View clinical trials related to Critical Illness.
Filter by:Feasibility trial investigating the potential higher frequency of robotic assisted early mobilization in intubated COVID19 patients on the ICU.
Profile known and novel biomarkers in blood in COVID19 patients to characterize the host response to SARS-CoV-2 over time and in response to treatment. The investigators aim to: - Better understand the disease. The investigators will achieve this by characterizing the biology of COVID-19 infection and the pathophysiology of the host response using clinical data together with cellular and molecular measurements over the course of the disease. This will allow better insights for the discovery and development of novel therapeutics. - Understand why different patients have different phenotypes and disease presentations over time. The investigators will achieve this by analyzing for patient subgroups. This will allow targeted patient stratification and better matching of resources. - Understand how patients are responding to the different medications being tested in clinical trials. The investigators will achieve that by co-enrolling with therapeutic trials. This will allow an understanding of the biological effects of these interventions. Study Design: Observational adaptive study of a translational nature, combining clinical data and basic science investigations in blood samples in the same patients, longitudinally, with serial interim analyses. Primary outcomes: 90 day ICU mortality. Secondary outcomes: measures of ICU utilization and disease severity, and 90 day in-hospital mortality. The study ends after 3 months from admission to the ICU, hospital discharge or death. Location: St. Michael's Hospital (Unity Health Toronto), an academic center in downtown Toronto affiliated with the University of Toronto. The investigators will collect: A) Detailed clinical data including investigations, mechanical ventilation and cardiovascular parameters. B) Blood samples for state-of-the-art multi-omics biomarker discovery and development: cytokines, anti-COVID19 antibodies, autoimmune serology, metabolomics, transcriptomics, epigenomics, deep immune phenotyping, viral loads. For those patients who die with COVID19 The investigators will perform bedside post-mortem biopsies of lung, heart, kidney and muscle. Sampling times: From admission to the maximal severity phase through convalescence, in order to capture the evolution and dynamics of the disease and the recovery process: days 0,1, 3, 5, 7, 10, 15 and 22, and then every 2 weeks until the end of the study (3 months from admission to the ICU, hospital discharge or death).
This proof-of-concept study examines whether the acute brain dysfunction that occurs in critically ill patients is improved by administration of intravenous guanfacine.
Objective: To evaluate non-inferiority of Trimbow, an approved therapy for treatment of severe COPD, in ICU compared to the standard of care which is based on the same therapeutic approach. Study location: CHU Sart-Tilman, 4000 Liège, Belgium Study duration: 2 years Type : Interventional Methodology: Prospective clinical trial Number of patients: 200 (randomized 1:1) Main Inclusion criteria : - Maintenance therapy (LAMA or LABA) for COPD - Age >18 - Admission for AE of COPD - Signed Inform consent - Admitted in ICU >24h
Introduction. Initiation of acute kidney replacement therapy (KRT) is common in critically ill adults admitted to the intensive care unit (ICU), and is associated with increased morbidity and mortality. KRT has been linked to poor neurocognitive outcomes, leading to a reduced quality of life, as well as increased utilization of healthcare resources. Adults initiated on dialysis in the ICU may be particularly at risk of neurocognitive impairment, as survivors of critical illness are already predisposed to developing cerebrovascular disease and cognitive dysfunction over the long-term relative to healthy controls. Regional cerebral oxygen saturation (rSO2) may provide a critical early marker of long-term neurocognitive impairment in patients in this population. The INCOGNITO-AKI study aims to understand cerebral oxygenation in patients undergoing KRT, either continuous or intermittent, in the ICU. These findings will be correlated with long-term cognitive and functional outcomes, as well as structural brain pathology. Methods and analysis. 108 patients scheduled to undergo treatment for acute kidney injury with KRT in the Kingston Health Sciences Centre ICU will be recruited into this prospective observational study. Enrolled patients will be assessed with intradialytic cerebral oximetry using near infrared spectroscopy (NIRS). Delirium will be assessed daily with the Confusion Assessment Method-Intensive Care Unit (CAM-ICU) and delirium severity quantified as cumulative CAM-ICU-7 scores. Neurocognitive impairment will be assessed at 3- and 12-months after hospital discharge using the Kinarm and Repeatable Battery for the Assessment of Neuropsychological Status (RBANS). Structural brain pathology on MRI will also be measured at the same timepoints. Driving safety, adverse events, and medication adherence will be assessed at 12-months to evaluate the impact of neurocognitive impairment on functional outcomes. Ethics and dissemination. This study has been approved by the Queen's University Health Sciences and Affiliated Teaching Hospitals Research Ethics Board (Approval number: DMED-2424-20). Results will be presented at critical care scientific conferences and a lay summary will be provided to patients and families in their preferred format.
