View clinical trials related to Toxemia.
Filter by:In patients diagnosed as sepsis on PICU admission, early and accurate identification of patients who will develop organ dysfunction (severe sepsis) is critical for effective management and positive outcome. A multiple marker approach would improve clinical utility compared with use of a single marker. The primary goal of this part of study is to define a combination of multiple markers, derived from novel biomarkers (nCD-64, IL-27, sTREM, HLA-DR, IL-10), metabolomics and routine clinical parameters, which could predict severe sepsis and determine the severity of disease.
The pharmacokinetics of antimicrobials is profoundly modified in Intensive care unit (ICU) patients. To adapt the treatment, it is recommended to measure blood levels of antibiotics. Some antibiotics, such as amikacin, are easy to monitor, while for other molecules, such as piperacillin/tazobactam, the drug monitoring is more difficult to obtain. These two molecules have similar physicochemical characteristics (hydrophilicity) and therefore have closed pharmacokinetic properties. OPTIMA is a study aiming at criteria will be used to judge whether the pharmacokinetic (PK) parameters of amikacin are predictive of those of piperacillin and tazobactam.
Using abdominal computed tomography (CT) imaging, the investigators will estimate total body muscle mass at two time points in Intensive Care Unit (ICU) by assessing cross-sectional muscle areas at the L3 vertebral body level. This allows for a determination of the rate of sarcopenia development in the ICU. With this information, the investigators propose to test if the rates of the development of sarcopenia differ in critically ill subjects with sepsis compared to a reference group of critically ill subjects with trauma (without sepsis).
Platelets are important mediators of an inflammatory response and a key component of the innate immune system to defend the human body against invading pathogens. However, little evidence exists regarding the number of platelets that should be used als transfusion threshold in septic patients. In this trial platelet transfusion will be performed with either <50000/µl or <20000/µl as a trigger.
The aim of this observative, prospective study with cross-sectional design is to explore possible correlations/associations between microcirculation parameters and sublingual endothelial glycocalyx in sepsis. Therefore, 30 critically ill septic patients and 10 healthy controls were enrolled.
In this clinical outcomes analysis, the effect of a machine learning algorithm for severe sepsis prediction on in-hospital mortality, hospital length of stay, and 30-day readmission was evaluated.
The sepsis syndrome has recently been more stringently defined as "a life-threatening organ dysfunction caused by a dysregulated host response to infection". Clinical and paraclinical tools are investigated for their ability to adequately recognize sepsis early.
Septic shock is a major cause of morbidity and mortality. SIRS (systemic inflammatory response syndrome) can progress over hours to days to severe sepsis and septic shock. Currently, lactate levels are used to guide resuscitative efforts and have been shown to be a predictor of mortality independent of vital sign abnormalities (1). However, their use seems to be limited to trending in a given patient, and not for prognostic value of a single level (2). This is because there is significant overlap in lactate levels of individuals who progress to death and multisystem organ failure as compared to those who do not (2). Blood cultures are also extensively used to detect blood stream infection (BSI), but these are time consuming and are not immediately useful to clinicians caring for sick patients. A biomarker that adequately distinguishes between patients at high risk for progression to severe sepsis/shock/death and those who will not would be helpful in the appropriate initiation of aggressive treatment and appropriate disposition of patients in clinical care. Previously, the investigators demonstrated that sPLA2-IIA detected by ELISA assay had a sensitivity of 87% and a specificity of 91% in detecting sepsis (3). Zeus Pharmaceuticals has developed a bedside point-of-care test measuring sPLA2-IIA in real time. The investigators propose to study this assay in terms of its discriminatory value in distinguishing between SIRS from non-infectious causes, sepsis, severe sepsis, and septic shock in a cohort of patients presenting to the emergency department at Anderson and Bethlehem campuses. The investigators propose to better define the threshold level for this marker assay as well as seek to establish its utility in a clinical population. The investigators will take samples of blood from emergency department patients presenting who meet SIRS criteria or have a positive q-SOFA screen. The investigators will take subsequent samples of blood when lactate levels are redrawn as per St. Luke's sepsis protocol. After informed consent is obtained, blood specimens will be run in analyzer provided by Zeus for sPLA2-IIA. The investigators will record presence and quantity of sPLA2-IIA, as well as other markers of sepsis such as lactate, vital signs, blood cultures, and patient oriented outcomes (ie ICU days, organ dysfunction, and survival to discharge). Printouts from analyzer will be stored in locked cabinet, and remaining blood will be discarded. The data will then be compiled by the investigators at St. Luke's University Hospital. The results will be correlated with the patients' clinical progression to determine the biomarker's utility and cut-off values for predicting progression of SIRS. As clear threshold levels for this marker have yet to be defined, the investigators would like to enroll patients meeting criteria until the investigators have enrolled 50 patients with septic shock. It is anticipated that, proportionally, this will lead to enrollment of 75-100 patients with severe sepsis, 100-150 patients with sepsis, and 100-150 patients meeting SIRS criteria who are not septic. This will help delineate if there is any value in this assay for distinguishing among the severity of sepsis pathophysiology.
As a common and serious medical condition , sepsis is a life-threatening organ dysfunction caused by a dysregulated host response to infection , which is a major and familiar cause of death in intensive care units(ICU). As a frequent laboratory abnormality in patients with sepsis , thrombocytopenia on intensive care unit admission is independently associated with increased mortality in patients. Furthermore, a low platelet count is a marker with further significance , which is always used for evaluating the prognosis of patients. Herein, this study aimed to investigate the effect of renin-angiotensin system on thrombocytopenia in patient with sepsis and explore the possible underlying molecular mechanisms.
Molecular testing is a largely validated approach allowing rapid identification of positive blood cultures. However, due to its high cost and its limited information on susceptibility, it is considered as an add-on technique reserved for specific patient populations. In our study, we specifically evaluated molecular testing in a critical care setting and measured its impact on the therapeutic management of critically ill with positive blood cultures. Through the analysis of 110 positive blood culture episodes included in both pre- and post intervention period, we measured a drastic 14h-reduction of the time to administration of the optimal antimicrobial treatment with the use of the molecular approach.