Active clinical trials for "Shock"

Antibiotic dosing in septic shock patients poses a challenge for clinicians due to the pharmacokinetic changes seen in this population. Piperacillin/tazobactam is often used for empirical treatment, and initial appropriate dosing is crucial for reducing mortality. We determined the pharmacokinetic profile of piperacillin 4g every 8 hour in 15 patients treated empirically for septic shock. A PK population model was established with the dual purpose to assess current standard treatment and to simulate alternative dosing regimens and modes of administration. Time above the minimal inhibitory concentration (T>MIC) predicted for each patient were evaluated against clinical breakpoint MIC for Pseudomonas aeruginosa (16 mg/L). Pharmacokinetic-pharmacodynamic (PK-PD) targets evaluated were 100% f T>MIC and 50% fT>4xMIC.

Some studies have shown that antiplatelets agents could reduce organ dysfunction in septic shock in mice and human models. Platelets are actors in immunity and their activation can be complicated by tissue damage with vascular occlusions which can lead to organ dysfunction. Investigators can hypothesize an increase in platelet activation and in leukocyte-platelet aggregates in septic shock.

Introduction: Evidence suggests that sepsis and septic shock severely impair mitochondria and that the resulting mitochondrial dysfunction is related to the severity and outcome of the resulting organ dysfunction. In sepsis mitochondrial abnormalities - biochemical and ultrastructural - have been recognized in multiple organs, including liver, kidney, skeletal and heart muscle tissue and blood cells. Circulating immune cells play an important role in the pathophysiology of sepsis. Stimulation of the immune system alters the energy requirements of immune cells; down-regulation of immune-cell activity has been associated with prolonged sepsis and unfavourable outcome. The aim of the project is to comprehensively investigate changes in mitochondrial function of immune cells in patients with severe sepsis and septic shock. The following main hypotheses will be evaluated: Severe sepsis and septic shock leads to increased energy requirements of immune cells and to an increase in mitochondrial enzyme activities and energy production. Changes of mitochondrial function in human immune cells are associated with alterations in clinical and laboratory markers of severity of sepsis. Prolonged sepsis and unfavourable outcome is associated with down regulation of mitochondrial function. Methods: A total of 30 adult patients admitted to the intensive care unit (ICU) due to severe sepsis or septic shock will be included in the study; 30 healthy volunteers serve as controls. Patients with any type of chronic infectious, inflammatory or autoimmune diseases, after transplantations or receiving immunosuppressive agents are excluded. Collected baseline characteristics include patient demographics, diagnosis and severity of illness scores at the time of admission. Daily collected follow up data include clinical and laboratory parameters of organ dysfunction, use of vasopressors/inotropes, use of antibiotics, use of steroids and results of microbiological cultures/stains. Negative identification and isolation of monocytes, B cells and CD4 T cells will be performed daily from ICU admission to discharge using an antibody-antigen mediated immunomagnetic cell isolation procedure that depletes all blood cells except the specific target cells. Mitochondrial function of immune cells will be assessed by measurement of mitochondrial complex activity for complexes I to IV by a standard titration protocol. Additionally, the levels of pro- and anti-inflammatory cytokines (Interleukin (IL)-1, IL-6, IL-10, TNF-α) will be assessed throughout the stay in the ICU. For comparison mitochondrial function of of monocytes, B cells and CD4 T cells and cytokine levels will be measured in a group of 10 healthy volunteers. Analysis plan: Changes in mitochondrial function of immune cells over time compared to a healthy control group and during the course of severe sepsis and septic shock is the main outcome parameter of this study. Assessed predictors are determined by the severity of the underlying septic condition and include clinical and laboratory evidence for dysfunction of vital organ systems and changes in levels of inflammatory and anti-inflammatory cytokines.

Acute circulatory failure may be related to hypovolemia. Fluid loading increases stroke volume in approximatively half of challenges. Determining fluid responsiveness prevents unnecessary fluid loading. Passive leg raising (PLR) provides a transient increase of 300 ml in venous return for a short time. The measurement of stroke volume (SV) before and after a PLR test allows physician to detect fluid responsiveness, when stroke volume increases is higher than 15 %. Beside thermodilution, the use of non invasive device to measure stroke volume becomes largely employed. Arterial Pressure based Cardiac Output (APCO), provided by the Flotrac/Vigileo system, does not required specific materials nor repeated calibration. The third generation software is believed to be more accurate and more precise for SV measurement. The aim of this study is to test the performance of the Flotrac/Vigileo device in a situation of rapid venous return changes induced by PLR and then by fluid loading. Patients will be classify posteriorly in responders and non responders, according to the magnitude of the fluid loading-induced SV changes measured by transthoracic echocardiography.

The purpose of this study is to evaluate the hypothesis that advanced hemodynamic monitoring results in an earlier detection of circulatory failure in newborn infants

After a basic training to echocardiography, emergency physicians will have to answer simple clinical questions about circulatory failure mechanisms. The objective of the study is to assess the agreement between these answers and those of the expert physician in patients admitted in the emergency department with a circulatory failure due to sepsis or not. Emergency physicians will volunteer to take part in a basic training on echocardiography. The training will include 4 hours of theory, 2 hours of interactive clinical cases and 6 hours of tutored practice at patients' bedside (10 to 15 examinations). The objective of the practice sessions will be to learn the technical grounds of transthoracic echocardiography (TTE), the different views and to identify the anatomical structures. The second part of the study will start after the training. Each eligible patient will be successively assessed by two investigators: one emergency physician recently trained and the expert physician. The echocardiography will be performed as soon as possible in the emergency department before or after the initiation of treatment without delaying it. The order of hemodynamic assessments will be random depending on the availability of the investigators; both assessments will however be performed within 30 minutes. Each investigator will independently read the echocardiography in real time at patients' bedside. They will then answer a limited list of standardized questions using two-choice answers or predefined choices. Finally investigators will choose a therapeutic proposition among a predefined list based on the answers. Only the results of the echocardiography performed by the expert physician will be used in patient management.

CHIC study's purpose is to compare the efficiency, in terms of blood pressure stability, of three changeovers of norepinephrine used routinely in ICU. The three techniques are: Quick change Double pumping Smart infusion pumps

Randomized, controlled, prospective trial, including ICU patients with Sepsis or septic Shock, at the early phase. patients will be randomized in 2 groups regarding the hemodynamic management and catecholamin doses: Group 1: standard hemodynamic goals and catecholamin infusion to achieve: mean arterial pressure > or equal to 65 mmHg and diastolic arterial pressure > ou equal to 50 mmHg within the first 60 minutes. Group 2: personalized hemodynamic goals and catecholamin infusion until normal transcranial doppler: IP<1,2.

VEGF is a key molecule in the control of vascular permeability via interactions with the VEGF-receptor on the endothelial cell. Several authors reported plasma VEGF levels are elevated in sepsis shock and associated with increased mortality (1,2). In septic shock, the main elements of treatment are intravenous fluids, appropriate antibiotics and vasopressors. Some authors observed positive fluid balance is associated with increased mortality rates in patients (3,4). To the best of our knowledge, no studies have shown a correlation between VEGF levels and the fluid balance. The aim of our study was to determine the role of VEGF in capillary leakage and the positive fluid balance in septic shock.

Arthroscopic surgery is effective in treating osteochondral lesions of the talus. However, there are still some patients with postoperative ankle pain. This study aims to investigate the clinical efficacy of shock wave adjuvant therapy in the treatment of postoperative pain caused by cartilage injury of talus after arthroscopy and to provide basis for further popularization and application.