Am B isome for Injection is a sterile, non-pyrogenic lyophilized product for intravenous infusion. Each vial contains 50 mg of amphotericin B, USP, intercalated into a liposomal membrane consisting of approximately 213 mg hydrogenated soy phosphatidylcholine; 52 mg cholesterol, NF; 84 mg distearoylphosphatidylglycerol; 0.64 mg alpha tocopherol, USP; together with 900 mg sucrose, NF; and 27 mg disodium succinate hexahydrate as buffer. Following reconstitution with Sterile Water for Injection, USP, the resulting pH of the suspension is between 5.0-6.0.
Am B isome is a true single bilayer liposomal drug delivery system. Liposomes are closed, spherical vesicles created by mixing specific proportions of amphophilic substances such as phospholipids and cholesterol so that they arrange themselves into multiple concentric bilayer membranes when hydrated in aqueous solutions. Single bilayer liposomes are then formed by microemulsification of multilamellar vesicles using a homogenizer. Am B isome consists of these unilamellar bilayer liposomes with amphotericin B intercalated within the membrane. Due to the nature and quantity of amphophilic substances used, and the lipophilic moiety in the amphotericin B molecule, the drug is an integral part of the overall structure of the Am B isome liposomes. Am B isome contains true liposomes that are less than 100 nm in diameter. A schematic depiction of the liposome is presented below.
Note: Liposomal encapsulation or incorporation into a lipid complex can substantially affect a drug' functional properties relative to those of the unencapsulated drug or non-lipid associated drug. In addition, different liposomal or lipid-complex products with a common active ingredient may vary from one another in the chemical composition and physical form of the lipid component. Such differences may affect the functional properties of these drug products.
Amphotericin B is a macrocyclic, polyene, antifungal antibiotic produced from a strain of Streptomyces nodosus.
Amphotericin B is designated chemically as:
[1R-(1R*,3S*,5R*,6R*,9R*,11R*,15S*,16R*,17R*,18S*,19E,21E,23E,25E,27E,29E,31E,33R*,35S*,36R*,37S*)]- 33-[(3-Amino-3,6-dideoxy-(beta)-D-mannopyranosyl)oxy]-1,3,5,6,9,11,17,37- octahydroxy-15,16,18-trimethyl-13-oxo-14,39-diox-abicyclo[33.3.1] nonatriaconta-19,21,23,25,27,29,31-hepta-ene-36-carboxylic acid (CAS No. 1397-89-3).
Amphotericin B has a molecular formula of C 47 H 73 NO 17 and a molecular weight of 924.09.
The structure of amphotericin B is shown below:
Amphotericin B, the active ingredient of Am B isome, acts by binding to the sterol component of a cell membrane leading to alterations in cell permeability and cell death. While amphotericin B has a higher affinity for the ergosterol component of the fungal cell membrane, it can also bind to the cholesterol component of the mammalian cell leading to cytotoxicity. Am B isome, the liposomal preparation of amphotericin B, has been shown to penetrate the cell wall of both extracellular and intracellular forms of susceptible fungi.
Am B isome has shown in vitro activity comparable to amphotericin B against the following organisms: Aspergillus species ( A. fumigatus, A. flavus), Candida species ( C. albicans, C. krusei, C. lusitaniae, C. parapsilosis, C. tropicalis), Cryptococcus neoformans, and Blastomyces dermatitidis . However, standardized techniques for susceptibility testing of antifungal agents have not been established and results of such studies do not necessarily correlate with clinical outcome.
Am B isome is active in animal models against Aspergillus fumigatus, Candida albicans, Candida krusei, Candida lusitaniae, Cryptococcus neoformans, Blastomyces dermatitidis, Coccidioides immitis, Histoplasma capsulatum, Paracoccidioides brasiliensis, Leishmania donovani and Leishmania infatum . The administration of Am B isome in these animal models demonstrated prolonged survival of infected animals, reduction of microorganisms from target organs, or a decrease in lung weight.
