View clinical trials related to ARDS.
Filter by:Acute respiratory distress syndrome (ARDS) is a severe form of acute respiratory failure. The therapeutic management is currently based on the treatment of the cause of ARDS, and on mechanical ventilation with positive expiratory pressure (PEEP). Another strategy that could be used is Time Controlled Adaptive Ventilation (TCAV) method based on ventilation using the airway pressure release ventilation (APRV) mode. Electrical impedance tomography (EIT) allows individual, non-invasive, real-time, bedside, radiation-free imaging of an anteroposterior section of the right and left lungs, with global and regional dynamic analyses. The aim of the study is to evaluate EIT for PHigh titration of TCAV.
This is a single-centre prospective observational study aimed to determine if Pocc (occlusion pressure at 100 msec), TCe ( Expiratory time constant ), Mechanical Stress power, Ventilatory ratio and C20/Cdyn would predict outcomes in patients with moderately severe ARDS (Acute respiratory distress syndrome), who are on mechanical ventilation
The RADAR-Canada trial is a pilot RCT undertaken to assess the acceptability of, compliance with, and biologic consequences of a deresuscitation protocol designed to expedite the removal of excess interstitial fluid in patients who remain in a positive fluid balance following admission to an intensive care unit (ICU).
During cardiopulmonary bypass (CPB), oxygenation of the patient on the pump can be left completely under pump control, or the lungs can be ventilated with low tidal volume to reduce atelectasis. In recent years, the concept of mechanical power has been used to determine the extent of ventilator-related lung damage. This concept of mechanical power, by which the energy transferred by the ventilator to the lungs can be calculated, will be measured at certain intervals in CPB surgery patients on the pump and compared between the two groups. The investigators aimed to investigate the effect of two different ventilation methods on mechanical power and its relationship with postoperative pulmonary complications.
The objective of this research is to utilize respiratory effort parameters as a tool to assist in adjusting sedative drug levels for patients undergoing mechanical ventilation in the intensive care unit, in comparison to the conventional usual care approach.
Septic shock (SS) is a life-threatening condition resulting from excessive inflammatory response to bacterial, viral or/and fungal infections. It is associated with dysregulation of the immune system, activation of immune cells, and massive release of cytokines, commonly known as the cytokine storm (CS). The clinical manifestations of SS depend on the initial site of infection. However, the classic symptoms are associated with severe dysfunction of the respiratory and cardiovascular systems, which are observed from the early phase. Respiratory insufficiency frequently requires different forms of oxygen supplementation, including mechanical ventilation and even extracorporeal oxygenation. The severity of respiratory and other organ dysfunction depends on the inflammatory response to the infection and circulating toxins, which correspond to excessive cytokine release. In the past years, several studies documented that reduction of SS-related inflammatory response and CS improved organ function and alleviated the clinical course of SS. Unfortunately, an effective strong anti-inflammatory without side effects medications has not yet been found. Therefore, the use of natural anti-inflammatory and antioxidant substances seems very promising. Xanthohumol (Xn) is a natural prenylated chalcone extracted from the female inflorescences of hop cones (Humulus lupus) and possesses strong anti-inflammatory and antioxidant properties. It is widely used as a supplement to diet. Xanthohumol inhibits CS and has been showed to be an effective medication for reducing the severity of lung injury. It has been documented that Xn inhibits proinflammatory pathways in a different manner. A decrease in cytokine production and release can affect endothelial function and correct inflammatory-related vascular hyperpermeability, reducing uncontrolled water shift to extravascular space and then tissue edema. Clinical observation showed that administration of Xn alleviated clinical course, improved respiratory function, and reduced mortality in critically ill COVID-19 patients. Xanthohumol is safe and well tolerated by humans, and no adverse effects have been reported yet. Based on its strong anti-inflammatory and antioxidative properties, it can be speculated that the use of Xn can effectively reduce the inflammatory response and improve the clinical course in SS patients.
Patients who are very ill either due to a severe infection, major organ injury, trauma or a major operation may require significant support with devices such as a dialysis machine for the kidneys or Extracorporeal Membrane Oxygenation (ECMO) for the heart and lungs. This is often due to a reaction of the body to the insult which is termed inflammation. The investigators would like to assess if the use of a device that can remove the agents driving this reaction can lead to a quicker recovery form the illness. The device is a blood filter called HA380 and it would be connected to either the dialysis machine or the ECMO circuit. The investigators want to assess the feasibility of conducting a study with the HA380 column. We will also evaluate if the use of the HA380 column has an effect on the time spent on dialysis or ECMO, time spent on the breathing machine, time spent requiring drugs to support blood pressure and time spent in the intensive care unit.
Patients presenting to the emergency department (ED) may require breathing support with machines depending on the condition. Throughout the breathing support, the settings on the breathing machines will be tailored to the patient's requirements. These settings are manually adjusted by trained physicians. Currently, there are machines which can automatically change the settings based on real-time specific information obtained from the patient. This study aims to compare the use of machines which require manual adjustments (open-loop conventional ventilators) and machines which can automatically change the settings (closed-loop automated ventilators). Patients will be carefully selected to ensure no harm is caused whilst delivering the best care. This study will look into the duration when patients are receiving optimum settings and levels of oxygen and carbon dioxide in the blood. The outcomes of this study would allow us to identify methods to improve patient care.
This study to apprehend the relation of SpO2/FiO2 to PaO2/FiO2 in ARDS patients.
The purposes of our study are to: 1) determine the incidence of paradoxical response to chest wall loading in mechanically ventilated patients; 2) identify sub-populations in which it is most likely to occur (e.g., severe ARDS); and 3) standard the bedside procedure for demonstrating this physiology.