View clinical trials related to Respiratory Insufficiency.
Filter by:COVID-19 is a respiratory illness caused by SARS-CoV-2 with a range of symptoms from mild, self-limiting respiratory tract infections to severe progressive pneumonia, multiorgan dysfunction and death. A portion of individuals with COVID-19 experience life-threatening hypoxia requiring supplemental oxygen and mechanical ventilation. Management of hypoxia in this population is complicated by contraindication of non-invasive ventilation and limitations in access to mechanical ventilation and critical care staff given the clinical burden of disease. Positional therapy is readily deployable and may ultimately be used to treat COVID-19 related respiratory failure in resources limited settings; and, it has been demonstrated to improve oxygenation and is easy to implement in the clinical setting. The overall goal of this randomized controlled trial is to establish the feasibility of performing a randomized trial using a simple, minimally invasive positional therapy approach to improve hypoxia and reduce progression to mechanical ventilation. The objectives are to examine the effectiveness and feasibility of maintaining an inclined position in patients with confirmed or suspected COVID-19 associated hypoxemic respiratory failure. The investigators hypothesize that (1) oxyhemoglobin saturation will improve with therapy, (2) participants will tolerate and adhere to the intervention, and that (3) participants who adhere to positional therapy will have reduced rates of mechanical ventilation at 72 hours. If successful, this feasibility trial will demonstrate that a simple, readily deployed nocturnal postural maneuver is well tolerated and reverses underlying defects in ventilation and oxygenation due to COVID-19. It will also inform the design of a pivotal Phase III trial with estimates of sample sizes for clinically relevant outcomes.
Trial design: Prospective, multi-centre, randomised, pragmatic, double blind trial Methods: Participants: Adult (>18 years) within 24 hours of admission to intensive care unit with proven or suspected COVID-19 infection, whether or not mechanically ventilated. Exclusion criteria: symptoms of febrile disease for ≥1 week, treatment limitations in place or moribund patients, allergy or intolerance of any study treatment, incl. long QT syndromes, participation in another outcome-based interventional trial within last 30 days, patients taking Hydrochloroquine for other indication than COVID-19, pregnancy. Interventions: Patients will be randomised in 1:1:1 ratio to receive Hydrochloroquine 800mg orally in two doses followed by 400mg daily in two doses and Azithromycin 500 mg orally in one dose followed by 250 mg in one dose for a total of 5 days (HC-A group) or Hydrochloroquine+ placebo (HC group) or placebo + placebo (C-group) in addition to best standard of care, which may evolve during the trial period but will not differ between groups. Objective: To test the hypothesis that early administration of combination therapy slows disease progression and improves mechanical-ventilation free survival. Outcomes: Primary outcome: Composite percentage of patients alive and not on end-of-life pathway who are free of mechanical ventilation at day 14. Secondary outcomes: Composite percentage of patients alive and not on end-of-life pathway who are free of mechanical ventilation at day 14 in the subgroup of patients without the need of mechanical ventilation at baseline. ICU-LOS D28 and D 90 mortality (in hospital) Tertiary (exploratory) outcomes: Viral load at D7 of study enrolment (No of viral RNA copies/ml of blood), proportion of patients alive and rtPCR negative from nasal swab at D14, Difference of FiO2 requirement and respiratory system compliance between day 0 and 7. Randomization: In 1:1:1 ratio and stratified according to study centre and patients age (cut-off 70 years) Blinding (masking): Patients, treating clinicians, outcome assessors and data analyst will be blinded to study treatment allocation. Unblinded study pharmacist or research nurse will prepare investigational products.
COVID-19 may cause severe pneumonitis that require ventilatory support in some patients, the ICU mortality is as high as 62%. Hospitals do not have enough ICU beds to handle the demand and to date there is no effective cure. We explore a treatment administered in a randomized clinical trial that could prevent ICU admission and reduce mortality. The overall hypothesis to be evaluated is that HBO reduce mortality, increase hypoxia tolerance and prevent organ failure in patients with COVID19 pneumonitis by attenuating the inflammatory response.
Randomized clinical trial in which the main objective is to compare High Flow Nasal Cannula (HFNC) versus the standard respiratory care in the alleviation of dyspnea perception in patients with do-not-intubate (DNI) order. This is a pragmatic study that will take place in 10 Brazilians ICU facilities which are already participating in the main study RENOVATE NCT03643939.
