View clinical trials related to Pneumonia.
Filter by:Community-acquired Pneumonia (CAP) represents the single largest cause of death and morbidity in children worldwide (1). Respiratory viruses are the most common cause of CAP in preschool children, followed by bacteria. The atypical bacteria Mycoplasma pneumoniae and Chlamydia pneumoniae are common causes of pneumonia in children >5 years. The identification of the causal agent is pivotal, especially in children who require hospital admission, as it guides the choice of appropriate treatment. However, the microbial diagnosis of CAP in children is not easy to establish without invasive procedures, and chest X-Ray has failed to identify the aetiology of CAP. Clinical features of bacterial pneumonia, atypical bacterial pneumonia or viral pneumonia frequently overlap and cannot be used reliably to distinguish between the various aetiologies, as well as blood tests like white blood cell, C-reactive protein, including the more recently introduced serum procalcitonin (85% sensitivity and 45% specificity in identifying children without typical bacterial CAP. As a consequence, children with CAP usually receive unnecessary empirical antibiotics, contributing to the spread of antibiotic resistance or to side effects. Therefore, new methods, possibly fast, non- invasive and easily accessible in the outpatient settings (point-of-care) to optimize and personalize the management of children with suspected CAP are urgently needed Specific aim 1 To perform a clinical prospective study aimed to evaluate clinical, laboratory, microbiolical and outcomes data and to define LUS patterns (ultrasonomic) in children with CAP of different aetiologies: (viral, bacterial and atypical CAP) in different italian regions (Lazio, Puglia). Specific Aim 2 Development and validation of multi-factorial prediction models for the personalized diagnosis and management of paediatric CAP and building of a Decision Support System (DSS) based on validated prediction models that will be build based on the collection of "ultrasonomic", clinical, laboratory, treatments, outcomes and microbiological data collected from all partners. In particular, we will: i) develop, validate, and improve prediction models for the prediction of aetiology, outcome and treatment response; ii) take advantage of prediction models to better inform patients/caregivers on the risks and benefits of the proposed treatments; iii) use the outcome of the prediction models to individualize the management
Identification of the microbial profile of Ventilator associated pneumonia causing microorganisms among Respiratory ICU patients .
The infection of COVID-19 has caused serious threat to the life and health of all mankind and increased huge economic burden. According to the current statistics, the incidence of pulmonary fibrosis after COVID-19 infection is about 27.7% -87%, 81% of severe patients and 37% of moderate patients have residual lung lesions, and 53% of patients still have residual lung abnormalities one year after infection, resulting in restrictive pulmonary dysfunction and affecting the health and life of patients. Therefore, it is very important to study the diagnostic and prognostic markers of pulmonary fibrosis after infection of COVID-19. At present, relevant studies have been carried out on imagomics and serum proteomics of pulmonary fibrosis after COVID-19 infection, and serum biomarkers and imagomics marker models for diagnosing pulmonary fibrosis after COVID-19 pneumonia have been developed. However, there are few studies combining imageomics and serum proteomics, and the mechanism of pulmonary fibrosis after COVID-19 has not been fully clarified. In this study, it is planned to recruit patients with moderate, severe and critical COVID-19 pneumonia infection, collect venous blood from subjects, and perform chest HRCT follow-up. Blood samples were screened by proteomics and verified by expanded samples to screen diagnostic and prognostic markers of pulmonary fibrosis after COVID-19 infection. At the same time, based on deep learning technology, a model was developed to predict the occurrence and prognosis of pulmonary fibrosis after infection of COVID-19 combined with clinical characteristics, serum markers and AI imagomics, so as to provide ideas for further elucidating the mechanism of occurrence and development of pulmonary fibrosis after infection of COVID-19.
The primary purpose of this study is to assess the efficacy and safety of Huashibaidu granule for the treatment of community-acquired pneumonia in children compared with placebo and to demonstrate the efficacy of Huashibaidu granule in improving clinical symptoms, removing pathogens, and shortening clinical course.
High frequency oscillatory ventilation (HFOV), as an ideal lung protection ventilation method, has been gradually applied to neonatal intensive care treatment, and is currently recommended as a rescue method for neonatal acute respiratory distress syndrome (ARDS) after failure of conventional mechanical ventilation. Although its ability to improve oxygenation and enhance carbon dioxide (CO2) clearance has been repeatedly demonstrated in laboratory studies, its impact on the clinical results of these patients is still uncertain. Noninvasive high-frequency oscillatory ventilation (nHFOV) combines the advantages of HFOV and non-invasive ventilation, and has become the current research focus in this field. It is recommended to use it after the failure of routine non-invasive ventilation treatment to avoid intubation. For the treatment of intubation, there is still a lack of large-scale clinical trials to systematically explore its efficacy. The gradual increase of clinical application of nHFOV has also enriched its application in the treatment of other diseases. At present, non-invasive high-frequency oscillatory ventilation has not been applied to the study of adult COVID-19 with acute hypoxemia, which will be the first study in this field.
Exposure to molds in dwellings is a public health problem. Diagnosis of hypersensitivity pneumonitis due to mold exposure at home (domestic HP) are increasing. To perform the serodiagnosis of domestic HP a cohort constitued of proven cases and exposed healthy controls are needed. The HOME HP study aimed at obtaining a cohort of proven cases and exposed controls in order to be able to improve the serodiagnosis of domestic HP.
The current work aims to: 1. Measure the levels of Neutrophil CD64 Receptor, Monocyte Human Leukocyte Antigen-DR (mHLA-DR), and Triggering Receptor Expressed on Myeloid Cells 1 (TREM-1) in children suffering from pneumonia. 2. Compare these levels to their levels in healthy control children. 3. Analyze the cut-off point, sensitivity, specificity, and area under the ROC curve of these biomarkers to test their abilities to early differentiate children with pneumonia from healthy control children. 4. Conclude or reject their possible use as diagnostic and/or prognostic markers in pediatric pneumonia.
This phase II trial studies low-dose radiation therapy as a treatment for patients with severe COVID-19 pneumonia to improve clinical status.
A randomized, double-blind, placebo parallel control study and is expected to enroll 20-60 eligible patients with severe novel coronavirus pneumonia.
This study adopts a randomized, double-blind, placebo parallel control design, and is expected to include 120 eligible patients with severe novel coronavirus pneumonia.