View clinical trials related to Shock, Cardiogenic.
Filter by:This pilot study is designed to investigate the effect of inhaled nitric oxide on cardiac, pulmonary artery, and systemic hemodynamics at various time points during venoarterial extracorporeal membrane oxygenation (VA-ECMO) support. Patients who have been initiated on VA-ECMO will be invited to participate. Inhaled nitric oxide (iNO) will be used early after VA-ECMO cannulation (once consent is obtained). After baseline hemodynamic, biochemical, and echocardiographic parameters are assessed, iNO will be initiated and all parameters will be reassessed after 30 minutes and 6 hours. Inhaled nitric oxide will then be discontinued and all parameters repeated. At the time of VA-ECMO weaning (timing determined by clinical team), iNO will be reinitiated with repeat assessment of hemodynamic, biochemical, and echocardiographic parameters both prior to the wean and after the wean (whether successful or not).
This is a prospective, randomized, non-blinded, single-center efficacy study of acutely decompensated heart failure patients with reduced ejection fraction (HFrEF), low cardiac index (<2.2) as determined by pulmonary artery catheter (PAC) who have been hemodynamically stabilized and ready for transition to oral vasodilator therapy at the discretion of the clinician. The investigators would like to accomplish the following objectives with this study: 1. Establish the superiority of an upfront initiation strategy for sacubitril-valsartan at maintaining patients on ARNI therapy at one-month follow-up compared to usual care. 2. Establish the safety of initiating sacubitril-valsartan in an intensive care setting 3. Characterize the hemodynamic effect of sacubitril-valsartan on patients with low cardiac output 4. Expand the population of hospitalized patients that can be initiated on ARNIs and thus facilitate prior to hospital discharge patients who are on optimal goal-directed medical therapy (GDMT) for heart failure
Prospective combined clinical validation of an algorithmic calculated mean systemic filling pressure (Pms-Nav) with the gold standard for Pms (Pms calculated from venous return curves during inspiratory hold procedures with incremental airway pressures; Pms-Insp). Secondary correlation between invasive cardiac output measurement versus 3D TOE and carotid echo doppler measured cardiac output.
Data from case series and large retrospective trials suggest that the early treatment of cardiogenic shock AMI patients with the association of VA-ECMO and IABP may significantly decrease mortality, which is still unacceptably high nowadays (40-50% at 30 days). An important benefit for the patients randomized to the ECMO arm is expected and the risk-to-benefit ratio is expected to be in favor of the experimental treatment arm.
Extracorporeal life support (ECLS), also known as extracorporeal membrane oxygenation (ECMO), is an extracorporeal technique of providing effective cardiac and respiratory support to patients with lungs and/or heart failure. There was a growth in ECLS cases, centers, and center scale in China during the past decade. This multi-center registry was conducted by Chinese Society of Extracorporeal Life Support. The objectives were to investigate China statistics of ECLS and to evaluate the short-term and long-term outcomes of patients with ECLS.
The goal of this study is to describe the use of ECMO (Extracorporeal Membrane Oxygenation) in the pregnant or peripartum patient.
The investigation of patient characteristics and prognostic factors of the patients presented with cardiogenic shock (CS) will guide us to identify the better management strategy for these critically ill patients. Mechanical circulatory support (MCS) may improve the prognosis of some of severe subset of CS patients. The better understanding of the indications of initiation and weaning of MCS will improve the prognosis of critically ill CS patients.
Cardiogenic shock is a condition of low cardiac output that represents the end of a progressive deterioration of cardiac function. The main cause is ischemic heart disease but there are several causes of non-ischemic nature including sepsis. Sepsis is characterized by a picture of organ dysfunction caused by an altered response of the body to an infection. Its most serious form is septic shock, defined as a picture of sepsis in which the underlying abnormalities in the cardiovascular system and cellular metabolism are such as to increase mortality. An organ failure correlates directly with the function of others and this interdependence is especially evident when a cardiovascular failure is established. 3 Cardiac dysfunction in sepsis can be defined as that of a syndrome characterized by low cardiac output not related to myocardial ischemia. The use of levosimendan in cardiogenic shock during sepsis was first described in a 2005 case report. Since then there have been small studies and other case reports that have shown improvements in right and left ventricular contractility, ventricular coupling, cardiopulmonary performance, global oxygen transport, renal and splanchnic perfusion when compared to dobutamine and placebo. Other beneficial effects of this drug have emerged, including an anti-inflammatory, antioxidant and antiapoptotic action with a possible protection from ischemia-reperfusion damage. The present study aims to evaluate the correct use of levosimendan, after the occurrence of cardiogenic shock on a low cardiac index has been ascertained, with the aim of weaning from inotropic drugs in infusion.
The project's main goal is to collect baseline clinical and procedural data as well as to assess clinical outcomes for all patients undergoing ECMO or Impella implantation at all included sites. All patients undergoing ECMO and/or IMPELLA implantation will be prospectively registered. Device use is according to the decision of the treating physician and independent of this registry.
Veno-arterial extra-corporeal membrane oxygenation (VA-ECMO) is used as a rescue strategy for patients in acute hemodynamic deterioration such as cardiogenic shock and cardiopulmonary arrest with severe pulmonary congestion. VA ECMO is the fastest way to stabilize a patient with cardiogenic shock and improve end-organ perfusion. However, one of the major disadvantages of peripheral VA-ECMO is that it provides no left ventricular unloading and increases left ventricular (LV) afterload secondary to the retrograde blood flow. Therefore, LV wall tension and myocardial oxygen demand may actually increase in the setting of VA ECMO. The Impella® device is a miniature rotary blood pump which can be inserted retrograde across the aortic valve. In this configuration, it withdraws blood from the LV and ejects it into the ascending aorta. It unloads the left ventricle, reducing LV wall tension and myocardial oxygen demand and increasing myocardial blood flow. The Impella® 5.0 is an FDA approved pump designed for intermediate support in patients with severe, cardiogenic shock. The axillary positioning allows for early extubation and ambulation and is more stable than groin placement. In present practice, the decision to place an Impella® pump in VA-ECMO patients is based on the perceived need for direct LV unloading or when a bridge device is required to transition off ECMO support. Patients with peripheral VA ECMO are managed with inotropic agents at the beginning and once patients develop pulmonary edema mechanical LV unloading is considered electively. The advantage of LV unloading with Impella® has been demonstrated in recent studies. We also reported that concomitant implantation of Impella® with VA ECMO for LV unloading resulted in improved survival and recovery of ventricular performance in patients with cardiogenic shock. Compared to delayed elective LV unloading, early LV unloading could lead to decreased pulmonary edema, improved oxygenation delivery to the myocardium, increased chance of LV recovery and improved survival. The objective of this prospective study is to assess whether the early direct ventricular unloading using axillary Impella® leads to higher rates of cardiac recovery, defined as survival free from mechanical circulatory support, heart transplantation or inotropic support at thirty days, compared with the conventional, elective placement of Impella® after developing significant pulmonary congestion.