Optimal PEEP for Postoperative Oxygenation and Lung Aeration (ULTRASVENT-2) (ULTRASVENT-2)

Postoperative pulmonary complications remain a significant cause of morbidity and prolonged hospital stay after major surgical interventions under general anesthesia. While positive end-expiratory pressure (PEEP) is widely used to prevent alveolar collapse, the optimal target levels across different surgical sub-types remain controversial in modern anesthesiology. This trial aims to establish robust clinical evidence regarding perioperative lung protection using a comprehensive functional-anatomical approach.

Primary Endpoint and Measurement Standardization:

The primary outcome of the trial is the non-invasive oxygenation index, the S/F ratio (SpO2/Fraction of inspired oxygen), assessed exactly 2 hours post-extubation in the Post-Anesthesia Care Unit (PACU) and tracked dynamically over the first 24 hours of the postoperative period. To eliminate confounding variables and ensure absolute reproducibility across participating centers, the primary endpoint measurement is strictly standardized according to the following criteria:

1. Room Air Breathing (FiO2 0.21): The evaluation is performed while the patient breathes atmospheric air without supplemental oxygen. This eliminates the masking of intrapulmonary shunts and prevents hyperoxia-induced absorption atelectasis.
2. Patient Position: The patient must be placed in a strict supine position. This positioning represents the most physiologically challenging state for the respiratory system, inducing cranial displacement of the diaphragm and maximizing gravity-dependent alveolar collapse.
3. Full Wakefulness Criteria: The measurement is executed only when the patient reaches a full awake status, defined as a modified Post Anesthesia Recovery Score (PARS) greater than 8, with the specific ventilation sub-score being equal to 2 (ability to deep breathe and cough freely). This cognitive and motor filter guarantees that any recorded functional impairment is caused by true parenchymal collapse rather than residual neuromuscular blockade or opioid-induced respiratory depression.

Differentiated Lung Ultrasound (LUS) Track:

To identify the anatomical substrate behind changes in gas exchange, regional lung aeration patterns will be recorded as the key secondary endpoint using a delta LUS score (postoperative score minus preoperative baseline). The diagnostic burden on the investigators is optimized using two parallel diagnostic tracks:

• Express Track (Strata 1 and 4): A rapid, 2-zone simplified protocol focusing exclusively on the most gravity-dependent bilateral dorsal-basal sectors (Zone 6). This assessment takes 2 to 3 minutes and minimizes interference with routine PACU workflows.
• Panoramic Mapping Track (Strata 2 and 3): A comprehensive 12-zone thoracic mapping performed under Intensive Care Unit (ICU) conditions. Furthermore, a nested validation sub-study will incorporate high-resolution chest computed tomography (CT) scans performed strictly based on clinical indications (such as refractory hypoxemia or suspected pneumonia). CT data will serve as the gold standard reference to calculate the true sensitivity and specificity of the 12-zone ultrasound findings.

Surgical Stratification and Sample Size Design:

Patients will be randomized in a 1:1 ratio to receive either a fixed standard (lower) PEEP or a fixed higher PEEP strategy throughout the intraoperative period (from intubation to extubation). Randomization is performed independently within 4 parallel strata to achieve a total sample size of 320 to 360 patients:

• Strata 1: Non-abdominal surgery (n = 100; PEEP 5 cm H2O versus PEEP 8 cm H2O).
• Strata 2: Major open abdominal surgery (n = 60 to 80; PEEP 5 cm H2O versus PEEP 8 cm H2O).
• Strata 3: Major laparoscopic abdominal surgery (n = 60 to 80; PEEP 7 cm H2O versus PEEP 12 cm H2O).
• Strata 4: Low-trauma laparoscopic surgery (n = 100; PEEP 5 cm H2O versus PEEP 12 cm H2O).

Statistical Analysis Framework:

Data processing will be conducted in the jamovi software environment using General Linear Models (GLM). The analysis will incorporate continuous and categorical baseline covariates (Body Mass Index, age, ASA physical status, and duration of surgery) to reduce residual variance. A key element of the statistical plan is the evaluation of interaction effects between the PEEP level and the specific surgical stratum to determine whether a higher PEEP provides a universal benefit or if its protective role is strictly dependent on the surgical phenotype.

Implementation Protocol Phases:

To guarantee data integrity and eliminate investigator bias, the project is structured into four consecutive logical phases:

Phase 1: Regulatory start, including central registration on ClinicalTrials.gov, Local Ethics Committee (LEC) submission and approval, and prospective publication of the formal Study Protocol manuscript.

Phase 2: Standardized hands-on calibration and training of the core investigator team (4 to 6 specialists) regarding precise zone identification and digital data entry.

Phase 3: A mandatory run-in period dedicated to inter-rater reliability testing. Each investigator must scan a test cohort, and the enrollment of randomized trial patients can begin only after achieving an inter-operator consensus threshold defined as a Cohen's Kappa coefficient greater than or equal to 0.7 and an absolute category agreement greater than or equal to 80%.

Phase 4: Active enrollment utilizing an adaptive recruitment strategy. The trial will commence by enrolling patients in high-volume, low-risk groups (Strata 1 and 4) to seamlessly refine logistical and database processes before activating the complex and labor-intensive ICU-based cohorts (Strata 2 and 3).