View clinical trials related to Infections, Respiratory.
Filter by:Objectives: 1. To compare the immune response of patients with or without sepsis presenting to the ED with a(n) (suspected) infection. 2. To determine immune response aberrations that are associated with an increased risk of developing sepsis in patients presenting to the ED with a(n) (suspected) infection without sepsis. 3. To determine the long term cognitive and physical sequelae of sepsis after admission.
Vapendavir (VPV) is a drug being developed to treat human rhinovirus (RV) infection, one virus responsible for the common cold. Vapendavir prevents the virus from entering cells and making more infectious copies of itself. A study is being planned to investigate VPV in patients with chronic obstructive pulmonary disease (COPD, a lung disease making it difficult to breathe) who develop a rhinoviral infection; however, VPV has not been approved for use in treating any indication (disease) by the FDA or any other global regulatory agency. Therefore, VPV is considered investigational, and the study doctor is conducting this investigational research study. Safety will be monitored throughout the entire study.
The Norwegian Institute of Public Health (NIPH) is introducing a new electronic tool for direct observation of compliance with recommended infection prevention and control measures in healthcare. The solution is called the National Tool for Observation of Infection Prevention Measures (NOST). NOST is a quality improvement tool that includes a web-based solution for observing compliance with recommendations for hand hygiene and other IPC measures. Through NOST, healthcare personnel will be able to identify the local level of compliance, which in turn can reveal areas for improvement. This protocol includes the evaluation of NOST in hospitals. The evaluation is designed as a cluster-randomized controlled trial with two arms where eligible wards in hospitals are randomly allocated into an intervention and a control arm. NOST is implemented in the intervention wards at the start of the evaluation period, and compliance with hand hygiene and other outcomes are measured in both the interventions and control wards one year later. The objective of evaluating NOST is to: - measure if implementation of NOST leads to improved infection prevention and control in the form of increased compliance with hand hygiene recommendations, and - measure if changes in the quality of infection prevention and control as a result of implemented NOST affects the epidemiology of healthcare-associated infections in healthcare institutions and the length of hospital stays.
Current virus detection methods often take significant time or can be limited in sensitivity, specificity or cost. There is therefore a need for diagnostic methods that are simple to use, sensitive, rapid and inexpensive. This is a proof of concept study to determine whether the OxDx system (a new a rapid pathogen identification technology) is able to detect and differentiate different viruses from nasopharyngeal swabs/aspirate specimens. The data collected will be used to "train" the algorithms to be able to accurately identify respiratory viruses. The accuracy with which the algorithms estimate the test dataset will be monitored at regular intervals during the training dataset collection period. The OxDx system is still under development, which means that it is still "learning". The system needs to see more information so that it can be sufficiently accurate to be used in clinical practice and should become more accurate in identifying these viruses as it sees more and more information from patients. This study will take place at Portsmouth Hospitals University NHS Trust and aims to recruit 1000 patients. To do this, we will recruit both adults and children who either present to the emergency department or are admitted to QAH with a clinical suspicion of a respiratory viral infection. All participants will have a nose and/or throat swab taken as part of their clinical assessment, and we would ask to take a further nasal swab for the purpose of the study. Research sampling will be combined with routine clinical samples where possible to reduce the frequency of testing. We will use most of the information to teach the system how to become more accurate at identifying respiratory viruses. We will keep the remaining information separate and use it to test how accurate the system is. All of the data will be kept securely. Basic information will be collected including age, gender, results of blood tests taken for clinical review, treatment and outcome data. No results from the swabs taken for the purpose of the study will be available to either the participant or the clinical team and the information will have no effect on patient care.
The medical charts of all COVID-19 cases (n=1200) from 17 long-term care facilities in Montreal, Canada will be reviewed, to compare patients who survived to patients who did not survive. Through multilevel logistic regression, the risk of death will be estimated for institutional predictors of mortality, while controlling for individual risk factors. Individual covariates include clinical features (age, sex, Charlston comorbidity index, SMAF autonomy score, severity criteria) and medical treatments (IV fluids, anticoagulation, oxygen, regular opiates, corticosteroids). Aggregate covariates include epidemiological data (attack rates, timing of outbreak) and institutional characteristics (number of beds, air exchange per hour, presence of a dedicated COVID-19 unit at the time of outbreak, staff compliance to infection control measures, staff infection rates, understaffing, proportion of semi-private rooms, proportion of wandering wards and other special units).
