addition, large doses of salicylates (>= 3-4 g/day) can cause hypoprothrombinemia, an additional risk factor for bleeding.
Celecoxib; Tramadol: (Major) Due to the thrombocytopenic effects of mitoxantrone, an additive risk of bleeding may be seen in patients receiving concomitant anticoagulants, NSAIDs, platelet inhibitors, including aspirin, strontium-89 chloride, and thrombolytic agents. In addition, large doses of salicylates (>= 3-4 g/day) can cause hypoprothrombinemia, an additional risk factor for bleeding.
Chikungunya Vaccine, Live: (Contraindicated) Do not administer live vaccines to mitoxantrone recipients; no data are available regarding the risk of secondary transmission of infection by live vaccines in patients receiving mitoxantrone. At least 2 weeks before initiation of mitoxantrone therapy, consider completion of all age appropriate vaccinations per current immunization guidelines. Mitoxantrone recipients may receive inactivated vaccines, but the immune response to vaccines or toxoids may be decreased.
Chlorpheniramine; Ibuprofen; Pseudoephedrine: (Major) Due to the thrombocytopenic effects of mitoxantrone, an additive risk of bleeding may be seen in patients receiving concomitant anticoagulants, NSAIDs, platelet inhibitors, including aspirin, strontium-89 chloride, and thrombolytic agents. In addition, large doses of salicylates (>= 3-4 g/day) can cause hypoprothrombinemia, an additional risk factor for bleeding.
Cholera Vaccine: (Moderate) Patients receiving immunosuppressant medications may have a diminished response to the live cholera vaccine. When feasible, administer indicated vaccines prior to initiating immunosuppressant medications. Counsel patients receiving immunosuppressant medications about the possibility of a diminished vaccine response and to continue to follow precautions to avoid exposure to cholera bacteria after receiving the vaccine.
Ciclesonide: (Minor) Because systemically administered corticosteroids exhibit immunosuppressive effects when given in high doses and/or for extended periods, additive effects may be seen with other immunosuppressives or antineoplastic agents.
Ciprofloxacin: (Major) Chemotherapy including mitoxantrone has been shown to decrease oral absorption of ciprofloxacin, presumably by altering the intestinal mucosa. In 6 cancer patients receiving chemotherapy and after 13 days of chemotherapy, there were decreases in mean maximum serum concentration, in mean time to reach maximum concentration, and in the area under the concentration curve of ciprofloxacin. Concomitant use of mitoxantrone with other quinolones may decrease GI absorption of the quinolone and possibly decrease the antimicrobial effect of the quinolone. The effects of mitoxantrone on the pharmacokinetics of intravenous ciprofloxacin are unclear at this time.
Clozapine: (Major) It is unclear if concurrent use of other drugs known to cause neutropenia (e.g., antineoplastic agents) increases the risk or severity of clozapine-induced neutropenia. Because there is no strong rationale for avoiding clozapine in patients treated with these drugs, consider increased absolute neutrophil count (ANC) monitoring and consult the treating oncologist.
Corticosteroids: (Minor) Because systemically administered corticosteroids exhibit immunosuppressive effects when given in high doses and/or for extended periods, additive effects may be seen with other immunosuppressives or antineoplastic agents.
Cortisone: (Minor) Because systemically administered corticosteroids exhibit immunosuppressive effects when given in high doses and/or for extended periods, additive effects may be seen with other immunosuppressives or antineoplastic agents.
Cyclosporine: (Major) Concurrent use of mitoxantrone with other agents which cause bone marrow or immune suppression such as other immunosuppressives may result in additive effects. In addition, high doses of cyclosporine (starting at 16 mg/kg/day IV) may increase exposure to anthracyclines in cancer patients. Cyclosporine is a substrate and inhibitor of P-glycoprotein, an energy-dependent drug efflux pump encoded for by the multidrug resistance gene-1 (MDR1). Overexpression of this protein has been described as a mechanism of resistance to naturally-occurring (non-synthetic) chemotherapy agents. Cyclosporine can block MDR1-mediated resistance when given at much higher doses than those used in transplantation and may also enhance the efficacy of mitoxantrone by inhibiting this protein. Valspodar is a cyclosporine analog with less renal and immunosuppressive effects than cyclosporine while retaining effects on MDR. The addition of cyclosporine or valspodar to mitoxantrone therapy may increase the intracellular concentrations of mitoxantrone leading to increased efficacy and side effects.
Cytarabine, ARA-C: (Minor) There is a synergistic cytotoxic effect seen during the concomittant administration of mixotrantrone and high-dose cytarabine, ARA-C. In studies of leukemic blast cells from patients treated with this combination, there was enhanced accumulation of araCTP, the active form of cytarabine, in these cells.
