View clinical trials related to Toxemia.
Filter by:Severe sepsis and sepsis shock are common in emergency department, with a high mortality rate. The potential severity of this disease impose a diagnosis as early as possible to start antibiotic therapy and hemodynamic support. Conventional biomarkers are an important support for the emergency physician. However, comparison of sensitivity and specificity for new biomarkers, like presepsine, suggests that they can be more efficient in this area. In this single-center, prospective, non-interventional study, we propose to compare the sensitivity of presepsine to that of lactate for the diagnosis of severe sepsis and septic shock We emit to main hypothesis that the sensitivity of presepsine is higher than that of lactate for the diagnosis of severe sepsis.
Despite major advances in the treatment and understanding of the pathophysiological mechanisms, mortality of severe sepsis remains high, ranging from 25 to 50%. With a prevalence > 20% in intensive care units, it is now in a population increasingly aging with many co-morbidities, a real public health problem. Thus, changes in treatment to physiological axes could change the prognosis of these patients. Protein Tyrosine Phosphatase 1B (PTP1B) is involved in the negative regulation of many cellular pathways such as the response to insulin, leptin and certain growth factors and endothelial nitric oxide production. PTP1B appears to be particularly involved in the control of endothelial function and insulin secretion. Under these conditions, encouraging results have been obtained in a model of insulin resistance (obesity, diabetes) and as part of pro-angiogenic therapy by inhibition of PTP1B on models of heart failure. Recent advances have broadened the pathophysiological implications of PTP1B conferring a potential role in the regulation of inflammatory processes. In an experimental model of septic shock (Inserm 1096), the investigators demonstrated a significant improvement in survival and cardiovascular function in genetically deficient mice PTP1B (PTP1B - / -). Finally, PTP1B is involved in the downregulation of the signaling pathway of insulin via a feedback phenomenon. Septic shock induces many changes in carbohydrate metabolism. These changes result in hyperglycemia associated with insulin resistance, an independent risk factor of morbidity and mortality. Taken together, these data suggest that the expression of PTP1B could be useful in septic patients by modulating insulin resistance and thus the prognosis of these patients. This justifies the investigator clinical research project on the relationship between the expression of PTP1B levels, glycemic status and prognosis evaluated by the SOFA score in patients with septic shock with multiple organ failure.
The purpose of this study is to determine the epidemiology and outcome of sepsis at Yuetan subdistrict in Beijing in mainland China).
It has always been a real challenge to treat sepsis in critically ill patients. The mortality is as high as 20% in patients with severe sepsis and 46% with septic shock develops. Early diagnosis and early treatment are the principles. Along with appropriate resuscitation, judicious and thoughtful intravenous antibiotic therapy is the critical determinant of survival in sepsis and septic shock given that ineffective initial therapy worsens the outcome. Blood culture and subsequent susceptibility testing are the gold standard for microbiological diagnosis to direct the optimal use of antibiotic. However, this conventional approach usually takes 5-7 days to wait for the final report. Positive results were reported in only 30% of patients with sepsis and 50 to 60% septic shock. Moreover, the very low bacteria level in blood and prior use of antibiotics may prevent pathogen growth. Surface-enhanced Raman scattering (SERS) is a novel spectroscopy technique based on Raman scattering and localized surface plasma resonance (LSPR), which results in strongly enhanced Raman signals derived from molecules attached to nanometre-sized gold (Au) and silver (Ag) structures. SERS provides the structural information of biomedical molecules with ultra-sensitive characterization down to single molecular level in fast and non-destructive manner. The clinical application of SERS in sepsis will first help to recognize pathogens as well as their specific drug sensitivity, and then optimally guide the initial antibiotics usage. Plasma from twenty blood culture proven Gram positive, negative and Candida cases will separately subject to metabolomics profiling and bioinformatics analysis to establish each pathogen metabolites profile. The sensitivity and specificity of SERS and metabolomics in identifying pathogen and antibiotics-resistant strains will be evaluated. The investigators expected both techniques to play a crucial role in modern sepsis treatment and bring great impact on mortality reduction.
