Fang Ke, Da Huanhuan, Sun Ruixiang, Wang Jun, Wang Jiaoting, Jiang Haijiao, Wang Tao, Xu Qiancheng
Department of Critical Care Medicine, the First Affiliated Hospital of Wannan Medical College (Yijishan Hospital), Anhui Provincial Clinical Research Center for Critical Respiratory Disease, Wuhu 241000, Anhui, China.
Anesthesia Operating Room, the First Affiliated Hospital of Wannan Medical College (Yijishan Hospital), Wuhu 241000, Anhui, China. Corresponding author: Jiang Haijiao, Email:
Zhonghua Wei Zhong Bing Ji Jiu Yi Xue. 2024 Apr;36(4):415-421. doi: 10.3760/cma.j.cn121430-20230829-00714.
To investigate the establishment method, coordination points and safe transport management strategy of vena-arterial extracorporeal membrane oxygenation (VA-ECMO) in patients with downtime difficulties during cardiopulmonary bypass (CPB).
A observation study was conducted. The patients admitted to the department of critical care medicine of the First Affiliated Hospital of Wannan Medical College (Yijishan Hospital) from January 2020 to October 2022 were enrolled. These patients could not be separated from CPB and received VA-ECMO-assisted CPB surgery. The clinical data of the patients were recorded, including the basic information of the patients, the data of VA-ECMO establishment and transport process, the clinical indicators before and after VA-ECMO installation, the operation data of VA-ECMO and clinical outcomes. The experience was summarized from the aspects of extracorporeal membrane oxygenation (ECMO) establishment, transport process, team cooperation, and adverse events during transport. The clinical indicators before and after ECMO operation were compared. According to whether ECMO was successfully weaned, the patients were divided into a successful weaning group and a failure weaning group, and the clinical data between the two groups were compared.
Eighteen patients who underwent VA-ECMO-assisted CPB were enrolled, including 10 males and 8 females. The average age was (56.7±12.3) years old. Preoperative left ventricular ejection fraction (LVEF) was 0.46±0.10, and the main reasons for switching to VA-ECMO assistance included right ventricular systolic weakness in 6 cases, total cardiac systolic weakness in 5 cases, left ventricular systolic weakness in 4 cases, high pulmonary arterial pressure in 2 cases, and intractable ventricular fibrillation in 1 case. Among the 18 patients transferred from CPB to VA-ECMO, 10 cases were successfully weaned and 8 cases failed. In ICU, 8 cases survived, 5 cases died, and 5 cases gave up treatment and discharged. The average time for successful CPB to VA-ECMO establishment was (24.6±7.4) minutes, initial blood flow was (3.3±0.4) L/min, and transit time was (8.4±1.5) minutes. ECMO-assisted duration averaged (82.0±69.3) hours. Adverse events occurred in 9 patients during ECMO establishment and transfer. Post-ECMO onboarding for 4 hours, significant improvements were noted in blood lactic acid (Lac), pH value, mean arterial pressure (MAP), central venous oxygen saturation (ScvO) as compared with pre-ECMO onboarding [Lac (mmol/L): 10.5±7.0 vs. 15.2±6.8, pH value: 7.38±0.92 vs. 7.26±0.87, MAP (mmHg, 1 mmHg ≈ 0.133 kPa): 74.9±13.7 vs. 58.4±17.0, ScvO: 0.678±0.065 vs. 0.611±0.061, all P < 0.01], and vasoactive-inotropic score (VIS) was also decreased (39.8±29.8 vs. 68.9±64.4, P < 0.01). Compared with successful weaning group, the patients in the failed weaning group exhibited higher pre-machine Lac (mmol/L: 18.8±7.8 vs. 12.3±4.3, P < 0.05), longer CPB time [minutes: 238.0 (208.8, 351.2) vs. 200.0 (185.8, 217.0), P < 0.05], and shorter ECMO-assisted time [hours: 19.5 (11.0, 58.8) vs. 94.5 (65.8, 179.8), P < 0.01]. However, there was no statistically significant difference in pre-machine pH value, ScvO, MAP, VIS score, and initial blood flow and establishment time of ECMO between the two groups.
VA-ECMO is an effective circulatory aid for CPB surgery that cannot be weaned after CPB. The establishment and transfer of CPB "bridge" to ECMO aid depends on multi-disciplinary treatment (MDT) cooperation. The success rate of ECMO weaning is related to the Lac and CPB duration. If it is not possible to detach from the CPB successfully, VA-ECMO should be initiated as early as possible.
探讨体外膜肺氧合(VA-ECMO)在体外循环(CPB)停机困难患者中的建立方法、配合要点及安全转运管理策略。
进行一项观察性研究。纳入2020年1月至2022年10月在皖南医学院第一附属医院(弋矶山医院)重症医学科住院的患者。这些患者无法脱离CPB并接受VA-ECMO辅助CPB手术。记录患者的临床资料,包括患者基本信息、VA-ECMO建立及转运过程中的数据、VA-ECMO安装前后的临床指标、VA-ECMO运行数据及临床结局。从体外膜肺氧合(ECMO)建立、转运过程、团队协作及转运过程中的不良事件等方面总结经验。比较ECMO运行前后的临床指标。根据ECMO是否成功撤机,将患者分为成功撤机组和撤机失败组,比较两组间的临床资料。
纳入18例行VA-ECMO辅助CPB的患者,其中男性10例,女性8例。平均年龄(56.7±12.3)岁。术前左心室射血分数(LVEF)为0.46±0.10,转为VA-ECMO辅助的主要原因包括右心室收缩无力6例、全心收缩无力5例、左心室收缩无力4例、肺动脉高压2例、顽固性室颤1例。18例从CPB转为VA-ECMO的患者中,10例成功撤机,8例撤机失败。在重症监护病房(ICU),8例存活,5例死亡,5例放弃治疗出院。CPB至VA-ECMO成功建立的平均时间为(24.6±7.4)分钟,初始血流量为(3.3±0.4)L/min,转运时间为(8.4±1.5)分钟。ECMO辅助时间平均为(82.0±69.3)小时。9例患者在ECMO建立及转运过程中发生不良事件。与ECMO上机前相比,ECMO上机4小时后,血乳酸(Lac)、pH值、平均动脉压(MAP)、中心静脉血氧饱和度(ScvO)有显著改善[Lac(mmol/L):10.5±7.0 vs. 15.2±6.8,pH值:7.38±0.92 vs. 7.26±0.87,MAP(mmHg,1 mmHg≈0.133 kPa):74.9±13.7 vs. 58.4±17.0,ScvO:0.678±0.065 vs. 0.611±0.061,均P<0.01],血管活性药物评分(VIS)也降低(39.8±29.8 vs. 68.9±64.4,P<0.01)。与成功撤机组相比,撤机失败组患者上机前Lac更高(mmol/L:18.8±7.8 vs. 12.3±4.3,P<0.05),CPB时间更长[分钟:238.0(208.8,351.2)vs. 200.0(185.8,217.0),P<0.05],ECMO辅助时间更短[小时:19.5(11.0,58.8)vs. 94.5(65.8,179.8),P<0.01]。然而,两组间上机前pH值、ScvO、MAP、VIS评分以及ECMO的初始血流量和建立时间差异无统计学意义。
VA-ECMO是CPB术后无法停机时有效的循环辅助手段。CPB“桥梁”至ECMO辅助的建立和转运依赖多学科治疗(MDT)协作。ECMO撤机成功率与Lac及CPB持续时间有关。若无法成功脱离CPB,应尽早启动VA-ECMO。
