View clinical trials related to Pulmonary Valve Insufficiency.
Filter by:Three endotracheal tubes (ETTs) with different surfaces properties will be studied regarding formation and structure of the biofilm formed on those ETTs. Cultures from oropharynx and tracheal secretions as well as pieces of the ETT will be examined. Findings from electron microscopy (EM) and microbiology will be analyzed and compared in respect to the three materials.
The investigators assessed the efficacy and safety of this noninvasive Ventilation (NIV) bundle strategy compared with a conventional treatment in postoperative patients with ARF.
The purpose of this study is to evaluate the efficacy and safety of rivaroxaban compared with placebo in the prevention of symptomatic venous thromboembolism (VTE) events and VTE-related death post-hospital discharge in high-risk, medically ill patients.
Mechanical ventilation (MV) is a cornerstone of management of acute respiratory failure, but MV per se can provoke ventilator-induced lung injury (VILI), especially in acute respiratory distress syndrome (ARDS). Lung protective ventilation strategy has been proved to prevent VILI by using low tidal volume of 6-8 ml/kg of ideal body weight and limiting plateau pressure to less than 30 cmH2O. However, heavy sedation or even paralysis are frequently used to ensure the protective ventilation strategy, both of which are associated with respiratory muscles weakness. Maintaining of spontaneous breathing may decrease the need of sedative drug and improve gas exchange by promoting lung recruitment. Pressure-targeted mode is the most frequent way of delivering after 48 hours of initiating MV. Three types of pressure-controlled mode are available in intubated patients: Biphasic Intermittent Positive Airway Pressure (BIPAP), Airway Pressure Release Ventilation (APRV), and Pressure-Assist Controlled Ventilation (also called BIPAPassist). They are based on pressure regulation but have the difference in terms of synchronization between the patient and the ventilator. The different working principle of these modes may result in different breathing pattern and consequently different in tidal volume and transpulmonary pressure, which may be potentially harmful. The investigators bench study with a lung model demonstrated higher tidal volume and transpulmonary pressure with the BIPAPassist over APRV despite similar pressure settings and patient's simulated effort. However, the impact of each mode on the delivered tidal volume and the transpulmonary pressure in spontaneously breathing mechanically ventilated patients is currently unknown. Their hypothesis is that when the investigators compare the three pressure-controlled modes, the asynchronous mode (APRV) will result in more protective ventilation strategy over the two other modes (BIPAP and BIPAPassist).
The purpose of this study is to compare the measure of the CO2 obtained on the end-tidal expiratory gas (ETCO2) with the value of CO2 obtained by transcutaneous measure (PTCO2), in home-ventilated neuromuscular patients.
Pressure support (PS) is a commonly used mode of ventilation which is triggered based upon the patient's own inspiratory efforts. For the most part, pressure support is well tolerated by patients. However, because the trigger for pressure support is an inspiratory effort by the patient, and because the resulting support is constant, the ventilator response can be "out of sync" with the patient's needs. The problem of patient-ventilator asynchrony has been documented to be large in approximately one quarter of patients who require mechanical ventilation. Asynchrony is associated with increased or abnormal work of breathing (WOB) and prolonged duration of mechanical ventilation. Diagnosing asynchrony at the bedside can be challenging. Electrical activation of the diaphragm (Eadi) recording can provide clinicians with a more accurate picture of patient-ventilator synchrony and may thus result in decreased asynchrony and decreased or normalized work of breathing for the patient. The purpose of this physiologic study is to evaluate the role of protocolized pressure support ventilation (based upon Eadi) in comparison to standard pressure support ventilation.
Hematopoietic stem cell transplantation (HSCT) is used to treat an expanding array of malignant and non-malignant disorders. This is a prospective multicenter study, in pediatric allo-BMT recipients to analyze the spectrum of noninfectious pulmonary complications (PC), to evaluate the prevalence and course of PFT abnormalities before and after transplant, and to detect risk factor for PC.
Patients with underlying neuromuscular disorder (NMD) often suffer from weakness in the inspiratory and expiratory muscles. Consequently they do not have the strength to generate the minimum flow of 160 to 300 liters/minute for an efficient cough function. The restricted cough function allows secretion to accumulate, which in turn causes narrowing of the airway lumen and makes ventilation of the neuromuscular patient even more difficult. The patient's susceptibility to infection increases again and the vicious circle repeats itself. Severe secretion retention may even lead to ventilator failure. Effective secretion and cough management instead reduces the risk for stay in hospital. Therefore, secretion and cough management is a mandatory part of the therapeutic concept for treating patients with neuromuscular disease. The therapeutic efficacy of the Lung Insufflation Assist Maneuver(LIA) integrated in the ventilator VENTIlogic LS-plus manufactured by Weinmann GmbH+Co KG was studied in a pilot study carried out by the Dep. for Pediatric Pulmonology and Sleep Medicine at the University Hospital of Essen/Germany in cooperation with Research & Development at Weinmann GmbH &Co KG, Germany . The objective of the pilot study was to examine the therapeutic efficacy of LIAM as a cough support function in patients with neuromuscular disease and indications for mechanical ventilation. We hypothesized that i) a certain insufflation maneuver pressure may be optimal to achieve the highest individual peak cough flow and ii) that this pressure is below the pressure needed to achieve the maximum insufflation capacity. We define the lowest insufflation capacity at which the best individual PCF can be achieved as optimum insufflation capacity (OIC). The study was performed using two different techniques in order to demonstrate that findings are not dependent on maneuver details but are rather based on effects of maneuver pressure. The protocol was limited to techniques which do not require breath stacking: i) insufflation with an Intermittend Positive Pressure (IPPB) device and ii) with the VENTIlogic LS using LIAM.
Respiratory failure after extubation is a relevant consequence of poor airway clearance due to respiratory muscle weakness and respiratory failure after extubation and reintubation is associated with increased morbidity and mortality. the study will evaluate the contribution of Mechanical Insufflation-Exsufflation (MI-E) in Preventing Respiratory Failure After Extubation as compared manually assisted coughing
The purpose of the study is to compare the pharmacokinetics of nebulized amikacin administered with three vibrating mesh nebulizers coupled with a single limb circuit bilevel ventilator in healthy volunteers. Following our previous in vitro study, our hypotheses are that the pharmacokinetics varies among the devices tested and that a most efficient device can be identified.