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52 active trials for Mechanical Ventilation

Mitochondrial Dysfunction of Alveolar and Circulating Immune Cells During Acute Respiratory Distress Syndrome: Impact of Infectious Aggression and Alveolar Stretching as a Result of Mechanical Ventilation.

Sepsis leads to a deregulated host response that can lead to organ failure. During sepsis, experimental and clinical data suggest the occurrence of mitochondrial dysfunctions, particularly in circulating muscle and monocytes, which may contribute to organ failure and death. Lower respiratory infection is the leading cause of death from infectious causes. Mechanical ventilation (MV) is required in 20% of cases of bacterial pneumopathy with Streptococcus pneumoniae (S.p.) , with mortality reaching 50%. There are then frequently criteria for acute respiratory distress syndrome (ARDS), combining bilateral lung involvement and marked hypoxemia. Cyclic stretching of lung cells induced by MV causes sterile inflammation and tissue damage (i.e. ventilator-induced lung injury [VILI]), which can cause cellular dysfunction that alter the immune response, particularly during ARDS. This is why the application of a so-called protective MV is then required. However, this does not prevent about one-third of patients from showing signs of alveolar overdistension, as evidenced by an increase in motor pressure (MP) (MP? 15 cmH2O), associated with an increase in mortality. The deleterious effects of MV could be explained by the occurrence of mitochondrial abnormalities. Indeed, the cyclic stretching of lung cells leads to dysfunction in the respiratory chain and the production of free oxygen radicals (FOS), altering membrane permeability. These phenomena could promote VILI, facilitate the translocation of bacteria from the lung to the systemic compartment and lead to alterations in immune response. In our model of S.p. pneumopathy in rabbits, animals on MV develop more severe lung disorders (lack of pulmonary clearance of bacteria, bacterial translocation in the blood, excess mortality), compared to animals on spontaneous ventilation (SV). Intracellular pulmonary mitochondrial DNA (mtDNA) concentrations, a reflection of the mitochondrial pool, are significantly decreased in ventilated rabbits compared to SV rabbits and in infected rabbits compared to uninfected rabbits. At the same time, the mitochondrial content of circulating cells decreased early (H8) in all infected rabbits, but was only restored in rabbits in SV, those who survived pneumonia (Blot et al, poster ECCMID 2015, submitted article). These data suggest an alteration in the mechanisms that restore mitochondrial homeostasis (mitochondrial biogenesis and mitophagy) during the dual infection/MV agression, which may explain the observed excess mortality. Other work by our team illustrates the importance of these phenomena by showing in a mouse model of polymicrobial infection that inhibition of mitophagia in macrophages promotes survival (Patoli et al, in preparation). Human data on this subject are non-existent. The phenomena of mitochondrial dysfunction nevertheless deserve to be explored in humans during the combined MV/pneumopathy aggression in order to understand its possible impact on the effectiveness of the host's immune response. In a personalized medicine approach, these data would open up prospects for targeted therapies, capable of activating mitochondrial biogenesis and/or modulating mitophagia, to prevent organ dysfunction and mortality during severe CALs treated with antibiotic therapy.

Start: June 2019

Titration of Oxygen Levels During Mechanical Ventilation With Electronic Alerts

Fractional oxygen during mechanical ventilation, is a life sustaining therapy in the intensive care unit , used for about a million patients annually. Oxygen therapy needs to be tightly balanced as both hypoxia and hyperoxia are harmful. Establishing precision in oxygenation has significant implications for improving patient outcomes, resource utilization and reducing iatrogenic harm to a vulnerable population. The investigators propose an approach using a oxygen titration protocol consisting of electronic health records based alerts to guide oxygen adjustment.

Start: January 2021

Comparison of the Q-NRG+ Indirect Calorimetry Device Versus the V(Max) Encore Device in Mechanically Ventilated Children

The overarching aim of this proposal is to examine the feasibility of the Q-NRG+ indirect calorimetry device and its agreement with (Vmax) Encore indirect calorimetry device in mechanically ventilated children. The overall hypothesis of this study is that the Q-NRG+ will provide minute-to-minute oxygen consumption (VO2) and carbon dioxide production (CO2) measurements that are in agreement with those obtained by the standard indirect calorimetry device currently used at our institution (Vmax Encore).