Daclatasvir: (Moderate) Systemic exposure of mitoxantrone, a substrate of the drug transporter breast cancer resistance protein (BCRP), may be increased when administered concurrently with daclatasvir, a BCRP inhibitor. Taking these drugs together could increase or prolong the therapeutic effects of mitoxantrone; monitor patients for potential adverse effects.
Deflazacort: (Minor) Because systemically administered corticosteroids exhibit immunosuppressive effects when given in high doses and/or for extended periods, additive effects may be seen with other immunosuppressives or antineoplastic agents.
Dengue Tetravalent Vaccine, Live: (Moderate) Patients receiving immunosuppressant medications may have a diminished response to the dengue virus vaccine. When feasible, administer indicated vaccines at least 2 weeks prior to initiating immunosuppressant medications. If vaccine administration is necessary, consider revaccination following restoration of immune competence. Counsel patients receiving immunosuppressant medications about the possibility of a diminished vaccine response and to continue to follow precautions to avoid exposure after receiving the vaccine.
Dexamethasone: (Minor) Because systemically administered corticosteroids exhibit immunosuppressive effects when given in high doses and/or for extended periods, additive effects may be seen with other immunosuppressives or antineoplastic agents.
Diclofenac: (Major) Due to the thrombocytopenic effects of mitoxantrone, an additive risk of bleeding may be seen in patients receiving concomitant anticoagulants, NSAIDs, platelet inhibitors, including aspirin, strontium-89 chloride, and thrombolytic agents. In addition, large doses of salicylates (>= 3-4 g/day) can cause hypoprothrombinemia, an additional risk factor for bleeding.
Diclofenac; Misoprostol: (Major) Due to the thrombocytopenic effects of mitoxantrone, an additive risk of bleeding may be seen in patients receiving concomitant anticoagulants, NSAIDs, platelet inhibitors, including aspirin, strontium-89 chloride, and thrombolytic agents. In addition, large doses of salicylates (>= 3-4 g/day) can cause hypoprothrombinemia, an additional risk factor for bleeding.
Diflunisal: (Major) Due to the thrombocytopenic effects of mitoxantrone, an additive risk of bleeding may be seen in patients receiving concomitant anticoagulants, NSAIDs, platelet inhibitors, including aspirin, strontium-89 chloride, and thrombolytic agents. In addition, large doses of salicylates (>= 3-4 g/day) can cause hypoprothrombinemia, an additional risk factor for bleeding.
Digoxin: (Moderate) Some antineoplastic agents have been reported to decrease the absorption of digoxin tablets due to their adverse effects on the GI mucosa; the effect on digoxin liquid is not known. The reduction in digoxin tablet absorption has resulted in plasma concentrations that are 50% of pretreatment levels and has been clinically significant in some patients. It is prudent to closely monitor patients for loss of clinical efficacy of digoxin while receiving antineoplastic therapy.
Diphenhydramine; Ibuprofen: (Major) Due to the thrombocytopenic effects of mitoxantrone, an additive risk of bleeding may be seen in patients receiving concomitant anticoagulants, NSAIDs, platelet inhibitors, including aspirin, strontium-89 chloride, and thrombolytic agents. In addition, large doses of salicylates (>= 3-4 g/day) can cause hypoprothrombinemia, an additional risk factor for bleeding.
Diphenhydramine; Naproxen: (Major) Due to the thrombocytopenic effects of mitoxantrone, an additive risk of bleeding may be seen in patients receiving concomitant anticoagulants, NSAIDs, platelet inhibitors, including aspirin, strontium-89 chloride, and thrombolytic agents. In addition, large doses of salicylates (>= 3-4 g/day) can cause hypoprothrombinemia, an additional risk factor for bleeding.
Elbasvir; Grazoprevir: (Moderate) Administering mitoxantrone with elbasvir; grazoprevir may result in elevated mitoxantrone plasma concentrations. Mitoxantrone is a substrate for the breast cancer resistance protein (BCRP); both elbasvir and grazoprevir are BCRP inhibitors.
Eltrombopag: (Moderate) Use caution and monitor for adverse reactions if eltrombopag and mitoxantrone are coadministered. Eltrombopag is an inhibitor of Breast Cancer Resistance Protein (BCRP). Drugs that are substrates for this transporter, such as mitoxantrone, may exhibit an increase in systemic exposure if coadministered with eltrombopag.
Etodolac: (Major) Due to the thrombocytopenic effects of mitoxantrone, an additive risk of bleeding may be seen in patients receiving concomitant anticoagulants, NSAIDs, platelet inhibitors, including aspirin, strontium-89 chloride, and thrombolytic agents. In addition, large doses of salicylates (>= 3-4 g/day) can cause hypoprothrombinemia, an additional risk factor for bleeding.
Febuxostat: (Major) Coadministration of febuxostat and cytotoxic antineoplastic agents has not been studied. After antineoplastic therapy, tumor cell breakdown may greatly increase the rate of purine metabolism to uric acid. Febuxostat inhibits uric acid formation, but does not affect xanthine and hypoxanthine formation. An increased renal load of these two uric acid precursors can occur and result in xanthine nephropathy and calculi.
