7 Clinical Trials for Various Conditions
Ventilator associated events (VAE) is a quality metric defined by 48 hours of stability followed by 48 hours of escalation of ventilator settings within the ICU. VAE have been associated with poor outcomes and increases the cost of care, yet is not easy to avoid. Operationalizing all the standards of care known to improve outcomes of those requiring mechanical ventilation in the critical care environment requires a comprehensive approach. ICU teams are encouraged to follow best practice protocols to help liberate and prevent VAEs. Yet, compliance with protocols in most ICUs is suboptimal for multiple reasons. With the advent of computerized mechanical ventilators capable of streaming data from breath to breath and biomedical integration systems (BMDI) such as Capsule (UTMB's BMDI system), software systems have been developed to help identify variances in the standard of care. Automation in near real-time ventilator data feedback has been shown to reduce the incidences of VAEs. This quality improvement project will leverage Vyaire's Respiratory Knowledge Portal (RKP) to collect and store meaningful data regarding ventilator-associated events (VAE), alarm policy compliance, ventilator weaning, and lung protective analytics. Goals: 1. To collect quality metrics utilizing RKP from patients requiring mechanical ventilation over a 3-4-month period for a retrospective baseline analysis. 2. Provide the RKP tool to the ICU team to determine if the use of RKP's webportal and Messenger Zebra phone app improves quality of mechanical ventilation and outcomes. 3. To determine a return on investment (ROI) for a software system like RKP.
The primary aim of this study is to evaluate the CleanSweep™ Closed Suction System on time to first successful spontaneous breathing trial in mechanically ventilated patients in the medical intensive care unit. Secondary aims of this study are to evaluate the use endotracheal tube sweeping compared to closed suctioning effect on length of mechanical ventilation, length of ICU stay, length of total hospital stay, and occurrence of ventilator-associated events.
Insertion of a breathing tube to enable treatment with mechanical ventilation (respirator) is often associated with complications, such as infection and lung injury. Leakage of secretions around the breathing tube (microaspiration) is a major factor leading to complications. The investigators propose that a standardized, enhanced oral suction protocol will be effective in reducing microaspiration and harms associated with mechanical ventilation. The investigators hypothesize that those randomized to the enhanced oral suction protocol will have less microaspiration and other ventilator-associated conditions than those in the usual care, standard suction group.
The purpose of this study is to test the efficacy of a novel cleaning device in keeping silver-coated endotracheal tubes free from bacterial colonization.
Aerosol delivery during mechanical ventilation has long been a long debated topic. As evidence-based knowledge about the delivery of aerosol to the lungs of mechanically ventilated patients increases, one piece of the puzzle has remained unexplored; measurement of clinically relevant outcomes. The primary aim of this research is to compare clinical outcomes (ventilator-associated events (VAEs), length of stay (LOS) in intensive care unit (ICU), and total days on mechanical ventilation) when using a traditional jet nebulizer versus a newer generation vibrating mesh nebulizer during mechanical ventilation. The secondary aim of this research is to identify source of bacteria by obtaining cultures of each nebulizer and ventilator circuit and plating them for colony growth and identification.
The purpose of this study is to evaluate the in-vivo efficacy of a novel device (endOclear) for cleaning the endotracheal tube (ETT) lumen from secretions. The investigators hypothesize that a protocol of routine ETT cleaning with endOclear may increase the ETT luminal volume measured at extubation compared to the current standard of care. The device may therefore be clinically useful by better maintaining the ETT original function.
Ventilator-associated events (VAE) are a scourge of critical care settings and hospital systems at large. There is extensive evidence that ventilator-associated pneumonia (VAP) and related VAEs increase mortality rates in critically ill patients by up to 50%, while simultaneously increasing cost of care. C Best-practice guidelines state that positioning ventilated patients at an angle between 30-45 degrees significantly reduces the potential for VAP and other VAE to develop. While the intent of the guidelines is to govern patient elevation angle, the lack of a mechanism to accurately measure patient elevation requires that nurses rely on the head-of-bed (HOB) protractor - a tool which reflects the angle of the bed, not the patient - to measure compliance. Depending upon the position and posture of the patient in the bed, a patient's elevation angle may be significantly different from the HOB angle. Critical care teams currently rely on built-in HOB protractors and digital inclinometers that measure the angle of the bed not the patient. Angulus, LLC has developed a dual-component Angulus sensor to fill this gap in critical care technology. Angulus enables critical care practitioners to instantaneously understand a patient's elevation, identify when the patient is outside of the desired 30-45 degree recumbency scope, and efficiently correct the patient's orientation with immediate feedback. Angulus supports real-time minute-to-minute data display as well as longitudinal aggregation of data.