View clinical trials related to Aspergillosis.
Filter by:The treatment of CPA is with oral itraconazole for 6-12 months. Oral itraconazole results in better clinical outcomes in CPA compared to supportive care. A recent study comparing 6 months with 12 months of oral itraconazole for longer duration treatment found longer duration reduced CPA relapse and improved clinical outcomes. However, longer duration of itraconazole could cause emergence of drug resistant Aspergillus fumigatus and therapy related adverse event. A recent study found nebulized amphotericin B non-inferior to oral itraconazole for treating CPA as primary therapy. However, the study was small and included patients with simple aspergilloma and used nebulized amphotericin B for 7 days.To be effective, an inhaled drug should be delivered in sufficient quantity to achieve therapeutic levels.The minimum inhibitory concentration of amphotericin B for A.fumigatus is 0.5 mg/L. In one study, nebulization of 30 mg of amphotericin B deoxycholate achieved a mean concentration of 0.68 mg/L in the bronchoalveolar lavage fluid. Notably, the serum levels of amphotericin B after nebulization are 20 times less than after systemic administration and is safer. Further, there is a dose-response relation with nebulized amphotericin B, the higher the dose used for nebulization, the higher are the levels achieved in the lung tissue. Nebulized amphotericin B has been used in lung transplant recipients to prevent invasive aspergillosis. Also, two recent studies have demonstrated that use of nebulized amphotericin B as maintenance therapy led to a reduction in ABPA relapse rates and prolonged time to exacerbation. We believe that inhaled amphotericin B as a maintenance therapy could reduce CPA relapse and prolong time to relapse. In this study, we plan to evaluate nebulized amphotericin B as a maintenance therapy in clinically stable CPA patients treated with 12 months of oral antifungal therapy
In previous retrospective study (SEIFEM 2016 study) the investigators evaluated the incidence of proven/probable invasive aspergillosis (IA) and the role of mold active primary antifungal prophylaxis (PAP) in a "real life" setting of acute myeloid leukemia (AML )patients receiving intensive consolidation therapy. All cases of proven/probable IA, observed during consolidation chemotherapy in adult and pediatric AML patients between 2011 and 2015, were retrospectively collected in a multicenter study involving 38 Italian hematologic centers. The investigators observed 56 (2.2%) cases of IA [43 probable (1.7%) and 13 proven (0.5%)]. The overall mortality rate and the mortality rate attributable to IA (AMR) on day 120 were 16% and 9%, respectively. In multivariate analysis, parameters that influenced the outcome were age ≥60 years and treatment with high doses of cytarabine (HDAC). The investigators also observed that centers involved in this survey had different antifungal policies during the AML consolidation phase. The results from this study show that in a large real-world setting the mold active PAP, with itraconazole or posaconazole, decreases the rate of IA after consolidation course. In SEIFEM 2016 study the investigators demonstrated that the incidence of IA during the AML consolidation is low. However, the mortality is not negligible, mainly in older patients. Further, a sub-analysis in the subset of patients older than 60 years demonstrated that patients who didn't receive mold active prophylaxis had higher incidence of IA than patients who received mold active prophylaxis (15% vs 6%). Therefore, as prophylaxis seems to prevent IA in consolidation, further studies should be performed especially in elderly patients treated with HDAC to confirm our data and to identify the subset of patients who require PAP.
Prospective observational pilot study to evaluate the utility of breath VOCs to detect invasive aspergillosis in lung transplant recipients that are suspected of invasive fungal disease (IFD).
The investigators hypothesize that a combination of prednisolone and itraconazole would significantly reduce the exacerbation rate at one-year of patients with acute allergic bronchopulmonary aspergillosis (ABPA) compared to itraconazole or prednisolone monotherapy. In this study, 300 subjects aged ≥18 years with acute ABPA will be randomized to treatment with either prednisolone, itraconazole, or prednisolone plus itraconazole, all for four months each. After collecting baseline demographic, immunologic, and imaging data, the investigators will follow the patients every 2 months for the first two visits and then every four months for three visits. The primary outcome will be the proportion of subjects experiencing exacerbation (asthma or ABPA) 12 months after treatment completion.
There is an intricate link between bronchiectasis and fungi. Patients with cystic fibrosis frequently manifest fungal sensitization and fungal colonization with Aspergillus fumigatus.6 Aspergillus species also has a cause-and-effect relationship with non-CF (cystic fibrosis) bronchiectasis.7, 8 In allergic bronchopulmonary aspergillosis (ABPA), Aspergillus is the cause of bronchiectasis. In contrast, in other causes of bronchiectasis, A fumigatus can theoretically promote allergic response, which may result in poor lung function, increase the risk of exacerbations, and even cause ABPA over time.9, 10 In a recent study, we found an overall prevalence of Aspergillus sensitization of 29.5% and the prevalence of chronic aspergillus infection was 76%.11 The prevalence of chronic aspergillus colonization in non-(tuberculosis) TB-non-CF fibrosis was 47.5% (49/103).11 By mechanism similar to chronic bacterial colonization, chronic aspergillus infection or aspergillus sensitization can increase the risk of bronchiectasis exacerbation. Therefore, eradication of A. fumigatus from the airways of patients with bronchiectasis would decrease the future risk of a bronchiectasis exacerbation. Notably, in ABPA, use of itraconazole and voriconazole reduce the exacerbations by reducing the fungal burden in the airways.12, 13 In this randomized trial, we will investigate whether treatment with oral itraconazole for six months would reduce the future risk of bronchiectasis exacerbation in patients with non-CF-non-ABPA bronchiectasis.