Fenoprofen: (Major) Due to the thrombocytopenic effects of mitoxantrone, an additive risk of bleeding may be seen in patients receiving concomitant anticoagulants, NSAIDs, platelet inhibitors, including aspirin, strontium-89 chloride, and thrombolytic agents. In addition, large doses of salicylates (>= 3-4 g/day) can cause hypoprothrombinemia, an additional risk factor for bleeding.
Fludrocortisone: (Minor) Because systemically administered corticosteroids exhibit immunosuppressive effects when given in high doses and/or for extended periods, additive effects may be seen with other immunosuppressives or antineoplastic agents.
Flunisolide: (Minor) Because systemically administered corticosteroids exhibit immunosuppressive effects when given in high doses and/or for extended periods, additive effects may be seen with other immunosuppressives or antineoplastic agents.
Flurbiprofen: (Major) Due to the thrombocytopenic effects of mitoxantrone, an additive risk of bleeding may be seen in patients receiving concomitant anticoagulants, NSAIDs, platelet inhibitors, including aspirin, strontium-89 chloride, and thrombolytic agents. In addition, large doses of salicylates (>= 3-4 g/day) can cause hypoprothrombinemia, an additional risk factor for bleeding.
Fluticasone: (Minor) Because systemically administered corticosteroids exhibit immunosuppressive effects when given in high doses and/or for extended periods, additive effects may be seen with other immunosuppressives or antineoplastic agents.
Fluticasone; Salmeterol: (Minor) Because systemically administered corticosteroids exhibit immunosuppressive effects when given in high doses and/or for extended periods, additive effects may be seen with other immunosuppressives or antineoplastic agents.
Fluticasone; Umeclidinium; Vilanterol: (Minor) Because systemically administered corticosteroids exhibit immunosuppressive effects when given in high doses and/or for extended periods, additive effects may be seen with other immunosuppressives or antineoplastic agents.
Fluticasone; Vilanterol: (Minor) Because systemically administered corticosteroids exhibit immunosuppressive effects when given in high doses and/or for extended periods, additive effects may be seen with other immunosuppressives or antineoplastic agents.
Formoterol; Mometasone: (Minor) Because systemically administered corticosteroids exhibit immunosuppressive effects when given in high doses and/or for extended periods, additive effects may be seen with other immunosuppressives or antineoplastic agents.
Fostamatinib: (Moderate) Monitor for mitoxantrone toxicities that may require mitoxantrone dose reduction if given concurrently with fostamatinib. Concomitant use of fostamatinib with a BCRP substrate may increase the concentration of the BCRP substrate. The active metabolite of fostamatinib, R406, is a BCRP inhibitor; mitoxantrone is a substrate for BCRP. Coadministration of fostamatinib with another BCRP substrate increased the BCRP substrate AUC by 95% and Cmax by 88%.
Glecaprevir; Pibrentasvir: (Moderate) Caution is advised with the coadministration of glecaprevir and mitoxantrone as coadministration may increase serum concentrations of mitoxantrone and increase the risk of adverse effects. Mitoxantrone is a substrate of breast cancer resistance protein (BCRP); glecaprevir is an inhibitor of BCRP. (Moderate) Caution is advised with the coadministration of pibrentasvir and mitoxantrone as coadministration may increase serum concentrations of mitoxantrone and increase the risk of adverse effects. Mitoxantrone is a substrate of breast cancer resistance protein (BCRP); pibrentasvir is an inhibitor of BCRP.
Hydrocodone; Ibuprofen: (Major) Due to the thrombocytopenic effects of mitoxantrone, an additive risk of bleeding may be seen in patients receiving concomitant anticoagulants, NSAIDs, platelet inhibitors, including aspirin, strontium-89 chloride, and thrombolytic agents. In addition, large doses of salicylates (>= 3-4 g/day) can cause hypoprothrombinemia, an additional risk factor for bleeding.
Hydrocortisone: (Minor) Because systemically administered corticosteroids exhibit immunosuppressive effects when given in high doses and/or for extended periods, additive effects may be seen with other immunosuppressives or antineoplastic agents.
Ibuprofen: (Major) Due to the thrombocytopenic effects of mitoxantrone, an additive risk of bleeding may be seen in patients receiving concomitant anticoagulants, NSAIDs, platelet inhibitors, including aspirin, strontium-89 chloride, and thrombolytic agents. In addition, large doses of salicylates (>= 3-4 g/day) can cause hypoprothrombinemia, an additional risk factor for bleeding.
Ibuprofen; Famotidine: (Major) Due to the thrombocytopenic effects of mitoxantrone, an additive risk of bleeding may be seen in patients receiving concomitant anticoagulants, NSAIDs, platelet inhibitors, including aspirin, strontium-89 chloride, and thrombolytic agents. In addition, large doses of salicylates (>= 3-4 g/day) can cause hypoprothrombinemia, an additional risk factor for bleeding.