Determination of capillary lactate by using "point-of-care" technique is accessible, fast and allows to quantify the circulatory and metabolic dysfunction caused by sepsis. Compared to conventional assay techniques in arterial blood, capillary assay technique may have an increased susceptibility to metabolic alterations induced by sepsis in its initial stages. This increased sensitivity is not necessarily relevant in the management of the most serious patients for whom the diagnosis is obvious, but it could be very useful in patients for whom a diagnosis of severe sepsis or shock have not yet been adopted, particularly to help better identify patients who would require intensive management and avoid the installation of these serious disorders.
The purpose of The Preeclampsia Registry is to collect and store medical and other information from women who have been medically diagnosed with preeclampsia or a related hypertensive (high blood pressure) disorder of pregnancy such as eclampsia or HELLP syndrome, their family members, and women who have not had preeclampsia to serve as controls. Information from participants will be used for medical research to try to understand why preeclampsia occurs, how to predict it better, and to develop experimental clinical trials of new treatments.
Sepsis is a common cause of death in intensive care unit, timely and accurate diagnosis and treatment directly affect the survival rate. Single nucleotide polymorphism (SNP) was promising genetic biomarker for sepsis patients. The present study was designed to screen several SNP by whole exome sequencing which evaluate the sepsis related snp site in order to be a new target for the treatment of sepsis.
Background: Sepsis is a major cause of in-hospital morbidity and mortality. Current tools available to the clinician to initiate therapy of patients with sepsis mainly comprise of symptom classification systems and culture techniques, which provide aspecific and slow information. Objective: The ultimate goal of this program is to assist the physician at the bedside in tailoring the treatment of an individual patient suffering from sepsis by generating rapid molecular information about the causative pathogen and the host response. Deliverables: Rapid tests ("sample-in-result-out") that can be used by health care personnel at or close to the bedside and that provide rapid information (within two hours) about the presence or absence of sepsis, the causative pathogen and the risk of the individual patient for sepsis complications and death. Design: The program is organized into four Work Packages (WPs) along a clinical, discovery and technology platform. In WP1 two university hospitals will enroll 7500 patients admitted to the Intensive Care Unit during the first 3 years of the project; 25% - 40% of these patients will have or will develop sepsis. In WP2 (Pathogen Detection), blood obtained from these patients will be used to develop rapid, fully automated DNA-based bedside tests that identify microorganisms and also provide information about their resistance to antibiotics. In WP3 (Host Response), RNA from blood cells will be analyzed to find novel biomarkers and to develop rapid and easy to perform tests that provide information about the risk profile of the patient. In addition, plasma levels of selected protein biomarkers will be measured for comparison of their value with that of the identified leukocyte molecular signatures. WP4 is responsible for the ICT management of the project. The Clinical Platform (covered by WP1 and WP4) delivers patient data and biological samples to the discovery and technology platforms. The Discovery Platform (covered by WP2 and WP3) uses patient data and biological samples to develop tests for detection of the infectious agent causing sepsis and for stratification of patients according to their risk for sepsis complications, including death. The results generated within the discovery platform will be delivered to the technology platform. The Technology Platform (part of WP2 and WP3) has the specific aim to develop rapid assays that run on a fully automated (micro)fluidics platform that is so easy to operate that it can be used in decentralized settings such as (close to) the ICU. The developed assays will make use of the knowledge generated in the discovery platform.
The purpose of this study is to compare the tendency of plasma concentration and clearance of procalcitonin in the first 24 and 48 hours of management of patients with severe sepsis and septic shock with another marker of early prognosis represented by 48 hours delta sofa.
This study is to see whether the intravenous administration of methylene blue improves the outcome in severe sepsis and septic shock.