Active clinical trials for "Sepsis"

Central venous catheters (CVCs) are indispensable in modern critical care. However, CVC usage is associated with complications, including central line-associated bloodstream infections (CLABSIs), which in turn, is translated to higher healthcare costs and mortality. The use of antimicrobial-impregnated CVCs is one of the strategies to reduce CLABSI. Nevertheless, its' efficacy and beneficial effects, particularly in terms of patients' outcome had not been homogeneously demonstrated across literature. Moreover, antimicrobial-impregnated CVCs are more expensive compared to conventional non-impregnated ones, and hence its cost-effectiveness remains doubtful. To date, no local studies have been conducted to evaluate the efficacy and economic impact of antimicrobial-impregnated CVCs and on patients' outcome. The goal of this clinical trial is to determine the efficacy and cost-effectiveness of antimicrobial-impregnated CVCs in preventing (CLABSI) among critically ill patients in a Malaysia University Hospital Adult Intensive Care Unit. The main questions it aims to answer are: Is there any difference in CLABSI rates between patients using antimicrobial-impregnated CVCs and non-impregnated CVCs in Malaysia adult ICU? Does the use of antimicrobial-impregnated CVCs in CLABSI prevention in Malaysia adult ICU affect patient length of stay when compared to non- impregnated CVCs? Does the use of antimicrobial-impregnated CVCs in CLABSI prevention in the adult ICU setting affect healthcare costs when compared to non-impregnated CVCs? How antimicrobial resistance features of the bacteria causing CLABSI may differ in patients using antimicrobial-impregnated CVCs compared to non-impregnated CVCs? Patients who require a CVC for critical care in ICU will be recruited and randomly assigned to one of the two different groups to receive either a conventional non-impregnated CVC or an antimicrobial-impregnated CVC, which will be inserted and handled by medical practitioners. Participants will then be monitored for symptoms and signs of CLABSI, alongside length of ICU stay & healthcare costs. Researchers will compare CLABSI rates and other relevant parameters among the 2 groups to see if antimicrobial-impregnated CVCs are useful and cost-effective in CLABSI prevention.

Neonatal sepsis is a leading cause of neonatal mortality and continues to be a formidable problem for neonatologists and pediatricians world over. The prevalence of neonatal sepsis varies in different countries; in developed countries it is 1 to 10 cases per 1000 live births and in developing countries the incidence of neonatal septicemia increases to 49 to 170 cases per 1000 live births. The normal fetus is sterile until shortly before birth as the placenta and amniotic sac are highly effective barriers to infections. At birth, the newborn loses the protection afforded to it in the uterus and gets exposed to the microbial world.Neonatal sepsis is broadly divided into two types according to age of onset: Early-onset sepsis (<72 Hrs) and late-onset sepsis (≥72 hrs-28 days). Early-onset sepsis is acquired during fetal life, delivery, or at the nursery.Bacterial organisms causing NS may differ among countries, however, in most developing countries, gram-negative bacteria remain the major source of infection.To date, blood culture is the gold standard test for diagnosing sepsis, but it has some inherent limitations. It takes at least three or five days to be decisive and can be mistakenly negative because antibiotics are initiated empirically before collection and a well-developed microbiology laboratory is required.CRP is one of the most widely studied and applied acute phase proteins clinically, which can be induced by pre-inflammatory factor interleukin-6 (IL-6) to synthesize by liver cells, and it starts to rise in 12-24 hours of inflammatory response and reaches its peak at 48 hours.Interleukin-6 (IL-6) is a pleiotropic cytokine expressed by different cells in response to infections.

Determine the utility of blood resistin concentrations, when combined with clinical data, for predicting sepsis phenotypes that are associated with poor clinical outcomes. We hypothesize that resistin is a biomarker which provides critical prognostic information when used in conjunction with standard clinical data, in patients with sepsis and septic shock.