Ibuprofen; Oxycodone: (Major) Due to the thrombocytopenic effects of mitoxantrone, an additive risk of bleeding may be seen in patients receiving concomitant anticoagulants, NSAIDs, platelet inhibitors, including aspirin, strontium-89 chloride, and thrombolytic agents. In addition, large doses of salicylates (>= 3-4 g/day) can cause hypoprothrombinemia, an additional risk factor for bleeding.
Ibuprofen; Pseudoephedrine: (Major) Due to the thrombocytopenic effects of mitoxantrone, an additive risk of bleeding may be seen in patients receiving concomitant anticoagulants, NSAIDs, platelet inhibitors, including aspirin, strontium-89 chloride, and thrombolytic agents. In addition, large doses of salicylates (>= 3-4 g/day) can cause hypoprothrombinemia, an additional risk factor for bleeding.
Indomethacin: (Major) Due to the thrombocytopenic effects of mitoxantrone, an additive risk of bleeding may be seen in patients receiving concomitant anticoagulants, NSAIDs, platelet inhibitors, including aspirin, strontium-89 chloride, and thrombolytic agents. In addition, large doses of salicylates (>= 3-4 g/day) can cause hypoprothrombinemia, an additional risk factor for bleeding.
Interferon Alfa-2b: (Moderate) Additive myelosuppressive effects may be seen when alpha interferons are given concurrently with other myelosuppressive agents, such as antineoplastic agents or immunosuppressives.
Interferon Alfa-n3: (Moderate) Additive myelosuppressive effects may be seen when alpha interferons are given concurrently with other myelosuppressive agents, such as antineoplastic agents or immunosuppressives.
Intranasal Influenza Vaccine: (Contraindicated) Do not administer live vaccines to mitoxantrone recipients; no data are available regarding the risk of secondary transmission of infection by live vaccines in patients receiving mitoxantrone. At least 2 weeks before initiation of mitoxantrone therapy, consider completion of all age appropriate vaccinations per current immunization guidelines. Mitoxantrone recipients may receive inactivated vaccines, but the immune response to vaccines or toxoids may be decreased.
Itraconazole: (Moderate) Systemic exposure of mitoxantrone, a substrate of the drug transporter breast cancer resistance protein (BCRP), may be increased when administered concurrently with itraconazole, a BCRP inhibitor. Taking these drugs together could increase or prolong the therapeutic effects of mitoxantrone; monitor patients for potential adverse effects.
Ketoprofen: (Major) Due to the thrombocytopenic effects of mitoxantrone, an additive risk of bleeding may be seen in patients receiving concomitant anticoagulants, NSAIDs, platelet inhibitors, including aspirin, strontium-89 chloride, and thrombolytic agents. In addition, large doses of salicylates (>= 3-4 g/day) can cause hypoprothrombinemia, an additional risk factor for bleeding.
Ketorolac: (Major) Due to the thrombocytopenic effects of mitoxantrone, an additive risk of bleeding may be seen in patients receiving concomitant anticoagulants, NSAIDs, platelet inhibitors, including aspirin, strontium-89 chloride, and thrombolytic agents. In addition, large doses of salicylates (>= 3-4 g/day) can cause hypoprothrombinemia, an additional risk factor for bleeding.
Leflunomide: (Moderate) Closely monitor for mitoxantrone-induced side effects such as hepatotoxicity or hematologic toxicity when these drugs are used together. In some patients, a dosage reduction of mitoxantrone may be required. Following oral administration, leflunomide is metabolized to an active metabolite, teriflunomide, which is responsible for essentially all of leflunomide's in vivo activity. Teriflunomide is an inhibitor of the Breast Cancer Resistance Protein (BCRP). Use of teriflunomide with mitoxantrone, a substrate of BCRP, may increase mitoxantrone plasma concentrations.
Live Vaccines: (Contraindicated) Do not administer live vaccines to mitoxantrone recipients; no data are available regarding the risk of secondary transmission of infection by live vaccines in patients receiving mitoxantrone. At least 2 weeks before initiation of mitoxantrone therapy, consider completion of all age appropriate vaccinations per current immunization guidelines. Mitoxantrone recipients may receive inactivated vaccines, but the immune response to vaccines or toxoids may be decreased.
Measles Virus; Mumps Virus; Rubella Virus; Varicella Virus Vaccine, Live: (Contraindicated) Do not administer live vaccines to mitoxantrone recipients; no data are available regarding the risk of secondary transmission of infection by live vaccines in patients receiving mitoxantrone. At least 2 weeks before initiation of mitoxantrone therapy, consider completion of all age appropriate vaccinations per current immunization guidelines. Mitoxantrone recipients may receive inactivated vaccines, but the immune response to vaccines or toxoids may be decreased.