High-flow nasal cannula (HFNC) is a rather novel system to provide oxygen therapy, which provides flows up to 60 liters/minute (LPM) of heated and humidified gas through nasal prongs. HFNC is increasingly being used in patients with acute respiratory failure. In healthy volunteers and in patients with acute respiratory failure it has been shown to induce several effects beyond those expected for a standard oxygen therapy, such as increased carbon dioxide (CO2) clearance and positive airway pressure. One of the potential indications for HFNC is to facilitate weaning from mechanical ventilation and extubation. As weaning failure is one of the most complex challenges in mechanically ventilated patients, the use of HFNC after extubation, in order to prevent reintubation, has been evaluated in some clinical trials, with promising results. However, the role of HFNC postextubation is still controversial, and information regarding its effects on the pathophysiologic mechanisms of weaning failure is lacking. The goal of this proposal is to compare the acute physiologic effects of postextubation HFNC versus standard oxygen therapy, in critically ill patients, on relevant mechanisms related to weaning failure: work of breathing, lung function, systemic hemodynamics. This will be a randomized crossover study which will include critically ill mechanically ventilated patients, who fulfill criteria indicating they may be ready for weaning from mechanical ventilation, and in whom a spontaneous breathing trial (SBT) is planned to determine if they should be extubated. After checking eligibility and obtaining informed consent, patients will be monitored with an esophageal catheter (esophageal / gastric pressures to determine work of breathing, and electric activity of diaphragm to determine neuromechanical coupling), and a noninvasive ventilation monitor (electric impedance tomography to assess global and regional ventilation). Work of breathing, lung function, and systemic hemodynamics will be assessed during the SBT. Inclusion in the study will be confirmed only if they pass the SBT and are extubated. During the first 2 hours after extubation patients will undergo one hour of HFNC and one hour of standard oxygen therapy, with the crossover sequence being randomized previously at the time of inclusion, and with assessments repeated at the end of each treatment period.
Weaning ventilator support in critically ill patients is crucial. Both delayed extubation and unexpected early reintubation are harmful to the patients. Weaning parameters and spontaneous breathing trial are used to investigate the indication and predict the successful extubation. Hemodynamic stability and physical reserve are important indicators as well. Microcirculation parameters are known to be more sensitive to the change of hemodynamic status than macrocirculation parameters. We hypothesize that the change of sublingual microcirculation before and after spontaneous breathing trial is different between the the patients with successful extubation and the patients with failed extubation. Thus, this study measures sublingual microcirculation in patients receiving spontaneous breathing trial and record the extubation status (successful or failed). The microcirculation parameters before and after spontaneous breathing trial are compared between the the patients with successful extubation and the patients with failed extubation.
Critical illness myopathy (CIM) is a disabling condition that develops in critically ill patients. The syndrome is not only a cause of prolonged intensive care hospitalisation but also a main reason for delayed recovery. Critical illness myopathy presents as diffuse muscle weakness and failure to wean from mechanical ventilation. The pathogenesis of CIM is unclear. The proposed mechanisms for critical illness myopathy include muscle membrane depolarization, circulating depolarizing factor, and an endotoxin that reduces muscle sodium channel availability at depolarized membrane potentials. The electrophysiological diagnosis of CIM diagnosis is done by electromyography (EMG). In order to be able to detect changes in EMG, more than 2-3 weeks' time is required. Moreover the findings resemble other myopathies and are unspecific. EMG studies in paralysed muscles and sometimes unconscious patients is difficult or even impossible Since the 1950s, it has been attempted to investigate the muscle cell membrane properties, but it has not been possible to develop a clinically applicable diagnostic method. The novel electrophysiological method MVRCs is a possible future diagnostic method. It's more sensitive to muscle cell membrane changes than existing methods and it is simple enough to use in multiple clinical settings. The objective of this study is to investigate the utility of MVRCs in the early diagnosis of critical illness myopathy by investigating the muscle membrane properties in sepsis patients, who are in risk of developing CIM. In addition, this will contribute to a better understanding of the pathophysiology of critical illness myopathy. The study will enrol 70 participants in total, divided in to 2 groups of 20 patients aged ≥18 years; 1) patients with sepsis at intensive care units and 2) patients with chronic renal failure and uremia, and 30 sex- and aged-matched healthy participants. All subjects are to undergo neurological examinations, electromyography, nerve conduction studies, direct muscle stimulation and MVRCs. Blood tests will be taken in all patients. Patients with sepsis will be examined every week in 3 weeks. The presence of probable CIM will be determined on the 4th examination. Healthy participants and patients with chronic renal failure will only be examined in 1 occasion. The primary outcomes will be MVRCs parameters which will be compared between patients and healthy participants. Furthermore, MVRCs parameters will be correlated to blood sample results.
The risk of muscle wasting is high in the intensive care unit patients during the treatment process and this condition is associated with adverse clinical outcomes. The etiology of muscle wasting is multifactorial and medical nutrition therapy plays a key role in muscle wasting treatment and prevention. The aim of this study is assesing the malnutrition and fraility, anthropometric measurements, and muscle mass by ultrasound at the first admission to the intensive care unit and to determine the nutritional factors affecting clinical outcomes. In addition, it is planned to determine the risk factors affecting the change of anthropometric measurements and muscle wasting in the first week during the intensive care unit.
Study objectives: To determine whether, in critically ill patients with Acute Kidney Injury requiring renal replacement therapy (AKI-RRT), randomization to receive intravenous hyperoncotic albumin 20-25% (100 mL X two doses) compared to control/placebo normal saline boluses (100 mL X two doses) given during RRT sessions, leads to: 1. An increase in organ support-free days (primary outcome) at 28 days following randomization; and 2. An increase in RRT-free days (principal secondary outcome) at 28 days following randomization.