Active clinical trials for "Respiratory Insufficiency"

APRV mode of ventilation will result in an improved partial pressure of arterial oxygenation/ fraction of inspired oxygen (P/F ratio) on day 3 of mechanical ventilation. Sub hypotheses: APRV will be associated with a reduced amount of sedation used during the ICU stay in patients with respiratory failure. APRV will be associated with a reduction in the amount of vasoactive medication used for blood pressure support in patients with respiratory failure.

Most patients admitted to intensive care units require mechanical ventilation. Weaning from assisted/controlled ventilation begins when we recognize that the patient has recovered adeguately from acute respiratory failure. If weaning is delayed, costs are increased, as are the risks of nosocomial pneumonia, cardiac-associated morbility, and death. On the other hand, weaning too soon often results in reintubation, which is associated with complications similar to those of prolonged ventilation. The aim of this trial is to establish an evidence-based approach to weaning and to determine when a patient is ready to be weaned from mechanical ventilation, and what is the best weaning technique.

The purpose of this study is to determine whether two modes of artificial (i.e. mechanical) ventilation have an impact on patient synchrony with the ventilator (breathing machine) and on the patient's work of breathing.

A new artificial lung device has been developed that potentially provides added support to mechanical ventilation for severely damaged lungs. The Hattler Respiratory Assist Catheter is designed to provide gas exchange (deliver oxygen and remove carbon dioxide) for a period of up to 7 days, providing more time for the lungs to improve. Extrapolating from large animal data, the hypothesis is that the Hattler Catheter will be capable of providing 30% to 40% of the basal requirements of carbon dioxide exchange in a manner that is dependable and reproducible.

Patients who develop respiratory failure require the assistance of mechanical ventilation while recovering from their respiratory injury. For example, patients that are affected by COVID-19 can develop such severe respiratory failure that they are unable to breathe on their own and therefore require the assistance of a mechanical ventilator. A Bronchoscope is a tool that can be used to visualize the inside of the lungs to aid in further diagnosis and delivery of therapeutic agents in patients with respiratory disease or failure. However, bronchoscopy can cause air to leak from the patient's lungs into the room due to a poorly designed adapter that is required to facilitate the introduction of the bronchoscope into the lungs. This leak can lead to the patient losing oxygen during the procedure which can be harmful to the patient and delay or limit recovery. Additionally, the air that leaks can lead to the spread of bacteria/viruses into the ambient air, which can contaminate the intensive care unit and expose other patients and healthcare workers to harmful pathogens. This was highlighted most recently during the COVID-19 pandemic where national guidelines limited the use of bronchoscopy in patients affected by the virus due to concerns about spreading the virus within the hospital and to the healthcare workers. In this study, the investigators will evaluate the efficacy of a novel adapter that avoids air leakage during bronchoscopy. Patients with respiratory failure on mechanical ventilation who require bronchoscopy will be randomized into two groups (groups A and B). These patients will be identified by the intensive care unit physician. Informed consent will be obtained from the patient's health care proxy. Patients in group A will undergo bronchoscopy using the standard commercially available adapter. Patients in group B will undergo bronchoscopy using the newly developed bronchoscope adapter. The efficacy of the bronchoscopy adapter will be evaluated by analyzing ventilator-associated parameters as well as the level of air contamination after the procedure. A bronchoscope adapter that limits air leak would have significant value in improving patient outcomes who receive bronchoscopy. Additionally, this would allow bronchoscopy to be more readily performed in patients with potential bacterial/viral pathogen spread. Primary objective: Determination of equivalency or superiority of the new "leak-free adapter" compared to the standard commercial adapter to enable safe bronchoscopy in ventilated patients requiring bronchoscopy. Secondary objective: To determine if the adapter provides improved ventilation during bronchoscopy by limiting tidal volume loss and pathogen aerosolization.

The purpose of the COVIDNOCHE trial (HFNO versus CPAP Helmet Evaluation in COVID-19 Pneumonia) is to evaluate the comparative effectiveness of standard care non-invasive respiratory support (helmet CPAP versus HFNO) for acute hypoxemic respiratory failure from COVID-19 pneumonia on ventilator-free days (primary outcome) and other clinical outcomes measured up to 90 days.

Heparin is a blood thinner used to prevent blood clots in patients on a form of life-support called ECMO. Heparin can cause bleeding - the most common complication of ECMO. New materials used in ECMO machines may help prevent clots - this could allow the use of lower doses of heparin which might reduce the risk of bleeding. Our study will compare low dose to high dose heparin in patients on ECMO. We think low dose heparin may be adequate to prevent clotting, but may cause less bleeding and be safer for patients.

High-flow nasal oxygen (HFNO) therapy is an upcoming and beneficial modality for patients with acute hypoxemic respiratory failure (AHRF). To evaluate whether early use of HFNO in pneumonia patients with (AHRF) can reduce the need for invasive ventilation.

Ninety adult patients from both gender, with acute respiratory failure, intubated and mechanically ventilated. Their ages ranged from 50 to 70 years. They were selected from Intensive Care Unit (ICU), Department of Chest Diseases, Cairo University Hospitals. They have randomly assigned into three equal groups. Group (A): trained by threshold IMT device plus routine physical therapy. Group (B): trained by adjusting MV trigger sensitivity plus routine physical therapy. Group (C): only received routine physical therapy. (Negative inspiratory force NIF, arterial blood gases, P/F ration, respiratory rate RR, tidal volume VT, and rapid shallow breathing index RSBI) were measured before the study and at the end of the study (just before weaning for successfully weaned patients, or on the 10 day of intervention for failed weaning patients).

Stable patient with ARF spontaneously breathing light sedation (not too awake but with stable breathing pattern) and EAdi >8 uV. Four modes of mechanical ventilation were performed under different support level for the measuring of EAdi, air way pressure and other parameters.