key: cord-0982889-htx4x7fs
authors: Denning, David W.; Marr, Kieren A.; Lau, Wendi M.; Facklam, David P.; Ratanatharathorn, Voravit; Becker, Cornelia; Ullmann, Andrew J.; Seibel, Nita L.; Flynn, Patricia M.; van Burik, Jo-Anne H.; Buell, Donald N.; Patterson, Thomas F.
title: Micafungin (FK463), alone or in combination with other systemic antifungal agents, for the treatment of acute invasive aspergillosis()
date: 2006-05-06
journal: J Infect
DOI: 10.1016/j.jinf.2006.03.003
sha: 6ccbb562bbdca61165bb27cec24934d51dc91de4
doc_id: 982889
cord_uid: htx4x7fs

BACKGROUND: Micafungin (FK463) is a new lipopeptide compound (echinocandin) with activity against Aspergillus and Candida species. This study evaluated the safety and efficacy of micafungin in patients with proven or probable invasive aspergillosis (IA). METHODS: A multinational, non-comparative study was conducted to examine proven or probable (pulmonary only) Aspergillus species infection in a wide variety of patient populations. The study employed an open-label design utilizing micafungin alone or in combination with another systemic antifungal agent. Criteria for IA and therapeutic responses were judged by an independent panel. RESULTS: Of the 331 patients enrolled, only 225 met diagnostic criteria for IA as determined by the independent panel and received at least one dose of micafungin. Patients included 98/225 who had undergone hematopoietic stem cell transplantation (HSCT) (88/98 allogeneic), 48 with graft versus host disease (GVHD), and 83/225 who had received chemotherapy for hematologic malignancy. A favorable response rate at the end of therapy was seen in 35.6% (80/225) of patients. Of those only treated with micafungin, favorable responses were seen in 6/12 (50%) of the primary and 9/22 (40.9%) of the salvage therapy group, with corresponding numbers in the combination treatment groups of 5/17 (29.4%) and 60/174 (34.5%) of the primary and salvage treatment groups, respectively. Of the 326 micafungin-treated patients, 183 (56.1%) died during therapy or in the 6-week follow-up phase; 107 (58.5%) deaths were attributable to IA. CONCLUSIONS: Micafungin as primary or salvage therapy proved efficacious and safe in high-risk patients with IA, although patient numbers are small in the micafungin-only groups.

Micafungin (FK463), alone or in combination with other systemic antifungal agents, for the treatment of acute invasive aspergillosis * KEYWORDS Micafungin; Echinocandin; Aspergillosis; Antifungal; Combination; Amphotericin B Summary Background: Micafungin (FK463) is a new lipopeptide compound (echinocandin) with activity against Aspergillus and Candida species. This study evaluated the safety and efficacy of micafungin in patients with proven or probable invasive aspergillosis (IA). Methods: A multinational, non-comparative study was conducted to examine proven or probable (pulmonary only) Aspergillus species infection in a wide variety of patient populations. The study employed an open-label design utilizing

Invasive aspergillosis (IA) is a life-threatening infection that often occurs in adults or children with significant immunosuppression, particularly related to neutropenia or corticosteroid treatment. The frequency of IA varies substantially from one risk group to another and by locality, but is perhaps most influenced by the diagnostic approach taken in any given unit. Recent examples of incidence in high-risk groups include acute myeloid leukemia (8%), 1 acute lymphocytic leukemia (6.3%), 1 autologous hematopoietic stem cell transplantation (HSCT) (1.5%), 2 allogeneic stem cell transplantation after non-myeloablative conditioning (11%), 3, 4 allogeneic HSCT after myeloablative conditioning (15%; 11%), 5,6 lung transplantation (6.2%; 12.8%), 7, 8 hearte lung and small bowel transplantation (11%), 1 liver transplantation (3%), 9 and acquired immunodeficiency syndrome (AIDS) (2.1%). 10 Increasingly, recognized risk groups include medical intensive care unit patients, 11, 12 those with chronic pulmonary disease treated with corticosteroids, 13, 14 those receiving anti-tumor necrosis factor monoclonal antibody therapy (such as infliximab), 15 and severe acute respiratory syndrome (SARS). 16 Mortality due to IA is high. 17e19 A review of 1223 cases reported crude mortality rates of 86%, 66%, and 99% for pulmonary, sinus, and cerebral aspergillosis, respectively, 17 with only occasional reports of improvement seen since, despite the introduction of new agents in the last 10 years.

