View clinical trials related to Shock, Cardiogenic.
Filter by:The purpose of the program. Formulation of new treatments for heart and pulmonary failure through using organ-replacing technologies. Formulation of a clinical protocol and implementation of treatment methods into clinical practice heart and pulmonary failure using organ-replacing technologies. New methods were created for rehabilitating the function of affected organs after implantation of the LVAD, a total artificial heart, an extracorporeal life-sustaining system will be of great importance, both for Kazakhstan and for states with similar problems of donor organ deficiency, will also improve the effectiveness of surgical treatment and reduce the level of complications and mortality of patients on the extracorporeal life-sustaining system and septic patients.
In the ECMOsorb study the impact of a veno-arterial -ECMO in combination with an extracorporeal cytokine hemadsorption system in critically ill patients with cardiogenic shock is to be examined
Because of dual oxygenation and oxygenator performance (PO2 postoxygenator up to 500 mmHg), hyperoxemia (PaO2 > 150 mmHg) is frequent in veino-arterial ECMO, especially in the lower part of the body, which is mainly oxygenated by ECMO. By enhancing oxygen free radicals' production, hyperoxemia might favor gut, kidney and liver dysfunction. We hypothesize that targeting an extracorporeal normoxemia (i.e. PO2 postoxygenator between 100 and 150 mmHg) will decrease gut, kidney and liver dysfunctions, compared to a liberal extracorporeal oxygenation.
Extracorporeal veno-arterial membrane oxygenation" (ECMO-VA), are used to manage refractory cardiogenic shocks by replacing the failed "heart-lung" block. The Extracorporeal Life Support Organisation guidelines considers that the effectiveness of these techniques must be evaluated on the adequacy of tissue perfusion biomarker, of which is O2 saturation of venous blood found in the pulmonary artery using a Swan-Ganz catheter (SVO2) or in the superior vena cava/right atrium using a central venous catheter (ScVO2). During ECMO support, it can be also measured directly in the venous ECMO cannula (SmVO2). However, due to the difference in tips locations of the venous cannula of ECMO-VA, the central venous catheter and the Swan-Ganz catheter, and rheological issues, the SmVO2, SVO2 and ScVO2 values obtained may be different. Further we hypothesised that the level of admission flow may also affect the correlation between these different variables. The aim of this experimental study is to investigate the concordance of the saturation of venous blood collected from these 3 measurement sites. The primary objectives is to compare the concordance of ScVO2 and the SmVO2, the two more easily and systematically available variables The secondary objectives were : 1. to evaluate the concordance of the 3 variables describing oxygen saturation 2. to analyse the primary objectives during prespecified and calibrated flow changes 3. analyse the association between these 3 variables with prognosis variables (Perfusion index, lactatemia, CO2 veno-arterial differences, SOFA score, SAPS II, successful weaning from the ECMO) 4. analyse in an ancilary study the concordance between SmVO2 measured using blood sample and the value obtained using a continuous monitoring of SVO2 through the circuit.
In the last decade, venoarterial extracorporeal membrane oxygenation (VA-ECMO) has become the first-line therapy in patients with refractory cardiogenic shock. VA-ECMO provides both respiratory and cardiac support, is easy to insert, even at the bedside, provides stable flow rates, and is associated with less organ failure after implantation compared to large biventricular assist-devices that require open-heart surgery. In patients with potentially reversible cardiac failure (e.g. myocarditis, myocardial stunning post-myocardial infarction, post-cardiotomy or post-cardiac arrest), VA-ECMO might be weaned after a few days of support and used as a bridge to recovery. Although considered as the ultimate life-saving technology for refractory cardiac failure, veno-arterial ECMO is still associated with severe complications. Specifically, excessive LV afterload and lack of LV unloading under VA-ECMO might induce LV stasis with thrombus formation, pulmonary edema, myocardial ischemia caused by ventricular distension and ultimately increase mortality. ECMO support also exposes to many complications such as infections, hemorrhage or peripheral vascular embolism. These complications are more frequent with prolonged support and are responsible for significant morbidity and mortality, prolonged ICU and hospital stays and higher costs. Levosimendan, which acts to sensitize myocardial contractile proteins to calcium, improves cardiac contractility without increasing the intracellular calcium concentration. Unlike traditional inotropes such as dobutamine, levosimendan neither increases myocardial oxygen consumption nor impairs diastolic function or possess proarrhythmic effects. It also influences the opening of ATP-dependent potassium channels, including those in vascular smooth muscle cells, leading to coronary, pulmonary, and peripheral vasodilation and antiinflammatory, antioxidative, antiapoptotic, anti-stunning and cardioprotective effects. Additionally, Levosimendan which has a long lasting action (up to 7-9 d), resulting from the formation of active metabolite, may be used as a single 24h perfusion. In recent preliminary studies, the drug was associated with accelerated weaning from VA-ECMO and even improved survival. Therefore, a multicenter randomized trial with sufficient statistical power is needed in refractory cardiogenic shock patients supported by VA-ECMO to test if the early administration of Levosimendan can facilitate and accelerate VA-ECMO weaning, and ultimately translate in significantly less morbidity, reduced ICU and hospital length of stays and associated costs.
The Cardiogenic Shock Working Group is a multicenter registry where we collect de-identified clinical variables from the medical records and follow-up phone calls of shock patients from multiple institutions and centralize this data to a single registry for analysis of clinical outcomes.
Cardiac surgery is at high risk of low cardiac output syndrome after procedure. Monitoring cardiac function, and especially cardiac output, is important to identify cardiovascular dysfunction and to introduce and adjust optimal therapies. Invasive monitor such as pulmonary arterial catheter or transpulmonary thermodilution provide precise measurements but need an invasive access to arterial and central venous route, with possible complications. Cardiographic bioimpedencemetry (Niccomo device, Imedex Corp) allows a non invasive measurement of cardiac output and some other parameters of cardiovascular function. Nevertheless, the reliability of this device has been little studied after cardiac surgery.
Patients with anterior wall AMI treated by PCI will undergo, after successful revascularization of the infarct artery, measurement of the left ventricular pressure, and femoral angiogram. Patients with elevated LV pressure and adequate femoral access will be randomized to standard pharmacological treatment of AMI vs. mechanical unloading by Impella-CP (on top of the standard treatment) for 36-48 hours. LV unloading will be guided by measurement of PCWP by Swan-Ganz catheter. On the day 4-7, and at 3 months after the AMI, the patients will undergo SPECT and 3D-echocardiography to assess ventricular remodeling and extent of the post-infarct scar. The patients will be followed for at least 12 months for the occurrence of heart failure and adverse cardiovascular events. The study will test the hypothesis, whether the LV mechanical unloading after PCI will attenuate post-infarct scar and cardiac remodeling.
Cardiogenic shock (CC) is one of the major challenges of current cardiology. Despite the difficulty of establishing a strict and consensual definition, it is accepted that the CC clinically corresponds to persistent hypotension (systolic blood pressure 90 mmHg for at least 30 minutes or need for vasopressor support) associated with signs of visceral hypoperfusion (confusion, mottling, oliguria, hyperlactatemia), and hemodynamic with a lowered heart index ( 1.8 L/min/m2) despite appropriate or high filling pressures. This definition of the European Society of Cardiology (ESC) masks however the great variability of hemodynamic tables grouped under the term of CC and severity levels, also variable.However, it was suggested that the etiology of CC influenced both its hemodynamic profile and therefore its therapeutic management but also its prognosis in the medium and long term.
Prospective, monocentric open-label observational study for the assessment of acute hemodynamic effects following implantation of the IMPELLA CP cardiac support device