Mutants with decreased susceptibility to amphotericin B have been isolated from several fungal species after serial passage in culture media containing the drug, and from some patients receiving prolonged therapy. Drug combination studies in vitro and in vivo suggest that imidazoles may induce resistance to amphotericin B. However, the clinical relevance to drug resistance has not been established.
The assay used to measure amphotericin B in the serum after administration of Am B isome does not distinguish amphotericin B that is complexed with the phospholipids of Am B isome from amphotericin B that is uncomplexed. The pharmacokinetic profile of amphotericin B after administration of Am B isome is based upon total serum concentrations of amphotericin B. The pharmacokinetic profile of amphotericin B was determined in febrile neutropenic cancer and bone marrow transplant patients who received 1-2 hour infusions of 1.0 to 5.0 mg/kg/day Am B isome for 3 to 20 days.
The pharmacokinetics of amphotericin B after administration of Am B isome are nonlinear such that there is a greater than proportional increase in serum concentrations with an increase in dose from 1.0 to 5.0 mg/kg/day. The pharmacokinetic parameters of total amphotericin B (mean ± SD) after the first dose and at steady state are shown in the table below.
Based on total amphotericin B concentrations measured within a dosing interval (24 hours) after administration of Am B isome, the mean half-life was 7-10 hours. However, based on total amphotericin B concentration measured up to 49 days after dosing Am B isome, the mean half-life was 100-153 hours. The long terminal elimination half-life is probably a slow redistribution from tissues. Steady state concentrations were generally achieved within 4 days of dosing.
Although variable, mean trough concentrations of amphotericin B remained relatively constant with repeated administration of the same dose over the range of 1.0 to 5.0 mg/kg/day, indicating no significant drug accumulation in the serum.
The metabolic pathways of Am B isome are not known.
The mean clearance at steady state was independent of dose. The excretion of amphotericin B after administration of Am B isome has not been studied.
The effect of renal impairment on the disposition of Am B isome has not been studied. However, Am B isome has been successfully administered to patients with pre-existing renal impairment .
The effect of hepatic impairment on the disposition of Am B isome is not known.
Pediatric and Elderly Patients
The pharmacokinetics of amphotericin B after administration of Am B isome in pediatric and elderly patients have not been studied; however, Am B isome has been used in pediatric and elderly patients .
Gender and Ethnicity
The effect of gender or ethnicity on the pharmacokinetics of amphotericin B after administration of Am B isome is not known.
Am B isome is indicated for the following:
See DOSAGE AND ADMINISTRATION for recommended doses by indication.
Ten clinical studies supporting the efficacy and safety of Am B isome were conducted. This clinical program included both controlled and uncontrolled clinical studies. These studies, which involved 1904 patients, included patients with confirmed systemic mycoses, empirical therapy, and visceral leishmaniasis.
Seventeen hundred and fifty episodes were evaluable for efficacy, of which 1145 (302 pediatric and 843 adults) were treated with Am B isome.
Three controlled empirical therapy trials compared the efficacy and safety of Am B isome to amphotericin B. One of these studies was conducted in a pediatric population, one in adults, and a third in patients aged 2 years or more. In addition, a controlled empirical therapy trial comparing the safety of Am B isome to Abelcet® (amphotericin B lipid complex) was conducted in patients aged 2 years or more.
One compassionate use study enrolled patients who had failed amphotericin B deoxycholate therapy or who were unable to receive amphotericin B deoxycholate because of renal insufficiency.
Study 94-0-002, a randomized, double-blind, comparative multi-center trial, evaluated the efficacy of Am B isome (1.5-6.0 mg/kg/day) compared with amphotericin B deoxycholate (0.3-1.2 mg/kg/day) in the empirical treatment of 687 adult and pediatric neutropenic patients who were febrile despite having received at least 96 hours of broad spectrum antibacterial therapy. Therapeutic success required (a) resolution of fever during the neutropenic period, (b) absence of an emergent fungal infection, (c) patient survival for at least 7 days post therapy, (d) no discontinuation of therapy due to toxicity or lack of efficacy, and (e) resolution of any study-entry fungal infection.
The overall therapeutic success rates for Am B isome and amphotericin B deoxycholate were equivalent. Results are summarized in the following table. Note: The categories presented below are not mutually exclusive.
