AmB has been a mainstay of antifungal therapy for treating disseminated, life-threatening fungal infections. Perhaps the major reasons for lasting acceptance of AmB are its broad spectrum of activity and the relatively few examples of mycological resistance to the drug.18

In its pure form it has very little solubility in aqueous solutions at physiological pH, requiring complexing with some other agent for clinical administration; the first such agent was sodium deoxycholate. AmB can be administered intravenously, intrathecally, intralesionally, intra-articularly, and infused into surgical sites.32

In spite of its proven track record, the requirement for parenteral administration for long periods is inconvenient, frequently necessitating hospitalization and prolonged intravenous (IV) access. Furthermore, its well-known side effects and toxicity will sometimes require discontinuation of therapy despite a life-threatening systemic fungal infection.2

The mechanism of action of AmB, which is shared in common with other polyenes, is based on the binding of the hydrophobic moiety of the AmB molecule to the fungal cell membrane ergosterol moiety,10 producing an aggregate that forms transmembrane channels. These defects cause depolarization of the membrane and an increase in membrane permeability to protons and monovalent cations. Intermolecular hydrogen bonding interactions among hydroxyl, carboxyl, and amino groups stabilize the channel in its open form, destroying activity and allowing the cytoplasmic contents to leak out, leading to cell death.32 AmB also has the capability of binding to the cholesterol of mammalian cell membranes, which is responsible for a major fraction of its toxic potential. Fortunately, more avid binding of AmB to ergosterol than to cholesterol and to ergosterol-containing membranes than to cholesterol-containing membranes has been demonstrated by spectrophotometry. Although some studies question the role of ergosterol binding in the effects of AmB, and no simple relationship between the binding and biological activity of AmB has been found, it is assumed that the basis for the clinical usefulness of AmB is its greater affinity for ergosterol-containing membranes than for cholesterol-containing membranes.32

Multiple attempts have been made to improve on the early preparations of AmB. The principal motivation to the development of additional AmB products is the search for agents that are more efficacious, more tolerable, and less toxic, particularly less nephrotoxic than AmB deoxycholate. One of the earliest was the development of a methyl ester of AmB. This agent, however, proved to have significant neurotoxicity, which caused its further investigation to be abandoned.32 Most of the efforts at improving AmB over the last 30 years have been focused on the preparation of AmB with a lipid conjugate. Several preparations have been investigated, three of which came to clinical trials and commercialization: AmB colloidal dispersion (ABCD) composed of disk-like structures, AmB lipid complex (Abelcet, formerly ABLC) formed by a concentration of ribbon-like structures of a bilayered membrane, and AmB liposomal (AB-Lip) that consists of unilamellar vesicles containing AmB.2,13,14,22,28

It is increasingly apparent that AmB lipid preparations are the new “gold standard” of polyene therapy.38 Lipid formulations of AmB are better tolerated than AmB deoxycholate and have been used mainly in patients intolerant to conventional AmB or unlikely to tolerate it because of already-altered renal function.7,28,38,48 High costs, a relative paucity of clinical data, and the existence of alternative antifungal therapies (azoles and echinocandins) explain why lipid formulations have been generally used as second-line therapy.20

AmB administration is limited by infusion-related toxicity, an effect postulated to result from proinflammatory cytokine production by innate immune cells. Because AmB is a microbial product, it has been hypothesized that it stimulates immune cells via toll-like receptors in mammalian cells.42 A study with almost 400 patients23 showed that more than half of them had at least one infusion-related adverse event.

The principal acute toxicity of AmB deoxycholate, nausea, vomiting, rigors, fever, hypertension/hypotension, and hypoxia do appear to be mitigated by the addition of some of the above-mentioned lipid moieties to the AmB molecule. In a large randomized, double-blind, multicenter trial comparing liposomal AmB with conventional AmB, as empirical antifungal therapy in patients with persistent fever and neutropenia, Walsh et al. analyzed a total of 7025 infusions that were prospectively monitored: 3622 infusions in patients receiving liposomal AmB and 3403 in those receiving conventional AmB. Patients receiving liposomal AmB had fewer infusion-related reactions than did those receiving conventional AmB. When all infusions were analyzed for infusion-related reactions, infusion-related increases in temperature of more than 1°C occurred in 7.4% of liposomal AmB and 16% of the infusions of conventional AmB (p<0.001); infusion-related reactions without fever occurred in 21% of the infusions of liposomal AmB vs. 52% of infusions of conventional AmB (p<0.001). Among the documented cardiorespiratory events, there was a significantly lower incidence of hypertension, tachycardia, hypotension, and hypoxia in recipients of liposomal AmB than in recipients of conventional AmB. Flushing reactions occurred almost exclusively in patients treated with liposomal AmB (p<0.001). Reflecting the reduced frequency of infusion-related reactions in patients receiving liposomal AmB, these patients were significantly less likely to receive acetaminophen, diphenhydramine, meperidine, hydrocortisone, or lorazepam to prevent such reactions.50 It soon became apparent, however, that the acute toxicities associated with ABCD were not substantially less than that of the deoxycholate preparation.32,51

