View clinical trials related to Critical Illness.
Filter by:The goal of this clinical trial Is conducted to evaluate the efficacy and safety of active or sham HD-tDCS in combination with dexmedetomidine in patients with moderate to severe ARDS due to COVID-19 with delirium in intensive care unit (ICU). The hypothesis was that HD-tDCS combined with concomitant dexmedetomidine would reduce delirium rates.
Sleep of critically ill patients is highly disturbed with a high sleep fragmentation; patients spend most of their sleep in very short sleep episodes, lasting less than 10 minutes. Causes of theses sleep alterations are complex including environmental noise (alarms, beepers, conversations…), continuous light, nurse care and repetitive measures of vital parameters. Numerous studies have reported a relationship between severe sleep alterations and a prolonged weaning period and mortality. Improving sleep quality in critically ill patients is a major challenge to promote ICU patient's recovery. A very promising treatment is the application of a nocturnal " quiet-time " during which non urgent care, comfort care, systematic measures of vital parameters are delayed and clustered in order to limit room entries. However, " quiet time " procedures have failed to improve sleep quality to date. A miniaturized medical device recording one EEG channel and embedding an automated sleep scoring algorithm running in real-time was devised. This device (positioned on forehead, and continuously recording noise and light levels) indicates if the patient is awake or asleep using a tablet positioned at doorstep of the room, so that nurses know if patient is sleeping, without entering the room. Hypothesis proposes that applying sleep protection procedures (clustering cares, limiting room entries, reducing lights and noise, delaying non urgent care…) when patients are sleeping (= EEG-guided strategies) will increase patients sleep quality. This study will assess the effect of such device on sleep quality in ICU patients. This is a "before / after" design. The first group ("control group"), will be recorded but the sleep scoring will not be displayed by the tablet and patient will be expose to standard care. Then, procedure will be established collegially with nurses, nurses assistants and doctors. Then, the second group ("treated group") will be recorded with the device displaying the status of the patient (asleep/awake) and all caregivers will be asked to follow the established rules ("EEG-guided sleep protection rules")
Pain is common in intensive care and gives rise to multiple consequences that can impact the future of patients. The placement of deep venous catheters are painful gestures of common practice in intensive care. However, some patients are ventilated and sedated and their level of pain is difficult to judge. Quantitative pupillometry seems to be a reliable tool for assessing pain in these patients unable to communicate. The method is already common practice in the operating room for this indication and recent studies increasingly validate its use in intensive care. The aim of the study is to validate the different levels of pain that can be assessed by pupillometry within this population during catheterization and to identify any non-responding subgroups (in order to conduct future clinical trials evaluating pain therapies).
The purpose of this study is to assess fluid accumulation (FA) in the body using BIA (Bioelectrical Impedance Analysis) in critically ill patients treated in the ICU. This study is an observational cohort with an initial phase that analyzes prospective individual patient data
Critical illnesses represent a significant physiological assault that triggers changes in the patient's immune system, resulting in an immunopotentiating response (systemic inflammatory response syndrome, SIRS) and an immunosuppressive response (compensatory anti-inflammatory response syndrome, CARS). The balance between SIRS and CARS is essential for the patient to return to a state of immune homeostasis and accelerate the healing process. However, when CARS is disproportionately intense, it leads to a state of immunoparalysis, which predisposes the patient to vulnerability to opportunistic infections, associated with a peak in late mortality. The majority of patients admitted to the ICU are considered immunocompetent. However, the investigators suspect that a significant proportion of them exhibit predominance of CARS and a state of functional immunosuppression. There is currently no diagnostic test to determine whether a patient is functionally immunocompetent at a specific point in time. The goal of this observational study is to learn about the immune system dysfunction occurring in critical illness. The main questions it aims to answer are: - What is the prevalence of immune system dysfunction in critical illness? - Does immune system dysfunction affect multiple organ failure trajectory and mortality in critical illness? - Is immune system dysfunction related to an increased risk of opportunistic hospital-acquired infections in critical illness? - Is immune system dysfunction related to age, fragility, nutritional status or previous comorbidities in critical illness? To answer these questions, the investigators will prospectively study a population of critically ill patients, defined by the presence of organ failure. The investigators will analyse a panel of genes and molecules involved in immunological synapse, using peripheral blood samples at different moments of the evolution of critical illness. Based on the analysis, the investigators will classify the patients' functional immune status and correlate it with the outcomes.
The aim of this study is to test the effect of 1week of extracorporeal diaphragm pacing (EDP) combined either with or without tilt table verticalization (TTV) on diaphragm function in patients with mechanical ventilation compared to conventional physiotherapy (CPT).
Getting the right dose of antibiotic promptly is an important part of treating infections. Unfortunately, when an infection is severe (sepsis) the body changes how it processes antibiotics. Consequently, some people with severe infection retain antibiotics for too long (risking adverse effects), whilst others excrete antibiotics too quickly (risking under-treatment). Mathematical models can help researchers understand drug handling variability (known as pharmacokinetics) between people. These models require very accurate information about drug administration and drug blood concentration timings. Researchers usually rely on someone recording these timings, but recording errors can make models inaccurate. We would like to understand if using data from routinely used electronic drug infusion devices (recording the exact time of administration) can improve the accuracy of pharmacokinetic models. We intend to investigate this with an antibiotic (vancomycin) that clinicians already routinely monitor blood concentrations for. Adults and children treated at St George's Hospital intensive care units will be invited to participate in the study which will last for 28-days within a 14-month period. Participants will donate a small amount of extra blood and provide researchers access to their clinical data. Blood will be taken at special times during vancomycin treatment from lines placed as part of standard treatment, minimising any pain or distress. There will be no other changes to patient's treatment. In the future, data from this study might help change the way we dose antibiotics. The National Institute for Health and Care Research and Pharmacy Research UK are supporting the study with funding.
There are no clear international guidelines for dosing vitamin D based on deficiency severity. Therefore, a new clinical trial is needed to evaluate the benefits of early vitamin D supplementation in maintaining sufficient levels for critically ill patients. The investigators conducted a multicenter clinical trial in Taiwan focusing on vitamin D and critically ill patients. 240 patients with low calcidiol levels will be enrolled and be provided varying supplementation doses to maintain their serum calcidiol levels ≥ 30 ng/mL within 30 days of ICU admission. The results will serve as a valuable reference for intensivists when formulating appropriate vitamin D treatment strategy to maximize clinical benefits for critically ill patients.
Introduction: Lactoferrin has several uses due to its effects. It has anti-inflammatory, antioxidant, immunomodulatory, antibacterial, antifungal, and antiviral effects. Its safety is proven by food and drug administration. Aims: The objective is to study the effect of lactoferrin on improving clinical outcomes in ICU patients when compared to placebo, and also to evaluate its safety. Patients and populations: A sample of 650 patients (325 patients in both groups A, and B) who will be admitted to ICU departments in Mansoura university hospital will be used to represent the population in ICU. Methods: A sample of 650 participants was randomized 1:1 into two groups (group A (325 patients), and group B (325 patients)). This study is a double-blind, randomized controlled clinical trial. Randomization was performed by independent clinical pharmacists working in hospital ICU departments.
The goal of this RCT is to compare the effectiveness of aminophylline and furosemide combination vs furosemide alone in producing effective diuresis in critically ill adults in ICU. ICU patients with the need of improved diuresis will be recruited and given either infusion of aminophylline and furosemide combination or furosemide alone, and their hourly urine output will be monitored to compare their effectiveness.