View clinical trials related to Pneumonia, Ventilator-Associated.
Filter by:In intensive care, many gastric tubes are inserted on a regular basis. There are different practices in terms of the location of the gastric tube. In some cases, the tube is inserted through the nose and in others, it is inserted through the mouth. In the literature and in practice, these gastric tubes create discomfort and complications that have an impact not only on the patient, but also on the treatments and the length of the patient's stay in hospital. Nosocomial Ventilator Associated Pneumonia is the most serious common complication for patients intubated with a gastric tube. It is possible that placement site may have an impact on the risk of developing Ventilator Associated Pneumonia, particularly by increasing the risk of bacterial pululation opposite the sinuses when the tube is placed via the nasal route. Investigator hypothesises that placing the gastric tube orally will reduce the rate of ventilator-associated pneumonia compared with the nasal route in mechanically ventilated intensive care patients.
Oral care with chlorhexidine was used to be considered an effective way to prevent ventilator-associated pneumonia (VAP). However, recent evidence revealed that oral care with chlorhexidine may associate with higher mortality and increasing risks of acute respiratory distress syndrome due to the aspiration of chlorhexidine. In addition, the majority of relevant studies in the past have only focused on cardiothoracic intensive care unit (ICU) or post-operation patients. Thus, whether this is effective and safe for medical ICU patients remains unclear.
It has been shown that oral hygiene reduces the incidence of ventilator-associated pneumonia (VAP). The nasopharynx is considered to be an important source of contaminated micro aspiration to the lung however, the effect of nasopharyngeal decontamination on VAP has not been yet investigated. The investigators hypothesized that decontamination of oral and nasopharyngeal cavities with combined Povidone Iodine and glycyrrhizin would remarkably reduce the incidence of VAP.
HAI (Hospital-acquired infection) is very common in ICU,and lack of understanding of environmental exposure omics and environment-host microbial interactions restricts the prevention and control of HAI. In this project, the investigators try to analyze the spatial and temporal distribution characteristics and evolution of microorganisms and their functions in the ICU environment through metagenome.
Background: Invasive mechanical ventilation (MV) is used as a cornerstone in the treatment plan of intensive care units (ICUs) patients to provide adequate tissue oxygenation to support the body during the treatment course. Ventilator-associated pneumonia (VAP) is a preventable iatrogenic complication that can develop in patients undergoing mechanical ventilation. VAP is pneumonia that develops 2 days after endotracheal intubation; the patient must have new or progressive radiological infiltrate, infection alerts (e.g. fever, white blood cell count change), altered sputum characters, and isolation of a causative organism, all together to diagnose VAP. VAP is the most frequent hospital-acquired infection occurring in the ICUs and has a high associated mortality rate. Mortality rate for VAP ranges from 24-51%. Therefore, this study aims to evaluate the VAP preventive effect of the selected EPB and related nurses' education on the incidence and severity of VAP, as well as assess the nurses' compliance with the selected VAP preventive EBP Hypothesis: H1: Implementation of VAP prevention EBP and related nurses' education would reduce the incidence of VAP among mechanically ventilated patients compared to those receiving conventional care. H2: Implementation of VAP prevention EBP and related nurses' education would reduce the severity of VAP among mechanically ventilated patients compared to those receiving conventional care. Research question: Q1: What level of compliance do ICU staff have with implementing of VAP prevention EBP? Trial design The current study will utilize a prospective, longitudinal, single-arm design, pre & post-experimental. The research's purpose, risks, and potential benefits will be explained to all participants before their voluntary consent and recruitment into the study. Participation was completely voluntary, and written informed consent was obtained from all participants or their families. ICU nurses will receive tutorial sessions, including four hours of theory and six hours of clinical training in the clinical setting. The tutorial sessions will cover the proper implementation of ten VAP preventive bundles as an EVB. The clinical training will use a demonstration and redemonstration approach to learning to ensure that they understand and can implement the ten VAP preventive bundles efficiently. Participants sample and setting The study will be held at the ICU of the National Hepatology and Tropical Medicine Research Institute (Imbaba Fever Hospital) (NHTMRI-IFH), Giza, Egypt. The total capacity of the ICUs is 20 beds. Data collection procedure After obtaining ethical and administrative approval, informed consent will be obtained from eligible patients. The pre-experimental phase will be started by assessing VAP incidence and severity among the participating MV patients using tools 1 and 2, as well as ICU staff compliance to implement the VAP preventive bundle utilizing tool 3 as baseline data for 30-40 days. After finishing the pre-assessment, the following week will be considered washing time before starting the post-experimental time to ensure that all pre-assessment patients are discharged. During the washing time, the nurses will receive a tutorial session on how to implement the adopted VAP preventive bundle, and then the medical and nursing staff will start implementing the VAP preventive bundle in the post-experimental phase for 30-40 days. Tools 1, 2, and 3 will be utilized to evaluate VAP incidence, severity, and ICU staff compliance to implement the VAP preventive bundle. All data will be collected in an Excel sheet for potential statistical analysis.