Start: November 2020

Evaluation of the Hemodynamic Effects of Transvenous Phrenic Stimulation

Mechanical ventilation is a cornerstone in the management of severe forms of pneumonia, acute respiratory distress syndrome. It provides essential oxygen to patients, ventilates the lungs but also has deleterious effects like any treatment, in particular by reducing cardiac output by reducing venous return. Mechanical ventilation also has effects on the diaphragm: diaphragmatic dysfunction. It is explained by a prolonged inactivity of this muscle with a reduction of muscle fibers that can settle down quickly, after only a few days of mechanical ventilation. This dysfunction results in a reduction in the latter's ability to generate intrathoracic pressure necessary for ventilation, slows the withdrawal of mechanical ventilation and lengthens the duration of stay in intensive care unit. To reduce this dysfunction, phrenic stimulation has been proposed as an alternative to remuscler the diaphragm thanks to electrodes located on a central venous catheter, also used to deliver the usual therapies in intensive care unit. The HEMOSTIM study is interested in the effects of phrenic stimulation on regional ventilation, cardiac output and cerebral perfusion: investigator hypothesize that diaphragmatic stimulation allows an improvement of these parameters.

Start: March 2021

Simple Mechanical Device to Control Pressure in the Balloon of the Endotracheal Tube to Prevent Ventilator-acquired Pneumonia

Hypothesis: Nosten® device is able to reduce the time of underinflated balloon and removes excess pressure. This device may thus reduce the risk of ventilator-acquired pneumonia (VAP) and early tracheal lesions resulting from intubation with decreased discomfort, morbidity, and nursing workload. The main objective of the investigators is to show that Nosten® device is more effective than monitoring and manual inflation of the balloon of the tracheal tube to prevent VAP occurrence.

Start: August 2015

Identification of Risk Factors for Alteration of the Cellular-arterial Gradient of CO2

Monocentric, prospective, observational and descriptive study on the evaluation of risk factors for alteration of the alveoarterial gradient of CO2 in pre-hospital patients, intubated and then ventilated in an invasive manner; and their impact on intra-arterial fatehospital.

Start: June 2020

Ventilation With ASV Mode in Children

ASV mode of ventilation is an automatic mode with closed-loop control used for mechanical invasive ventilation in intubated patients. It has been studied in adult patients but not in children. This interventional physiology study will include 40 children on mechanical invasive ventilation.

Start: September 2019

Mortality in Patients With Severe COVID-19 Pneumonia Who Underwent Tracheostomy

Background: Invasive mechanical ventilation (IMV) in COVID-19 patients has been associated with a high mortality rate. In this context, the utility of tracheostomy has been questioned in this group of ill patients. This study aims to compare in-hospital mortality in COVID-19 patients with and without tracheostomy due to prolonged IMV Methods: Cohort study of adult COVID-19 patients subjected to prolonged IMV. Since the first COVID-19 case (March 3, 2020) up to November 30, 2020, all adult critical patients supported with IMV by 10 days or more at the Hospital Clínico Universidad de Chile will be included in the cohort. Pregnant women and non-adult patients will be excluded. Baseline characteristics, comorbidities, laboratory data, disease severity, and ventilatory support will be retrospectively collected from clinical records. The indication of tracheostomy, as part of our standard of care, will be indicated by a team of specialists in intensive care medicine, following national guidelines, and consented to by the patient's family. The 90-days mortality rate will be the primary outcome, whereas IMV days, hospital/CU length of stay, and the frequency of healthcare-associated infections will be the secondary outcomes. Also, a follow-up interview will be performed one year after a hospital discharged in order to assess the vital status and quality of life. The mortality of patients subjected to tracheostomy will be compared with the group of patients without tracheostomy by logistic regression models. Furthermore, propensity-score methods will be performed as a complementary analysis.

Start: March 2020

The Emergency Department Sedation Pilot Trial

The ED-SED Pilot is a multicenter, prospective, before-and-after study conducted on 344 mechanically ventilated emergency department patients at three academic medical centers: Washington University in St. Louis School of Medicine (St. Louis, MO), Cooper Hospital of Rowan University (Camden, NJ), and University of Iowa Carver College of Medicine (Iowa City, IA). The overall goal is to assess the feasibility of implementing targeted sedation (in terms of sedation depth) for mechanically ventilated ED patients in order to reduce the incidence of unnecessary deep sedation and improve clinical outcomes.

