Pichugin V V, Derugina A V, Domnin S E, Shirshin A S, Fedorov S A, Buranov S N, Jourko S A, Ryazanov M V, Danilova D A, Brichkin Yu D
MD, DSc, Professor, Anesthesiologist-Resuscitator; Specialized Cardiosurgical Clinical Hospital named after Academician B.A. Korolev, 209 Vaneeva St., Nizhny Novgorod, 603136, Russia; Professor, Department of Anesthesiology, Intensive Care Medicine, and Transfusiology; Privolzhsky Research Medical University, 10/1 Minin and Pozharsky Square, Nizhny Novgorod, 603005, Russia.
DSc, Associate Professor, Head of the Department of Physiology and Anatomy; National Research Lobachevsky State University of Nizhny Novgorod, 23 Prospect Gagarina, Nizhny Novgorod, 603022, Russia.
Sovrem Tekhnologii Med. 2023;15(5):15-22. doi: 10.17691/stm2023.15.5.02. Epub 2023 Oct 30.
is to study the effect of combined introduction of nitric oxide and hydrogen into the extracorporeal circuit of cardiopulmonary bypass (CPB) for antioxidant activity and organ damage during cardiac surgery.
The study included 91 patients who underwent heart surgery under CPB. The patients were randomized into 3 groups: group 1 comprised 30 patients (control); group 2 consisted of 33 patients with an isolated supply of nitric oxide (40 ppm) to the extracorporeal circuit; group 3 included 28 patients with a combined supply of nitric oxide (40 ppm) and hydrogen (1.2 ppm) into the extracorporeal circuit. The intensity of lipid peroxidation processes was studied by the content of diene conjugates (DC), triene conjugates (TC), Schiff bases (SB) in blood plasma; erythrocyte aggregation was also examined. The studies were carried out at the following stages: stage 1 (initial) - after induction of anesthesia; stage 2 - before CPB; stage 3 - 5 min after CPB initiation; stage 4 - at the 30 minute of CPB; stage 5 - at the 60 minute of CPB; stage 6 - at the 90 minute of CPB; stage 7 - at CPB termination; stage 8 - at the end of the operation.
The content of DC increased statistically significantly at the 90 minute of CPB to 1.093±0.573 rel. units (M±SD) in patients of group 1; to 0.322±0.047 rel. units in group 2; to 0.287±0.003 rel. units in group 3, while the DC content was statistically significantly lower in patients of groups 2 and 3 compared to group 1. A statistically significant increase in the content of TC compared to the initial value was observed at the 90 minute of CPB in group 1 (up to 0.334±0.114 rel. units), while the content of TC was statistically significantly lower in patients of groups 2 and 3. A statistically significant growth in the content of SB occurred at the 90 minute of CPB in patients of group 1 up to 33.324±15.640 rel. units. This indicator was statistically significantly lower in groups 2 and 3 relative to the patients of group 1. The dynamics of erythrocyte aggregation in patients of group 1 showed statistically significant growth of this indicator from the start of CPB to the end of the operation (from 44.8±1.4 to 73.1±2.2%). The statistically significant difference from the indicator at the beginning of the operation started at the 30 minute of CPB and lasted until the end of the operation. In patients of group 2, it decreased statistically significantly during CPB (from 56.5±2.3% before the CPB initiation to 47.4±1.2% at the CPB termination); in patients of group 3, it was decreasing from the 60 minute of CPB to the end of the operation and was statistically significantly lower than in patients of both groups 1 and 2. No postoperative complications were noted (acute heart failure, acute respiratory failure, multiple organ failure) in patients of groups 2 and 3. A statistically significant decrease in both the duration of mechanical ventilation and stay in the intensive care unit was registered in group 3 compared to group 2.
The combined use of gaseous nitric oxide and hydrogen during CPB allowed a statistically significant decrease in the level of activation of lipid peroxidation and erythrocyte aggregation, which ensured a higher level of organ protection during cardiac surgery, faster activation of patients, and a shorter stay in the intensive care unit.
旨在研究在心脏手术期间将一氧化氮和氢气联合引入体外循环(CPB)回路对抗氧化活性和器官损伤的影响。
该研究纳入了91例在CPB下接受心脏手术的患者。患者被随机分为3组:第1组包括30例患者(对照组);第2组由33例患者组成,其体外循环回路单独供应一氧化氮(40 ppm);第3组包括28例患者,其体外循环回路联合供应一氧化氮(40 ppm)和氢气(1.2 ppm)。通过血浆中二烯共轭物(DC)、三烯共轭物(TC)、席夫碱(SB)的含量研究脂质过氧化过程的强度;还检测了红细胞聚集情况。研究在以下阶段进行:第1阶段(初始)——麻醉诱导后;第2阶段——CPB前;第3阶段——CPB开始后5分钟;第4阶段——CPB 30分钟时;第5阶段——CPB 60分钟时;第6阶段——CPB 90分钟时;第7阶段——CPB结束时;第8阶段——手术结束时。
第1组患者在CPB 90分钟时DC含量在统计学上显著增加至1.093±0.573相对单位(M±SD);第2组为0.322±0.047相对单位;第3组为0.287±0.003相对单位,而第2组和第3组患者的DC含量与第1组相比在统计学上显著更低。与初始值相比,第1组患者在CPB 90分钟时TC含量在统计学上显著增加(高达0.334±0.114相对单位),而第2组和第3组患者的TC含量在统计学上显著更低。第1组患者在CPB 90分钟时SB含量在统计学上显著增加至33.324±15.640相对单位。该指标在第2组和第3组相对于第1组患者在统计学上显著更低。第1组患者红细胞聚集的动态变化显示,从CPB开始到手术结束该指标在统计学上显著增加(从44.8±1.4%到73.1±2.2%)。与手术开始时指标的统计学显著差异从CPB 30分钟开始并持续到手术结束。在第2组患者中,CPB期间其在统计学上显著降低(从CPB开始前的56.5±2.3%降至CPB结束时的47.4±1.2%);在第3组患者中,从CPB 60分钟到手术结束其一直在降低,且在统计学上显著低于第1组和第2组患者。第2组和第3组患者未观察到术后并发症(急性心力衰竭、急性呼吸衰竭、多器官功能衰竭)。与第2组相比,第3组患者的机械通气时间和重症监护病房停留时间在统计学上均显著缩短。
在CPB期间联合使用气态一氧化氮和氢气可使脂质过氧化和红细胞聚集的激活水平在统计学上显著降低,这确保了心脏手术期间更高水平的器官保护、患者更快的恢复以及在重症监护病房更短的停留时间。
