Active clinical trials for "Pulmonary Aspergillosis"

A study to evaluate the safety and tolerability of opelconazole for the prevention of fungal aspergillus infections in the lung in participants who have received a lung transplant.

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.

This study is being done to evaluate the efficacy of treatment using oral glucocorticoid, anti-fungal agent, anti-IgE mAb for patient with ABPA.

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.

This study explores the role of treatment with interferon-gamma to improve outcomes in chronic pulmonary aspergillosis (CPA). CPA is a progressive infection caused by the fungus Aspergillus affecting patients with chronic lung disease like Chronic Obstructive Lung Disease (COPD) or previously treated tuberculosis (TB). It causes gradual destruction of lung tissue by slowly enlarging cavities, frequent secondary infections and poor quality of life. Because of its indolent nature and nonspecific x-ray findings, it often remains unrecognised for years. Around 3600 people live with CPA in the United Kingdom. Mortality from CPA may be up to 40% in five years. Treatment for CPA relies on antifungals for prolonged periods, but only around 60% of patients improve. It is often long-term or lifelong as the response is slow and some patients experience relapses. In addition, only one class of oral antifungal drugs is licensed for CPA, and they are associated with side effects and high cost. Better treatments are needed for CPA. We do not know why many patients do not respond to treatment. Maybe CPA patients have a weakened immune system and are more susceptible to Aspergillus. Our data suggest that CPA patients produce lower amounts of ΙFNγ, a substance that facilitates the immune system's response against Aspergillus. We have also shown that, when given to patients with CPA who have failed to improve on antifungal treatment, interferon-gamma leads to improvement in important patient-centred outcomes like flares of lung disease or hospital admissions. Interferon-gamma is already in use in the National Health Service of the United Kingdom for other indications. Therefore, its use in CPA should be explored. However, CPA is a rare condition and the tolerability of interferon-gamma is not fully established in these patients. To understand whether a large-scale study is feasible in CPA, we first need preliminary data in smaller numbers of patients. We propose a randomised trial of interferon-gamma in addition to antifungals in CPA. Patients with CPA starting antifungal treatment will be eligible. Participants (25 per group) will be randomly assigned to interferon-gamma for 12 weeks (in addition to antifungals) or antifungals only. To test whether the treatment works, we will use measurements of the cavities on chest CT scan and scores on a quality-of-life questionnaire. We will assess for tolerability of treatment at intervals similar to clinical practice. Criteria for progression to the large-scale study will be set based on the proportion of patients willing to participate, and on the proportion who complete the treatment. Data collected on those parameters will allow us to determine the number needed for a definite study. If the large-scale study confirms our observations that interferon-gamma improves outcomes in CPA, then treatment duration can be shortened and relapses avoided. In addition, interferon-gamma can then be explored in other chronic lung disease.

At present, pulmonary diffusion and target antifungal concentrations for APC in patients with sarcoidosis or chronic obstructive pulmonary disease (COPD) are unknown.

This study is investigating the role of allergic (Th2) inflammation in patients with Cystic Fibrosis (CF) and history of fungal infection and/or Allergic Bronchopulmonary Aspergillosis. Little is known about fungal infection in CF and conflicting results exist on whether this results in worse lung function over time. There is concern that persistent fungal infection can result in worse clinical outcome measures in patients with CF. Also, it is unclear how ABPA develops, but may be related to the amount of fungus a patient with CF is infected with. This study looks at inflammatory patterns and allergic responses to fungal elements to help identify biomarkers and signs of allergic disease in fungally infected patients with CF.

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.

In this study, a new, non-invasive method for diagnosis of pulmonary aspergillosis (PA) will be tested in a clinical pilot project.

The purpose of this study is to identify the number of individuals with severe CoVID who require ventilator support and who develop serious fungal infections. The study is an observational study, meaning that we are not providing any intervention that does not involve usual standard of care. Our chief goal is to find evidence of fungal infection by using traditional, approved methods of diagnosis, but by applying these methods in the same way and frequency among all study participants. We will be looking especially for evidence of a fungal infection known as Aspergillus, which can causes a serious lung infection called invasive aspergillosis (IA).