Prone Positioning and Abdominal Binding on Lung and Muscle Protection in ARDS Patients During Spontaneous Breathing

Study Description

Brief Summary

Ventilator-induced diaphragmatic dysfunction and intensive care unit (ICU)-acquired weakness are two consequences of prolonged mechanical ventilation and critical illness in patients with acute respiratory distress syndrome (ARDS). Both complicate the process of withdrawing mechanical ventilation, increase hospital mortality and cause chronic disability in survivors. During transition from controlled to spontaneous breathing, these complications of critical illness favor an abnormal respiratory pattern and recruit accessory respiratory muscles which may promote additional lung and muscle injury. The type of ventilatory support and positioning may affect the muscle dysfunction and patient-self-inflicted lung injury at spontaneous breathing onset. In that regard, ARDS patients with ventilator-induced diaphragmatic dysfunction and ICU-acquired weakness who are transitioning from controlled to partial ventilatory support probably present an abnormal respiratory pattern which exacerbates lung and muscle injury. Physiological-oriented ventilatory approaches based on prone positioning or semi recumbent positioning with abdominal binding at spontaneous breathing onset, could decrease lung and muscle injury by favoring a better neuromuscular efficiency, and preventing intense inspiratory efforts and high transpulmonary driving pressures, as well as high-magnitude pendelluft. In the current project, in addition to perform a multimodal description of the severity of ventilator-induced diaphragmatic dysfunction and ICU-acquired weakness in prolonged mechanically ventilated ARDS patients, prone positioning and supine plus abdominal binding at spontaneous breathing onset will be evaluated.

Detailed Description

Study protocol will have three steps. The first step is a multimodal description to characterize ICU acquired weakness and ventilator-induced diaphragm dysfunction in prolonged mechanically ventilated ARDS patients at spontaneous breathing onset. The second step is a crossover clinical trial to test different ventilatory approaches oriented to improve physiological variables related to lung injury and diaphragm performance. The third step is a randomized controlled trial to test the effect of the previous ventilatory approaches on lung inflammatory response and biomarkers of lung and muscular injury.

FIRST PHASE: A multimodal physiological description will be performed in assist-control ventilation at spontaneous breathing onset. At the study entry, the assessments will include conventional electromyography; electrical activity of the diaphragm; ultrasound of respiratory and non-respiratory muscles; respiratory flow; tidal volume; airway, esophageal and gastric pressures; and hemodynamic and electric impedance tomography monitoring at the end of 2-hours of spontaneous breathing period.

SECOND PHASE: After the multimodal physiological description, a controlled randomized crossover trial will assign patients to three strategies of 2-hours period on assisted pressure-controlled ventilation mode: A.- Control group: supine at 45º, B.- Abdominal binding: supine at 45º plus abdominal binding, C.- Prone positioning (without abdominal banding). These strategies will be performed under standard positive end-expiratory pressure (PEEP) (ARDSNet strategy) and individualized PEEP (obtained at the lowest combination of collapse and overdistension according to electrical impedance tomography), applied in random order. Therefore, each patient will receive the six approaches, with washout periods of 15-minutes in assisted/controlled ventilation.

THIRD PHASE: The day next to the crossover trial, each patient will be randomized to one of the three ventilatory strategies previously defined, A.- Control group: supine at 45º, B.- Abdominal binding: supine at 45º plus abdominal binding, C.- Prone positioning. These three strategies will be applied under standard PEEP (ARDSNet strategy). Between crossover and pilot randomized controlled trial, the patients will remain under moderate sedation in assisted pressure-controlled ventilation mode receiving an individualized PEEP level.

Study Design

Outcome Measures

Primary Outcome Measures

1. (Second Phase) High-Magnitude Pendelluft [Two hours on each ventilatory strategy during phase 2 (day 2 of the protocol)]

   Frequency of high-magnitude pendelluft monitored by electrical impedance tomography

2. (Third Phase) Change in Inflammatory Biomarkers Measured by ELISA IL-6, IL-8, TNF-α, IFN-γ, IL-18, IL-1β, Caspase-1, RAGE, Angiopoietin-1 and 2) and change in oxidative stress related biomarkers (F2 Isoprostane and Ferric reducing ability of plasma) [At baseline and after 24 hours of each ventilatory strategy during phase 3 (day 3 of the protocol)]

   ELISA-based detection of inflammatory biomarkers (absolute and ratios) and oxidative stress related biomarkers (absolute and ratios) measured in plasma and in exhaled breath condensate

3. (Third Phase) Change in Regional Lung Inflammation [At baseline and after 24 hours of each ventilatory strategy during phase 3 (day 3 of the protocol)]

   Regional lung inflammation will be evaluated with dynamic positron emission tomography/computed tomography of fluoro-2-deoxy-D-glucose (18F-FDG) net uptake rate

4. (Third Phase) Change in Fast-Twitch Skeletal Muscle Troponin I Measured by ELISA [At baseline and after 24 hours of each ventilatory strategy during phase 3 (day 3 of the protocol)]

   ELISA-based detection of fast-twitch skeletal muscle troponin I measured in plasma

Secondary Outcome Measures

1. (Second Phase) Respiratory Mechanics Variables [Two hours on each ventilatory strategy during phase 2 (day 2 of the protocol)]

   Esophageal pressure swing, transdiaphragmatic pressure and transpulmonary driving pressure measured by a esophageal/gastric catheter

2. (Third Phase) Change in High-Magnitude Pendelluft [At baseline and after 24 hours of each ventilatory strategy during phase 3 (day 3 of the protocol)]

   Frequency of high-magnitude pendelluft monitored by electrical impedance tomography

3. (Third Phase) Change in Respiratory Mechanics Variables [At baseline and after 24 hours of each ventilatory strategy during phase 3 (day 3 of the protocol)]

   Esophageal pressure swing, transdiaphragmatic pressure and transpulmonary driving pressure measured by a esophageal/gastric catheter

4. (Third Phase) Change in Neuromechanical Coupling of Diaphragm [At baseline and after 24 hours of each ventilatory strategy during phase 3 (day 3 of the protocol)]

   Change in neuromechanical coupling of diaphragm, which corresponds to the ratio between transdiaphragmatic pressure and electrical activity of the diaphragm measured by a esophageal/gastric catheter

Eligibility Criteria

Criteria

Inclusion Criteria:

• Adult ARDS patients with moderate-severe ARDS on controlled protective mechanical ventilation for more than 3 days

• Stable hemodynamics

• Level of consciousness enough to initiate spontaneous breathing

Exclusion Criteria:

• Unstable hemodynamics

• Tracheostomy

• Abnormal level of consciousness

• Central nervous system injury

• Esophageal varices

• Pregnancy

• Contraindications for installation of electrical impedance tomography or ultrasound assessments

Contacts and Locations

Locations

Sponsors and Collaborators

• University of Chile

Investigators

• Principal Investigator: Rodrigo Cornejo, University of Chile

Study Documents (Full-Text)

More Information

Publications