Measles/Mumps/Rubella Vaccines, MMR: (Contraindicated) Do not administer live vaccines to mitoxantrone recipients; no data are available regarding the risk of secondary transmission of infection by live vaccines in patients receiving mitoxantrone. At least 2 weeks before initiation of mitoxantrone therapy, consider completion of all age appropriate vaccinations per current immunization guidelines. Mitoxantrone recipients may receive inactivated vaccines, but the immune response to vaccines or toxoids may be decreased.
Meclofenamate Sodium: (Major) Due to the thrombocytopenic effects of mitoxantrone, an additive risk of bleeding may be seen in patients receiving concomitant anticoagulants, NSAIDs, platelet inhibitors, including aspirin, strontium-89 chloride, and thrombolytic agents. In addition, large doses of salicylates (>= 3-4 g/day) can cause hypoprothrombinemia, an additional risk factor for bleeding.
Mefenamic Acid: (Major) Due to the thrombocytopenic effects of mitoxantrone, an additive risk of bleeding may be seen in patients receiving concomitant anticoagulants, NSAIDs, platelet inhibitors, including aspirin, strontium-89 chloride, and thrombolytic agents. In addition, large doses of salicylates (>= 3-4 g/day) can cause hypoprothrombinemia, an additional risk factor for bleeding.
Meloxicam: (Major) Due to the thrombocytopenic effects of mitoxantrone, an additive risk of bleeding may be seen in patients receiving concomitant anticoagulants, NSAIDs, platelet inhibitors, including aspirin, strontium-89 chloride, and thrombolytic agents. In addition, large doses of salicylates (>= 3-4 g/day) can cause hypoprothrombinemia, an additional risk factor for bleeding.
Methylprednisolone: (Minor) Because systemically administered corticosteroids exhibit immunosuppressive effects when given in high doses and/or for extended periods, additive effects may be seen with other immunosuppressives or antineoplastic agents.
Mometasone: (Minor) Because systemically administered corticosteroids exhibit immunosuppressive effects when given in high doses and/or for extended periods, additive effects may be seen with other immunosuppressives or antineoplastic agents.
Nabumetone: (Major) Due to the thrombocytopenic effects of mitoxantrone, an additive risk of bleeding may be seen in patients receiving concomitant anticoagulants, NSAIDs, platelet inhibitors, including aspirin, strontium-89 chloride, and thrombolytic agents. In addition, large doses of salicylates (>= 3-4 g/day) can cause hypoprothrombinemia, an additional risk factor for bleeding.
Naproxen: (Major) Due to the thrombocytopenic effects of mitoxantrone, an additive risk of bleeding may be seen in patients receiving concomitant anticoagulants, NSAIDs, platelet inhibitors, including aspirin, strontium-89 chloride, and thrombolytic agents. In addition, large doses of salicylates (>= 3-4 g/day) can cause hypoprothrombinemia, an additional risk factor for bleeding.
Naproxen; Esomeprazole: (Major) Due to the thrombocytopenic effects of mitoxantrone, an additive risk of bleeding may be seen in patients receiving concomitant anticoagulants, NSAIDs, platelet inhibitors, including aspirin, strontium-89 chloride, and thrombolytic agents. In addition, large doses of salicylates (>= 3-4 g/day) can cause hypoprothrombinemia, an additional risk factor for bleeding.
Naproxen; Pseudoephedrine: (Major) Due to the thrombocytopenic effects of mitoxantrone, an additive risk of bleeding may be seen in patients receiving concomitant anticoagulants, NSAIDs, platelet inhibitors, including aspirin, strontium-89 chloride, and thrombolytic agents. In addition, large doses of salicylates (>= 3-4 g/day) can cause hypoprothrombinemia, an additional risk factor for bleeding.
Natalizumab: (Major) Natalizumab should not be used in combination with mitoxantrone because of the potential for increased risk of progressive multifocal leukoencephalopathy and other serious infections. Ordinarily, multiple sclerosis patients receiving chronic immunomodulatory therapy should not be treated with natalizumab.
Nonsteroidal antiinflammatory drugs: (Major) Due to the thrombocytopenic effects of mitoxantrone, an additive risk of bleeding may be seen in patients receiving concomitant anticoagulants, NSAIDs, platelet inhibitors, including aspirin, strontium-89 chloride, and thrombolytic agents. In addition, large doses of salicylates (>= 3-4 g/day) can cause hypoprothrombinemia, an additional risk factor for bleeding.
Ocrelizumab: (Moderate) Ocrelizumab has not been studied in combination with other immunosuppressive or immune modulating therapies used for the treatment of multiple sclerosis. Concomitant use of ocrelizumab with any of these therapies may increase the risk of immunosuppression. Use caution when switching patients from long-acting therapies with immune effects such as mitoxantrone. The median elimination half-life of mitoxantrone is 75 hours (range 23 to 215 hours).
