Active clinical trials for "Shock"

Septic shock is a common reason for admission to intensive care units and severe infections are responsible for 6 million deaths a year worldwide. Fluid management appears to be a major issue in resuscitation and particularly in septic shock, where generalised oedema is almost systematic and is a major factor in poor prognosis during sepsis. The formation of oedema corresponds to an imbalance, according to Frank-Starling's law of the heart, between the vascular compartment and the interstitial compartment, which is composed of the interstitial liquid and an extracellular matrix. This extracellular matrix consists essentially of a network of collagen and fibroblast fibres. Even though all of the plasma in the body transits through the interstitium in 24 hours and desite its major importance in the microenvironment and intercellular communication, the interstitial compartment has not been fully described. In oncology, interstitial tissue seems to contribute to tumour growth through changes in matrix composition and pressure in the interstitium. This pressure actively contributes to the regulation of transcapillary filtration, and thus to the oedema and hypovolemia observed during sepsis. In usual conditions, the fibroblasts exert a tension on the collagen fibres of the matrix via integrin Beta-1 (ITGB1). This tension is released under the action of pro-inflammatory mediators, resulting in negative pressure which potentiates the formation of oedema. It has been shown in an endotoxemia model that there is a thousandfold higher concentration of ITGB1 in the interstitium compared to the vascular compartment, suggesting a local secretion of this cytokine. The alteration of the extracellular matrix could also play a role in the perpetuation of oedema during septic shock. Considered as an organ in its own right, interstitial tissue is far from playing a passive role between the vascular compartment and the cells. The hypothesis is that interstitial fluid analysis could improve our understanding of the physiopathology of sepsis, in particular on the alteration of the mechanisms of fluid movement regulation, which remains very poorly understood while being closely associated with prognosis in patients with sepsis.

Sepsis is a life-threatening condition, caused by a systemic infection. It is particularly dangerous in already fragile populations and needs to be identified quickly to be treated as fast as possible, as discussed during the 2016 sepsis consensus and highlighted by the 2021 Surviving Sepsis Campaign. Yet, while there are scores to quickly identify patients who are at an increased risk of mortality (namely quick-SOFA, q-SOFA), these scores are also highly unspecific and cannot guarantee an adequate risk stratification. Therefore, it would be extremely valuable to further stratify mortality risk in patients who present to the emergency medical evaluation, especially those who present with stable hemodynamics but are at increased risk of decompensation during hospital stay. Furthermore, in the emergency room, it is sometimes impossible to re-evaluate patients regularly, thus, it would be important to immediately identify high-risk patients. Unfortunately, at the moment, there is no consensus. Through this study, the investigators will try to identify ultrasound parameters and biochemical markers which can be obtained during the first visit in the emergency room (ER) and that allow a quick risk stratification of patients with sepsis. The rationale of this study is to improve early identification of septic patients who are at risk of rapid deterioration in the course of their permanence in the ER and the hospital wards in general. The investigators selected a number of clinical, laboratory and bedside ultrasound parameters which have been previously shown to be correlated with mortality in sepsis, and will seek to identify which among these parameters best correlates with prognosis when acquired in the very first minutes of a patient's arrival in the ER. The objective would be to analyse these parameters and eventually to propose a new early sepsis score which might help the emergency physician to better tailor its efforts and clinical resources to the most sick patients.

The purpose of this study is to assess the effect of a higher mean arterial pressure on renal function for patients with shock and elevated central venous pressure.

Fluid management is one of the key issues in the initial management of septic shock (SS). Fluid overload and hypovolemia have been associated with increased mortality in several trials. Transthoracic echocardiography (TTE) and lung ultrasound are recommended for haemodynamic assessment in critically ill patients. However, the benefit of hemodynamic optimisation using echography has not been yet evaluated. The purpose of this multicenter, controlled, randomized trial is to assess the impact of an echocardiographic algorithm of hemodynamic optimization on fluid management in septic patients during the first 4 days of therapy.

