View clinical trials related to Invasive Pulmonary Aspergillosis.
Filter by: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.
Many children and young people are at risk of invasive fungal disease (IFD), such as those who have had a haematopoietic stem cell transplants, those with an immune deficiency or those who are prescribed immunosuppressive drugs, for example, corticosteroids. One type of mould that causes invasive fungal disease is called Aspergillus. There is currently no quick test which can tell us if someone has an invasive fungal disease caused by Aspergillus called Aspergillosis. It is a difficult condition to diagnose and the results from the tests that are involved take days or weeks to come back. These tests including a few different blood tests, a scan of the lungs (CT scans) and taking fluid from inside the lungs/airway. A new test for Aspergillosis is the lateral flow device (LFD) assay. This is a rapid test which gives a result within minutes. It involves testing a sample of the fluid from the lungs/airway. This fluid can be obtained as part of the routine investigations for Aspergillosis. It has been shown to be a good and safe test in adults but the investigators do not know if it will be a valuable test in children and young people yet. The purpose of this study is to determine whether the LFD test can effectively diagnose Aspergillosis in children and young people.
To assess the safety and efficacy of nebulized PC945 in combination with systemic antifungal therapy for the treatment of refractory IPA
Invasive aspergillosis (IA) are difficult to diagnose in the ICU population, as the patients often do not present the conventional risks factors of immunocompromised patients (EORTC/MSG criteria). In the ICU population, patients often present other risk factors, such as cirrhosis, COPD, influenza and currently SARS-Cov2. The clinicians are thus currently missing precise criteria to distinguish colonization from IA in these patients, while they need to decide if an antifungal treatment is necessary or not. A new algorithm, entitled BM ASP ICU, based on investigators field experience and the scientific literature, which takes into account both EORTC/MSG criteria and a combination of fungal biomarkers, was proposed recently by Haman et al, Annals Intensive Care, 2021. Additional serological assays (immunoprecipitation and ELISA) showed since their interest, especially concerning SARS-Cov2 patients, a new population at risk of IA in the ICU, which emerged in the past months. The present study aims at prospectively implementing the BM ASP ICU algorithm during two years in the routine practice of six ICU units distributed in general and teaching hospitals situated northeast of France. The BM ASP ICU algorithm would be completed by serological assays aiming at assessing a sensitization towards Aspergillus fumigatus. The investigators plan to include 400 ICU patients at risk of IA; SARS-Cov2 patients will be part of the cohort. A weekly screening including culture of respiratory samples, galactomannan antigen, fungal qPCRS (targeting A. fumigatus), and A. fumigatus serology will be applied for all included patients. The performance (sensitivity and specificity, likelihood ratios) of each fungal biomarkers, alone and in combination with others, will be assessed, for all patients, and also within subgroups of patients with specific risk factors (such as SARS-Cov2 for example). These results should lead to solid understanding of which combination of tests is optimal to diagnose IA and thus to initiate appropriate antifungal treatment. the investigators hope that this study will result in improved survival rate of ICU patients with IA.
This study will establish a non-invasive diagnostic approach and evaluate clinical outcomes for children at high-risk for pulmonary invasive fungal infection (PIFI).
This trial is aimed to study the immunological and pathological characteristics of influenza versus non-influenza severe community-acquired pneumonia patients in ICU.
The investigators propose to study the efficacy and safety of three-week antifungal therapy with caspofungin in hospitalized patients with proven or probable IPA underlying chronic obstructive pulmonary disease.
Invasive aspergillosis is a serious and often fatal infection in patients who are neutropenic or have undergone solid organ or stem cell transplantation. However, early diagnosis of invasive aspergillosis is a challenge. Reiss and Lehmann first described the value of serum Galactomanna (GM) for diagnosis of invasive pulmonary aspergillosis in 1979. The availability of the Platelia Aspergillus, a sandwich ELISA that has been approved by FDA in 2003 for managing patients at risk of invasive aspergillosis because of the early detection of the GM antigen. In several studies so far the specificity of the serum galactomannan assay was greater than 85%; however, variable sensitivity from 29~100% was noted over years. In addition, low values and false-negative results are seen more often in nonneutropenic and solid organ transplantation patients as opposed to severely granulocytopenic patients .There are several factors that might explain the reported difference in the performance of antigen detection, including the biological factors and epidemiological factors. In recent years, specimens of other body fluids are increasingly used for detection of Aspergillus galactomannan antigen, including urine, bronchoalveolar lavage(BAL) fluid, cerebrospinal fluid and even the tissue specimen. However, the sensitivity and specificity of the GM detection in various specimens still have considerably variation. Ultrasound-guided transthoracic aspirate is a safe and useful method for collecting specimens for accurate bacteriologic diagnosis of lung abscess and obstructive pneumonitis10. We also reported a study of diagnosis of pulmonary Cryptococosis by ultrasound guided percutaneous aspiration. We plan to perform a prospective single-center study to investigate the role of GM in the target organ (lung tissue/fluid) by using ultrasound-guided fine needle aspirate for early diagnosis invasive aspergillosis compared with the serum galactomannan.
The purpose of this study is to determine whether inhalation with aerosolized amphoterin B 10mg/d is more effective than aerosolized amphoterin B 2mg/d to reduce the incidence of invasive pulmonary aspergillosis.