Ofatumumab: (Moderate) Concomitant use of ofatumumab with mitoxantrone may increase the risk of immunosuppression. Ofatumumab has not been studied in combination with other immunosuppressive or immune modulating therapies used for the treatment of multiple sclerosis, such as mitoxantrone. Consider the duration and mechanism of action of drugs with immunosuppressive effects when switching therapies for multiple sclerosis patients. The median elimination half-life of mitoxantrone is 75 hours (range 23 to 215 hours).
Olopatadine; Mometasone: (Minor) Because systemically administered corticosteroids exhibit immunosuppressive effects when given in high doses and/or for extended periods, additive effects may be seen with other immunosuppressives or antineoplastic agents.
Osimertinib: (Moderate) Monitor for an increase in mitoxantrone-related adverse reactions if coadministration with osimertinib is necessary. Mitoxantrone is a BCRP substrate and osimertinib is a BCRP inhibitor.
Oxaprozin: (Major) Due to the thrombocytopenic effects of mitoxantrone, an additive risk of bleeding may be seen in patients receiving concomitant anticoagulants, NSAIDs, platelet inhibitors, including aspirin, strontium-89 chloride, and thrombolytic agents. In addition, large doses of salicylates (>= 3-4 g/day) can cause hypoprothrombinemia, an additional risk factor for bleeding.
Ozanimod: (Moderate) Concomitant use of ozanimod with mitoxantrone may increase the risk of immunosuppression. Ozanimod has not been studied in combination with other immunosuppressive or immune modulating therapies used for the treatment of multiple sclerosis. Use caution when switching patients from long-acting therapies with immune effects such as mitoxantrone. The median elimination half-life of mitoxantrone is 75 hours (range 23 to 215 hours).
Pegfilgrastim: (Major) Pegfilgrastim induces the proliferation of neutrophil-progenitor cells, and because antineoplastic agents exert toxic effects against rapidly growing cells, pegfilgrastim should not be given 14 days before or for 24 hours after cytotoxic chemotherapy.
Peginterferon Alfa-2a: (Moderate) Additive myelosuppressive effects may be seen when alpha interferons are given concurrently with other myelosuppressive agents, such as antineoplastic agents or immunosuppressives.
Peginterferon Alfa-2b: (Moderate) Additive myelosuppressive effects may be seen when alpha interferons are given concurrently with other myelosuppressive agents, such as antineoplastic agents or immunosuppressives.
Piroxicam: (Major) Due to the thrombocytopenic effects of mitoxantrone, an additive risk of bleeding may be seen in patients receiving concomitant anticoagulants, NSAIDs, platelet inhibitors, including aspirin, strontium-89 chloride, and thrombolytic agents. In addition, large doses of salicylates (>= 3-4 g/day) can cause hypoprothrombinemia, an additional risk factor for bleeding.
Prednisolone: (Minor) Because systemically administered corticosteroids exhibit immunosuppressive effects when given in high doses and/or for extended periods, additive effects may be seen with other immunosuppressives or antineoplastic agents.
Prednisone: (Minor) Because systemically administered corticosteroids exhibit immunosuppressive effects when given in high doses and/or for extended periods, additive effects may be seen with other immunosuppressives or antineoplastic agents.
Ropeginterferon alfa-2b: (Moderate) Additive myelosuppressive effects may be seen when alpha interferons are given concurrently with other myelosuppressive agents, such as antineoplastic agents or immunosuppressives.
Rotavirus Vaccine: (Contraindicated) Do not administer live vaccines to mitoxantrone recipients; no data are available regarding the risk of secondary transmission of infection by live vaccines in patients receiving mitoxantrone. At least 2 weeks before initiation of mitoxantrone therapy, consider completion of all age appropriate vaccinations per current immunization guidelines. Mitoxantrone recipients may receive inactivated vaccines, but the immune response to vaccines or toxoids may be decreased.
Safinamide: (Moderate) Safinamide at the 100 mg dose and its major metabolite may inhibit intestinal breast cancer resistance protein (BCRP), which could increase plasma concentrations of BCRP substrates such as mitoxantrone. Monitor patients for increased pharmacologic or adverse effects of BCRP substrates during concurrent use of safinamide, particularly the 100 mg dose.
SARS-CoV-2 (COVID-19) vaccines: (Moderate) Patients receiving immunosuppressant medications may have a diminished response to the SARS-CoV-2 virus vaccine. When feasible, administer indicated vaccines prior to initiating immunosuppressant medications. Counsel patients receiving immunosuppressant medications about the possibility of a diminished vaccine response and to continue to follow precautions to avoid exposure to SARS-CoV-2 virus after receiving the vaccine.