Micafungin (FK463) is a new lipopeptide compound (echinocandin) synthesized through the chemical modification of a product from Coleophoma empetri. 20, 21 Its antifungal activity resides at the cell wall as it inhibits the synthesis of (1,3)-beta-D-glucan. Pre-clinical studies indicate that micafungin has fungicidal activity against almost all Candida species, including azole-resistant Candida albicans, and kills the growing tips of Aspergillus species, like other echinocandins. The median minimum inhibitory concentration (MIC) values for Aspergillus species (including Aspergillus fumigatus, Aspergillus flavus, Aspergillus niger, and Aspergillus terreus) were substantially lower than those of other non-echinocandins tested (ie, 0.0078 mg/mL compared with 0.5e 2 mg/mL for amphotericin B), indicating the potential for greater clinical activity than itraconazole and amphotericin B in the same clinical isolates. 21 In murine models of IA (both A. fumigatus and A. terreus) micafungin was highly effective in preventing mortality (and superior to liposomal amphotericin B against an A. terreus infection), although cultures tend to remain positive in tissues. 22e25 A dose response from 1 mg/kg to 5 mg/ kg was observed. 24 Micafungin has also been shown to confer synergistic activity to amphotericin B in vitro 26 and in murine aspergillosis models. 27e29 Initial studies in male volunteers, adult HSCT recipients, and human immunodeficiency virus (HIV) patients indicated that micafungin was well tolerated over a wide range of doses. 30 The objective of the current study was to evaluate the safety and efficacy of micafungin, when administered alone or in combination with other systemic antifungal agents, in patients with proven or probable invasive infections due to Aspergillus species.

This study, utilizing two identical protocols with two exceptions (see below) (FG463-21-01 in Europe and protocol 98-0-046 in the rest of the world), was an open-label, non-comparative, multinational study in adult and pediatric patients enrolled from 1998 to 2002. Ethical approval was obtained from all 62 participating sites. The study was designed to demonstrate the safety and efficacy of micafungin in the treatment of acute IA that had failed to respond to prior therapy (labeled ''refractory''; inadequate response to, or failure of, !72 h of systemic antifungal therapy), or in patients who were unable to take alternative therapy because of adverse events associated with that therapy (labeled ''toxicity failure''). In addition, patients with newly diagnosed IA who had received 48 h of systemic antifungal therapy were eligible for enrollment. These patients were labeled ''primary''.

Adult and pediatric patients of any age, except premature neonates, with a proven or probable invasive infection due to Aspergillus species were enrolled. Only patients with pulmonary aspergillosis could be enrolled as probable cases. (In the European protocol, patients <18 years of age and patients classified as primary were excluded.) Proven IA was defined as either tissue from an infected site showing hyphae consistent with Aspergillus spp. with or without confirmatory culture from the same site, or as a positive culture from a sterile site (ie, percutaneous aspiration). Probable IA (only pertaining to pulmonary infection) was defined as clinical features of IA with either radiological features consistent with the diagnosis or a positive respiratory culture (sputum or bronchoalveolar lavage).