This therapeutic equivalence had no apparent relationship to the use of prestudy antifungal prophylaxis or concomitant granulocytic colony stimulating factors.
The incidence of mycologically confirmed and clinically diagnosed, emergent fungal infections are presented in the following table. Am B isome and amphotericin B were found to be equivalent with respect to the total number of emergent fungal infections.
Mycologically confirmed fungal infections at study-entry were cured in 8 of 11 patients in the Am B isome group and 7 of 10 in the amphotericin B group.
Study 97-0-034, a randomized, double-blind, comparative multi-center trial, evaluated the safety of Am B isome (3.0 and 5.0 mg/kg/day) compared with amphotericin B lipid complex (5 mg/kg/day) in the empirical treatment of 202 adult and 42 pediatric neutropenic patients. One hundred and sixty-six patients received Am B isome (85 patients received 3 mg/kg/day and 81 received 5 mg/kg/day) and 78 patients received amphotericin B lipid complex. The study patients were febrile despite having received at least 72 hours of broad spectrum antibacterial therapy. The primary endpoint of this study was safety. The study was not designed to draw statistically meaningful conclusions related to comparative efficacy, and in fact, Abelcet is not labeled for this indication.
Two supportive prospective randomized, open label, comparative multi-center studies examined the efficacy of two dosages of Am B isome (1 and 3 mg/kg/day) compared to amphotericin B deoxycholate (1 mg/kg/day) in the treatment of neutropenic patients with presumed fungal infections. These patients were undergoing chemotherapy as part of a bone marrow transplant or had hematological disease. Study 104-10 enrolled adult patients (n=134). Study 104-14 enrolled pediatric patients (n=214). Both studies support the efficacy equivalence of Am B isome and amphotericin B as empirical therapy in febrile neutropenic patients.
Treatment of Patients with Aspergillus Species Candida Species and/or Cryptococcus Species Infections Refractory to Amphotericin B Deoxycholate, or in Patients Where Renal Impairment or Unacceptable Toxicity Precludes the Use of Amphotericin B Deoxycholate
Am B isome was evaluated in a compassionate use study in hospitalized patients with systemic fungal infections. These patients either had fungal infections refractory to amphotericin B deoxycholate, were intolerant to the use of amphotericin B deoxycholate, or had pre-existing renal insufficiency. Patient recruitment involved 140 infectious episodes in 133 patients, with 53 episodes evaluable for mycological response and 91 episodes evaluable for clinical outcome. Clinical success and mycological eradication occurred in some patients with documented aspergillosis, candidiasis, and cryptococcus.
Am B isome was studied in patients with visceral leishmaniasis who were infected in the Mediterranean basin with documented or presumed Leishmaniasis infantum . Clinical studies have not provided conclusive data regarding efficacy against L. donovani and L. chagasi.
Am B isome achieved high rates of acute parasite clearance in immunocompetent patients when total doses of 12-30 mg/kg were administered. Most of these immunocompetent patients remained relapse-free during follow-up periods of 6 months or longer. While acute parasite clearance was achieved in most of the immunocompromised patients who received total doses of 30-40 mg/kg, the majority of these patients were observed to relapse in the 6 months following the completion of therapy. Of the 21 immunocompromised patients studied, 17 were coinfected with HIV; approximately half of the HIV infected patients had AIDS. The following table presents a comparison of efficacy rates among immunocompetent and immunocompromised patients infected in the Mediterranean basin who had no prior treatment or remote prior treatment for visceral leishmaniasis. Efficacy is expressed as both acute parasite clearance at the end of therapy (EOT) and as overall success (clearance with no relapse) during the follow-up period (F/U) of greater than 6 months for immunocompetent and immunocompromised patients:
When followed for 6 months or more after treatment, the overall success rate among immunocompetent patients was 96.5% and the overall success rate among immunocompromised patients was 11.8% due to relapse in the majority of patients. While case reports have suggested there may be a role for long-term therapy to prevent relapses in HIV coinfected patients (Lopez-Dupla, et al. J. Antimicrob Chemother 1993;32:657-659), there are no data to date documenting the efficacy or safety of repeat courses of Am B isome or of maintenance therapy with this drug among immunocompromised patients.
