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| Application of high frequency with low tidal volume by pressure controlled ventilation mode in infant thoracoscopic surgery |
| ZOU Nan ZHANG Jianmin XIN Zhong▲ |
| Department of Anesthesiology, Beijing Children′s Hospital, Capital Medical University National Center for Children′s Health, Beijing 100045, China |
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Abstract Objective To investigate the application of high frequency with low tidal volume by pressure controlled ventilation mode in thoracoscopic surgery for infants, and to provide a feasible ventilation method for infants who cannot achieve one lung ventilation in thoracoscopic surgery. Methods Nineteen infants who received thoracoscopic surgery in Beijing Children′s Hospital, Capital Medical University from December 2016 to August 2019 were selected as study objects. Single lumen main endotracheal intubation was performed after induction of anesthesia. The respiratory rate (RR) was 24-34 times/min, the inspiration/exhalation ratio (I∶E) was 1∶1.5, and the tidal volume was maintained at 9-10 mL/kg. After the establishment of artificial pneumothorax, used high frequency with low tidal volume by pressure controlled ventilation mode, RR was 30-40 times/min, I∶E was 1∶1, and the tidal volume was maintained at 6-7 mL/kg. Heart rate (HR), percutaneous pulse oxygen saturation (SpO2), mean arterial pressure (MAP), RR, the airway peak pressure (PPEAK), and end-expiratory partial carbon dioxide (PETCO2) were observed and recorded at before used high frequency with low tidal volume by pressure controlled ventilation mode (Ta), 10 min after used high frequency with low tidal volume by pressure controlled ventilation mode (T10), 30 min after used high frequency with low tidal volume by pressure controlled ventilation mode (T30) and bilateral ventilation was restored 10 min (Tz). Anaesthesia related complications were recorded. Results HR, RR, PPEAK and PETCO2 levels at T10, T30 were higher than those at Ta, SpO2 and MAP levels were lower than those at Ta (all P < 0.05). HR and PETCO2 levels at T30 were lower than those at T10, while SpO2, MAP and RR levels were higher than those at T10 (all P < 0.05). HR, RR, PPEAK and PETCO2 levels at Tz were lower than those at T10 and T30, SpO2 and MAP levels were higher than those at T10 and T30 (all P < 0.05). PPEAK and PETCO2 levels at Tz were higher than those at Ta (all P < 0.05). There were no complications related to anesthesia such as hoarseness and atelectasis occurred after extubation. Conclusion For infants who cannot achieve one lung ventilation in thoracoscopic surgery, the application of high frequency with low tidal volume by pressure controlled ventilation mode is a feasible method.
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[1] 肖婷,屈双权.小儿单肺通气技术新进展[J].临床小儿外科杂志,2016,15(6):625-628.
[2] 李廷坤,李长生,吕帅国,等.小潮气量快频率双肺通气辅以二氧化碳气胸用于胸腔镜食管癌根治术患者气道管理的效果[J].中华麻醉学杂志,2017,7(1):96-99.
[3] 张维智,史素丽,吕改华.允许性高碳酸血症在胸腔镜治疗新生儿先天性食管闭锁手术中的应用[J].临床麻醉学杂志,2017,33(2):117-120.
[4] 吕凯敏,冯继峰,吕锋.支气管阻塞器单肺通气在小儿胸腔镜中的应用[J].临床肺科杂志,2019,24(9):1626-1629.
[5] McHoney M,Mackinlay G,Munro F,et al. Effect of patient weight and anesthetic technique on CO2 excretion during thoracoscopy in children assessed by end-tidal CO2 [J]. J Laparoendosc Adv Surg Tech A,2008,18(1):147-151.
[6] 朱诗利,张溪英,屈双权.新生儿胸腔镜手术的麻醉管理[J].医学临床研究,2016,33(6):1232-1233.
[7] Lumb AB,Slinger P. Hypoxic pulmonary vasoconstriction: physiology and anesthetic implications [J]. Anesthesiology,2015,122(4):932-946.
[8] Dunham-Snary KJ,Wu D,Sykes EA,et al. Hypoxic Pulmonary Vasoconstriction:From Molecular Mechanisms to Medicine [J]. Chest,2017,151(1):181-192.
[9] 刘晶,廖信芳,李海洋,等.胸腔镜辅助下婴儿先天性肺囊腺瘤肺切除术的麻醉管理[J].实用医学杂志,2015,31(5):785-787.
[10] Bernasconi F,Piccioni F. One-lung ventilation for thoracic surgery:current perspectives [J]. Tumori,2017,103(6):495-503.
[11] Amitani K,Yagihara M,Tagawa T,et al. Two cases of diaphragmatic surgery in children under artificial pneumothorax [J]. Masui,2012,61(1):82-84.
[12] 章征兵,万彩云,郭晨,等.单腔气管导管支气管插管单肺通气在新生儿胸腔镜手术中的应用[J].江西医药,2018,53(6):626-628,643.
[13] Zhu YQ,Fang F,Ling XM,et al. Pressure-controlled versus volume-controlled ventilation during one-lung ventilation for video-assisted thoracoscopic lobectomy [J]. J Thorac Dis,2017,9(5):1303-1309.
[14] Licker M,de Perrot M,Spiliopoulos A,et al. Risk factors for acute lung injury after thoracic surgery for lung cancer [J]. Anesth Analg,2003,97(6):1558-1565.
[15] 张银文,潘亚男,毛晓博,等.快速康复外科指导下胸腔镜手术围术期处理的重建[J].中国医药导报,2017,14(8):115-119.
[16] 欧阳卫东,胡华琨,许凯,等.小潮气量肺保护通气策略在新生儿胸腔镜手术中的应用[J].实用临床医学,2016, 17(5):52-54.
[17] El Tahan MR,Pasin L,Marczin N,et al. Impact of Low Tidal Volumes During One-Lung Ventilation. A Meta-Analysis of Randomized Controlled Trials [J]. J Cardiothorac Vasc Anesth,2017,31(5):1767-1773.
[18] 刘晶,廖信芳,黄伟坚,等.胸腔镜辅助下婴儿先天性肺囊腺瘤围术期的呼吸管理[J].广东医学,2015,36(2):249-251.
[19] Fuchs H,Rossmann N,Schmid MB,et al. Permissive hypercapnia for severe acute respiratory distress syndrome in immunocompromised children:A single center experience [J]. PLoS One,2017,12(6):e0179974.
[20] 刘晶,苏润霞,黎昆伟,等.允许性高碳酸血症通气策略在婴儿胸腔镜肺切除术中的应用观察[J].山东医药,2017, 57(31):92-94.
[21] Kiss T,Wittenstein J,Becker C,et al. Protective ventilation with high versus low positive end-expiratory pressure during one-lung ventilation for thoracic surgery (PROTHOR):study protocol for a randomized controlled trial [J]. Trials,2019,20(1):213. |
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