Patients were excluded from the study if they were pregnant or nursing; had markedly abnormal liver test parameters defined as transaminase >10Â upper limit of normal (ULN), total bilirubin >5Â ULN, or alkaline phosphatase >5Â ULN; or had a life expectancy judged to be less than 5 days. was administered intravenously in either an inpatient or an outpatient setting. Based on results of earlier studies, 31e33 patients received micafungin once daily as a 1-h infusion at an initial dose of 75 mg per day (1.5 mg/kg per day for patients weighing 40 kg). If there were continued positive culture findings, or if the patient experienced progression of disease or no improvement based on clinical signs and symptoms, and if micafungin was well tolerated, the dose of micafungin could be increased in 75 mg increments (1.5 mg/kg per day increments for patients weighing 40 kg) after at least 7 days of any dose of micafungin at the investigator's discretion. For patients enrolled in the non-European protocol, dose increases above 225 mg (4.5 mg/kg per day for patients weighing 40 kg) required the approval of the medical monitor. Dose escalation was not allowed above 200 mg per day for patients enrolled in the European protocol. Micafungin was administered intravenously for at least 7 days and up to a maximum of 90 days unless an extension was approved by the sponsor's medical monitor. Intermittent dosing of the same daily dose (a minimum of 3 days a week) was permitted after a response to micafungin was recorded, in the event daily therapy was no longer possible. The duration of follow-up post-treatment was 6 weeks.

Refractory patients could receive micafungin alone or in addition to their current systemic antifungal therapy, without alteration of dose or preparation, at the discretion of the investigator. If the patient was in the toxicity failure group, micafungin dosing was to commence after discontinuation of the previous systemic antifungal agent.

Patients underwent blood collection for determination of clinical laboratory profile at baseline and at scheduled times during therapy, and at Week 6 following treatment. All adverse events through 72 h after the last administration of study drug, whether ascertained through patient interview, physical examination, laboratory findings, or other means, were recorded. Ongoing adverse events were followed for as long as necessary to adequately evaluate the patient's safety or until the event stabilized. Adverse events, coded using a modified Coding System for Thesaurus of Adverse Reactions Terms (COSTART) dictionary, were tabulated by patient group, age group, relationship to study drug, and intensity, and for those patients who discontinued study drug.

An independent review was conducted by three reviewers (DWD, TFP, KAM), with the objective of providing consistent assessments of the baseline diagnosis of IA and disease status on study entry for efficacy failure patients, the efficacy outcome following micafungin treatment, and the causality of death with regard to aspergillosis. Patients were classified as primary, efficacy failure (refractory), or toxicity failure. ''Primary'' patients received 48 h or less of prior antifungal therapy for the infection. Efficacy failure patients had infection that progressed or failed to improve while on therapeutic doses of systemic antifungal therapy for at least 72 h. Toxicity failure patients had significant renal or hepatic toxicity at the time micafungin was started. Furthermore, refractory patients were further categorized into two groups: patients who received micafungin in addition to their current antifungal therapy (combination therapy), and patients who received only micafungin (micafungin alone).

The primary endpoint was treatment success at end of therapy. Responses were categorized as complete response (CR), partial response (PR), stabilization (S) of disease, or failure (F), based on radiological, mycological, and clinical response, or failure. The criteria for response were identical to those used in evaluation of the response to caspofungin, 34 and two of the reviewers were common to both independent panels. A favorable response was defined as a complete or partial response. The reemergence of Aspergillus infection or a new fungal infection and the use of additional antifungal therapy during the 6-week post-treatment period were also assessed. The causality of death was assessed with regard to the Aspergillus infection.

Two analyses were pre-specified: all patients who received at least one dose of micafungin (full analysis set [FAS]) were included in the safety analysis, and a per protocol set (PPS) was defined as those patients who had proven or probable IA at baseline and had received at least seven doses of study drug. All patients who received at least one dose of study drug and who met the protocolspecified criteria as determined by the independent review panel were analyzed as a modified full analysis set (mFAS).

Treatment success rate was based on the global assessment of efficacy at the end of therapy following the independent review. A two-sided 95% confidence interval (CI) was constructed based on the large sample normal approximation of the binomial distribution. The primary endpoint was analyzed by key demographic variables and fungal infection risk factors. Selected laboratory data, including hematology and serum chemistry data, were tabulated by patient group (primary, efficacy failure micafungin and other, efficacy failure micafungin alone, and toxicity failure). Summary statistics for each assessment time and changes from baseline were generated.