Am B isome is contraindicated in those patients who have demonstrated or have known hypersensitivity to amphotericin B deoxycholate or any other constituents of the product unless, in the opinion of the treating physician, the benefit of therapy outweighs the risk.
Anaphylaxis has been reported with amphotericin B deoxycholate and other amphotericin B-containing drugs, including Am B isome. If a severe anaphylactic reaction occurs, the infusion should be immediately discontinued and the patient should not receive further infusions of Am B isome.
As with any amphotericin B-containing product the drug should be administered by medically trained personnel. During the initial dosing period, patients should be under close clinical observation. Am B isome has been shown to be significantly less toxic than amphotericin B deoxycholate; however, adverse events may still occur.
Patient management should include laboratory evaluation of renal, hepatic and hematopoietic function, and serum electrolytes (particularly magnesium and potassium).
No formal clinical studies of drug interactions have been conducted with Am B isome. However, the following drugs are known to interact with amphotericin B and may interact with Am B isome.
Antineoplastic agents: Concurrent use of antineoplastic agents may enhance the potential for renal toxicity, bronchospasm, and hypotension. Antineoplastic agents should be given concomitantly with caution.
Corticosteroids and corticotropin (ACTH): Concurrent use of corticosteroids and ACTH may potentiate hypokalemia which could predispose the patient to cardiac dysfunction. If used concomitantly, serum electrolytes and cardiac function should be closely monitored.
Digitalis glycosides: Concurrent use may induce hypokalemia and may potentiate digitalis toxicity. When administered concomitantly, serum potassium levels should be closely monitored.
Flucytosine Concurrent use of flucytosine may increase the toxicity of flucytosine by possibly increasing its cellular uptake and/or impairing its renal excretion.
Azoles (e.g. ketoconazole, miconazole, clotrimazole, fluconazole, etc.): In vitro and in vivo animal studies of the combination of amphotericin B and imidazoles suggest that imidazoles may induce fungal resistance to amphotericin B. Combination therapy should be administered with caution, especially in immunocompromised patients.
Leukocyte transfusions: Acute pulmonary toxicity has been reported in patients simultaneously receiving intravenous amphotericin B and leukocyte transfusions.
Other nephrotoxic medications: Concurrent use of amphotericin B and other nephrotoxic medications may enhance the potential for drug-induced renal toxicity. Intensive monitoring of renal function is recommended in patients requiring any combination of nephrotoxic medications.
Skeletal muscle relaxants: Amphotericin B-induced hypokalemia may enhance the curariform effect of skeletal muscle relaxants (e.g. tubocurarine) due to hypokalemia. When administered concomitantly, serum potassium levels should be closely monitored.
No long term studies in animals have been performed to evaluate carcinogenic potential of Am B isome. Am B isome has not been tested to determine its mutagenic potential. A Segment I Reproductive Study in rats found an abnormal estrous cycle (prolonged diestrus) and decreased number of corpora lutea in the high dose groups (10 and 15 mg/kg, doses equivalent to human doses of 1.6 and 2.4 mg/kg based on body surface area considerations). Am B isome did not affect fertility or days to copulation. There were no effects on male reproductive function.
There have been no adequate and well-controlled studies of Am B isome in pregnant women. Systemic fungal infections have been successfully treated in pregnant women with amphotericin B deoxycholate, but the number of cases reported has been small.
Segment II studies in both rats and rabbits have concluded that Am B isome had no teratogenic potential in these species. In rats, the maternal non-toxic dose of Am B isome was estimated to be 5 mg/kg (equivalent to 0.16 to 0.8 times the recommended human clinical dose range of 1 to 5 mg/kg) and in rabbits, 3 mg/kg (equivalent to 0.2 to 1 times the recommended human clinical dose range), based on body surface area correction. Rabbits receiving the higher doses, (equivalent to 0.5 to 2 times the recommended human dose) of Am B isome experienced a higher rate of spontaneous abortions than did the control groups. Am B isome should only be used during pregnancy if the possible benefits to be derived outweigh the potential risks involved.
