View clinical trials related to Septicemia.
Filter by:In this study, the investigators will deploy a software-based clinical decision support tool (eCARTv5) into the electronic health record (EHR) workflow of multiple hospital wards. eCART's algorithm is designed to analyze real-time EHR data, such as vitals and laboratory results, to identify which patients are at increased risk for clinical deterioration. The algorithm specifically predicts imminent death or the need for intensive care unit (ICU) transfer. Within the eCART interface, clinical teams are then directed toward standardized guidance to determine next steps in care for elevated-risk patients. The investigators hypothesize that implementing such a tool will be associated with a decrease in ventilator utilization, length of stay, and mortality for high-risk hospitalized adults.
This study evaluates the impact of aminoglycosides in hypotensive septic oncologic patients. In the oncologic patient population, sepsis is a major health concern due to high mortality rates and healthcare costs. Prior research shows aminoglycosides antibiotics are frequently used to treat sepsis, but their clinical impact in hypotensive oncology patients upon the progression of sepsis is not known.
Severe infections (sepsis) are a frequent cause of admission to the intensive care unit. Sepsis represent a significant risk for the health of patients in the short and medium term. Sepsis are notably linked to a change in the function of immune cells. In some patients, a state of pseudo-dormancy of monocyte and macrophage immune cells, called myeloid cell immunosuppression, is observed. This situation, which leads to a worsening of the infection, must be avoided because it represents a danger for the patient, even during antibiotic therapy. At present, these events are still very poorly understood. Research is needed to understand how the immunosuppression of myeloid cells occurs in order to adapt existing treatments or to find new ones. Laboratory work on animal models of sepsis has shown that this state of myeloid cell immunosuppression is closely linked to a modification of energy production by myeloid cells (monocytes and macrophages). The function of the mitochondria ("energy factory" of the cells) in these cells is impaired. Thus, restoring mitochondrial function in myeloid cells could be a therapeutic solution against the immunosuppression of myeloid cells during severe sepsis. The aim of this study is to verify whether alterations in mitochondrial function in myeloid cells occur in both patients with and without bacterial infection.
This trial studies how changes in microRNAs may correlate with sepsis outcomes. Sepsis is a type of severe infection of the blood stream, and its diagnosis may be obscured by many other conditions such as surgery, trauma, and cancer. MicroRNAs are biomarkers found in the blood and tissue. Blood samples may help correlate changes in microRNA expression to patient reactions to a sepsis infection.
We propose to develop novel diagnostic tests for severe sepsis and community acquired pneumonia (CAP). This program, entitled Community Acquired Pneumonia & Sepsis Outcome Diagnostics (CAPSOD), is a multidisciplinary collaboration involving investigators at six organizations: NCGR; Duke University Medical Center, Durham, NC; Henry Ford Hospital, Detroit, MI; Eli Lilly and Company, Indianapolis, IN; Indiana Centers for Applied Protein Sciences, Indianapolis, IN; and ProSanos Corp., La Jolla, CA. In the United States, Community Acquired Pneumonia is the sixth leading cause of death and the number one cause of death from infectious diseases. Of the 5.6 million annual cases of CAP, 1.1 million require hospitalization for intensive therapy. Sepsis, commonly known as blood poisoning or bloodstream infection, is the tenth leading cause of death in the US and the number one cause of death in non-cardiac intensive care units. Incidence of sepsis is increasing by 9% each year and mortality rates vary between 25 and 50%. Cost to the US healthcare system exceeds $20 billion each year. In patients with suspected sepsis or early CAP, rapid identification of patients who will develop severe sepsis or CAP is critical for effective management and positive outcome. The CAPSOD study is designed to identify novel tests for early diagnosis of severe sepsis and CAP. When performed in patients at the earliest stages of disease, these tests will have prognostic value, rapidly identifying those who will have poor outcomes or complicated courses. CAPSOD will prospectively enroll patients with sepsis and CAP at Duke University Medical Center and Henry Ford Hospital. The study will use advanced bioinformatic, metabolomic, proteomic and mRNA sequencing technologies to identify specific protein changes, or biomarkers, in patient blood samples that predict outcome in sepsis and CAP. Development of biomarker-based tests will permit patient selection for appropriate disposition, such as the intensive care unit, and use of intensive medical therapies, thereby reducing mortality and increasing effectiveness of resource allocation.