A total of 331 patients were enrolled in the study: 224 were from the United States, 38 from Germany, 17 from Brazil, 17 from Canada, 12 from the United Kingdom, seven from South Africa, five from France, four from Italy, three from Peru, two from Spain, and two from Sweden. Of these, 326 patients received at least one dose of study drug and were evaluated as the FAS. The PPS comprised 204 patients who had proven or probable IA infection at baseline and received at least seven doses of study drug. Of the 326 patients who received at least one dose of study drug, 101 were excluded because the diagnosis did not meet the protocol-specified criteria as determined by the independent review panel. The resultant 225 patients comprised the mFAS e patients who had proven or probable IA infection at baseline and received at least one dose of study drug.

The demographics of the patients enrolled (mFAS) are described in Table 1 . Of note, 58 subjects were children (25.8%) and, of these, 27 (12.0%) were under the age of 10 years. The youngest patient enrolled was 3 months of age; the oldest was 82 years. Only 66 patients (29.3%) had profound neutropenia at enrollment, although 32.9% (74/225) had this as their primary risk factor for IA. Thirty-six of the 66 patients with profound neutropenia at baseline (54.5%) had recovery of neutropenia during treatment with micafungin, but the timing of recovery was not recorded systematically.

Within the mFAS group there were 29 patients with IA in whom micafungin was used as primary therapy. Among the mFAS, 192/225 (85.3%) patients were enrolled as refractory patients and four (1.8%) as toxicity failures. Of the 192 refractory patients, 153 (79.7%) had documented progression, 35 (18.2%) had stable disease at baseline, and four were indeterminate, as 

In the independent review, 121 of 326 patients (37.1%) in the FAS demonstrated a complete or partial response. However, detailed analysis of efficacy results are reported based on the mFAS as defined by the independent review panel (unless otherwise noted). A total of 35.6% of the patients achieved a favorable response, with an additional 11.1% of the patients experiencing stabilization of disease (Table 3) . (A favorable response [CR þ PR] was seen in 139/266 (52.3%), based on the investigator global assessment at end of therapy.) The highest rate of success was 75% (3/4), in the toxicity failure group. Importantly, 11/29 (37.9%) in the primary therapy group responded, five of 17 (29.4%) receiving combination therapy and six of 12 (50%) receiving micafungin monotherapy (Table 3 ). Just over one half of the patients (120/225 [53.3%]) experienced progression of their fungal infections on study. Favorable responses for patients only treated with micafungin (18 were refractory patients, 12 were primary patients, and four were toxicity failure patients) were seen in 44.1% (15/34) . Favorable responses were observed in 30/96 (31.3%) patients in the mFAS who did not have at least one dose increase above the initial dose of 75 mg per day The independent reviewers attempted to assess what impact surgery might have made on the response. This assessment was based on the nature of the surgery, location of disease, and postsurgical findings. In the mFAS, 80 patients had invasive surgery, and reviewers considered it to have possibly had an impact in 27/80 patients (33.8%) who had a positive (non-lethal) outcome.

Adverse events that were considered by the investigator to be possibly or probably related to the study drug were reported for 104/326 patients (31.9%). Overall, the more common study of drugrelated adverse events were bilirubinemia (4.3%), nausea (4.3%), vomiting (2.8%), increased serum glutamic pyruvic transaminase (SGPT) (2.8%), increased alkaline phosphatase (2.8%), diarrhea (2.1%), and hypertension (2.1%). A total of 78/326 (23.9%) patients who had an adverse event considered by the investigator to be related to study drug had at least one adverse event of moderate to severe intensity, and 10/326 (3.1%) patients had at least one adverse event that was considered to be life threatening. Treatment was stopped due to an adverse event in 85/326 patients (26.1%), including 17/70 children (24.3%). Adverse events considered related to study drug which lead to study drug discontinuation are described in Table 5 .