Many drugs are excreted in human milk. However, it is not known whether Am B isome is excreted in human milk. Due to the potential for serious adverse reactions in breast-fed infants, a decision should be made whether to discontinue nursing or whether to discontinue the drug, taking into account the importance of the drug to the mother.
Pediatric patients, age 1 month to 16 years, with presumed fungal infection (empirical therapy), confirmed systemic fungal infections or with visceral leishmaniasis have been successfully treated with Am B isome. In studies which included 302 pediatric patients administered Am B isome, there was no evidence of any differences in efficacy or safety of Am B isome compared to adults. Since pediatric patients have received Am B isome at doses comparable to those used in adults on a per kilogram body weight basis, no dosage adjustment is required in this population. Safety and effectiveness in pediatric patients below the age of one month has not been established.
Experience with Am B isome in the elderly (65 years or older) comprised 71 patients. It has not been necessary to alter the dose of Am B isome for this population. As with most other drugs, elderly patients receiving Am B isome should be carefully monitored.
The following adverse events are based on the experience of 592 adult patients (295 treated with Am B isome and 297 treated with amphotericin B deoxycholate) and 95 pediatric patients (48 treated with Am B isome and 47 treated with amphotericin B deoxycholate) in Study 94-0-002, a randomized, double-blind, multi-center study in febrile, neutropenic patients. Am B isome and amphotericin B were infused over two hours.
The incidence of common adverse events (incidence of 10% or greater) occurring with Am B isome compared to amphotericin B deoxycholate, regardless of relationship to study drug, is shown in the following table:
Am B isome was well tolerated. Am B isome had a lower incidence of chills, hypertension, hypotension, tachycardia, hypoxia, hypokalemia, and various events related to decreased kidney function as compared to amphotericin B deoxycholate.
In pediatric patients (16 years of age or less) in this double-blind study, Am B isome compared to amphotericin B deoxycholate had a lower incidence of hypokalemia (37% versus 55%), chills (29% versus 68%), vomiting (27% versus 55%), and hypertension (10% versus 21%). Similar trends, although with a somewhat lower incidence, were observed in open-label, randomized Study 104-14 involving 205 febrile neutropenic pediatric patients (141 treated with Am B isome and 64 treated with amphotericin B deoxycholate). Pediatric patients appear to have more tolerance than older individuals for the nephrotoxic effects of amphotericin B deoxycholate.
The incidence of adverse events occurring in more than 10% of subjects in one or more arms regardless of relationship to study drug are summarized in the following table:
In Study 94-0-002, the large, double-blind study of pediatric and adult febrile neutropenic patients, no premedication to prevent infusion related reaction was administered prior to the first dose of study drug (Day 1). Am B isome-treated patients had a lower incidence of infusion related fever (17% versus 44%), chills/rigors (18% versus 54%), and vomiting (6% versus 8%) on Day 1 as compared to amphotericin B deoxycholate-treated patients.
The incidence of infusion related reactions on Day 1 in pediatric and adult patients is summarized in the following table:
Cardiorespiratory events, except for vasodilatation (flushing), during all study drug infusions were more frequent in amphotericin B-treated patients as summarized in the following table:
The percentage of patients who received drugs either for the treatment or prevention of infusion related reactions (e.g., acetaminophen, diphenhydramine, meperidine and hydrocortisone) was lower in Am B isome-treated patients compared with amphotericin B deoxycholate-treated patients.
In the empirical therapy study 97-0-034, on Day 1, where no premedication was administered, the overall incidence of infusion related events of chills/rigors was signifcantly lower for patients administered Am B isome compared with amphotericin B lipid complex. Fever, chills/rigors and hypoxia were significantly lower for each Am B isome group compared with the amphotericin B lipid complex group. The infusion related event hypoxia was reported for 11.5% of amphotericin B lipid complex-treated patients compared with 0% of patients administered 3 mg/kg per day Am B isome and 1.2% of patients treated with 5 mg/kg per day Am B isome.
