View clinical trials related to Septic Shock.
Filter by:In 2016, sepsis and septic shock was redocumented as fatal organ dysfunction caused by infection-induced host response disorders (Singer et al. 2016). Infectious shock is a subtype of sepsis; its circulation abnormalities significantly increase the mortality rate. The definition was updated to facilitate rapid identification and timely treatment. Despite the continuous progress of awareness and intervention, the mortality rate of septic shock is approaching 40% or more (Gasim et al. 2016, Karampela et al. 2022). Infectious shock exists in the presence of imbalance of oxygen supply and demand as well as tissue hypoxia, early improvement of tissue hypoperfusion is key to the treatment, a specific cluster treatment program was recommended in the guidelines of sepsis rescue action (Rhodes et al. 2017). Severe sepsis remains associated with high mortality, and the early recognition of the signs of tissue hypoperfusion is crucial in its management. The effectiveness of oxygen-derived parameters as resuscitation goals has been questioned, and the latest data have failed to demonstrate clinical advantage (Rudd et al. 2020). Prompt diagnosis and appropriate treatment of sepsis are of ulmost importance and key to survival. However, routinely used biomarkers, such as C-reactive protein and procalcitonin, have shown moderate diagnostic and prognostic value. Of note, the recent consensus definition for sepsis is based on clinical criteria, implying the paucity of reliable sepsis biomarkers. The new diagnostic criteria also incorporate the use of the SOFA score, a composite prediction tool, which is derived by a combination of clinical signs and biomarkers of organ dysfunction, leaving aside classic inflammatory biomarkers (Pierrakos et al. 2020, Karampela et al. 2022). The venous oxygen saturation (SvO2) is <70% in the majority of patients with severe sepsis on admission to the intensive care unit (ICU). The central venous-to-arterial carbon dioxide difference or only carbon dioxide gap (PCO2 gap) has gained relevance as a measure of assessment of several parameters (Mallat et al. 2015). The balance of dioxide carbon (CO2) production by the tissues and its elimination through the lungs can be reflected by the difference between the mixed venous content (CvCO2) and the arterial content (CaCO2). This venous-arterial difference in CO2 content (CCO2) can be estimated by the following equation: ΔPCO2 = PvCO2 - PaCO2, denominated PCO2 gap and in physiological conditions it ranges from 2 to 5 mmHg. In a few words, it indicates the difference between partial pressure of carbon dioxide in central venous blood (PvCO2) and arterial blood (PaCO2) (Janotka et al. 2021). The venous-to-arterial carbon dioxide difference (Pv-aCO2) can indicate the adequacy of microvascular blood flow in the early phases of resuscitation in sepsis (Ospina-Tascon et al. 2016, de Sá 2022). Hence, other resuscitation goals, such as PCO2 gap, have been suggested, due to their ability to predict adverse clinical outcomes and simplicity in patients achieving normal oxygen derived parameters during the early phases of resuscitation in septic shock. The PCO2 gap can be a marker of cardiac output adequacy in global metabolic conditions that are less affected by the impairment of oxygen extraction capacity (Bitar et al. 2020).
Sepsis is organ dysfunction secondary to an inappropriate host response to infection. In the most severe cases, circulatory failure necessitating the introduction of vasopressor therapy is called septic shock. Sepsis and septic shock are life-threatening systemic organ dysfunctions requiring hospitalization in a critical care unit. According to several studies, sepsis accounts for around 30% of patients in these units. In this patient population, mortality in the critical care unit or in hospital is 25.8% and 35.3% respectively. Among the organ dysfunctions associated with sepsis, striated skeletal muscle damage is frequent and possibly severe. The literature refers to this as sepsis-induced myopathy, and describes three main mechanisms: mitochondrial dysfunction, exacerbated proteolysis and altered muscle membrane excitability. Of all the striated skeletal muscles that can be affected, the diaphragm and the muscles of the thoracic and abdominal wall play a major role in breathing. The diaphragm remains the main muscle involved in breathing. Its physiology is twofold. Firstly, through its contraction, the diaphragm is responsible for the lateral movement of the lower ribs, thus increasing the transverse diameter of the thorax. This first action is commonly referred to as "insertional". At the same time, lowering the phrenic center of the diaphragm increases abdominal pressure. Its distinctive upwardly convex domed appearance means that it is intimately in contact with both the chest wall and the abdominal cavity. This particular area of contact is called the apposition zone. It is on this zone, under the action of the abdominal compartment, that positive pressure also generates an outward thrust from the medial face of the lower ribs, a second action commonly referred to as "appositional". A number of studies, including that carried out by our team (US_DIAMONDS, NCT 02474797), have identified a high prevalence of diaphragmatic damage in patients with sepsis or septic shock. This can be as high as 60%. This diaphragmatic dysfunction would then be associated with a higher mortality rate in hospital and at D90 of discharge. The clinical evolution of post-resuscitation patients remains a little-studied subject. However, patients may present muscle dysfunctions in the longer term after a stay in intensive care. In our study, we demonstrated that less than half of patients recovered from diaphragmatic dysfunction on discharge from the critical care unit. In addition, Borges RC et al. found a significant decrease in the cross-sectional area of the rectus femoris at discharge, compared with the same measurement taken at D+2 of admission to the critical care unit. Finally, the impact of muscle dysfunction on dyspnoea during sepsis and after its resolution is uncertain. Similarly, the impact of muscle dysfunction and dyspnoea on quality of life is unknown. Sepsis is associated with muscle dysfunction of multiple mechanisms. The aim of this study is to assess the immediate and longer-term impact of muscle dysfunction on muscle, dyspnea and quality of life in patients with abdominal sepsis ("Abdominal sepsis" group) and patients with extra-abdominal sepsis ("Extra-abdominal" group). Depending on the location of sepsis, this study will enable us to assess and potentially confirm the preferential effect of abdominal sepsis on diaphragm function.
