View clinical trials related to Shock.
Filter by:Sensory and balance losses occur in hemiplegic patients. In some patients, sensory and balance rehabilitations may vary depending on the treatment they receive, depending on the treatment. It is a fact that the affected anatomic neuronal regions can cause different damages for each person together with interneuronal relations. This study aims to sense sensation with Extracorporeal Shock Wave Therapy to be applied to the plantar region.
Septic shock is a clinical condition that is defined as a subset of sepsis that causes very high mortality and morbidity. Surviving sepsis campaign guideline states that the target mean arterial pressure should be 65 mmHg and above in septic shock patients. It is known that abdominal pressure increases and perfusion of intra-abdominal organs decreases in septic shock patients. With this study, we aim to investigate the effects of targeted abdominal perfusion pressure (60 mmHg and above) on renal injury, reversal of renal injury, liver functions and ultimately mortality in patients with septic shock.
The sublingual microcirculation is impaired in sepsis and septic shock. Sidestream dark field imaging technology has been developed into a clinical tool to help the clinician assess the microcirculation at the bedside. The ideal resuscitation fluid has not been identified. The investigators aim to use this new bedside technology to establish the microcirculation properties of two popular resuscitation fluids.
This observational, pharmacological, prospective study aims to assess the improvement of ventricular systolic function mediated by norepinephrine (NE) administration in preload non-responders septic shock patients. Left ventricular outflow tract velocity time integral (LVOT-VTI) is an echocardiographic index of ventricular systolic function and it will be measured at different NE dosages.
In the present study, we aim to investigate the effects of dobutamine infusion and/or a single intravenous (IV) dose of the IL-6 antagonist Tocilizumab administered after percutaneous coronary intervention (PCI) to patients with acute myocardial infarction (AMI) presenting < 24 hours from onset of chest pain and an intermediate to high risk of cardiogenic shock (CS) by assessment with the ORBI risk score (≥10 - not in overt shock at hospital admission). Plasma concentrations of pro-B-type natriuretic peptide (proBNP) as a proxy for development of cardiogenic shock (CS) and hemodynamic instability will be sampled for primary endpoint analysis. Effects on clinical parameters, mortality, morbidity as well as specific indicators of inflammation, cardiac function, and infarct size will secondarily be assessed noninvasively. The rationale behind the current study is that inflammatory and neurohormonal responses are associated with subclinical hemodynamic instability in patients with AMI with high risk of CS have worse outcomes. The potentially unstable condition may be targeted pharmacologically as an add-on to existing therapy. This is investigated in patients at elevated risk of CS by sampling biomarkers reflecting the inflammatory and neurohormonal responses, as well as determining effects on patient outcomes and infarct size.
Lactate kinetics will be studied in hospitalized septic patients using a bolus injection of stable isotopically labeled lactate.
Scoring systems (SOFA, APACHE-II etc.) are used to estimate the mortality rates of patients treated in the intensive care unit. . In the scoring systems used, the disfunction level of the organs of the patients is measured. Blood gas analysis is routinely performed in patients whom intubated in the intensive care unit and receiving mechanical ventilation support, and the patient's treatment is optimized according to the results of the examination. The patient's mechanical ventilation settings are regulated by analyzing the Partial Arterial Carbondioxide (paCO2) value in the patient's blood gas result. The difference between the paCO2 value in the blood gas and the End-tidal Carbondioxide (EtCO2) value measured in the mechanical ventilator is 3-5mmHg in normal healthy people, while this difference is seen more in critical care patients. In critically ill patients in the intensive care unit, there is a greater increase in the difference between paCO2 and ETCO2 in cases where mortality is high, such as global perfusion disorder, shock situations, and massive pulmonary embolism, etc. In this study, it was planned to investigate the use of the difference between the paCO2 value in the blood gas taken from the patient and the ETCO2 value measured in the mechanical ventilator to predict the mortality rate of the patient.
Circulatory shock occurs when the supply of oxygen in the tissues decreases, which leads to cell damage and affects about one third of patients admitted to Intensive Care Units (ICU). Cardiac Output (CO) can be defined as the volume of blood ejected by the left ventricle per minute and is a very useful hemodynamic parameter in the monitoring of patients with signs of circulatory shock, since it can help define the etiology and management of such patients. Nevertheless, this parameter is underused in patients treated in Emergency Units, as its measurement usually involves invasive methods and few are available in this scenario. The pulmonary artery catheter is considered the gold standard method for determining the cardiac output, however, since it is an invasive method, in recent decades other devices capable of providing this hemodynamic variable in a less invasive way have been developed. Any method capable of providing CO without the need for pulmonary artery catheter insertion is called minimally invasive CO monitoring. The potential advantages of using these methods include the simplicity of measurements, faster acquisition of hemodynamic parameters and the possibility of implementing a monitoring strategy in places such as emergencies and emergency rooms. The evaluation of these parameters allows a faster determination of the etiology of circulatory shock, which enables the early initiation of goal-guided therapy. It is known that the use of goal-guided therapy proved to be effective in reducing peri- and postoperative morbidity and mortality in patients with high surgical risk; this strategy is also associated with reduced mortality, length of stay in the ICU and on mechanical ventilation in patients admitted to the ICU who are fluid responsive. To date, there is no data regarding the impact of a hemodynamic optimization strategy on patients in the first hours of shock. The investigators aim to assess whether goal-based hemodynamic therapy, through non-invasive hemodynamic monitoring, reduces the incidence of acute renal failure in patients with circulatory shock. A multicenter, randomized, open-label study will be carried out. The study will include patients over 18 years of age with signs of shock (systolic blood pressure less than 90 mmHg and/or mean arterial pressure less than 70 mmHg plus at least one of the following changes: lactate greater than 15 mg/dL, oliguria, neurological changes, and capillary refill time greater than 3 seconds) and who have signed an informed consent form (ICF). Included patients will be randomized in a 1:1 ratio into two groups. The Goal-Directed Therapy Group will be the one in which patients will be monitored by the ClearSightâ„¢ System (Edwards Life Sciences, Irvine, CA, USA) in the first 24 hours after randomization, where the parameters cardiac index (CI), systolic volume (SV), systolic blood pressure (SBP) and mean arterial pressure (MAP) will be used to determine medical management; if the CI is less than 2.2 L/min/m² and the SV less than 35 mL/beat, an aliquot of 500 mL of crystalloid solution will be administered; if the patient presents with CI less than 2.2 L/min/m², associated with SV greater than 35 mL/beat, dobutamine will be initiated; in patients with SBP less than 90 mmHg and/or MAP less than 70 mmHg, associated with SV greater than or equal to 35 mL/beat, norepinephrine will be initiated. In the Conventional Therapy group, the allocated patients will be treated according to the assistant team, where the following parameters will be evaluated: blood pressure, peripheral oximetry, heart rate, respiratory rate, and urine output; patients showing signs of hypovolemia will receive crystalloid solution; those who remain with hypotension refractory to volume replacement will be given vasoactive drugs; those with suggestive of cardiogenic shock will be given inotropic drugs; these procedures will be determined according to the clinical judgment of the assistant team.
This study will examine the differences in microcirculatory function and mitochondrial respiration in patients with shock after cardiovascular surgery.
Whole blood lactate concentration is widely used in shock states to assess perfusion. We aimed to determine if the change in plasma renin concentration over time would be superior to the change in lactate concentration for predicting in-hospital mortality in septic shock patients.