View clinical trials related to Pneumonia, Pneumocystis.
Filter by:We share our lives with microorganisms, and these generally do not pose a problem if an individual is healthy with a normal immune system. However, if the immune system was not functioning properly (e.g., cancer patients), they are at risk of infection. One microorganism, a fungus called Pneumocystis jirovecii (PCP), can cause severe chest infections in patients without properly functioning immune systems, leading to hospitalisation and death if untreated. If patients remain without a functioning immune system, they have a greater chance of repeated infection. PCP spreads through air from person-to-person and can survive on environmental surfaces. Patients can be infected after contact with these surfaces. Hospitals have a responsibility to ensure PCP infected patients do not pass it on to other unwell patients. In cases where PCP has infected multiple patients, knowing if the same fungi has been passed along (or transmitted) from patient-to-patient is vital in understanding if there is an outbreak in the hospital. Understanding how similar (the relatedness) the PCP strain is allows healthcare workers to detect any transmission between patients or the environment. To understand how related each patient's PCP infection is we will utilise a laboratory test called multilocus sequence typing (MLST). This test looks at sections of the fungi's genetic code using deoxyribonucleic acid (DNA) sequencing to create a code (genotype) which tells us how related one PCP is to others tested, allowing comparison between patients and ultimately spotting transmission. Our aim is to develop this sequencing test using PCP positive patient samples and ensure it performs to high-quality standards. Surplus material from seventy known PCP positive patient samples will be tested. Each sample will be analysed to see if the DNA genotype matches or is similar to other patient samples we have tested, helping to understand how PCP may spread between patients.
The main objective of the proposed research is to identify Pneumocystis jirovecii mutant strains on 4 genes encoding therapeutic targets such as dihydropteroate synthase (DHPS), dihydrofolate reductase (DHFR), cytochrome b (CYB), inosine-5'-monophosphate dehydrogenase (IMPDH) and therefore to assess the prevalence of potentially resistant strains in patients infected with P. jirovecii.
Pneumocystis jirovecii is a fungus that can colonize the airways of some patients and be responsible for a disease called pneumocystosis in other patients and mainly in immunocompromised patients. Pneumocystosis was mainly linked to HIV in the 1990s, but with the advent of new immunosuppressive molecules used in cancers or autoimmune diseases and with the increase in the number of transplants, the epidemiology has changed in recent years. Studies on P. jirovecii-related mortality are only based on patients with pneumocystosis. As a result, patients who are simply colonized or patients who are sick but not treated are not taken into account in these studies. The investigators therefore wish to study the overall mortality at six weeks and at three months in all patients with a positive sample for P. jirovecii
This study aims to generate clinical data on the efficacy, safety, and tolerability of rezafungin combined with 7 days of co-trimoxazole for treatment of Pneumocystis pneumonia (PCP) in adults living with human immunodeficiency virus (HIV), which would expand the knowledge of clinical use of rezafungin.
Corticosteroids exposure is a common risk factor for invasive fungal infections. Systemic corticosteroid therapy treats several medical conditions, including rejection in solid organ transplant recipients, malignancy, and autoimmune or inflammatory diseases. Corticosteroid exposure is a well-known risk factor for developing PJP. Still, it remains unclear how prior corticosteroid exposure influences the presentation, severity, and mortality of opportunistic fungal infections. The investigators aim to prospectively characterize the corticosteroid use as a dose response to inform risk of invasive fungal infections.
To evaluate the performance of radiomics in differentiating Pneumocystis jirovecii pneumonia (PCP) from other types of pneumonia and to improve the diagnostic efficacy of non-invasive tests in non-HIV patients.
To evaluate the sensitivity and specificity of the combined detection system for the diagnosis of pneumocystis infection in immunocompromised population in Southern China.
Pneumocystis jirovecii pneumonia (PjP) is a rare infectiouse disease with a high level of mortality. PjP is a classical opportunistic infection which concern HIV infected and immunocompromised patients. During the past decade, several therapeutic's progresses have been done in oncology, immunology and hematology. As a consequence, patients benefited of greater treatment efficacy but are exposed to a higher risk of opportunistic infections as PjP. The investigators hypothesis is that PjP incidence increase and its form is depending of underlying immune conditions. The investigators aim to describe its incidence, the PjP forms depending on comorbidities and to identifiy pronostics factors.
To determine the presence of IMDPH mutants of Pneumocystis jirovecii in solid organ transplant recipient with prior exposition to mycophenolic acid.
Chronic obstructive pulmonary disease (COPD) is a progressive lung disease associated with chronic inflammation in the airways and lung, resulting in significant morbidity and mortality worldwide. Smoking is the primary risk factor for development of COPD and progression of the disease is associated with acute exacerbations of COPD (AECOPD) that can be triggered by acute bacterial or viral airway infections or can occur independently of infection. AECOPD can lead to hospitalization, progression of the disease, and mortality. COPD affects an estimated 11.7% of the world population and was the third leading cause of death worldwide in 2019. This study is a randomized, double-blinded and placebo controlled study to determine if treating PJ in AECOPD with confirmed PJ colonization has a beneficial clinical impact. As a secondary goal of the study, it will be determined if TMP-SMX can decolonize these patients and if the decolonization is durable for at least 3 months. The causes of progression of COPD, especially in the absence of continued tobacco use, are incompletely understood and a significant area of need. One proposed trigger for progression and increased AECOPD is colonization (presence of the organism without an actual infection) with Pneumocystis jirovecii (PJ), a fungal pathogen best known for causing pneumonia in patients with HIV or other forms of immunosuppression. It has been found to be more prevalent in those with severe COPD, particularly during AECOPD, but as a colonizer, not a cause of acute pneumonia. Several studies have linked PJ with progression of COPD, showing that PJ perpetuates an inflammatory and lung remodeling response, contributing to development of airway obstruction, emphysema and accelerating the disease course. The aim of this study is to add trimethoprim-sulfamethoxazole (TMP-SMX) to standard of care treatment of AECOPD in patients who are colonized with PJ will improve the clinical outcome for the patient. This study is a pilot which will serve as proof of concept that screening for PJ in the AECOPD population and treating it with the commonly available, safe, and inexpensive antibiotic TMP-SMX will be an effective strategy.