Of the 326 patients enrolled, 183 (56.1%) died during therapy or in the 6-week follow-up phase. Of these deaths, 107 (58.5%) were considered attributable to IA, 30 (16.4%) to another cause but with IA at death, and 18 (9.8%) to another cause without aspergillosis; 28 (15.3%) were of indeterminate cause. The more common primary direct causes of death were sepsis (24/ . Thirty-four patients died while on therapy, 18 (52.9%) due to IA; 149 patients died after micafungin treatment was stopped, 90 (60.4%) due to IA. However, most of these post-treatment deaths were in the week following micafungin discontinuation, and were related to decisions to withdraw support or institution of another (unsuccessful) antifungal treatment.

Ten patients died due to non-Aspergillus fungal infections, or a non-Aspergillus fungal infection contributed to the patient's death: five patients with mucormycosis, two with Alternaria sp., one with Chaetomium sp., one with Scedosporium sp., and one with invasive scopulariopsis. Two patients had multiple fungal organisms that contributed to their deaths: one patient with Aspergillus and Rhizopus, and one with Aspergillus and Candida.

A total of 145 patients in the mFAS were assessed during the 6-week follow-up visit. Of those patients, 47 (32.4%) had a complete or partial response.

The study design was a prospective, open-label, non-comparative, multinational study. The study was initiated prior to the licensing of both voriconazole and caspofungin. Rarity of the disease usually hinders rapid patient accrual in this therapeutic area but, in fact, 331 patients were enrolled in less than 4 years in 62 centers. As a result, efficacy and safety information on a wide variety of Aspergillus species infections and patient populations was obtained. Although a previous trial with caspofungin, which enrolled 90 patients, has already been published, 34 this paper describes the largest therapeutic study to date of IA treated with an echinocandin. In the independent review, 80 of 225 patients (35.6%) in the mFAS demonstrated a complete or partial response to micafungin, comparable to the modified intent-to-treat result seen with caspofungin (44.6%). 34 There is no consensus on the enrollment criteria for clinical failure (salvage) in acute IA. For instance, how many days of primary therapy are necessary before primary therapy can be considered a failure? Also, the variety of at-risk populations and extent of disease at presentation, including extrapulmonary dissemination in some, make a uniform definition suspect. Some patients have very extensive pulmonary infection at diagnosis, which is usually fatal, and so any worsening of disease is synonymous with death. Indeed in all prospective studies of acute IA, including this study, early deaths are a constant feature. Other patients have limited single or multifocal disease that typically responds well to treatment, even if enlarging in volume before shrinking. 35 In fact, most rapidly progressive pulmonary lesions do enlarge in the first few days of antifungal therapy, 35 making a realistic early determination of response difficult. Likewise, fever and other clinical signs often take several days before starting to resolve. In the present study, patients had to have had at least 3 days of antifungal therapy before enrollment. Most patients, however, were heavily pretreated. For example, the 148 patients in receipt of a lipid amphotericin B had actually received a mean of 23 days therapy at a mean dose of 6.09 mg/kg immediately prior to enrollment. Because of the heterogeneity of previous therapy, the extent and progressive nature of disease, and different underlying poor prognostic factors, a planned independent review placed patients into different categories to facilitate comparison with other studies.

One such category was primary treatment, and 11/29 (37.9%) in this group responded. Another category was efficacy failure or refractory patients. Unfortunately, for the purposes of analysis, only 18 patients in this group received 39 and 39% with caspofungin, 34 as assessed by modified intention-to-treat analyses.

Combination therapy for IA has been much discussed, but there are few published data describing the use of combination therapy in human subjects. 40e44 Few data describing the use of micafungin as part of combination therapy are available, despite support from in vitro and in vivo studies. 25,45e48 The primary argument for considering combination treatment is to enhance overall response rates. Secondary arguments include increasing the antifungal spectrum in empiric therapy to encompass more pathogens including resistant fungi; realizing better pharmacodynamic parameters of one agent over another for certain body sites; preventing the development of resistance; and (possibly) being able to use reduced doses of one or both drugs without loss of activity while minimizing toxicity. During the time in which this study was performed, physicians were only likely to use combination therapy for very ill patients with a high mortality probability. That is probably what happened in this trial, as it was a physician's choice to add or substitute micafungin for refractory cases. Of the 202 amphotericin B-treated patients (36 amphotericin B deoxycholate þ 166 lipid-associated amphotericin) treated with the combination of micafungin and an amphotericin preparation, 75 (37.2%) responded.

