Importance of alveolar recruitment strategy revisited

Jin Kyoung Kim

doi:10.4097/kjae.2014.67.2.75

Low tidal volume, rather than high tidal volume, ventilation is often used for mechanical ventilation during surgery to avoid lung injury due to alveolar overdistention. Under general anesthesia with a muscle relaxant, there is a risk of compressing the lungs by diaphragmatic displacement, which can be aggravated in patients placed in the supine position. Such a risk becomes even higher during reduced tidal volume ventilation, causing alveolar atelectasis and hypoxemia. Therefore, positive end expiratory pressure (PEEP) is applied to prevent spontaneous closure of alveoli.

In this volume, Jung et al. [1] reports on the importance of the alveolar recruitment strategy (ARS). The authors applied ARS before the start of one-lung ventilation (OLV), and compared the oxygenation score between high- and low-tidal volume groups. Repetitive open and closure of collapsed alveoli by positive pressure ventilation could cause damage to the capillary endothelium and alveolar epithelium. Excessive expansion and risk of alveolar injury may even occur during low tidal volume ventilation due to an uneven distribution of ventilated volume to already open alveoli. However, Jung et al. [1] showed that preemptive ARS commonly increases PaO₂ without causing hemodynamic instability in groups with or without PEEP during OLV. The improvement in oxygenation was better in the group where ARS was combined with PEEP. Their study design and intriguing results will draw the attention of general readers of the journal.

The ARS helps to open collapsed alveoli, which is effectively maintained by PEEP. Therefore, both ARS and PEEP maneuvers are compulsory to improve oxygenation and lung mechanics during general anesthesia [2]. Diverse ARS methods have been reported in recent clinical studies. The recommended ARS is peak inspiratory pressure up to 40 cmH₂O at 10 respiratory cycles with 15-20 cmH₂O PEEP. Adequate PEEP level following ARS is reportedly 5-20 cmH₂O depending on the condition of the patient (i.e., pulmonary function and physical condition) and also the type of operation.

The time to apply ARS is typically (1) immediately after intubation before confirming lung sounds, (2) after suctioning, or (3) just before extubation. Functional residual capacity is reduced in 50% of patients after tracheal suctioning, in which case combined ARS and PEEP effectively restores PaO₂ [3]. Along with increased PaO₂, several reports have indicated that ARS with PEEP during OLV decreases AaDO2, and decreases the alveolar dead space ventilation ratio [4,5,6]. In addition to OLV anesthesia, ARS with appropriate PEEP is required to improve PaO₂ in patients with minimal lung injury during other surgeries with a high risk of atelectasis such as laparoscopic surgery [7,8,9], pediatric patients [10], and obese patients [9]. This preemptive ARS effect during low tidal volume OLV has been described previously [11]. Preemptive ARS can also be applied before pneumoperitoneum during laparoscopic surgery [8] with the purpose of improving oxygenation.

However, high intrathoracic pressure during ARS may cause hemodynamic instability. Therefore, adjustment of the pressure and application duration should consider a patient's hemodynamic status and the potential risks [5]. In obese patients, higher pressures are required for adequate ARS and PEEP [9]. The risk of hemodynamic derangement by such high pressures can be prevented by intravascular volume replacement [12]. Interestingly, one study reported that applying ARS with PEEP to the donor lung in situ as well as after transplantation lowers the risk of primary graft dysfunction [13]. Several reports have suggested the beneficial effects of ARS with PEEP during general abdominal surgery to reduce post-operational complications [14].

In conclusion, applying ARS and PEEP during surgery or in patients vulnerable to atelectasis is helpful for improving oxygenation and lowering postoperative pulmonary complications. PEEP must be sustained to keep alveoli in their open state and optimize patient oxygenation. In addition, adequate ARS before applying PEEP is essential to maximize the benefits of PEEP.

References

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