View clinical trials related to Critically Ill.
Filter by:Biofilm is a microstructure organised into aggregates of microbiological species within a polymeric matrix. As early as the 2000s, the Centers for Disease Control and Prevention (CDC) recognised the possible role of the biofilm lining endotracheal endotracheal tubes in the development of ventilator-associated pneumonia (VAP) , the most common infection in intensive care, with a high morbidity and mortality rate and a significant increase in hospital costs. Targeting biofilm therefore now appears to be a new area of interest for limiting the risk of VAP, and this rationale has led to the development of an intraluminal for abrading biofilm deposited on the inside of the intubation probe . Evaluation of this type of strategy nevertheless justifies the introduction of more precise methods for characterisation of the biofilm. To this end, the investigator carried out an initial clinical study describing the biofilm on intubation probes, BIOPAVIR 1, showing the existence of several biofilm structures, each associated with a specific microbiological signature. Several limitations including a lack of power due to an insufficient number of patients and the use of number of patients, and the use of a confocal microscopy technique with poor axial without the possibility of acquiring metabolic images of the biofilm. Based on the previous description of biofilm by optical coherence tomography (OCT), and a recent experience with an optimised form of high-resolution OCT, called full-field OCT, the investigator hypothesise that full-field OCT will allow more accurate characterisation of biofilm, due to its high spatial resolution and its potential ability to capture metabolic activity in the biofilm BIOPAVIR 2 proposes to use the performance of full-field OCT to better characterise the biofilm lining endotracheal tubes in patients undergoing mechanical ventilation in intensive care units. This project represents a first step towards understanding the link between the development of biofilm on intubation and the occurrence of VAP
Rapid and accurate determination of body weight in adult intensive care patients is very important for both calculating target tidal volume during invasive mechanical ventilation support and dose dependent drug administration. In this patient group, measuring actual body weight with a calibrated scale by standing the patient up is often impossible due to acute illness. Instead, estimated body weight determined by health care personnel or estimated body weights calculated according to anthropometric measurements are used. These calculations have some limitations in showing actual body weight, and there is some controversial information in current literature regarding their validity in critically ill patients. There is newly developed patient transfer scale called Marsden M-999® manufactured by Marsden Weighing Machine Group Ltd, which has the advantage of being used in patients who are unable to stand up, in rapidly and accurately measuring the current body weight in critically ill patients. This study aimed to evaluate the validity of these methods by comparing the body weights calculated by visual estimation and various anthropometric methods in critically ill Turkish patients with the actual weight measured by the mentioned scale.
29.3% of bacteremias in intensive care units (ICU) are linked to vascular devices, with a significant proportion related to central venous catheters, and an influence on both morbility and mortality. It is now accepted that microbiological biofilm plays a key role on both bacterial and fungal development on inner surface of vascular devices but there is yet a lack of clinical relevant data documenting a causal relation between biofilm formation and bacteremias. We assume that a more precise characterization of central venous catheter-deposited biofilm could help us better understand invasive medical device-related healthcare infections in critically ill patients.
To assess the safety and feasibility of the IKORUS device in critically ill patients and to gather exploratory data on haemodynamic coherence
The goal of this randomized feasibility trial is to evaluate the feasibility of Mechanical Insufflation-Exsufflation (MI-E) in invasively ventilated critically ill patients. The main question[s] it aims to answer are: - Is MI-E feasible? - Is MI-E safe? Participants in the intervention group will receive: - MI-E - Airway secretions will be removed by endotracheal suctioning, as part of routine airway care. - Manual hyperinflation will only be used when necessary in an emergency situation. Patients in the control group will receive endotracheal suctioning and manual hyperinflation when clinically indicated. The primary outcome is the proportion of delivered MI-E sessions (2 times per calendar day a MI-E session of 3 x 3 cycles of an in- and exsufflation) per patient according to study protocol (feasibility). Secondary outcomes are the total number of serious adverse events in relation to MI-E (safety) and preliminary exploratory data on the need for airway care interventions and clinical outcomes including duration of invasive ventilation, length of stay in ICU and mortality (efficacy).
Acute kidney injury is a well-recognized complication in critically ill patients. Up to date there is no clinically established method to reduce the incidence or the severity of acute kidney injury. Remote ischemic preconditioning (RIPC) will be induced by three cycles of upper limb ischemia. The aim of the study is to reduce the incidence of AKI by implementing remote ischemic preconditioning (identified by the urinary biomarkers tissue inhibitor of metalloproteinases-2 (TIMP-2) and insulin-like growth factor-binding protein 7(IGFBP7)
Measurement of Whole Blood Lactate Concentrations Whole blood lactate concentrations will be measured at the time of study enrollment and at 24, 48, and 72 hours. Measurement of Plasma Renin Concentrations Serum renin concentration will be measured on blood samples drawn from arterial catheters on supine position right after inclusion. Discarded whole blood samples (waste blood samples) in EDTA tubes are prospectively collected from each patient at the time of study enrollment and at 24, 48, and 72 hours.
In this pilot study we will study the feasibility of providing and following ICU patients with smart technology for three months after discharge from a general ward of the Leiden University Medical Centre.
The purpose of this study is to evaluate the efficacy and safety of remimazolam besylate compared to propofol for sedation in critically ill patients with deep sedation.
Certain diseases relating to the heart can only be definitively treated with surgery. When untreated, these can lead to heart failure with a lack of supply of oxygen-rich blood to the tissues, leading to damage to other organs. Adults who undergo heart surgery vary greatly in terms of age and relative health. This has significant implications when predicting outcomes in the aftermath of surgery. For example, a 90-year-old man with a variety of comorbidities such as diabetes and high cholesterol who requires a heart valve replacement may have an unfavourable chance of surviving the postoperative period when compared to an 18-year-old woman with no significant medical history undergoing the same procedure. Almost invariably, patients are admitted to an Intensive Care Unit (ICU) following heart surgery. This is done to facilitate close monitoring of the patients' vital organ functions and to also provide organ support if needed. For the heart, this can include the administration of drugs to help a heart pump forcibly, cause blood vessels to contract and increase blood pressure. Patients who have undergone heart surgery have been placed on a mechanical ventilator, following a tube placed in their windpipe. This form of ventilation often continues in ICU for a period of time, depending on the patient's condition. One specific type of ICU level monitoring that occurs in patients who have undergone heart surgery is cardiac output monitoring. This involves a thin tube, called a pulmonary artery catheter, that extends from the skin to the heart, via large blood vessels. Cardiac output monitoring is essential in this patient group to guide organ support and to provide information of how well the heart is functioning. In this observational study, the investigators wish to study patients who have undergone cardiac surgery, are receiving mechanical ventilation and have pulmonary artery catheters inserted. The investigators will collect cardiopulmonary data in these patients and compare these data with values of exhaled and inhaled gases (oxygen and carbon dioxide) over the same time period. This will enable the investigators to investigate the link between cardiopulmonary data and respired gas values. A better understanding of this link between cardiopulmonary function and oxygen/carbon dioxide values will then inform future studies aiming to determine the effect of various interventions in similar patient groups.