Active clinical trials for "Pneumonia"

This study aim will be to assess the effectiveness of chest ultrasound as a diagnostic and differentiating modality in cases of pneumonia and lung congestion . It also evaluates chests sonography effectiveness in follow-up of patients with pneumonia and lung congestion .

Background: The lung is a privileged organ; blood does not reflect most lung processes well, if at all. Therefore, for population scale diagnostics, the investigator team is developing non-invasive portals to the lung, for eventual early detection/risk assessment and diagnostic purposes. However, large macromolecules are not likely suspended nor readily detected in the breath. In particular, genomic DNA in the breath condensate (EBC) is very sparse, and where present, generally highly fragmented, not readily amenable to sequencing based assessments of DNA somatic mutation burden or distribution. Because gDNA (and protein) is challenging to obtain non-invasively from EBC, the study team considered alternative surrogate lower airway specimens. Cough capture is rarely done, and the investigator team is in the process of optimizing its collection. Importantly, the team will be evaluating how much of coughed material is from saliva contamination. Additionally, analyzing material that is target captured by capturing deep lung extracellular vesicles (EVs) using immobilized CCSP/SFTPC antibodies targeting EVs from distal bronchiole Club and alveolar type 2 cells could circumvent the mouth contamination problem, leaving a non-invasive portal to the deep lung suitable for large molecules, and in turn suitable for myriad epidemiologic and clinical applications. Proposal: The investigator team proposes (Aim 1) to pursue optimizing cough collection, and testing the efficacy and practicality of partitioning cough specimen for deep-lung specific extra-cellular vesicles (EVs). This cough specimen will be compared to that from invasively collected deep lung samples BAL/bronchial brushings, and to the potential contaminating mouthrinse, all from the same individuals. (Aim 2) The study team initially proposes to examine these cough specimens for somatic mutations by SMM bulk sequencing for single nucleotide variation, developed in the Vijg/Maslov labs. Finally, the investigator team will (Aim 3) test all airway specimens (cough, mouthwash and BAL) for lung surrogacy of cough, using proteins known to be specific for lung, as opposed to oral cavity/saliva, in the Sidoli/proteomics core. Impact: The investigator team envisions that the translational impact of non-invasively obtained DNA or protein markers could allow for more rapid acute clinical diagnoses, and facilitate precision prevention and/or early detection of many acute and chronic respiratory disorders, including lung cancer, asthma and COPD, acute and chronic infectious diseases, and indeed systemic disorders of inflammation and metabolism.

Klebsiella pneumoniae (K. pneumoniae) is an important opportunistic pathogen contributing to nosocomial and antimicrobial-resistant infections. The increasing prevalence of infections caused by multidrug-resistant K. pneumoniae has emerged as a major clinical and public health threat, while the serous organ and life-threatening infections caused by highly virulent K. pneumoniae have also emerged( Russo and Marr, 2019; Wyres et al., 2020).

This is a phase 2a, multinational, multicenter, double-blind, randomized, placebo-controlled, dose-ranging safety, tolerability and PK study in patients with HABP (Hospital Acquired Bacterial Pneumonia) or VABP (Ventilator Associated Bacterial Pneumonia) caused by ABC to identify safe and well-tolerated doses and to assess the PK profile of OMN6 in patients.

Radiation pneumonitis is the main dose-limiting toxicity of thoracic radiotherapy, which can affect life quality, survival, and the tumor-controlling effects of patients receiving thoracic radiotherapy. The purpose of this study is to: Identify biomarkers including serum proteins, gene expression, genetic changes, and epigenetic modifications that determine radiation pneumonitis. Investigate the relationship between radiation pneumonitis and other toxicities induced by radiotherapy. Construct a predictive model for radiation pneumonitis. Evaluate survival and treatment outcome of patients with radiation pneumonitis.

In this study, researchers propose a unique (individualized) approach to steroid treatment seeking to give the right dose of steroid to the right patient and at the right time. This study seeks to compare usual care to an individualized steroid dosing strategy by testing a marker of inflammation in the blood called C- reactive protein (CRP). The overall goal is to reduce an individual's exposure to steroids and the risk of potential side effects thereby increasing the potential benefit of using steroids to control inflammation in pneumonia.

Radiation pneumonitis is the most common complication and the major dose-limiting toxicity associated with radiotherapy, which can cause poor quality of life or life-threatening symptoms and might hinder the tumor-controlling effects of radiotherapy. Consequently, establishing reliable predictors for the occurrence of RP is of great significance such that the therapeutic effects of RT can be maximized while minimizing its adverse effects. The aim of this study is to figure out the biological prediction models of radiation pneumonitis.

Intermountain Health has developed a electronic decision support tool to help doctors provide the best care for pneumonia. The purpose of this study is to enhance the existing tool (called ePneumonia (electronic Pneumonia) or ePNa) so that it can be used at other institutions, and to test deployment of the tool at another institution's hospitals.

The goal of this clinical trial is to propose a seamless intervention linking rapid bacterial isolate identification and antibiotic resistance gene detection and targeted antibiotic prescription to minimise time between infection onset and appropriate treatment in patients with Pseudomonas aeruginosa or carbapenemase producing Enterobacterales infections. This is an investigator initiated trial. The primary hypothesis is that these interventions will lead to improved clinical outcomes amongst patients with hospital-acquired bloodstream infection, hospital-acquired pneumonia or ventilator-associated pneumonia due to carbapenem non-susceptible Pseudomonas aeruginosa or Enterobacterales, compared to standard antibiotic susceptibility testing. Patients will be randomised to either a control or intervention arm. Patients randomised to the intervention arm will have relevant specimens analysed by rapid microbiological diagnostics and will have early availability of ceftazidime-avibactam if appropriate. Patients randomised to the control arm, will have samples analysed by clinical microbiology laboratories using standard of care diagnostics. Antibiotics will be available to these patients as per usual institutional practice.

RESPIRE is a randomized, unblinded, controlled study to measure the impact of a strategy based on a PCR test on the adjustment of antimicrobial therapy in immunocompromised patients suspected with ventilator-associated or hospital-acquired pneumonia (VAP/HAP) requiring mechanical ventilation (MV) in Intensive Care Unit (ICU). The gold-standard microbiological diagnostic method for pneumonia in the ICU is based on culture identification and antimicrobial susceptibility testing. Results are obtained in several days after the initiation of empiric antimicrobial therapy, exposing patients to a potential inappropriate broad-spectrum antimicrobial treatment. We aim to measure the impact of a PCR-based strategy to improve the percentage of patients with VAP or HAP receiving targeted antimicrobial therapy 24 hours after diagnosis compared to standard care