The main aim of this study is to examine the various effects of continuous methylene blue infusion in septic cancer patients and to compare it with the traditional infusion of noradrenaline in such patients .
The investigators selected patients diagnosed with sepsis who were admitted to the Intensive Care Unit (ICU) of Huai'an First People's Hospital between June 2022 and December 2023, as well as healthy individuals with normal kidney function during the same period, for the research. The investigators collected blood samples from patients with septic shock or sepsis at 6 hours, 12 hours, 24 hours, 48 hours, 3 days, 5 days, and 7 days after diagnosis, and also collected blood samples from the healthy individuals. The blood samples were stored in gel separation vacuum tubes containing heparin as an anticoagulant. The supernatant was removed and stored at -80°C, and the levels of plasma ELA (enzyme-linked immunosorbent assay) were measured using a standardized ELA kit. Additionally, serum NGAL (neutrophil gelatinase-associated lipocalin) and creatinine levels were measured simultaneously. The subjects were divided into three groups based on the KDIGO diagnostic criteria: sepsis-associated acute kidney injury (S-AKI) group, sepsis non-AKI group, and normal control group. Finally, the data were analyzed to determine the early diagnostic value of ELA for S-AKI. Approximately 70 specimens were collected in total.
The goal of this quasi-experimental interventional study is to determine the effectiveness of a multifaceted stewardship intervention in reducing overall vancomycin use in five tertiary care Pediatric Intensive Care Units (PICU). There are two groups of subjects in this study: PICU clinicians/sepsis stakeholders and patients admitted to one of the participating PICUs during the study period. The intervention will at a minimum include: - Implementation of a clinical guideline indicating when vancomycin should and should not be used - Unit-level feedback on overall vancomycin use within and across centers - Clinician education.
Septic shock is associated with substantial burden in terms of both mortality and morbidity for survivors of this illness. Pre-clinical sepsis studies suggest that mesenchymal stem (stromal) cells (MSCs) modulate inflammation, enhance pathogen clearance and tissue repair and reduce death. Our team has completed a Phase I dose escalation and safety clinical trial that evaluated MSCs in patients with septic shock. The Cellular Immunotherapy for Septic Shock Phase I (CISS) trial established that MSCs appear safe and that a randomized controlled trial (RCT) is feasible. Based on these data, the investigators have planned a phase II RCT (UC-CISS II) at several Canadian academic centres which will evaluate intermediate measures of clinical efficacy (primary outcome), as well as biomarkers, safety, clinical outcome measures, and a health economic analysis (secondary outcomes).
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.
The aim of the study is to demonstrate that "frail" patients, defined as having a CFS score greater than or equal to 5, and "severely" frail patients, defined as having a CFS score between [6-7] as defined by Bagshaw et al (14), constitute an independent risk factor (RF) for mortality. In the same way, as an exploratory study, we will try to find out whether clinical frailty constitutes a risk factor for extending the length of hospital stay, the risk of short/medium-term readmission, as has already been demonstrated for patients admitted to intensive care from all causes (15), or for impaired quality of life. The objective is to have a better understanding of the implications and outcomes associated with pre-hospital frailty in young critically ill patients. This analysis will also help to clarify prognoses and contribute to better decision-making on the intensity and proportionality of care, as well as providing better information and helping to manage the expectations of patients and their families in terms of survival prognosis and subsequent quality of life.
The study will enhance the theory in the frame of reference on the efficacy of Ulinastatin while managing sepsis and subsequent morbidity and mortality. Moreover, the present study will explore Ulinastatin's prophylactic role in progression of multiple organ dysfunctions. Furthermore, the study will have the clinical implications in predicting the ICU admitted patient's stay and related cost in the context of new drug. Current researches will explore the new dimensions in Pakistan's healthcare facilities, paving the way of future academics to analyze it in order to enhance healthcare outcomes.
Patients with septic shock with norepinephrine >0.25ug/kg/min were enrolled. Informed consent was obtained for inclusion in the study and random assignment into the combination or norepinephrine group. Contact the research assistant to obtain patient number information and print out the appropriate labels.Notify the ward dispensing nurse to open the experimental drug cassette (placed in the refrigerator 4℃ drug cabinet). Extract the corresponding experimental medication according to the patient label number, dispense it and send it to the ward, label it and hand it over to the bedside nurse to start using it. The time point at which the medication was connected to the patient and activated was recorded as the zero point for the start of the study. The data were monitored according to the time points specified in the study: baseline,0h , 6h, D1, D2, and post-drug withdrawal.