Day 1 body temperature increased above the temperature taken within 1 hour prior to infusion (preinfusion temperature) or above the lowest infusion value (no preinfusion temperature recorded).
Patients were not administered premedications to prevent infusion related reactions prior to the Day 1 study drug infusion.
There have been a few reports of flushing, back pain with or without chest tightness, and chest pain associated with Am B isome administration; on occasion this has been severe. Where these symptoms were noted, the reaction developed within a few minutes after the start of infusion and disappeared rapidly when the infusion was stopped. The symptoms do not occur with every dose and usually do not recur on subsequent administrations when the infusion rate is slowed.
In Study 94-0-002, a significantly lower incidence of grade 3 or 4 toxicity was observed in the Am B isome group compared with the amphotericin B group. In addition, nearly three times as many patients administered amphotericin B required a reduction in dose due to toxicity or discontinuation of study drug due to an infusion related reaction compared with those administered Am B isome.
In empirical therapy study 97-0-034, a greater proportion of patients in the amphotericin B lipid complex group discontinued the study drug due to an adverse event than in the Am B isome groups.
The following adverse events also have been reported in 2% to 10% of Am B isome-treated patients receiving chemotherapy or bone marrow transplantation in five comparative, clinical trials:
Body as a Whole --abdomen enlarged, allergic reaction, cellulitis, cell mediated immunological reaction, face edema, graft versus host disease, malaise, neck pain, and procedural complication.
Cardiovascular System --arrhythmia, atrial fibrillation, bradycardia, cardiac arrest, cardiomegaly, hemorrhage, postural hypotension, valvular heart disease, vascular disorder, and vasodilatation (flushing).
Digestive System --anorexia, constipation, dry mouth/nose, dyspepsia, dysphagia, eructation, fecal incontinence, flatulence, hemorrhoids, gum/oral hemorrhage, hematemesis, hepatocellular damage, hepatomegaly, liver function test abnormal, ileus, mucositis, rectal disorder, stomatitis, ulcerative stomatitis, and veno-occlusive liver disease.
Hemic & Lymphatic System --anemia, coagulation disorder, ecchymosis, fluid overload, petechia, prothrombin decreased, prothrombin increased, and thrombocytopenia.
Metabolic & Nutritional Disorders --acidosis, amylase increased, hyperchloremia, hyperkalemia, hypermagnesemia, hyperphosphatemia, hyponatremia, hypophosphatemia, hypoproteinemia, lactate dehydrogenase increased, nonprotein nitrogen (NPN) increased, and respiratory alkalosis.
Musculoskeletal System --arthralgia, bone pain, dystonia, myalgia, and rigors.
Nervous System --agitation, coma, convulsion, cough, depression, dysesthesia, dizziness, hallucinations, nervousness, paresthesia, somnolence, thinking abnormality, and tremor.
Respiratory System --asthma, atelectasis, hemoptysis, hiccup, hyperventilation, influenza-like symptoms, lung edema, pharyngitis, pneumonia, respiratory insufficiency, respiratory failure, and sinusitis.
Skin & Appendages --alopecia, dry skin, herpes simplex, injection site inflammation, maculopapular rash, purpura, skin discoloration, skin disorder, skin ulcer, urticaria, and vesiculobullous rash.
Special Senses --conjunctivitis, dry eyes, and eye hemorrhage.
Urogenital System --abnormal renal function, acute kidney failure, acute renal failure, dysuria, kidney failure, toxic nephropathy, urinary incontinence, and vaginal hemorrhage.
The following infrequent adverse experience have been reported in post-marketing surveillance, in addition to those mentioned above: angioedema, erythema, urticaria, cyanosis/hypoventilation, pulmonary edema, agranulocytosis, hemorrhagic cystitis.
The effect of Am B isome on renal and hepatic function and on serum electrolytes was assessed from laboratory values measured repeatedly in Study 94-0-002. The frequency and magnitude of hepatic test abnormalities were similar in the Am B isome and amphotericin B groups. Nephrotoxicity was defined as creatinine values increasing 100% or more over pretreatment levels in pediatric patients, and creatinine values increasing 100% or more over pretreatment levels in adult patients provided the peak creatinine concentration was >1.2 mg/dL. Hypokalemia was defined as potassium levels </=2.5 mmol/L any time during treatment.
