Voriconazole as primary antifungal prophylaxis in patients with neutropenia after hematopoietic stem cell transplantation or chemotherapy for acute myeloid leukemia

Posaconazole versus voriconazole as antifungal prophylaxis during induction therapy for acute myelogenous leukemia or myelodysplastic syndrome

OBJECTIVE

Patients with acute myelogenous leukemia or myelodysplastic syndrome undergoing induction chemotherapy are at increased risk of invasive fungal infection due to prolonged, severe neutropenia. Due to this risk, national guidelines recommend invasive fungal infection prophylaxis in this population until the resolution of neutropenia. Although posaconazole has demonstrated superiority over fluconazole and itraconazole, there is limited evidence for voriconazole for invasive fungal infection prophylaxis in this population. Even less data are available comparing posaconazole and voriconazole directly. The study objective was to investigate the efficacy and safety of delayed-release posaconazole tablets versus voriconazole for primary invasive fungal infection prophylaxis. The primary outcome was rate of discontinuation of either agent. Secondary outcomes included specific rates of discontinuation due to adverse events and drug-drug interactions, rates of breakthrough invasive fungal infection, and 30-day and 100-day mortality rates.

METHODS

This was a retrospective cohort study of adult patients admitted to NYU Langone Health between 1 January 2014 and 31 August 2017 and initiated on invasive fungal infection prophylaxis during induction or reinduction chemotherapy for acute myelogenous leukemia or myelodysplastic syndrome.

RESULTS

In total, 77 patients were included in the study: 43 using posaconazole delayed-release tablets and 34 using oral voriconazole. In the posaconazole group, 30% of patients (n = 13) discontinued therapy for any reason compared with 35% (n = 12) of patients in the voriconazole group (p = 0.64). A higher percentage of patients in the voriconazole group discontinued due to adverse events (6 patients, 18% vs. 1 patient, 2%, p = 0.04). Mortality rates at 30 and 100 days were similar between both groups. No breakthrough invasive fungal infections was noted in either group.

CONCLUSION

Overall, discontinuations for any reason were similar in patients taking both posaconazole delayed-release and oral voriconazole. Both posaconazole delayed-release tablets and oral voriconazole appear to be effective at preventing invasive fungal infection in acute myelogenous leukemia and myelodysplastic syndrome patients undergoing induction chemotherapy, although posaconazole may be more tolerable.

A strategy for designing voriconazole dosage regimens to prevent invasive pulmonary aspergillosis based on a cellular pharmacokinetics/pharmacodynamics model

Background

Invasive pulmonary aspergillosis (IPA) is a life-threatening disease in immunosuppressed patients. Voriconazole is commonly used to prevent and treat IPA in the clinic, but the optimal prophylactic antifungal regimen is unknown. The objective of this study was to clarify the mechanism underlying how voriconazole prevents IPA based on a target cellular pharmacokinetics/pharmacodynamics model, with the aim of identifying a way to design an optimal prophylactic antifungal regimen.

Methods

A nystatin assay was used to establish a target-cells model for A. fumigatus infection. An inhibitory effect sigmoid E_max model was developed to explore the cellular PK/PD breakpoint, and Monte Carlo simulation was used to design the prophylactic antifungal regimen.

Results

The intracellular activity of voriconazole in the target cells varied with its concentration, with the minimum inhibitory concentration (MIC) being an important determinant. For A. fumigatus strains AF293 and AF26, voriconazole decreased the intracellular inoculum by 0.79 and 0.84 lg cfu, respectively. The inhibitory effect sigmoid E_max model showed that 84.01% of the intracellular inoculum was suppressed by voriconazole within 24 h, and that a PK/PD value of 35.53 for the extracellular voriconazole concentration divided by MIC was associated with a 50% suppression of intracellular A. fumigatus. The Monte Carlo simulation results showed that the oral administration of at least 200 mg of voriconazole twice daily was yielded estimated the cumulative fraction of response value of 91.48%. Concentration of voriconazole in the pulmonary epithelial lining fluid and the plasma of > 17.77 and > 1.55 mg/L, respectively, would ensure the PK/PD > 35.53 for voriconazole against most isolates of A. fumigatus and may will be benefit to prevent IPA in clinical applications.

Conclusions

This study used a target cellular pharmacokinetics/pharmacodynamics model to reveal a potential mechanism underlying how voriconazole prevents IPA and has provided a method for designing voriconazole prophylactic antifungal regimen in immunosuppressed patients.

Voriconazole Antifungal Prophylaxis in Children With Malignancies: A Nationwide Study

BACKGROUND

Antifungal prophylaxis (AFP) is recommended in at-risk hematology-oncology patients. We evaluated the safety of AFP with voriconazole (VRC) in pediatric hematology/oncology patients.

MATERIALS AND METHODS

A retrospective study of VRC AFP in children with malignancies hospitalized in all 7 Greek pediatric hematology/oncology centers during 2008 to 2012 was conducted. Patients' demographics, outcome, and adverse event (AE) data were recorded.

