Effect of High Versus Low Fraction of Inspired Oxygen During Alveolar Recruitment

The incidence of obesity (defined by a body mass index (BMI) > 30 kg/m2) is increasing worldwide. In selected individuals, bariatric surgery may offer means of achieving long-term weight loss, improved health, and healthcare cost reduction. Physiological changes that occur because of obesity and general anesthesia predispose to respiratory complications following bariatric surgery.

Obesity affects many respiratory functions, including, among others, a reduction in functional residual capacity, an increase in airway resistance, and a high level of ventilation-perfusion mismatch. The combination of obesity and postoperative respiratory muscle dysfunction could promote respiratory failure.

Absorption atelectasis occurs in most patients, typically due to absorption of gas, compression of the lung tissue, and impairment of surfactant function. Additionally, during laparoscopic surgery, the increased abdominal pressure of capnoperitoneum may shift the diaphragm cranially and decrease respiratory compliance.

Compression of basal lung regions due to a stiffened diaphragm would accelerate the formation of absorption atelectasis that was already initiated during anesthesia induction.

Such deterioration is associated with pulmonary densities revealed by computed tomography. In addition to physiologic impairment, atelectasis could contribute to perioperative lung injury and PPC.

The RM with PEEP has been advocated as efficient for atelectasis treatment. Reports on the impact of FiO2 during RM on atelectasis development are rare, and have not limited FiO2 to the RM per se.

While RM with high FiO2 can improve oxygenation rapidly, there is a greater possibility of absorption atelectasis occurring.

Diagnostic ultrasonography is the only clinical imaging technology in use that does not depend on electromagnetic radiation. Lung ultrasonography can be considered an attractive complementary diagnostic tool and one of the most promising techniques (Daabis et al., 2014). Therefore, Lung ultrasonography is a safe and cheap tool used during the perioperative period and to detect intraoperative respiratory complications resulting from absorption atelectasis.

The modified Lung Ultrasound Score (LUSS) system involves examination of all intercostal spaces: each hemi-thorax is divided into six regions: 2 anterior, 2 lateral and 2 posterior with four longitudinal lines and one axial line [figure 1 (B, C)]. Each region score shows sufficient sensitivity to detect loss of aeration during laparoscopic surgery. The degree of de-aeration rated from 0 to 3 (zero for no atelectasis and 3 for complete atelectasis ) defining substantial atelectasis as a score of 2 or 3 assigned to any region