This study aims to collect clinical cases and follow-up data from patients with chronic pulmonary aspergillosis, post-COVID-19 aspergillosis, and post-COVID-19 patients without aspergillosis. Using in vitro assays, we will measure the phagocytic function of neutrophils when stimulated by fungal hyphae, their ability to produce neutrophil extracellular traps (NETs), the expression of cell surface molecules at the time of enrollment, changes in cell surface molecule expression after stimulation with fungal hyphae, and the quantification of autoantibodies in the blood. This research will focus on the short-term (within 3 months), medium-term (6-12 months), and long-term (more than 12 months) changes in cell surface molecules and functions following infection.
Invasive aspergillosis (IA) is the most common mould infection in immunocompromised patients with haematological disease. Voriconazole, a triazole, improves overall survival of patients with an IA and is the mainstay of therapy. Resistance of A. Fumigatus emerged as an important clinical problem and infections with azole resistant Aspergillus have a high mortality. Nowhere in the world, azole resistance is more prevalent than in the Netherlands. Rapid detection of resistance is key to improve the patient's outcome but fungal cultures take time and are often negative. The investigators aim to detect azole resistance associated mutations in fungal DNA extracted directly from serum or plasma to accelerate diagnosis and improve outcome of patients infected with azole resistant A. fumigatus.
To assessed the current situation and outcome of critically ill patients with invasive aspergillus infection.
The diagnosis of invasive pulmonary aspergillosis (IPA) bears grave implications for the prognosis and treatment plan of the immunosuppressed patient. Thus far, such diagnosis in the immunosuppressed patient, such as patients with acute myeloid leukemia (AML), relied heavily on chest computed tomography (CT) and bronchoalveolar lavage (BAL), an invasive approach bearing many caveats. Volatile organic compounds (VOC) are compounds that could be detected in exhaled air, and have shown some potential in the non-invasive diagnosis of various conditions, including IPA. In this prospective longitudinal study we aim to compare the VOC profiles of patients diagnosed with AML (baseline) to the profile of the same patient diagnosed with IPA later on, and to the post recovery profile in the same patient. This approach should resolve many of the issues plaguing prior attempts at VOC based IPA diagnosis, mainly the lack of properly designed controls. Samples will be collected from consenting patients using Tedlar bags, and analyzed using thermal desorption gas chromatography mass spectrometry (TD-GC-MS). VOCs detected will be digitally analyzed to construct different classification models, with predictive performances compared to the clinical diagnosis using the accepted methods will be assessed by binary logistic regression.
The last decade has seen a significant increase in secondary Aspergillus infections, not only due to primary hypersensitivity, and immunodeficiency based on oncological diseases and their therapy, but mainly due to a rise in severe respiratory infections (H1N1, COVID-19, bacterial infections). This is most evident in critically ill patients whose life is threatened by invasive pulmonary aspergillosis (IPA), with over 90 % of cases being caused by Aspergillus fumigatus. In recent decades, various biomarkers with well-known limits of use (Aspergillus DNA, galactomannan, 1,3-ß-D-glucan) have been used for early diagnosis of IPA. However, the clinical need to clearly distinguish the onset of IPA from colonization is much more significant. The current biomarkers only provide "probable IPA" interpretation, and the diagnosis is rarely confirmed. Based on our preliminary studies, the use of new low molecular weight substances (secondary metabolites) combined with acute-phase proteins (pentraxin 3) allows very reliable immediate confirmation of IPA. In tissue samples, bronchoalveolar lavage fluid, endotracheal aspirate, breath condensate, serum, and urine of critically ill patients, the investigators will be able to recognize and confirm IPA in time using highly sensitive mass spectrometry detecting specific microbial siderophores in correlation with a significantly increased concentration of acute-phase host protein (pentraxin 3) within hours of the beginning of the invasion of lung tissue. Through a prospective multicentre study, the investigators will evaluate the benefit of new biomarkers in non-invasive IPA confirmation, improve the IPA diagnostic algorithm and transfer the detection method to MALDI-TOF spectrometers widely used in Clinical laboratories in the Czech Republic. In MALDI-TOF mass spectrometry, the ion source is matrix-assisted laser desorption/ionization (MALDI), and the mass analyser is a time-of-flight (TOF) analyser. The study results will contribute to a high clarity of IPA cases, the accurate introduction of antifungal therapy, and a better prognosis of survival of critically ill patients.