View clinical trials related to Circulatory Failure.
Filter by:Predicting arterial lactate and blood gas values with sufficient accuracy by simply analyzing central venous blood would be interesting in intensive care unit patients in whom the insertion of an arterial catheter or arterial punctures could be avoided. This prospective study aims at externally validating published mathematical models built to predict arterial values from central venous blood analysis.
Effective chest compressions are essential to survival in an arrest patient receiving CPR (cardiopulmonary resuscitation). A challenge in providing effective chest compressions is frequent interruption of compressions. A major cause of a recurrent interruption of chest compressions is pulse checks. Pulse checks are difficult to quickly and accurately perform in the AHA recommended time interval of under 10 seconds for reasons ranging from inexperience to body habitus. Unnecessarily long pulse checks often delay reinitiating chest compressions leading to a fall in perfusion pressure to the coronary arteries lowering the chances of return of spontaneous circulation (ROSC). To potentially solve the issues of evaluating the chest compression effectiveness and minimize the time interval of pulse checks, the authors have constructed a novel device that can be rapidly applied to an arresting patient and evaluate the current state of the circulatory system. The device is called the Rapid Pulse Confirmation (RPC) device. It is designed to applied over a major artery (radial, ulnar, brachial, carotid, and femoral) and detect Doppler shift of red blood cells to gauge red blood cell velocity and rate of pulsation. Feasibility testing on the device was carried out using patients requiring cardiopulmonary bypass. Arrest and return of spontaneous circulation during cardiopulmonary bypass is predictable and provided an ideal environment to test the initial performance of a device meant to detect return of spontaneous circulation. The primary working hypothesis was that there would be no significant difference in time of detection of ROSC between the arterial line catheter and the RPC device at the end of cardiopulmonary bypass. The secondary hypothesis was that there would be no difference in pulse rate reading between the arterial line catheter and the RPC device.
Patients in ICU who suffer from circulatory insufficiency, regardless the cause that require invasive hemodynamic monitoring. The aim of the study is to correlate stroke volume variation which predicts fluid responsiveness with change of the blood pressure after intravenous admission of propofol. This test could become a surrogate of stroke volume variation in patients with contraindications to minimally invasive hemodynamic monitoring.
The objective of this study is to assess the parathyroid hormone serum concentrations and kinetics in critically ill patients admitted to the intensive care unit due to multi-organ failure and undergoing citrate anticoagulation continuous renal replacement therapy.
The objective of the observational cohort study is (1) to deduce whether measurements of peripheral near-infrared spectroscopy (NIRS) (lower limb) associate with the development of organ dysfunction as assessed by daily Sequential Orfgan Failure Score (SOFA) in the Intensive Care Unit (ICU), (2)whether cerebral (frontal) tissue haemoglobin oxygen saturation (StO2) values are associated with delirium in the ICU and (3) the association of frontal and peripheral StO2 with other micro- and macrohemodynamic parameters in this patient group , (4) to deduce the associations between shock, endotheliopathy, disseminated intravascular coagulation (DIC) and tissue perfusion and, last, the feasibility of central and peripheral NIRS monitoring in shock patients in the ICU using the Medtronic INVOS NIRS StO2 appliances. In addition, the investigators target to evaluate (5) the incidence, evolution, and outcome of sepsis-associated DIC, and (6) the associations between a) continuous hemodynamic data, b) laboratory data (such as syndecan-1 (SDC-1), vascular adhesion protein 1 (VAP1), CD73, heparin binding protein (HBP), endostatin, chromogranin, mitochondrial function tests,blood count d-dimer, international normalized ratio (INR), neuron specific enolase and metabolomics data) (7) and study associations of singlenucleotide polymorphisms with developing organ dysfunction and 90-day mortality. To compare the hemodynamic alterations of burn patients to septic patients with the intention to find new ways to monitor and manage hemodynamic and particularly microcirculation in burn patients.
Assessment of intravascular volume status is difficult in critically ill patients. Evidence suggests that only 50% of hemodynamically unstable patients respond to a fluid challenge. Moreover, if cardiopulmonary function cannot compensate for the increase in preload, fluid loading may compromise microvascular perfusion and oxygen delivery and cause or aggravate peripheral and pulmonary edema. Inappropriate fluid expansion can increase morbidity and mortality thus making it important to accurately assess fluid responsiveness in critically ill patients. The volume responsiveness can be defined as a 15% increase in stroke volume (SV) or cardiac output (CO) after a 500-ml infusion. This study tested whether echocardiographic parameters can predict fluid responsiveness in critically ill patients following a low volume 100-ml crystalloid solution infusion over 1 minute.
Extra-corporeal membrane oxygenation (ECMO) life support system can provide both cardiac and respiratory support to patients with heart and respiratory failure. It can save time for these patients to regain organ function or to receive transplantation. Both the investigators' team and Ince et al. from the Netherland found that the microcirculatory dysfunction is more severe in ECMO non-survivors. The next step of research is to find out the key factors that affect microcirculation in ECMO patients. Because the blood flow supplied by the venoarterial ECMO (VA-ECMO) is directly related to macrocirculation, this study aims to investigate the effect of adjustment of VA-ECMO blood flow on microcirculation. The investigators hope that the results of this study can help the medical team to improve the quality of ECMO care.
Objectives: To investigate whether respiratory variations of inferior vena cava diameters (cIVC) predict fluid responsiveness in spontaneously breathing patients with septic acute circulatory failure and irregular heartbeats. Design: Prospective, bicentric study, intensive care units. Patients and measures: Spontaneously breathing patients with sepsis and clinical signs of acute circulatory failure are included. A positive response to fluid loading (FL) is defined as an increase of the stroke volume (SV) >10%. The investigators measured the minimum inspiratory and maximum expiratory diameters of the IVC (idIVC and edIVC) during standardized (st) and unstandardized (ns) breathing. The investigators calculated cIVCst and cIVCns before a 500ml-colloid FL.
Hypovolemia and acute circulatory failure affects more than 60% of patients hospitalized in intensive care or resuscitation. The volume expansion (VE) by fluid replacement therapy is the first treatment improve circulatory function. However, too much VE can be harmful. So, the use of dynamic predictive indicators of fluid responsiveness is recommended in patients with sepsis.In patients with spontaneous ventilation, few studies have evaluated these parameters. In mechanical ventilation, indices based on the respiratory variation of the diameters of vena cava have been studied and validated to predict the response to VE. However there is no similar study in spontaneously breathing patients without ventilatory support. The investigators hypothesize that the respiratory variations in the IVC diameters and femoral artery flow during standardized respiratory cycles are predictive factors of fluid responsiveness in spontaneously breathing patients with sepsis, acute circulatory failure, and regular cardiac rhythm.
The study investigates the influence of a clinically indicated fluid challenge on end-expiratory lung impedance, assessed by electrical impedance tomography (EIT). EIT data will be collected before, during and after infusion of 500 ml of crystalloid solution in mechanically ventilated patients on an operative intensive care unit.