Active clinical trials for "Respiratory Tract Infections"

The purpose of this study is to learn more about how to better track smell recovery in people who have been infected with the SARS-CoV-2 virus (which causes COVID-19). Many people who have been infected by this virus develop changes in their sense of smell (olfaction). We are interested in measuring smell function objectively via smell cards that test odor intensity, identification, and discrimination. Objective and precise olfactory testing that can be performed in the convenience of one's home will help identify people with smell loss after infection by SARS-CoV-2. We will use results from this test to better understand the relationship between SARS-CoV-2 infection and recovery of olfactory function and to learn whether the AROMHA longitudinal smell test is a reliable olfactory function tracking tool to quantify smell loss in the context of COVID infection. These results may inform the design of therapeutic clinical trials to accelerate the recovery of smell function.

Type I interferons (IFN-I) production is induced by the detection of viral molecules, such as RNA or DNA viral strands, through pattern recognition receptors (PRR) present on many immune cell types. Despite a minimal concentration, IFN-I secretion activate the secretion, by neighbouring cells, of more than 700 proteins with antiviral properties (inhibition of viral replication, destabilization of virus membranes, etc.). IFN-I constitute therefore one of the major first line of defence established by the immune system in response to viral infection. Briefly, during the Coronavirus disease (COVID-19) pandemic, several teams including ours, highlighted a lack of IFN-I response in approximately one in five individuals presenting a severe form of COVID-19. Interestingly, within a large part of them, in vitro investigations revealed the presence of autoantibodies presenting neutralizing capacities against alpha and/or omega interferons This finding confirms the deleterious role of anti-IFN-I autoantibodies on the antiviral immune response and the key role of IFN-I pathway regarding defences against COVID-19 infection. Furthermore, those observations pave the way to interesting research that would allow understanding the underlying pathophysiological mechanisms of severe viral respiratory infection. The research hypothesis are: i) IFN-I deficiency could induce severe forms of viral infections which could lead to intensive care admission ii) IFN-I deficiency could increase viral loads in nasopharyngeal samples, and be associated with protracted viral clearance iii) The frequency of viral co-infections may be higher in case of IFN-I antiviral pathway blockade, iv) severe forms of respiratory viruses' infections could be induced by other anti-cytokine autoantibodies. In addition to confirming research hypotheses recently mentioned, the aim of this clinical protocol will be to assess the impact of antiviral innate immune response alterations in severe respiratory infections.

In this study the Investigators aim to deploy UTE and HP 129Xe MRI for structural and functional evaluation of persistent lung abnormalities in COVID-19 survivors.

The fast increase of Multidrug-resistant microorganisms (MDRO) due to the high amount of antimicrobials being poorly used may be limited by better regulating antimicrobial usage globally. The goal of this observational study is the performance of the MeMed BV® test in the MeMed Key® device at the emergency department to a) support the differential diagnosis between bacterial and viral infections of the respiratory tract and b) provide evidence of how the use of this test may limit gut colonization by MDRO.

The study aims to characterize the distributive pattern of viruses in upper airway and its relationship with influenza seasons, symptomatology and exposure setting. A total of 500 adults residing in Hong Kong would be recruited, who would complete a questionnaire and return self-collected nasal and throat swabs for metagenomic analyses.

This is a multi-centre, prospective, short period incidence observational study of patients in participating hospitals and intensive care units (ICUs) with SARI. The study period will occur, in both Northern and Southern hemispheric winters. The study period will comprise a 5 to 7-day cohort study in which patients meeting a SARI case-definition, who are newly admitted to the hospitals / ICUs at participating sites, will be included in the study. The study will be conducted in 20 to 40-hospital/ ICU-based research networks globally. All clinical information and sample data will only be recorded if taken as part of the routine clinical practice at each site and only fully anonymised and de-identified data will be submitted centrally. The primary aim of this study is to establishing a research response capability for a future epidemic / pandemic through a global SARI observational study. The secondary aim of this study is to investigate the descriptive epidemiology and microbiology profiles of patients with SARI. The tertiary aim of this study is to assess the Ethics, Administrative, Regulatory and Logistic (EARL) barriers to conducting pandemic research on a global level.

This study is a prospective observation study for lower respiratory tract infections in medical intensive care unit. Microbiologic and clinical characteristics and outcomes of patients with severe pneumonia in medical intensive care unit will be monitored and analyzed.

A research team member will brush the inferior surface of the subjects' middle turbinate (nasal cavity) using a cytology brush to obtain the cells needed to perform our functional respiratory assays. An individual trained in phlebotomy will draw one 3 ml lavender top tube of blood to test c-reactive protein, calprotectin, and lactoferrin. They will also draw a 5 ml gold top serum separator tube of blood to test fibroblast growth factor-19. The participant will answer questions from the baseline survey and report their current medications interview-style with the research team member.

To compare the results obtained by analysis of a self-collected anterior nasal (AN) swab as part of the Labcorp COVID-19+Flu+RSV Test Home Collection Kit to a healthcare provider (HCP)-collected AN swab in patients with symptoms of viral respiratory infection consistent with influenza A (Flu A), influenza B (Flu B), respiratory syncytial virus (RSV) and/or SARS-CoV-2 (C-19).

Lower Respiratory Tract infections are a common cause of admission to the intensive care unit. Children routinely receive antibiotics until the tests confirm whether the infection is bacterial or viral. The exclusion of bacterial infection may take 48 hours or longer for culture tests on biological samples to be completed. In many cases, the results may be inconclusive or negative if the patient has already received antibiotics prior to the sample being taken. A rapid assay to detect the most likely cause of infection could improve the speed with which antibiotic therapy is rationalised or curtailed. This study aims to assess whether a new genetic testing kit which can identify the presence of bacteria and viruses within hours rather than days is a feasible tool in improving antibiotic prescribing and rationalisation of therapy in critically ill children with suspected lower respiratory tract infection.