SARS-CoV-2 Virus (COVID-19) Adenovirus Vector Vaccine: (Moderate) Patients receiving immunosuppressant medications may have a diminished response to the SARS-CoV-2 virus vaccine. When feasible, administer indicated vaccines prior to initiating immunosuppressant medications. Counsel patients receiving immunosuppressant medications about the possibility of a diminished vaccine response and to continue to follow precautions to avoid exposure to SARS-CoV-2 virus after receiving the vaccine.
SARS-CoV-2 Virus (COVID-19) mRNA Vaccine: (Moderate) Patients receiving immunosuppressant medications may have a diminished response to the SARS-CoV-2 virus vaccine. When feasible, administer indicated vaccines prior to initiating immunosuppressant medications. Counsel patients receiving immunosuppressant medications about the possibility of a diminished vaccine response and to continue to follow precautions to avoid exposure to SARS-CoV-2 virus after receiving the vaccine.
SARS-CoV-2 Virus (COVID-19) Recombinant Spike Protein Nanoparticle Vaccine: (Moderate) Patients receiving immunosuppressant medications may have a diminished response to the SARS-CoV-2 virus vaccine. When feasible, administer indicated vaccines prior to initiating immunosuppressant medications. Counsel patients receiving immunosuppressant medications about the possibility of a diminished vaccine response and to continue to follow precautions to avoid exposure to SARS-CoV-2 virus after receiving the vaccine.
Smallpox and Monkeypox Vaccine, Live, Nonreplicating: (Contraindicated) Do not administer live vaccines to mitoxantrone recipients; no data are available regarding the risk of secondary transmission of infection by live vaccines in patients receiving mitoxantrone. At least 2 weeks before initiation of mitoxantrone therapy, consider completion of all age appropriate vaccinations per current immunization guidelines. Mitoxantrone recipients may receive inactivated vaccines, but the immune response to vaccines or toxoids may be decreased.
Smallpox Vaccine, Vaccinia Vaccine: (Contraindicated) Do not administer live vaccines to mitoxantrone recipients; no data are available regarding the risk of secondary transmission of infection by live vaccines in patients receiving mitoxantrone. At least 2 weeks before initiation of mitoxantrone therapy, consider completion of all age appropriate vaccinations per current immunization guidelines. Mitoxantrone recipients may receive inactivated vaccines, but the immune response to vaccines or toxoids may be decreased.
Sofosbuvir; Velpatasvir; Voxilaprevir: (Major) Avoid concurrent administration of voxilaprevir with mitoxantrone. Taking these medications together may increase the plasma concentrations of mitoxantrone. Mitoxantrone is a substrate for the drug transporter Breast Cancer Resistance Protein (BCRP). Voxilaprevir is a BCRP inhibitor.
Sulindac: (Major) Due to the thrombocytopenic effects of mitoxantrone, an additive risk of bleeding may be seen in patients receiving concomitant anticoagulants, NSAIDs, platelet inhibitors, including aspirin, strontium-89 chloride, and thrombolytic agents. In addition, large doses of salicylates (>= 3-4 g/day) can cause hypoprothrombinemia, an additional risk factor for bleeding.
Sumatriptan; Naproxen: (Major) Due to the thrombocytopenic effects of mitoxantrone, an additive risk of bleeding may be seen in patients receiving concomitant anticoagulants, NSAIDs, platelet inhibitors, including aspirin, strontium-89 chloride, and thrombolytic agents. In addition, large doses of salicylates (>= 3-4 g/day) can cause hypoprothrombinemia, an additional risk factor for bleeding.
Teriflunomide: (Moderate) Concurrent use of teriflunomide, an inhibitor of the breast cancer resistance protein (BCRP), with mitoxantrone, a substrate of BCRP, may increase exposure to mitoxantrone. Consider reducing the dosage of mitoxantrone as necessary and clinically appropriate, and monitor patients closely. Additive hepatotoxicity or hematologic toxicity may occur. The potential for additive effects should also be considered when such medications would be prescribed after teriflunomide administration has ceased, if the patient has not received the teriflunomide elimination procedure.
Tolmetin: (Major) Due to the thrombocytopenic effects of mitoxantrone, an additive risk of bleeding may be seen in patients receiving concomitant anticoagulants, NSAIDs, platelet inhibitors, including aspirin, strontium-89 chloride, and thrombolytic agents. In addition, large doses of salicylates (>= 3-4 g/day) can cause hypoprothrombinemia, an additional risk factor for bleeding.
Triamcinolone: (Minor) Because systemically administered corticosteroids exhibit immunosuppressive effects when given in high doses and/or for extended periods, additive effects may be seen with other immunosuppressives or antineoplastic agents.
Tuberculin Purified Protein Derivative, PPD: (Moderate) Immunosuppressives may decrease the immunological response to tuberculin purified protein derivative, PPD. This suppressed reactivity can persist for up to 6 weeks after treatment discontinuation. Consider deferring the skin test until completion of the immunosuppressive therapy.