Start: September 2020

Echocardiographic Evaluation in ARDS Patients

The purpose of this study is to assess the left diastolic function at different levels of in patients affected by the acute respiratory distress syndrome (ARDS)

Start: September 2018

Influence of Respiratory Mechanics on Diaphragmatic Dysfunction in COPD Patients Who Have Failed NIV (RHYDIAN)

Although non-invasive mechanical ventilation (NIV) is the gold standard treatment for patients with acute exacerbation of COPD (AECOPD) who develop respiratory acidosis, failure rate are still high ranging from 5% to 40%. Recent studies have shown that the onset of severe diaphragmatic dysfunction (DD) during AECOPD increases risk of NIV failure and mortality in this subset of patients. Although the imbalance between the load and the contractile capacity of inspiratory muscles seems the main cause of AECOPD-induced hypercapnic respiratory failure, data regarding the influence of mechanical derangement on diaphragmatic performance in this acute phase are lacking. With this study we aim at investigating the impact of respiratory mechanics on diaphragm function in AECOPD patients who experienced NIV failure. AECOPD with respiratory acidosis admitted to the ICU of the University Hospital of Modena from 2017-2018 undergoing mechanical ventilation (MV) due to NIV failure were enrolled. The study protocol consisted of two consecutive phases; in the first step measurements of static respiratory mechanics and end expiratory lung volume (EELV) were performed after 30 minutes of MV in volume control mode. In the second step transdiaphragmatic pressure (Pdi) was calculated by means of a sniff maneuver (Maximal Pdi) after 30 minutes of spontaneous breathing trial. Linear regression analysis and Pearson's correlation coefficient was used to asses the association between Maximal Pdi values and static and dynamic mechanical features and the association between Maximal Pdi and Pdi/Maximal Pdi.

Start: January 2017

Respiratory Muscle Training in ICU Patients

Respiratory muscle weakness is common after mechanical ventilation and occurs early. This can limit functional recovery. Respiratory muscle training is often neglected in clinical practice. Some data indicates that inspiratory muscle training increases inspiratory muscle strength and quality of life. The aim of the study is to assess the impact of combined inspiratory and expiratory muscle training on inspiratory muscle strength. The second aim is to assess the impact of this training program on expiratory muscle strength.

Start: October 2020

Influence of Renal Replacement TherApy on Indirect Calorimetry

Renal replacement therapy may affect carbon dioxide elimination, which may theoretically influence measurement of energy expenditure by means of indirect calorimetry. However, available clinical studies are noct conclusive on this issue. This observational study aims to investigate the effect of renal replacement therapy on indirect calorimetry in critically ill mechanically ventilated patients.

Start: October 2020

Pediatric Acute Respiratory Distress Syndrome Asia Study

Mortality rates in children with pediatric acute respiratory distress syndrome (PARDS) are higher in Asia compared to other regions. In adults with acute respiratory distress syndrome, the only therapy that improves mortality rates is a lung protective ventilation strategy. The pediatric ventilation recommendations are extrapolated from evidence in adults, including ventilation with low tidal volume, low peak/plateau pressures and high-end expiratory pressure. A recent retrospective study of ventilation practices in Asia showed varying practices with regards to pulmonary and non-pulmonary therapies, including ventilation. This study aims to determine the prevalence and outcomes of PARDS in the Pediatric Acute and Critical Care Medicine Asian Network (PACCMAN). This study will also determine the use of pulmonary (mechanical ventilation, steroids, neuromuscular blockade, surfactant, pulmonary vasodilators, prone positioning) and non-pulmonary (nutrition, sedation, fluid management, transfusion) PARDS therapies. To achieve this aim, a prospective observational study which involves systematic screening of all pediatric intensive care unit (PICU) admissions and collection of pertinent clinical data will be conducted. Recruitment will be consecutive and follow up will continue to intensive care discharge.

Start: August 2019

Neuromuscular Blockade in the Intentive Care Unit, an Observational Study.

The study Short description of the protocol intended for the lay public. Include a brief statement of the study hypothesis. (Limit: 5000 characters) Neuromuscular blocking agents (NMBAs) are drug capable of inducing a complete paralysis of the muscle. Their use is frequent in the intensive care unit (ICU). Most of the time it is used as a single infusion to facilitate endotracheal intubation, but in the ICU the use of continuous infusion is common in several pathologies: acute distress respiratory syndrome, post-cardiac arrest survivor under hypothermia to prevent shivering, abdominal compartment syndrome, severe traumatic brain injury with uncontrolled intra-cranial pressure and severe asthma among others. A monitoring of the dose of NMBAs is recommended to guide the depth of paralysis and to guide recovery, but in the ICU, the interest of such a monitoring during continuous infusion is unclear and the level of evidence is low. The investigators propose to conduct a prospective multicentric observational study to describe the current practice in the use of NMBAs in mechanically ventilated patients in the ICU. As a primary objective we will describe the prevalence of NMBAs use in the ICU. As a secondary objective, the investigators will investigate the impact of protocol and/or monitoring devices of NMBAs on the dose administered and clinical outcome endpoints.

