The goal of this clinical trial is to compare two different types of perioperative mechanical ventilation (MV), specifically Protective Mechanical Ventilation (PMV) and MV with the lowest possible Driving Pressure (ΔP), in relation to the appearance of postoperative pulmonary complications (PPCs) in adult patients who are operated and have higher risk of PPCs. The main questions it aims to answer are: * Is MV with lower ΔP better than conventional PMV in preventing PPCs in patients with higher risk for PPCs? * Does MV with lower ΔP decrease hospital stay, Intensive Care Unit (ICU) need and mortality? * Does MV with lower ΔP suit better than PMV to lung characteristics and needs intraoperatively? Researchers will compare MV with the lowest possible Driving Pressure (ΔP) to Protective Mechanical Ventilation (PMV) to see if any of this is more protective than the other concerning PPCs. All participants will receive perioperative MV. Half of them will receive conventional Protective Mechanical Ventilation (PMV). This will include well known generally protective settings for mechanical ventilation of patients, concerning volumes, pressures, respiratory rate, inspiratory gases and ventilation maneuvers. The rest of participants will be ventilated with the lowest possible Driving Pressure (ΔP). This will be similar to PMV in the chosen volumes, respiratory rate, inspiratory gases and ventilation maneuvers. However, the pressure inside lung at the end of expiration, eg Positive End Expiratory Pressure (PEEP), will be not be preset for every patient. Initially, the investigators will perform a maneuver that will quantify each individual's lung characteristics and mechanics. According to this, the investigators will find the exact PEEP that seems to suit each patients lungs most, and use this perioperatively, trying to provide lungs the best conditions every time. After the completion of the operation, all the patients will be screened for PPCs, via arterial blood testing and chest X ray, and the results will be statistically analyzed trying to find if any of the forementioned strategies of mechanical ventilation surpasses the other concerning PPCs appearance. PPCs include atelectasis, respiratory failure, bronchospasm, pleural effusion, pneumonia, aspiration and pneumothorax. Furthermore hospital stay, ICU need and mortality will be noted. Finally, measurements of perioperative lung pressures, volumes and derived variables will be noted and compared statistically as well.
Study Type
INTERVENTIONAL
Allocation
RANDOMIZED
Purpose
PREVENTION
Masking
SINGLE
Enrollment
200
This group is mechanically ventilated with Invasive Mechanical Ventilation with Volume Control Ventilation mode with PEEP Initially 8 cm H2O. Afterwards, the lungs are recruited with the aforementioned maneuver. During subsequent derecruitment, PEEP is decreased by 2 cm H20 and compliance is noted in each stage. The goal is to find PEEP with maximum compliance (Cmax). A new recruitment maneuver follows and during derecruitment PEEP is set at the optimum value that was previously defined. VT 8 ml/kg IBW RR --\> PaCO2 = 35-45 mmHg FiO2 0.4 - 0.5 --\> SpO2 \> 93% Recruitment Maneuver (as described) every hour
This group is mechanically ventilated with Invasive Mechanical Ventilation with Volume Control Ventilation mode with PEEP 8 cm H2O. VT 8 ml/kg IBW RR --\> PaCO2 = 35-45 mmHg FiO2 0.4 - 0.5 --\> SpO2 \> 93% Recruitment Maneuvers (as described) every hour
University Hospital of Patras
Pátrai, Greece
RECRUITINGPostoperative Pulmonary Complications
Number of the following Postoperative Pulmonary Complications 1. Postoperative Atelectasis (based on Chest X-Ray in Post-Anesthesia Care Unit - PACU) 2. Postoperative Respiratory Failure based on Arterial Blood Gases in PACU (type I and/or II) 3. Postoperative Bronchospasm 4. Postoperative Pleural Effusion 5. Postoperative Pneumonia 6. Postoperative Aspiration Pneumonitis 7. Postoperative Postoperative Pneumothorax
Time frame: Atelectasis -> Within 1 hour in PACURespiratory failure -> Immediately postoperatively & after 30 minutes in PACU.Bronchospasm, Pleural Effusion, Pneumonia, Aspiration Pneumonitis, Pneumothorax -> from immediately postoperative until end of study
Hospital Stay
Total hospital stay days from day of operation until hospital discharge.
Time frame: From day of operation until the end of patient stay inside hospital, because of return to home or due to death.
ICU need.
Potential Need for ICU admission.
Time frame: From day of operation until the end of patient stay inside hospital, because of return to home or due to death.
ICU stay
In case of ICU need, total days of ICU stay.
Time frame: From day of operation until the end of patient stay inside hospital, because of return to home or due to death.
28 Day mortality
Incidence of death in 28 days in each group.
Time frame: From day of operation until up to 28 days.
Mechanical Power (MP)
To calculate MP, the following must be recorded: RR, Peak Airway Pressure (Ppeak), Plateau Pressure (Pplat), and PEEP. The simplified equation will be used; MP = 0.098 × RR × \[Ppeak - (Plat-PEEP)/2\]
Time frame: From the moment of beginning of operation until the moment of the end of operation and mechanical ventilation
Volume-normalized Mechanical Power (MPcrs)
MPcrs = MP/Respiratory System Compliance (Crs)
Time frame: From the moment of beginning of operation until the moment of the end of operation and mechanical ventilation
Elastic Power (EP)
To calculate EP, the following must be recorded: RR, VT, Pplat, and PEEP. The following equation will be used: EP = 0.098 × RR × VT × \[(Plat+PEEP)/2\]
Time frame: From the moment of beginning of operation until the moment of the end of operation and mechanical ventilation
Volume-normalized Elastic Power (EPcrs)
EPcrs = EP/Crs
Time frame: From the moment of beginning of operation until the moment of the end of operation and mechanical ventilation
This platform is for informational purposes only and does not constitute medical advice. Always consult a qualified healthcare professional.