Typhoid Vaccine: (Contraindicated) Do not administer live vaccines to mitoxantrone recipients; no data are available regarding the risk of secondary transmission of infection by live vaccines in patients receiving mitoxantrone. At least 2 weeks before initiation of mitoxantrone therapy, consider completion of all age appropriate vaccinations per current immunization guidelines. Mitoxantrone recipients may receive inactivated vaccines, but the immune response to vaccines or toxoids may be decreased.
Varicella-Zoster Virus Vaccine, Live: (Contraindicated) Do not administer live vaccines to mitoxantrone recipients; no data are available regarding the risk of secondary transmission of infection by live vaccines in patients receiving mitoxantrone. At least 2 weeks before initiation of mitoxantrone therapy, consider completion of all age appropriate vaccinations per current immunization guidelines. Mitoxantrone recipients may receive inactivated vaccines, but the immune response to vaccines or toxoids may be decreased.
Yellow Fever Vaccine, Live: (Contraindicated) Do not administer live vaccines to mitoxantrone recipients; no data are available regarding the risk of secondary transmission of infection by live vaccines in patients receiving mitoxantrone. At least 2 weeks before initiation of mitoxantrone therapy, consider completion of all age appropriate vaccinations per current immunization guidelines. Mitoxantrone recipients may receive inactivated vaccines, but the immune response to vaccines or toxoids may be decreased.
Mitoxantrone inhibits DNA and RNA synthesis. It binds to DNA by intercalation between base pairs, preferable G-C base pairs. Mitoxantrone also forms electrostatic cross-links within DNA to stabilize the intercalation and forms lace-like intertwining of DNA strands. Mitoxantrone inhibits topoisomerase II, an enzyme known to be important for the repair of damaged DNA. The interaction with topoisomerase II leads to single and double strand DNA breaks. Mitoxantrone also binds to the intracellular cytoskeleton protein cytokeratin 8, which may impair cell division. Unlike other anthracyclines, mitoxantrone does not form oxygen free radicals. Mitoxantrone is not a substrate for reductases, does not undergo redox cycling and may inhibit microsomal oxidative-reductive drug metabolism. Very little lipid peroxidation occurs in cardiac tissues and this is most likely the reason for the decreased cardiac effects of mitoxantrone as compared to other anthracyclines. Mitoxantrone is not cell phase specific, but appears to be most active in the late G-2 phase. It has a cytocidal effect on both nonproliferating and proliferating cultured human cells; however, rapidly proliferating cells are more sensitive to mitoxantrone. Mitoxantrone has been shown in vitro to inhibit B-cell, T-cell and macrophage proliferation and impair antigen presentation, as well as the secretion of interferon gamma, tumor necrosis factor-alpha, and interleukin-2. Resistance to mitoxantrone is due to amplification of the multiple drug resistance gene (mdr) increasing the expression of P170-glycoprotein; however, this may not be the only mechanism of decreased mitoxantrone intracellular accumulation.
Pharmacokinetics:
Mitoxantrone is administered as an intravenous infusion. Mitoxantrone concentrations are highest in the liver, bone marrow, heart, lung, kidney, blood components, pancreas, spleen, and thyroid. Mitoxantrone is 78% bound to plasma proteins. No drug interactions with other highly protein bound drugs have been recognized. A three compartment model best describes the elimination profile of mitoxantrone. The initial alpha half-life is 2-15 minutes reflecting mitoxantrone distribution into blood components. The beta half-life ranges from 17 minutes to 3 hours due to redistribution of mitoxantrone back into the blood and into other tissues. The median terminal half-life of mitoxantrone is 75 hours (range 23-215 hours) reflecting slow release from tissues. Renal, hepatic, and metabolic clearance of mitoxantrone is low suggesting the major route of elimination from the plasma is by tissue uptake and binding. Mitoxantrone is then gradually released from these tissues. Mitoxantrone is metabolized to 2 inactive metabolites. The parent drug may also be conjugated with glutathione or glucuronide. Less than 10% of the total mitoxantrone dose is detected in the urine. Elimination of drug in the urine is pharmacokinetically insignificant but is clinically important since it will change the urine to a bluish-green color. Approximately 25% of a dose is eliminated via the hepatobiliary system after 5 days.
-Route-Specific Pharmacokinetics
Intravenous Route
After intravenous infusion, mitoxantrone is rapidly and extensively distributed to tissue.
-Special Populations
Hepatic Impairment
Severe hepatic dysfunction (bilirubin >3.4 mg/dl) lowers total body clearance and the AUC is more than 3-times greater than the value seen in patients with normal hepatic function. Dose adjustments of mitoxantrone may be needed in these patients (see Dosage, patients with hepatic impairment). In patients with hepatic dysfunction or abnormal third space volume the terminal half-life of mitoxantrone ranges from 53.3-173 hours.