View clinical trials related to Ventilatory Failure.
Filter by:In non-invasive mechanical ventilation (NIMV), the interface is the primary determinant of success, as adherence and quality of therapy mainly depend on it. The aim of this study is to investigate the usefulness of a customised mask approach to minimise leakage and upper airway obstruction. It will focus on ventilator registries and changes in the way they can be corrected with these customised masks. The process involves 3D face scanning and dedicated computer-aided design. The processing and manufacturing of the masks is based on additive manufacturing through 3D printing.
The goal of this research study is to assess the FDA approved technique for inserting a feeding tube (gastrostomy) along with a breathing tube (tracheostomy) for patients that cannot breathe or eat on their own in the ICU (Intensive Care Unit). All subjects in the study will receive a tracheostomy, but each patient will be randomly assigned a common method for gastrostomy placement. The placement of the tube and tracheostomy will occur as part of normal clinical practice. Researchers will compare subjects in the control group and the intervention group to evaluate the benefits of performing a tracheostomy and gastrostomy tube at the same time. Researchers will also evaluate the likelihood of the PUG procedure decreasing a patient's length of stay in the ICU.
Nearly 25% of Americans die in intensive care units (ICUs). Most deaths in ICUs are expected and involve the removal of ventilator support, or palliative withdrawal of mechanical ventilation (WMV). Prior work by the Principal Investigator (PI) found that patient suffering can be common; with 30-59% of patients going through this process experiencing distress. Thus, experts and national organizations have called for evidence to inform guidelines for WMV. This research study will 1) develop and refine a Comfort Measures Only Time out (CMOT) intervention consisting of a structured time out with check-list protocol for the ICU team (nurse, physician, respiratory therapist) to improve the process of WMV. and 2) Pilot test the CMOT intervention in 4 ICUs (2 medical/2 surgical) among 40 WMV patients.
During the percutaneous dilatational tracheostomy (PDT), large amount of droplets and aerosols are spread to the environment especially with the effect of ventilation during the dilatation phase. In such cases, it is recommended to take precautions such as masks and goggles or shields to protect practitioners from infection, however it has also been reported that droplets and aerosols can spread to the environment and can go far. Flow controlled ventilation (FCV) with the use of Tritube® and Evone® could reduce droplet spread during PDT and provide a safer environment while operating on patients with infected airways.
This is a prospective multicenter randomized control trial to assess percentage mask leak six months post instructor led positive pressure ventilation skills training in providers who undergo booster training compared to those who do not undergo any booster training
The data were retrospectively collected during the first and the second wave of epidemic in COVID-19 patients with Severe Acute Respiratory Syndrome Coronavirus 2, at the moment of intensive care unit admission and during the in intensive care unit staying.
Comorbidities associated with severe obesity determine an important public health problem. Few methods are considered potentially effective for the treatment of severe obesity and the clinical relevance of bariatric surgery is growing, as well as the number of procedures performed. The insertion of the physiotherapist in the multiprofessional team responsible for performing the surgical procedure is essential from the preoperative screening and evaluation to the prevention and treatment of postoperative complications. Therefore, the physiopathological aspects involved with severe obesity, the technical aspects and risks of the surgical procedure, as well as the physiotherapeutic techniques that have scientific proof must be known by the physiotherapist responsible for the surgical follow-up of the patient. In this context, the use of non-invasive ventilation (NIV) in the postoperative period of bariatric surgery has ample therapeutic potential. The present research project aims to evaluate the immediate prophylactic use of NIV on the respiratory and functional recovery of the patients.
Little is known about how lung mechanics are affected during the very early phase after starting mechanical ventilation. Since the conventional method of measuring esophageal pressure is complicated, hard to interpret and expensive, there are no studies on lung mechanics on intensive care patients directly after intubation, during the first hours of ventilator treatment and forward until the ventilator treatment is withdrawn. Published studies have collected data using the standard methods from day 1 to 3 of ventilator treatment for respiratory system mechanics, i.e. the combined mechanics of lung and chest wall. Consequently, information on lung mechanical properties during the first critical hours of ventilator treatment is missing and individualization of ventilator care done on the basis of respiratory system mechanics, which are not representative of lung mechanics on an individual patient basis. We have developed a PEEP-step method based on a change of PEEP up and down in one or two steps, where the change in end-expiratory lung volume ΔEELV) is determined and lung compliance calculated as ΔEELV divided by ΔPEEP (CL = ΔEELV/ΔPEEP). This simple non-invasive method for separating lung and chest wall mechanics provides an opportunity to enhance the knowledge of lung compliance and the transpulmonary pressure. After the two-PEEP-step procedure, the PEEP level where transpulmonary driving pressure is lowest can be calculated for any chosen tidal volume. The aim of the present study in the ICU is to survey lung mechanics from start of mechanical ventilation until extubation and to determine PEEP level with lowest (least injurious) transpulmonary driving pressure during ventilator treatment. The aim of the study during anesthesia in the OR, is to survey lung mechanics in lung healthy and identify patients with lung conditions before anesthesia, which may have an increased risk of postoperative complications.
Various guidelines for endotracheal intubation (insertion of breathing tube for mechanical ventilation) of Coronavirus Disease 2019 (COVID-19) patients recommend the use of videolaryngoscope (medical device used for intubation that has a camera to visualize the vocal cords between which the breathing tube will pass) over direct laryngoscope (conventionally-used medical device for intubation that depends on anesthetist's direct visualization of vocal cords). The reasons for this recommendation are to maximize the distance between the medical personnel and the patient's face during intubation to decrease the risk of viral particles transmission and to improve intubation success. For patients infected with COVID-19, Powered Air Purifying Respirator (PAPR) is recommended as an alternative to N95 masks during aerosol-generating procedures such as intubation because N95 masks may not fully protect medical personnel from viral transmission during intubation. There is no evidence to suggest that videolaryngoscope (VL) is superior to direct laryngoscope (DL) for intubation when PAPR is donned. The purpose of this study is to determine if McGrath VL is superior to DL for intubation when the anesthetist is wearing a PAPR. The investigators' hypothesis is that McGrath VL will decrease the time to intubation by 20 seconds and more compared to DL when PAPR is donned. The investigators also hope to learn if there is any difference in the difficulties encountered between the use of VL and DL.
This study uses the AirGo band to monitor changes in tidal ventilation in spontaneously breathing patients with COVID-19 associated respiratory failure. It aims to recognize patterns of ventilation associated with worsening respiratory failure in this patient population. If successful, this study will lead to the development of new robust methods for real-time, continuous monitoring of respiratory function in patients with respiratory failure. In turn, such monitoring methods may enable improvements in the medical management of respiratory failure and timing of interventions.