Currently, there are few studies that have been established that consist of a variety of established and coherent approaches that sought to profile the determinants of recovery, nor used interrogative procedures to understand lasting physical impairment. In this context, measurements obtained from an assessment of cardio-respiratory responses to physiological stress could provide an important insight regarding the integrity of the pulmonary-vascular interface and characterisation of any impairment or abnormal cardio-respiratory function [4]. Indeed, current approaches are being developed to support patients using previous knowledge from other acute respiratory infections (e.g. Acute Respiratory Distress Syndrome; ARDS and Middle Eastern Respiratory Syndrome; MERS), approaches that do not consider the novel challenges presented by COVID-19. The knowledge obtained from the proposed research plan will inform the development of COVID-19 specific rehabilitation and clinical management guidelines which can be implemented globally to increase patient wellbeing, physical capacity, and functional status which will be directly related national and international health and wellbeing, economical and societal impacts.
Since 2000, various emerging infectious diseases have repeatedly caused serious impact on the health of the global population and the healthcare systems. With the growing international transportation and improving accessibility of the healthcare systems, hospitals have been inevitably the first sentinels dealing with emerging infectious diseases. The biological disasters, such as the Severe Acute Respiratory Syndrome (SARS) in 2003, the Middle East Respiratory Syndrome (MERS) outbreak in South Korean in 2015, and the Coronavirus disease 2019 (COVID-19) outbreak this year, challenged our vulnerable healthcare systems and caused great loss of lives. Regarding the ongoing global epidemics and possible community outbreaks of the COVID-19, the management of biological disasters for an overcrowded emergency department should be planned. In the early 2020, the emergency department used a double-triage and telemedicine method to treat non-critical patient with suspected COVID-19. This application reduced the exposure time of the first responders and reserve adequate interview quality. However, for the critical patients treated in the isolated resuscitation rooms, the unique environment limited the teamwork and communication for the resuscitation team. These factors might led to poorer quality of critical care. The investigators designed a telemedicine-teamwork model, which connected the isolation room, prepare room and nursing station by an video-conferencing system in the emergency department. This model try to break the barriers of space between the rooms and facilitate the teamwork communications between each unit. Besides, by providing a more efficient workflow, this model could lower the total exposure time for all workers in the contaminated area. This study was conducted to evaluate the benefits of the telemedicine-teamwork model and provide a practical, safe and effective alternative to critical care of the patients with suspected highly infectious diseases.
This trial has two parts. Part A and Part B. Due to changes in the overall clinical development plan, Part B will no longer be conducted. The objectives originally described for Part B have been implemented in the ongoing development via a pivotal Phase I/II/III trial BNT162-02/C4591001 (ClinicalTrials.gov NCT: 04368728). Part A is for dose ranging of four different vaccines (BNT162a1, BNT162b1, BNT162b2, and BNT162c2) which will be undertaken with dose escalation and de-escalation plus the evaluation of interim dose levels. It also includes dose ranging in older participants. The vaccines BNT162a1, BNT162b1, BNT162b2, and BNT162c2 will be administered using a Prime/Boost (P/B) regimen. The vaccine BNT162c2 will also be administered using a Single dose (SD) regimen. Three additional cohorts aged from 18 to 85 years receiving BNT162b2 only. BNT162b2 has entered a Phase II/III evaluation of efficacy, with the intent to support an application for marketing authorization. The dosing regimen under investigation is two BNT162b2 doses given ~21 d apart.
Operational project to compare clinician collected nasopharyngeal (NP) samples to patient-obtained tongue, nasal and mid-turbinate (MT) samples in the detection of SARS-CoV-2 in an outpatient clinic setting
This is a first-in-human (FIH) study to explore the safety, tolerability and pharmacokinetics of PA after oral ascending dose administration to healthy male volunteers.