In the past, HSCT patients with IA have been reported to have very poor prognosis. 49 Even in the late 1990s, a 3-month clinical success rate of only 13% was suggested in a large survey for this patient population. 18 Favorable responses with micafungin, usually in combination with another agent, were seen in 22/88 (25%) allogeneic HSCT patients. In recent prospective studies with single drugs, caspofungin treatment yielded a salvage response rate of 14.3% (3/21) 34 compared with voriconazole and amphotericin B, as primary therapy, which had response rates of 32.4% (12/37) and 13.3% (4/30), respectively. 38 Data were not always available to evaluate detailed host risks that are known to impact prognosis of therapy, such as severity of graft versus host disease (GVHD), cumulative exposure to steroids, relapsed malignancy, or graft failure.

The initial dose of 75 mg per day of micafungin used in this study would now be considered a relatively low-treatment dose. 50 Nevertheless, among the 96 patients in the mFAS who did not have a dose increase above the initial dose of 75 mg per day (1.5 mg/kg in patients <40 kg), 30 (31.3%) responded. This initial dose of micafungin was partially effective regardless of patient group (primary versus efficacy failure/toxicity failure) or site/species of infection. Increasing the dose of micafungin was apparently effective in achieving therapeutic responses in a number of patients. For those patients who had a dose increase, favorable responses were seen in 38.8% (50/129), including both primary and efficacy failure patients at mean daily doses exceeding 200 mg per day without significant toxicity. Micafungin has proven efficacy in the treatment of esophageal candidiasis 31,50e52 and candidemia, 33, 53, 54 and in the prophylaxis of candidemia in patients undergoing HSCT. 55 This study demonstrated that micafungin, primarily in combination with amphotericin B, is efficacious in the treatment of acute IA in adult and pediatric patients who had failed to respond to prior therapy, or in patients who were unable to tolerate alternative therapy. Micafungin, alone and in combination with amphotericin B, was generally well tolerated. These results suggest that micafungin, either alone or in combination, is a viable option in the treatment of invasive aspergillosis. Randomized trials will be necessary to determine if combination therapy adds therapeutic benefit to one drug alone.

Epidemiology of invasive aspergillosis in France: a six-year multicentric survey in the Greater Paris area

Invasive fungal infections in autologous stem cell transplant recipients: a nation-wide study of 1188 transplanted patients

Incidence and outcome of bacterial and fungal infections following nonmyeloablative compared with myeloablative allogeneic hematopoietic stem cell transplantation: a matched control study

Nonmyeloablative bone marrow transplantation: infectious complications in 65 recipients of HLA-identical and mismatched transplants

Pathogenesis, clinical manifestations, and therapy

Late onset of invasive Aspergillus infection in bone marrow transplant patients at a university hospital

Aspergillus infections after lung transplantation: clinical differences in type of transplant and implications for management

The incidence of invasive aspergillosis among solid organ transplant recipients and implications for prophylaxis in lung transplants

Aspergillosis in liver transplant recipients: successful treatment and improved survival using a multistep approach

A 7-year study of severe hospitalacquired pneumonia requiring ICU admission

Invasive aspergillosis in critically ill patients without malignancy

Disseminated aspergillosis in intensive care unit patients: an autopsy study

Pulmonary infiltrates in patients receiving long-term glucocorticoid treatment: etiology, prognostic factors, and associated inflammatory response

Infliximab for steroid-refractory acute GVHD: a case series

Death of a SARS case from secondary Aspergillus infection

Therapeutic outcome in invasive aspergillosis

Invasive aspergillosis. Disease spectrum, treatment practices, and outcomes

Aspergillosis case-fatality rate: systematic review of the literature

Echinocandin antifungal drugs

Micafungin: a therapeutic review

Efficacy of FK463, a new lipopeptide antifungal agent, in mouse models of disseminated candidiasis and aspergillosis

Efficacy of FK463, a new lipopeptide antifungal agent, in mouse models of pulmonary aspergillosis