RESULTS

Four hundred twenty-nine VRC AFP courses in 249 patients (median age 6 y, 55% boys) were studied. The most common underlying diseases were acute lymphoblastic leukemia (51%), non Hodgkin lymphoma (8.6%), and acute myeloid leukemia (7.7%). The median number of VRC courses per patient was 1.7, whereas the median VRC dose was 7 mg/kg (range, 5 to 7 mg/kg) every 12 hours. During the last 2 weeks before AFP, 51% of the patients had received corticosteroids, 43% suffered from severe neutropenia, and 17.3% from mucositis. The median duration of VRC AFP was 17 days (range, 1 to 31 d). A single breakthrough fungemia due to Candida glabrata was recorded. Only 1 patient died due to the underlying disease. The most common AEs reported in 70/429 (16.3%) courses with ≥1 AE were elevated liver enzymes (50%), hypokalemia (24.3%), and ophthalmological disorders (14.3%). The median time of AE onset was 5 days (range, 1 to 21 d). Among 70 AEs reported, 38.5%, 48.4%, and 12.8% were of grade I, II, and III, respectively.

CONCLUSIONS

VRC prophylaxis in pediatric hematology/oncology patients appears to be well tolerated.

Foiling fungal disease post hematopoietic cell transplant: review of prophylactic strategies

Hematopoietic cell transplantation (HCT) offers definitive management for a wide variety of malignant and nonmalignant diseases. Conditioning regimens and therapies used to prevent and treat GvHD are immune suppressive, often increasing the risk of developing fungal disease due to yeasts or molds. Antifungal prophylaxis may be useful in preventing morbidity and mortality during and after HCT. In this article, we review the epidemiology and current literature regarding strategies for prevention of invasive fungal disease (IFD) in the pre-engraftment and post-engraftment settings, and propose future direction for scientific discovery.

Voriconazole prophylaxis in children with cancer: changing outcomes and epidemiology of fungal infections

BACKGROUND

Invasive mould infections are a significant cause of morbidity and mortality in pediatric cancer patients, particularly in those undergoing aggressive myeloablative chemotherapy. Voriconazole has been described as an appropriate and effective prophylactic agent in adults with cancer.

METHODS

We compared the etiology, predisposing factors and outcomes of invasive mould infection in patients treated for acute myeloid leukemia before and after implementation of voriconazole prophylaxis in a pediatric cancer center.

RESULTS

We observed no difference in the number of invasive mould infection between groups. However, isolated organisms were markedly different, with a shift from aspergillosis to phaeohyphomycosis after the implementation of voriconazole prophylaxis. Survival at 90 days was improved in patients receiving voriconazole prophylaxis (P = 0.05). We did not identify a significant increase in the incidence of zygomycosis associated with routine use of voriconazole prophylaxis.

CONCLUSIONS

Voriconazole prophylaxis was associated with improved survival in pediatric patients with acute myeloid leukemia, although other factors may be involved. Voriconazole prophylaxis was associated with a marked change in the pattern of mould infections, with a significant reduction in aspergillosis.

Voriconazole and its clinical potential in the prophylaxis of systemic fungal infection in patients with hematologic malignancies: a perspective review

Invasive fungal infections (IFIs) have become high prevalence in patients with hematologic malignancies. Drug-based strategies for IFIs include various approaches such as prophylactic, empiric, preemptive, and directed treatment. Prophylaxis is an attractive strategy in high-risk patients, given the lack of reliable diagnostics and the high mortality rate associated with IFIs. Prophylaxis includes the use of antifungal drugs in all patients at risk. An ideal antifungal compound for prophylaxis should have a potent and broad activity, be available both orally and intravenously, and have a low toxicity profile. Voriconazole fulfills all these criteria. The clinical efficacy of voriconazole against the majority of fungal pathogens makes it potentially very useful for the prevention of IFIs in patients with hematologic malignancies. Voriconazole appears to be very effective for the primary and secondary prevention of IFIs in these patients and recipients of allogeneic hematopoietic stem-cell transplantation. Randomized controlled trials evaluating voriconazole as primary antifungal prophylaxis in patients with neutropenia treated for a variety of hematologic malignancies have been performed, confirming its value as a prophylactic agent. Voriconazole is generally safe and well tolerated; however, its use is also associated with a number of concerns. In most patients with hematologic malignancies there is the potential for pharmacokinetic drug-drug interactions given that voriconazole is metabolized through the P450 cytochrome system.