Incidence of nephrotoxicity, mean peak serum creatinine concentration, mean change from baseline in serum creatinine, and, incidence of hypokalemia in the double-blind randomized study were lower in the Am B isome group as summarized in the following table:
The effect of Am B isome (3 mg/kg/day) vs. amphotericin B (0.6 mg/kg/day) on renal function in adult patients enrolled in this study is illustrated in the following figure:
In empirical therapy study 97-0-034, the incidence of nephrotoxicity as measured by increases of serum creatinine from baseline was significantly lower for patients administered Am B isome (individual dose groups and combined) compared with amphotericin B lipid complex.
The following graph shows the average serum creatinine concentrations in the compassionate use study and shows that there is a drop from pretreatment concentrations for all patients, especially those with elevated (greater than 1.7 mg/dL) pretreatment creatinine concentrations.
The toxicity of Am B isome due to overdose has not been defined. Repeated daily doses up to 7.5 mg/kg have been administered in clinical trials with no reported dose-related toxicity.
Management --If overdosage should occur, cease administration immediately. Symptomatic supportive measures should be instituted. Particular attention should be given to monitoring renal function.
Am B isome should be administered by intravenous infusion, using a controlled infusion device, over a period of approximately 120 minutes.
An in-line membrane filter may be used for the intravenous infusion of Am B isome; provided THE MEAN PORE DIAMETER OF THE FILTER IS NOT LESS THAN 1.0 MICRON.
NOTE: An existing intravenous line must be flushed with 5% Dextrose Injection prior to infusion of AmBisome. If this is not feasible, AmBisome must be administered through a separate line.
Infusion time may be reduced to approximately 60 minutes in patients in whom the treatment is well-tolerated. If the patient experiences discomfort during infusion, the duration of infusion may be increased.
The recommended initial dose of Am B isome for each indication for adult and pediatric patients is as follows:
Dosing and rate of infusion should be individualized to the needs of the specific patient to ensure maximum efficacy while minimizing systemic toxicities or adverse events.
Doses recommended for visceral leishmaniasis are presented below:
For immunocompetent patients who do not achieve parasitic clearance with the recommended dose, a repeat course of therapy may be useful.
For immunocompromised patients who do not clear parasites or who experience relapses, expert advice regarding further treatment is recommended.
Directions for Reconstitution, Filtration and Dilution
Read This Entire Section Carefully Before Beginning Reconstitution
Am B isome must be reconstituted using Sterile Water for Injection, USP (without a bacteriostatic agent). Vials of Am B isome containing 50 mg of amphotericin B are prepared as follows:
STORAGE OF AMBISOME
Unopened vials of lyophilized material must be stored under refrigeration at 2°-8° C (36°-46° F).
Storage of Reconstituted Product Concentrate
The reconstituted product concentrate may be stored for up to 24 hours at 2°-8° C (36°-46° F) following reconstitution with Sterile Water for Injection, USP. Do not freeze.
Storage of Diluted Product
Injection of Am B isome should commence within 6 hours of dilution with 5% Dextrose Injection.
As with all parenteral drug products, the reconstituted Am B isome should be inspected visually for particulate matter and discoloration prior to administration, whenever solution and container permit. Do not use material if there is any evidence of precipitation or foreign matter. Aseptic technique must be strictly observed in all handling since no preservative or bacteriostatic agent is present in Am B isome or in the materials specified for reconstitution and dilution.
Am B isome for Injection is available as single 50 mg vial cartons and in packs of ten individual vial cartons (NDC 0469-3051-30).
Each carton contains one pre-packaged, disposable sterile 5 micron filter.
Fujisawa Healthcare, Inc.
Deerfield, IL 60015-2548
Gilead Sciences, Inc.
San Dimas, CA 91773
Am B isome® is a registered trademark of Gilead Sciences, Inc.
003 Revised February 2000
Abelcet® is a registered trademark of the Liposome Company, Inc.