A pilot multicentric randomized controlled study investigating the feasibility of recruiting 50 pulmonary fibrosis patients in acute respiratory failure within18 months. Additionally, exploratory efficacy and safety outcomes will be evaluated.
Elderly patients residing in nursing homes are particularly at risk of experiencing urgent medical problems needing admission to the Emergency Department (ED). This circumstance contributes to ED overcrowding, increases the risk of ward admission of elderly patients, and puts them at an even higher risk of hospitalization-related adverse events. The study hypothesis is that a complex intervention, delivered directly in nursing homes by hospital physicians in case of urgent medical problems, would contribute to reduce hospitalization of older nursing home residents. The intervention consists in a hospital-based "multidisciplinary mobile unit" (MMU), composed of a hospital specialist and a resident in emergency-urgency medicine who are coordinated by a senior physician serving as "flow manager". The team is active on work days, 8 am to 6 pm, and is activated by general practitioners of nursing homes, in case of urgent medical needs of one of the residents. The activation is made by a phone call to the "flow manager", who triages the clinical needs of the case. The output of the phone consultation may include therapeutic advice provided by phone, immediate on-site visit by the MMU team (specialist and resident), scheduled visit by the MMU team, or direct admission to the hospital unit where MMU is based, avoiding ED visits. The MMU team is provided with a portable ultrasound system, an essential set of drugs and medical devices useful in a urgency setting (central venous lines, nasogastric tubes, rectal tubes, bladder catheters). During on-site visits, the MMU team performs diagnosis, stabilization and therapeutic advice, with the mission of avoiding ED visits and hospital admissions whenever possible. The MMU intervention is already active in two nursing homes, since December 2018. The aim of this prospective, pragmatic, multicenter, quasi-experimental study (sequential design with two cohorts) is to test the effects of the implementation of the MMU care model in terms of reduction of unplanned hospitalization rates (primary outcomes), mortality, health service use and costs (secondary outcomes). Two nursing homes (i.e., the ones who already benefit from the intervention) will serve as study group, and two nursing homes with similar geographical location will serve as control group. All residents of the participating nursing homes will be eligible for study inclusion. The study will last for 18 months, and a number of 338 residents is planned for inclusion.
The mortality burden of trauma in the United States is substantial, and is currently the leading cause of death in warfare and in civilians below age 45. Infection and sepsis are leading causes of morbidity and death in early survivors. Pneumonia (PNA) occurs in 17-36% of ventilated trauma patients; far more than non-trauma patients. The long held dogmatic notion of a mechanical predisposition to development of pneumonia in trauma has lacked robust support. However, there is evidence of the innate immune response to injury plays a major role in increasing susceptibility to infection. This application is for support of a Focused Program Award addressing the role that "danger signaling" due to "danger associated molecular patterns" (or DAMPs) derived from somatic tissue injuries play in altering innate immune signaling in the lung in ways that predisposes to PNA. This innate immune response plays a pivotal role in the development and progression of lung inflammation. The organization of the Focused Program Award is into six Projects with collaborators from the Departments of Surgery, Medicine and Anesthesiology at Beth Israel Deaconess Medical Center; the Department of Surgery at Brigham and Women's Hospital and the Departments of Biology and Biological Engineering at Massachusetts Institute of Technology. The human subjects interaction portion of this project is covered in the Human Subjects & Samples Project of the Award, although the information and tissues obtained from this Project will be shared with the other Projects, and the activities planned for those Projects are outlined in this application.
The goal of this study to evaluate whether eliminating the use of non-depolarizing neuromuscular blocking agents (NMBA) for maintenance of general anesthesia reduces postoperative pulmonary complications in higher risk patients.
Premature infants often receive respiratory support and supplemental oxygen for a prolonged period of time during their admission in the NICU. While maintaining the oxygen saturation within a narrow target range is important to prevent morbidity, manual oxygen titration can be very challenging. Automatic titration by a controller has been proven to be more effective. However, to date the performance of different controllers has not been compared. The proposed randomized crossover trial Comparing Oxygen Controllers in Preterm InfanTs (COCkPIT) is designed to compare the effect on time spent within target range. The results of this trial will help determining which algorithm is most successful in controlling oxygen, improve future developments in automated oxygen control and ultimately reduce the morbidity associated with hypoxemia and hyperoxemia.
The investigators aim to demonstrate that use of transpulmonary pressure to guide PEEP management is safe in patients with possible elevations of intracranial pressure.