Monitoring trough voriconazole plasma concentrations in haematological patients: real life multicentre experience

The objective of this retrospective study was to evaluate results from voriconazole therapeutic drug monitoring (TDM) in haematological patients in routine clinical practice. Between 2005 and 2010, 1228 blood samples were obtained from 264 haematological patients (median 3 samples/patient; range 1-27) receiving voriconazole for targeted/preemptive treatment of invasive aspergillosis (IA) (46.3% of samples), empirical therapy (12.9%) or prophylaxis (40.8%). A high-pressure liquid chromatography assay was used to analyse voriconazole concentrations. Clinical and laboratory data were analysed retrospectively. The median of the detected voriconazole plasma concentration was 1.00 μg ml(-1) (range <0.20-13.47 μg ml(-1)). Significant inter- and intra-patients variability of measured concentrations (81.9% and 50.5%) were identified. With the exception of omeprazole administration, there was no relevant relationship between measured voriconazole concentrations and drug dose, route administration, age, gender, CYP2C19*2 genotype, gastrointestinal tract abnormality, administration via nasogastric tube, serum creatinine, and liver enzymes. However, per patient analysis identified significant role of individual voriconazole dose and drug form change on measured plasma concentration. Measured voriconazole concentrations did not correlate with the treatment outcome of patients with IA. We only identified a limited number of adverse events related to voriconazole therapy; however, the median plasma concentration was not different from concentrations measured in samples without reported toxicity. Our retrospective study has suggested that routine monitoring of voriconazole plasma concentrations has probably only a limited role in daily haematological practice.

Outcome of Antifungal Combination Therapy for Invasive Mold Infections in Hematological Patients is Independent of the Chosen Combination

Invasive mold infection (IMI) remains a major cause of mortality in high-risk hematological patients. The aim of this multicenter retrospective, observational study was to evaluate antifungal combination therapy (ACT) for proven and probable IMI in hematological patients. We analyzed 61 consecutive cases of proven (n=25) and probable (n=36) IMI treated with ACT collected from eight Spanish hospitals from January 2005 to December 2009. Causal pathogens were: Aspergillus spp (n=49), Zygomycetes (n=6), Fusarium spp (n=3), and Scedosporium spp (n=3). Patients were classified in three groups according to the antifungal combination employed: Group A, liposomal amphotericin B (L-AmB) plus caspofungin (n=20); Group B, LAmB plus a triazole (n=20), and Group C, voriconazole plus a candin (n=21). ACT was well tolerated with minimal adverse effects. Thirty-eight patients (62%) achieved a favorable response (35 complete). End of treatment and 12-week survival rates were 62% and 57% respectively, without statistical differences among groups. Granulocyte recovery was significantly related to favorable response and survival (p<0.001) in multivariate analysis. Our results suggest that comparable outcomes can be achieved with ACT in high risk hematological patients with proven or probable IMI, whatever the combination of antifungal agents used.

Phototoxicity and photocarcinogenesis associated with voriconazole

The antifungal voriconazole was given its marketing authorization in 2002. Several kinds of adverse effects have been reported, including acute and chronic cutaneous adverse effects, mainly due to a phototoxicity mechanism. More recently, some authors have reported that voriconazole was involved in the occurrence of multiple and often-aggressive cutaneous squamous cell carcinomas if the treatment was maintained for a long time. According to safety data in studies assessing voriconazole effectiveness, 8% of outpatients may experience phototoxic events. An overview of the different types of phototoxicity and of the concerned population was given by the 61 published case reports of photo-induced voriconazole-related skin adverse events (including 18 cases of squamous cell carcinomas). The most likely mechanisms may be phototoxicity directly related to either voriconazole or to its N-oxide main metabolite, and an interaction with retinoid metabolism; moreover, immunodeficiency may enhance the risk of skin cancer. Several issues remain to be investigated, and studies are needed concerning the phototoxicity and photocarcinogenesis of voriconazole and the prognosis of chronic non-malignant skin lesions. Voriconazole prescription must be associated with strict photoprotection; in case of a phototoxic adverse event, another azole may be recommended.

Mucormycosis: its contemporary face and management strategies

Several countries have seen rising frequencies of mucormycosis among patients with haematological disorders, malignancies, or diabetes mellitus, and among transplant recipients. Growing numbers of immunocompromised hosts, widespread use of antifungal agents inactive against mucormycosis, or other unidentified factors, could be contributing to this situation. The predominant clinical manifestations of mucormycosis vary from host to host. Additionally, risk factors specific to different subgroups have been identified, such as leukaemia, allogeneic haemopoietic stem-cell transplant, voriconazole prophylaxis, diabetes, and malnutrition. We summarise the current state of knowledge of characteristics and risk factors and discuss topical developments in therapeutic methods and strategies in the management of mucormycosis.

Recommendations for broader coverage antifungal prophylaxis in childhood acute myeloid leukemia: ASH evidence-based review 2011

A 16-year-old female diagnosed with acute myeloid leukemia (AML) with inversion 16, a favorable prognostic indicator, has persistent neutropenia after her fourth cycle of dose-intensified chemotherapy. She was recently admitted for treatment with empiric antibiotics for febrile neutropenia, and an astute intern noticed a new lesion on her right foot with a dark necrotic center. A biopsy of the lesion showed spreading hyphae, consistent with Aspergillus. Despite her compliance with fluconazole fungal prophylaxis, computed tomography imaging revealed disseminated aspergillosis involving her lungs, liver, and kidneys. Amphotericin was started, but systemic fungemia and the development of multiorgan failure resulted in her death. You are in the difficult position of having to explain to her parents that she died in remission from chemotherapy-related complications. All of those involved in this unfortunate scenario wonder if something could have been done to prevent her death.