Start: November 2019

Mechanical Ventilation Strategy for Coronavirus Disease 2019 (COVID-19)

This is a prospective, randomized, single-center, open-label controlled trial, designed to compare the efficacy of two ventilation strategies (Low Tidal Volume and positive end-expiratory pressure (PEEP) based on the Acute Respiratory Distress Syndrome (ARDS) Network low PEEP-fraction of inspired oxygen inspired oxygen fraction (FIO2) Table versus Low Driving Pressure and PEEP guided by Electrical Impedance Tomography (EIT) in reducing daily lung injury score in patients with acute respiratory distress syndrome caused by COVID-19. The two strategies incorporate different prioritizations of clinical variables. The PEEP-FIO2 table strategy aims to reduce lung overdistension, even if it requires tolerating worse gas exchange. EIT-guided strategy prioritizes mechanical stress protection, avoiding alveolar overdistension and collapse.

Start: May 2020

Effects of Music Therapy on Reducing Delirium in Mechanically Ventilated Adults in Intensive Care Unit

Background: Delirium is a common acute confusion state in patients in intensive care units (ICUs). It has been linked to poor clinical prognoses (e.g., prolonged ICU stay) in critical patients. Furthermore, it might connect with long-term cognitive dysfunction. Mostly, pharmacological treatments have been frequently prescribed for preventing ICU delirium; however, their side effects might subsequently increase the risks of ICU delirium. Therefore, developing an effective non-pharmacological intervention of preventing delirium among critically mechanical ventilated patients is of clinical relevance. Purposes: To examine the effects of music intervention on reducing delirium in mechanically ventilated critical patients, to determine its beneficial effects on delirium-related outcomes, including sedation dosage and time, the duration of mechanical ventilation, and the length of ICU stay, and to compare the change of heart rate variability, electroencephalography and serum biomarkers after music therapy between groups.

Start: June 2020

Nesiritide for Ventilated Congestive Heart Failure

The congestive heart failure is a common disease among patients who receive cardiac surgery and may lead to prolonged ventilation support. Nesiritide was a potential therapy for congestive heart failure. This study aimed to compare the Nesiritide induced hemodynamical status changes among congestive heart failure patients with invasive ventilation support.

Start: May 2020

Hyperoxemia and Ventilator-associated Pneumonia

The aim of this prospective cohort single-center observational study is to determine the impact of hyperoxemia on ventilator-associated pneumonia (VAP) occurrence. SpO2 will be continuously recorded in order to determine the percentage of time spent with hyperoxemia. Patients with VAP will be prospectively identified. Patient characteristics and risk factors for VAP will be prospectively collected. Oxidant stress will be prospectively investigated in study patients: glutathion peroxidase (GPX), plasmatic superoxyde dismutase (SOD), total plasmatic antioxidant status (SAT) and urinary 8-isoprostanes will be performed at ICU admission, once a week, and at VAP occurrence. Patients with VAP will be compared with those with no VAP

Start: March 2018

Driving Pressure in Trauma

Traumatic chest injuries are responsible for significant morbidity and the cause of trauma-related death in 20%-25% of cases. Thoracic trauma can include multiple injuries, mainly osseous (ribs, sternal fractures, flail chest), pulmonary contusions or lacerations, pneumothoraces and pleural effusions, and sometimes involve wounds to the heart and vessels (aortic dissection, cardiac contusion) or diaphragm. Following trauma, patients with thoracic injuries are at risk of developing acute respiratory distress syndrome (ARDS). This worsening of respiratory function can lead to requirement for mechanical ventilation. In addition, changes to gas exchange may also be generated or aggravated by mechanical ventilation as a result of barotrauma, biotrauma, or ventilation-associated pneumonia. Many mechanical ventilation strategies have been tried in trauma patients in the last 30 years to determine the optimal method of maximizing gas exchange with minimal lung damage. The driving pressure of the respiratory system has been shown to strongly correlate with mortality in a recent large retrospective ARDSnet study. Respiratory system driving pressure [plateau pressure-positive end-expiratory pressure (PEEP)] does not account for variable chest wall compliance especially in cases of chest trauma. Esophageal manometry can be utilized to determine transpulmonary driving pressure. A recent study suggests that utilizing PEEP titration to target positive transpulmonary pressure via esophageal manometry causes both improved elastance and driving pressures. Treatment strategies leading to decreased respiratory system and transpulmonary driving pressure at 24 h may be associated with improved 28 day mortality. However, currently no specific study with chest trauma patients exists. We propose to investigate the effect of hight transpulmonary driving pressure on duration on mechanical ventilation, length of stay and mortality in patients with sever chest trauma.

Start: November 2018