A more recent multicenter study on acute infusion-related reactions to liposomal AmB reported that acute adverse effects occurred alone or in combination within 1 of 3 symptom complexes: (1) chest pain, dyspnea, and hypoxia; (2) severe abdomen, flank, or leg pain; and (3) flushing and urticaria. Most adverse reactions (86%) occurred within the first 5min of infusion. All patients experienced rapid resolution of symptoms after IV diphenhydramine administration. The analysis demonstrated an overall frequency of infusion-related reactions of 20%.40

A more dangerous side effect of rapid IV infusion is hyperkalemia secondary to shift of potassium from the intracellular compartment,5 with the potential for the development of fatal cardiac arrhythmias.25

AmB deoxycholate has been reported to produce significant cardiac toxicity, with ventricular arrhythmias and bradycardia reported in overdoses in children and in adults with preexisting cardiac disease, even when administered in conventional dosages and infusion rates.11 Case reports of arrhythmias in patients with normal concentration of potassium and magnesium who were given AmB intravenously suggest that it may be directly cardiotoxic.24

Severe hypertension associated with the use of AmB has also been reported in the literature. Of the eight reported cases, six developed severe hypertension within 1h after administration of AmB. All cases except one had received a non-lipid-containing preparation. At present, the exact mechanism leading to severe hypertension has not been established.53

The neurotoxic potential of AmB is also well documented. Intravenous injection has been associated with hyperthermia, hypotension, confusion, incoherence, delirium, depression, obtundation, psychotic behavior, tremors, convulsions, blurring of vision, loss of hearing, flaccid quadriparesis, with degeneration of the myelin in brachial plexus, akinetic mutism, and diffuse cerebral leukoencephalopathy.29,49

Anemia is a side effect in up to 75% of the patients treated with AmB (sometimes with thrombocytopenia). It is the result of direct suppression of erythropoiesis (and platelet formation). Hemolysis from direct interaction between erythrocytes and AmB is unlikely to be an important factor because much higher concentrations than are attained in therapy are necessary for its occurrence. The hematocrit generally stabilizes at 25–30%.29

Only a few case reports of AmB-induced hyperbilirubinemia have been documented in the literature, each with different patterns of corresponding abnormalities in liver function tests. The unpredictable nature of this adverse effect warrants monitoring of bilirubin levels and liver function at baseline and potentially during therapy with AmB, regardless of formulation, dosage, or duration of therapy.37

Hyperphosphatemia may be an under-recognized problem with administration of liposomal AmB. The phosphate load of liposomal formulations comes from the phospholipid carrier rather than AmB. Liposomal AmB contains 37mg of inorganic phosphate per 50mg of AmB administered. Additionally, liposomal AmB is highly protein bound and has slow tissue penetration, which may result in higher phosphate availability.43 Nevertheless, it has been suggested that the hyperphosphatemia associated with liposomal AmB administration represents pseudohyperphosphatemia because of interference of liposomal AmB with the Synchron LX20 Clinical System (Beckman) analyzer technique.34

Hypomagnesemia, usually mild, is a frequent feature of AmB therapy, secondary to renal magnesium wasting. Therefore routine monitoring of the serum magnesium levels is useful during AmB therapy.6

There are a few reports of dilated cardiomyopathy associated with AmB therapy, which reverts once treatment is discontinued.15,33,36

Hypokalemia secondary to urinary potassium wasting is a frequent adverse effect of AmB therapy; there are reports in the pediatric literature on hypokalemia-associated rhabdomyolysis induced by this drug.35,41 Correlation between rhabdomyolysis with myoglobinuria and AmB was first reported by Drutz et al. in 1970.16 Patients on AmB should be checked for this rare yet potentially life-threatening complication.30

There is a case report of cutaneous leucocytoclastic vasculitis in which AmB might have presumably been the etiological factor.12

It is unclear whether other chronic complications such as anemia, anorexia, and cardiomyopathy are less common with the lipid preparation of AmB than the deoxycholate. What is clear is that all three of the lipid preparations produce less substantial long-term nephrotoxicity.3,38

AmB is amphipathic and exhibits low solubility and permeability, resulting in negligible absorption when administered orally. Advances in drug delivery systems have overcome some of the solubility issues that prevent oral bioavailability and new formulations are currently in development.44 Novel lipid-based AmpB oral formulations in the animal model have provided excellent drug solubilization, drug stability in simulated gastric and intestinal fluids, and antifungal activity without renal toxicity in rats infected with Aspergillus fumigatus and Candida albicans.52

The pharmacokinetics, toxicity, and activity are directly dependent on the type of AmB formulation that is being used. New drug delivery systems such as nanospheres and microspheres can result in higher concentrations of AmB in the liver and spleen and lower concentrations in kidney and lungs, decreasing its toxicity. Furthermore, the administration of these drug delivery systems can enhance the drug accessibility to organs and tissues (e.g., bone marrow) otherwise inaccessible to the free drug.45

Incubation of AmB lipid complex (ABLC) with recombinant human apolipoprotein A-I induces solubilization of ABLC by transforming micron-sized phospholipid/AMB assemblies into discrete nanoscale disk-shaped complexes termed nanodisks. Transformation of ABLC into nanodisks seems to preserve the biological activity of AMB as well as the reduced toxicity of the ABLC formulation.46

Authors have nothing to declare.