Activity of micafungin (FK463) against an itraconazole-resistant strain of Aspergillus fumigatus and a strain of Aspergillus terreus demonstrating in vivo resistance to amphotericin B

Efficacy of voriconazole plus amphotericin B or micafungin in a guinea-pig model of invasive pulmonary aspergillosis

Drug interaction in vitro between a polyene (AmBisome: AmBi) and an echinocandin (FK463:FK) vs Aspergillus species

Synergistic effects of combination of FK463 with amphotericin B: enhanced efficacy in murine model of invasive pulmonary aspergillosis

Pathological findings in a murine pulmonary aspergillosis model: treatment with FK463, amphotericin B and a combination of FK463 and amphotericin B

Combination antifungal therapy with FK463 plus amphotericin B in treatment of experimental pulmonary aspergillosis

Assessment of maximum tolerated dose (MTD) of FK463 in cancer patients undergoing haematopoetic stem cell transplantation

Successful treatment of oesophageal candidiasis by micafungin: a novel systemic antifungal agent

Pharmacokinetic and maximum tolerated dose study of micafungin in combination with fluconazole versus fluconazole alone for prophylaxis of fungal infections in adult patients undergoing a bone marrow or peripheral stem cell transplant

A multicenter, open-label clinical study of micafungin (FK463) in the treatment of deep-seated mycosis in Japan

Efficacy and safety of caspofungin for treatment of invasive aspergillosis in patients refractory to or intolerant of conventional antifungal therapy

Increasing volume and changing characteristics of invasive pulmonary aspergillosis on sequential thoracic computed tomography scans in patients with neutropenia

NIAID mycoses study group multicenter trial of oral itraconazole therapy for invasive aspergillosis

A double-blind, randomized, controlled trial of amphotericin B colloidal dispersion versus amphotericin B for treatment of invasive aspergillosis in immunocompromised patients

Voriconazole versus amphotericin B for primary therapy of invasive aspergillosis

Efficacy and safety of voriconazole in the treatment of acute invasive aspergillosis

Combination and sequential antifungal therapy for invasive aspergillosis: review of published in vitro and in vivo interactions and 6281 clinical cases from

Antifungal and surgical treatment of invasive aspergillosis: review of 2,121 published cases

Combination antifungal therapy

Micafungin in combination with systemic antifungal agents in the treatment of refractory aspergillosis (RA) in bone marrow transplant (BMT) patients [abstract 2472

Efficacy and toxicity of caspofungin in combination with liposomal amphotericin B as primary or salvage treatment of invasive aspergillosis in patients with hematologic malignancies

Combined action of micafungin, a new echinocandin, and human phagocytes for antifungal activity against Aspergillus fumigatus

Combination antifungal therapy of murine aspergillosis: liposomal amphotericin B and micafungin

Combination therapy in treatment of experimental pulmonary aspergillosis: synergistic interaction between an antifungal triazole and an echinocandin

Synergy, pharmacodynamics, and time-sequenced ultrastructural changes of the interaction between nikkomycin Z and the echinocandin FK463 against Aspergillus fumigatus

Risks and outcomes of invasive fungal infections in recipients of allogeneic hematopoietic stem cell transplants after nonmyeloablative conditioning

A randomized, double-blind, parallel-group, doseeresponse study of micafungin compared with fluconazole for the treatment of esophageal candidiasis in HIV-positive patients

A randomized, double blind, comparative trial of micafungin (FK463) vs. fluconazole for the treatment of oesophageal candidiasis

Alternative day dosing of micafungin in the treatment of esophageal candidiasis

International, open-label, noncomparative, clinical trial of micafungin alone and in combination for treatment of newly diagnosed and refractory candidemia

Comparison of micafungin and liposomal amphotericin B for invasive candidiasis

Micafungin versus fluconazole for prophylaxis against invasive fungal infections during neutropenia in patients undergoing hematopoietic stem cell transplantation

We thank James Gamble, PhD, MBA, who provided medical writing services on behalf of Astellas Pharma US, Inc.