View clinical trials related to Shock.
Filter by:Use Mannose Binding Lectin (MBL) as a biomarker to measure levels of Pathogen- Associated Molecular Patterns (PAMP) during septic shock. This will allow evaluating interest of this biomarker to monitor and manage a septic shock. Consecutive patients admitted for sepsis in Intensive Care Unit Department will be included. This biomarker will be compared to all the parameters monitored usually for these patients in standard care.
Sepsis is defined as a life-threatening event due to a dysregulated immune response to an host. Blood purification techniques may be considered as a therapeutic weapon to front sepsis and septic shock. Haemoadsorption is one of the known blood purification technique that is employed in this study, and it is based on the principle that whole blood, contacting the surface of proper designed sorbent, would be cleared of certain substrates. With haemoadsorption it is possible to de-circulate from bloodstream high molecular weight substances, such as cytokines.In this study Cytosorb® cartridge, based on haemoadsorption principle is applied on septic patients, suffering for acute kidney failure, along with continuous veno-venous haemodialysis (CVVH-D).Microcirculation has a crucial role in the natural history of sepsis. In this prospective observational non interventional study, 10 septic patients with an acute kidney failure that need CVVH are enrolled. The primary endpoint of the study is to verify an improvement in the density of microcirculatory vessels and in the quality of blood flow after exposure to Cytosorb®. These two parameters are well described synthetically by the Perfused Vessel Density (PVD). As secondary endpoints we also want to analyze the modification of microcirculation after haemoadsorption therapy: microvascular blood flow, described by the microvascular flow index (MFI) and peripheral tissue oxygen perfusion during Cytosorb® exposure using near infrared spectroscopy technique (NIRS)
The objective of this study is to survey the type and the amount of non-resuscitation fluids that patients with septic shock receives during their first 5 days of ICU admission.
This is a randomized 1:1 blinded study that evaluate in acute left heart failure-cardiogenic shock patients if ivabradine treatment can reduce pulmonary wedge pressure, without inducing a significant or relevant reduction in cardiac output or increasing the risk of arterial hypotension and with the benefit of allowing a faster titration of heart failure drugs.
Cardiogenic shock is usually defined as primary cardiac dysfunction with low cardiac output leading to critical organ hypo perfusion and tissue hypoxia. Despite progress in the management of cardiogenic shock, mortality remains unacceptably high. This significant mortality, close to 40 %, is partly due to profound alterations of microcirculatory blood flow in cardiogenic shock, leading to multi organ failure, despite restoration of macro-hemodynamic parameters such as blood pressure and cardiac output. The microcirculation is the terminal vascular network of the systemic circulation consisting of microvessels with diameters < 20 μm including arterioles, capillaries, and venules. This part of the circulation is critical as it is responsible for nutrient delivering and oxygen transfer from the erythrocytes in the capillaries to the parenchymal cells to meet their metabolic demands, but it is also the area where water, other gases, hormones and waste products are exchanged. Hence, the evaluation of clinical signs of peripheral hypoperfusion reflecting microvascular perfusion is of interest. We aimed to study these parameters such as skin capillary refill time (CRT), mottling and central-to-toe temperature difference (ΔTc-p) in a cardiogenic shock population. Assessing the prognosis of these microcirculation parameters and their interaction with macrocirculation parameters such as arterial pressure, cardiac index, left ventricular ejection fraction is also the aim of this study. Lastly, looking at the prognostic value of these markers seems interesting.
To investigate changes in the concentration of glucose, lactate, pyruvate and glycerol in the extracellular fluid of the skeletal muscle following Dexmedetomidine administration in patients with septic shock.
Veno-arterial extra-corporeal membrane oxygenation (VA-ECMO) is indicated as a haemodynamic rescue strategy in decompensated acute or chronic heart failure presenting as cardiogenic shock. It has been used across aeitologies including post-myocardial infarction, dilated cardiomyopathy, acute myocarditis and in post-cardiotomy shock. VA ECMO has a number of effects on the circulation including improved end-organ perfusion and possibly improved coronary perfusion, and is a bridge to further therapies including permanent advanced mechanical circulatory support, cardiac transplantation and to cardiac recovery. Left ventricular assist devices (LVADs) provide long-term mechanical circulatory support and also profoundly mechanically unload the left ventricle. Multiple clinical studies have documented cardiac recovery using LVAD therapy, with a rate between 10-60% in selected populations. A large body of basic science has documented the pivotal role of mechanical load in determining ventricular contractile performance across species. Therefore both clinical data and basic laboratory studies support the notion that profound ventricular unloading may result in improved cardiac performance through a variety of mechanisms ranging from triggered de novo cardiomyocyte proliferation, subcellular calcium handling reverse remodeling, changes to the extracellular matrix of the heart, reverse remodeling of the neurohormal milleu, amongst many others. One of the major deficiencies of peripheral VA-ECMO is its lack of left ventricular unloading, with associated pulmonary congestion, which can derail clinical improvement and hamper cardiac recovery. Indeed, percutaneous VA-ECMO increases LV afterload due to the retrograde blood flow, and because of the lack of venting, there may be progressive LV distension. These conditions can result in a congested, pressure-overloaded ventricle, even in the absence of echocardiographic ventricular distension. This may be ameliorated with the addition of ventricular mechanical unloading using percutaneous therapies including the percutaneous left ventricular device, Impella CP. On the platform of VA-ECMO, the addition of an Impella device to reduce ventricular loading results in improved survival and recovery of ventricular performance in the setting of cardiogenic shock. In a number of small studies, the use of additional means to unload the ventricle, principally Impella, results in cardiac recovery and less ventricular distension. In chronic heart failure, direct ventricular unloading is critical to cardiac recovery. The objective of this randomized study is to determine whether the addition of early direct ventricular unloading using Impella CP leads to higher rates of cardiac recovery, defined as survival free from mechanical circulatory support, heart transplantation or inotropic support at thirty days. This study will also examine the clinical, biochemical, echocardiographic and radiologic effects of VA ECMO with and without the addition of Impella CP to directly vent the left ventricle to address adjunct important questions such as the effects on pulmonary congestion.
The objective of this study is to evaluate the effect of LJPC-501 infusion on mean arterial pressure (MAP) or reduction in sum norepinephrine (NE) equivalent dosing, at Hour 2 after the start of LJPC-501, in pediatric patients who remain hypotensive despite receiving fluid therapy and vasopressor therapy. In addition, this study will evaluate the safety and tolerability of LJPC-501 in pediatric patients, the change in MAP over 24 hours after the start of LJPC-501, the change in serum lactate concentrations, and the change in Pediatric Logistic Organ Dysfunction (PELOD) scores.
To evaluate the impact of enteral nutrition on microaspiration of gastric content and pharyngeal secretions
The aim of this study is to determine the effects of fluid alternations, hemodynamic changes, mechanical ventilation, pharmacologic agents, positional changes, and comorbidities on the Peripheral Intravenous waveform Analysis (PIVA) signal.