Ketamine is a commonly used drug for sedation and induction of anesthesia in patients with shock and/or cardiac dysfunction. Ketamine is characterized by its cardiovascular stimulatory effect due to increase release of endogenous catecholamines. On the other hand, laboratory data on the isolated human myofibers suggest that ketamine had a direct myocardial depressive effect; accordingly, many experts believe that ketamine might have a negative hemodynamic effect in catecholamine depleted patients such as critically ill patients. In critically ill patients, there are contradicting results for the effect of ketamine on the hemodynamic profile and there is paucity of clinical data about the effect of ketamine on cardiac contractility and cardiac output (CO). Cardiac output is the primary determinant of global oxygen delivery to organs and maintaining stable CO in critically ill patients is at most importance to avoid further organ damage in such patients. Therefore, this study is designed to evaluate the effect a single bolus of ketamine on CO in patients with septic shock in comparison to fentanyl bolus.

The study aims to investigate the safety and efficacy of the Synchronized Cardiac Support treatment wit the icor kit and the Xenios console with modified sensor box ECG and Software Version 3.2.4

Over-resuscitation including fluid overload has been associated with increased morbidity (prolonged duration of organ failure) and mortality in septic shock. "One-size-fits-all" resuscitation strategies may increase septic shock mortality. However, clinical studies on individualized resuscitation are lacking. Hemodynamic phenotyping may allow to individualize septic shock resuscitation. The ANDROMEDA-SHOCK trial found that a simple clinical and bedside CRT-targeted resuscitation reduces organ dysfunction and 28-day mortality in septic shock. The current study will examine the hypothesis that a CRT-targeted resuscitation based on hemodynamic phenotyping considering within an decision tree usual bedside clinical parameters such as pulse pressure, diastolic blood pressure, fluid responsiveness and cardiac performance can further decrease mortality in septic shock as compared to usual care.

Haemodynamic insufficiency after birth is seen commonly in babies born prematurely and is associated with adverse outcomes. In current clinical practice, a combination of blood pressure and clinical signs is used to guide therapy. However, blood pressure is a poor surrogate of systemic and organ (brain) blood flow distribution during transitional circulation. This state is characterised by increased peripheral vascular resistance and increased afterload causing myocardial depression and impaired blood flow distribution in spite of 'normal' blood pressure. Echocardiography-Doppler (Echo-D) measurement of superior vena cava (SVC) flow has been proposed as a more clinically relevant marker of circulatory impairment shortly after birth than systemic hypotension. When there is low SVC flow, several small-scale clinical trials have suggested dobutamine as the optimal therapeutic option. However the associations between SVC flow and short- and long- term outcomes are not strong enough to allow SVC flow alone to be the basis for the inclusion of patients into a confirmatory trial to demonstrate the efficacy and safety of dobutamine. NeoCirc-001 - The primary objective is to answer some important questions required for the design of a subsequent placebo-controlled trial (NeoCirc-003), which will evaluate the effectiveness of a new neonatal formulation of dobutamine to treat haemodynamic insufficiency in the first 72 hours after birth in babies born at less than 33 weeks' gestation. Observational data will be collected from this population with a view to determining the degree to which diagnostic measures influence treatment decisions. The primary outcome is death or worst cranial ultrasound (CUS) appearance at or before 36 weeks' gestation. NeoCirc-001A - The primary objective is to estimate the elimination half-life, and consequently the time to steady-state of dobutamine in extremely premature neonates. NeoCirc-001B - The primary objective is to construct a population pharmacokinetic pharmacodynamic model that will be validated using samples collected during the confirmatory trial (NeoCirc-003).

The main purpose of this study is to determine the effects of controlling the heart rate of patients with septic shock using an intravenous medication called esmolol.

The primary objective of this study is to assess reasonable safety and performance of the HeartMate PHP to provide hemodynamic support for up to 72 hours in patients with cardiogenic shock requiring stabilization.