Yu Ling-Shan, Chen Xiu-Hua, Zhou Si-Jia, Wang Zeng-Chun
Department of Cardiac Surgery, Fujian Children's Hospital (Fujian Branch of Shanghai Children's Medical Center), College of Clinical Medicine for Obstetrics & Gynecology and Pediatrics, Fujian Medical University, Fuzhou, China.
Department of Cardiac Surgery, Fujian Children's Hospital (Fujian Branch of Shanghai Children's Medical Center), College of Clinical Medicine for Obstetrics & Gynecology and Pediatrics, Fujian Medical University, Fuzhou, China.
J Cardiothorac Vasc Anesth. 2025 Jun 16. doi: 10.1053/j.jvca.2025.06.025.
This study aimed to evaluate the effect of positive end-expiratory pressure (PEEP) combined with 100% oxygen on atelectasis during emergence from anesthesia after one-lung ventilation (OLV) with a bronchial blocker in infants receiving thoracoscopic lobectomies.
This was a randomized controlled study.
This study was performed in a teaching hospital.
Infants who received thoracoscopic lobectomies in our hospital from June 2024 to December 2024 were included in this study.
Sixty-nine infants (Group A) with bronchial blocker OLV thoracoscopic lobectomies received no PEEP but maintained intraoperative oxygen levels (FiO 0.6-0.8) after the removal of the bronchial blocker until extubation during emergence from anaesthesia. Another 69 infants who met the inclusion criteria and received PEEP of 5 to 6 cmHO, combined with 100% oxygen, after removal of the bronchial blocker until extubation during emergence from anesthesia, were included in Group B.
The inclusion criteria were as follows: (1) These infants were diagnosed with congenital cystic adenomatoid malformation and received bronchial blockade OLV thoracoscopic lobectomies; (2) American Society of Anesthesiologists (ASA) class I to II (ASA class I means a normal healthy patient; class II means a patient with mild systemic disease); and (3) age younger than 1 year. The exclusion criteria were as follows: (1) preoperative chest computed tomography or ultrasound suggestive of atelectasis; (2) intraoperative ventilation mode was changed to bilateral lung ventilation; (3) intraoperative FiO greater than 0.9; (4) cardiorespiratory dysfunction; (5) large cysts causing significant mediastinal shift or compressing cardiac chambers; and (6) declined to participate.
There were no significant differences in the preoperative general condition, perioperative hemodynamics, duration of operation, or length of postoperative hospital stay between the two groups (P > 0.05). There were no significant differences in the oxygenation index, alveolar-arterial oxygen differential pressure, or oxygen saturation (SpO) at T1 (the completion of surgery) (p > 0.05). At T2 (30 minutes after extubation), the oxygenation index and PaO level were greater, the alveolar-arterial oxygen differential pressure was lower, and the lowest postoperative SpO level within 30 minutes after extubation was better in Group B than in Group A (p < 0.05). The time from bronchial blocker removal to extubation was shorter in Group B than in Group A (p < 0.05). Compared with those of Group A, the proportions of patients with lung ultrasound scores of 3 (juxtapleural consolidation, large-sized consolidations and B-lines, white lung) and bedside chest radiography atelectasis scores of 3 (lobar atelectasis) in both lungs after extubation were lower in Group B (p < 0.05). The prevalence of hypoxemia (after extubation, SpO < 90%) was 46 (66.7%) in Group A and 14 (20.3%) in Group B, and the differences were statistically significant (p < 0.05). The duration of oxygen administration after extubation in Group B was shorter than that in Group A (p < 0.05). There was a statistically significant correlation between lung ultrasound scores and the chest radiographic atelectasis score in both groups (p < 0.05).
In one-lung ventilation using bronchial blockers performed during thoracoscopic lobectomies in infants, applying PEEP at 5 to 6 cmHO combined with 100% oxygen ventilation after the removal of the bronchial blocker until extubation was associated with improved oxygenation and did not appear to increase the risk of atelectasis during emergence from anesthesia. However, further studies are needed to evaluate the safety of this strategy.
本研究旨在评估呼气末正压通气(PEEP)联合100%氧气对接受胸腔镜肺叶切除术的婴儿在单肺通气(OLV)后麻醉苏醒期肺不张的影响。
这是一项随机对照研究。
本研究在一家教学医院进行。
纳入2024年6月至2024年12月在我院接受胸腔镜肺叶切除术的婴儿。
69例接受支气管封堵器OLV胸腔镜肺叶切除术的婴儿(A组)在麻醉苏醒期拔除支气管封堵器后未使用PEEP,但维持术中氧水平(FiO 0.6 - 0.8)直至拔管。另一组69例符合纳入标准的婴儿在麻醉苏醒期拔除支气管封堵器后至拔管期间接受5至6 cmH₂O的PEEP联合100%氧气,纳入B组。
纳入标准如下:(1)这些婴儿被诊断为先天性囊性腺瘤样畸形并接受支气管封堵OLV胸腔镜肺叶切除术;(2)美国麻醉医师协会(ASA)分级为I至II级(ASA I级表示正常健康患者;II级表示患有轻度全身性疾病的患者);(3)年龄小于1岁。排除标准如下:(1)术前胸部计算机断层扫描或超声提示肺不张;(2)术中通气模式改为双侧肺通气;(3)术中FiO大于0.9;(4)心肺功能障碍;(5)大囊肿导致明显纵隔移位或压迫心腔;(6)拒绝参与。
两组术前一般情况、围手术期血流动力学、手术时间或术后住院时间无显著差异(P > 0.05)。在T1(手术结束时),两组的氧合指数、肺泡 - 动脉血氧分压差或血氧饱和度(SpO₂)无显著差异(p > 0.05)。在T2(拔管后30分钟),B组的氧合指数和PaO₂水平更高,肺泡 - 动脉血氧分压差更低,拔管后30分钟内最低术后SpO₂水平优于A组(p < 0.05)。B组从拔除支气管封堵器到拔管的时间比A组短(p < 0.05)。与A组相比,B组拔管后双肺肺超声评分3分(胸膜旁实变、大尺寸实变和B线、白肺)和床边胸部X线片肺不张评分3分(肺叶不张)的患者比例更低(p < 0.05)。低氧血症(拔管后,SpO₂ < 90%)的发生率在A组为46例(66.7%),在B组为14例(20.3%),差异有统计学意义(p < 0.05)。B组拔管后吸氧时间比A组短(p < 0.05)。两组肺超声评分与胸部X线片肺不张评分之间存在统计学显著相关性(p < 0.05)。
在婴儿胸腔镜肺叶切除术中使用支气管封堵器进行单肺通气时,在拔除支气管封堵器后至拔管期间应用5至6 cmH₂O的PEEP联合100%氧气通气与改善氧合相关,且在麻醉苏醒期似乎不会增加肺不张的风险。然而,需要进一步研究评估该策略的安全性。