Having bacteria in the blood can be very dangerous. This is called bacteraemia (or bacteremia) or bloodstream infection. It can lead to problems across the whole body, which is what happens in sepsis. Bacteria called Staphylococcus aureus (S. aureus) cause one kind of bacteraemia. Up to a third of people with this condition die within three months, even with antibiotics. One reason for such severe problems is that the bacteria can spread almost anywhere in the body, and hide in places where they are very hard to find. When people with S. aureus bacteraemia come into hospital and have had antibiotics, doctors sometimes cannot tell if they still have an infection source (called a 'focus') hiding in their body. The focus can be like an abscess and may need removing or the pus draining out. A focus might be obvious, if there is pain or swelling, or it might be hidden and deep. If these 'foci' can be found, then doctors can treat them and this helps to cure patients. To improve survival for patients with these life-threatening infections, it is vital that doctors find the focus of S. aureus bacteraemia as quickly as possible. However, the research team do not know the best way to do this. Most patients with S. aureus bacteraemia have a chest X-ray and a scan of the heart valves. Patients may go to the scanning department lots of times while doctors try to work out where these foci are. This is uncomfortable and takes a lot of time. In about 1 in 5 cases the doctors still cannot find the focus. This is very worrying for patients, their relatives and doctors. This study has been designed by researchers, doctors and patient advocates. It aims to work out if fewer patients may die when a specific type of scan called a 'PET/CT' is done quickly, because it finds more foci. To do this the team plan to do a clinical trial in patients with S. aureus bacteraemia. Half of the patients will receive the usual tests that patients currently get and the other half will receive an extra scan as soon as possible. The patients will be chosen randomly (like the flip of a coin) to go into one of the 2 groups. A year into the trial, an independent committee will check the results to make sure the extra scan is finding more foci. If this is the case, the trial will carry on. At the end of the study, we will share the results globally. The findings are expected to change the way this dangerous condition is managed, so patients do better.

We aim from this study to investigate the role of renal resistance index (RRI) in evaluation of Acute kidney injury development and fluid administration in sepsis patients considering the change in RRI values over 7 days from admission as a predictor of AKI development

Cardiac dysfunction is common following hospital admission with sepsis and one of the most frequent causes for readmissions to hospital, however underlying mechanisms by which this might occur are unclear. The CONDUCT-ICU investigators will conduct a pilot, cohort study, characterizing cardiac function in ICU survivors of sepsis using a combination of CMR imaging, biomarkers and patient reported outcome measures to investigate mechanisms of cardiac dysfunction following sepsis. Comparisons will be made to that of the general population.

Recent international recommendations suggest the use of carbapenem rather than cefepime in this situation, but with a low level of evidence, given the few existing studies. As cefepime is a less broad-spectrum antibiotic than carbapenems, its use would limit the selection of multidrug-resistant bacteria.

This protocol will collect real-world data retrospectively from the electronic health record (EHR) as data obtained from the delivery of routine medical care to develop a machine learning (ML)-based Clinical Decision Support (CDS) system for severe sepsis prediction and detection.

Sepsis is a life-threatening organ dysfunction caused by a dysregulated host response to infection and is associated with high morbidity and mortality. Sepsis3 gives sepsis a broad definition, reflecting the heterogeneity of the disease. So we need a precise treatment with a stratification of patient prognosis in order to reduce mortality in patients with sepsis.

Sepsis, or systemic infection, is a common reason for ICU admission and death throughout the world. Despite advances in the way we treat this condition, it remains a significant economic and healthcare burden. A key part of the treatment of sepsis is the administration of IV fluids and blood pressure medication. However, there is huge uncertainty around dosing of these drugs in an individual patient. A tool to personalise these medications could improve patient survival. The study team has developed a new method to automatically and continuously review and recommend the correct medication doses to doctors, which was created using artificial intelligence (AI) techniques applied to large medical databases. The researchers' previous work has shown it has the potential to improve patient survival rates. The tool will be capable of processing patient data within the electronic patient record of NHS hospitals in real-time to suggest a course of action. This tool will be evaluated and refined in simulation studies and then be tested in two NHS Trusts in "shadow mode" (results not provided to duty clinicians). This will allow comparison of actual decisions made and recommended decisions from the AI system. The second stage of this clinical evaluation will display the recommendations to clinicians to assess the acceptability of the tool and confirm technical feasibility to inform future clinical trials. The long-term expected benefits of this project are numerous: improved patient survival, reduced use of precious intensive care resources and reduction in healthcare costs.