Clinical presentation of patients after severe injury such as a severe infection, trauma or extensive burns is characterized by the simultaneous occurrence of dysregulation of the initial inflammatory response and immunosuppression associating quantitative and functional alterations of innate and adaptive immune cells. These acquired immune dysfunctions have been associated with an increased susceptibility to nosocomial infections, foremost among which are ventilator-associated pneumonia (VAP). Despite the implementation of a set of preventive measures, the incidence of these VAP remains high in intensive care, with rates in Europe of 1.5% per day of ventilation. Post-aggressive immunosuppression is characterized by the decrease in the expression of HLA-DR (belonging to the type II major histocompatibility complex, MHC-II) on the surface of monocytes (mHLA-DR). The administration of interferon gamma (IFNγ) can restore the level of mHLA-DR and may possibly improve the prognosis as an adjuvant therapy associated to antibiotics. However, the level of proof of this therapeutic strategy is low, limited to small cohorts of patients, or clinical studies without prior immunodepression assessment. The objective of this study is to conduct a randomized, double-blind, placebo-controlled superiority trial to assess the effect of IFNγ administration on the duration of mechanical ventilation following the first episode of VAP in patients having an HLA-DR < 8000 AB/C All reported data about recombinant human IFNγ 1b for the control of secondary infections in patients with septic shock used the dose of 100 micrograms per day by subcutaneous route for 3 to 5 days . At this dose, no retrospective study has reported any serious adverse effects and recombinant human IFNγ 1b allows an increase in monocyte membrane expression of mHLA-DR.
This study aims to determine the incidence, risk factors and outcome of ventilation associated common complication in the PICUs at Assiut University Children Hospital in Egypt.
The goal of this observational clinical trial is to learn about the role white blood cells (macrophages) play in lung inflammation in people with Acute Respiratory Distress Syndrome (ARDS). The main questions it aims to answer are: 1. How does the immune system respond to different kinds of lung injury and inflammation and how do those processes differ from each other? 2. What roles do the cells that live in the lungs (macrophages) play in turning off inflammation? How does their role differ from other cells that are called to the lung to help repair injury (recruited macrophages)? 3. Will more frequent testing of lung cell samples help reduce the time it takes to start treatment for ventilator-associated pneumonia (VAP) and therefore reduce the rates of initial therapy failure? Participants will be in the intensive care unit (ICU) on a mechanical ventilator (machine that helps patients breathe) because they have ARDS or are on a mechanical ventilator for some other reason (control group). The following will happen: 1. Participants will be given 100% oxygen through the breathing machine (mechanical ventilator) for 3-5 minutes. This is called pre-oxygenation. 2. A lung specialist (pulmonologist), a member of Dr. Janssen's research team, or respiratory therapist will place small amount of saline into the lung using a long catheter going through the breathing tube. 3. The fluid will be removed with suction and will be sent to the laboratory for testing. 4. This will be repeated two more times over the course of 10 days, or less if participants are taken off of the ventilator. The procedure will be performed no more than three times. 5. Two nasal brushings will be taken from the participants' nose. 6. Approximately 3 tablespoons of blood will be removed by putting a needle into the participants vein. This is the standard method used to obtain blood for tests. A total of 9 tablespoons will be taken for research purposes over the course of this study 7. Data including the participants age, sex, severity of illness, and other medical conditions will be recorded to determine how these can affect the white blood cells. 8. If bacteria are isolated from the fluid in the participants lung, the participants' physician may choose to place the participants on antibiotics to treat an infection. 9. A follow-up phone call may be made by a member of the research team after discharge from the hospital. At this time, the participant may be invited to participate in the Post-ICU clinic at National Jewish Health.
Critically ill patients are at high risk of acquiring pneumonia during the time that they are mechanically ventilated. This is known as ventilator-associated pneumonia (VAP). VAP results in increased duration of mechanical ventilation, increased ICU and hospital stay, increased risk of death and increased health care costs. VAP occurs in 20% of patients and it is estimated that each case of VAP costs the health care system $10 to 15,000 Canadian. Because of its impact on patient outcomes and the health care system, VAP is regarded as an important patient safety issue and there is an urgent need for better prevention strategies. Invasive mechanical ventilation requires the passage of an endotracheal tube (ETT) through the pharynx which is frequently colonized with bacterial pathogens and a bio-film rapidly forms on the ETT. VAP results either from aspiration of contaminated oropharyngeal secretions or from aspiration of bacteria from the bio-film. In this project, the efficacy of a novel ETT coated with an antibiotic compound that has been shown to reduce the formation of bio-film and pathogen colonization will be tested. Preliminary evidence as to whether utilization of this novel ETT reduces the occurrence of VAP and improves patient outcomes will be obtained through the conduct of a pragmatic, prospective, longitudinal, interrupted time, cross-over implementation study.
The aim of this experimental study was to investigate the effect of prone position use on ventilator values, blood gas and ventilator-associated pneumonia in intensive care unit patients. Between June 2021 and January 2022, 40 trials and 40 control patients were included in the intensive care units of two private hospitals and received mechanical ventilation support. The mechanical ventilator values, arterial blood gases and ventilator-related pneumonia conditions were evaluated and followed for at least 5 to 10 days just before the position was given by comparing the prone position (PP) and the patients were brought back into the supine position. The data were collected using 'Patient Follow-up Charts', 'Clinical Pulmonary Infection Score', 'Braden Pressure Half Risk Assessment' and 'Ramsey Sedation Scale' prepared in line with patient introduction form and evidence-based guidelines. In addition, life findings, cultural results and blood gas analyses were performed. Statistical analysis was performed using the 'NCSS (Number Cruncher Statistical System) 2007 (Kaysville, Utah, USA)' program. 'Descriptive statistics, parametric and nonparametric tests' were used to evaluate the data. The level of statistical signiation was considered 'p<0.05'.