Gelman B, Schleien C L, Lohe A, Kuluz J W
Division of Critical Care Medicine, Department of Pediatrics, University of Miami School of Medicine, FL 33101-6960, USA.
Crit Care Med. 1996 Jun;24(6):1009-17. doi: 10.1097/00003246-199606000-00022.
To test the hypothesis that selective brain cooling could be performed in an infant model of cardiac arrest and resuscitation without changing core temperature and to study its acute effects on regional organ blood flow, cerebral metabolism, and systemic hemodynamics.
Prospective, randomized, controlled study.
Research laboratory at a university medical center.
Fourteen healthy infant piglets, weighing 3.5 to 6.0 kg.
piglets were anesthetized and mechanically ventilated, and had vascular catheters placed. Parietal cortex (superficial brain), caudate nucleus (deep brain), esophageal, and rectal temperatures were monitored. All animals underwent 6 mins of cardiac arrest induced by ventricular fibrillation, 6 mins of external cardiopulmonary resuscitation (CPR), defibrillation, and 2 hrs of reperfusion. Normal core temperature (rectal) was regulated in all animals. In seven control animals (group 1), brain temperature was not manipulated. In seven experimental animals (group 2), selective brain cooling was begin during CPR, using a cooling cap filled with -30 degrees C solution. Selective brain cooling was continued for 45 mins of reperfusion after which passive rewarming was allowed. Regional blood flow (microspheres) and arterial and sagittal sinus blood gases were measured prearrest, during CPR, and at 10 mins, 45 mins, and 2 hrs of reperfusion.
Rectal temperature did not change over time in either group. In group 1, brain temperature remained constant except for a decrease of 0.6 degrees C at 10 mins of reperfusion. In group 2, superficial and deep brain temperatures were lowered to 32.8 +/- 0.7 (SEM) degrees C and 34.9 +/- 0.4 degrees C, respectively, by 15 mins of reperfusion. Superficial and deep brain temperatures were further lowered to 27.8 +/- 0.8 degrees C and 31.1 +/- 0.3 degrees C, respectively, at 45 mins of reperfusion. Both temperatures returned to baseline by 120 mins. Cerebral blood flow was not different between groups at any time point, although there was a trend for higher flow in group 2 at 10 mins of reperfusion (314% of baseline) compared with group 1 (230% of baseline). Cerebral oxygen uptake was lower in group 2 than in group 1 (69% vs. 44% of baseline, p=.02) at 45 mins of reperfusion. During CPR, aortic diastolic pressure was lower in group 2 than in group 1 (27 +/- 1 vs. 23 +/- 1 mm Hg, p = .007). Myocardial blood flow during CPR was also lower in group 2 (80 +/- 7 vs. 43 +/- 7 mL/min/100 g, p=.002). Kidney and intestinal blood flows were reduced during CPR in both groups; however, group 2 animals also had lower intestinal flow vs. group 1 at 45 and 120 mins of reperfusion.
Selective brain cooling by surface cooling can be achieved rapidly in an infant animal model of cardiac arrest and resuscitation without changing core temperature. Brain temperatures known to improve neurologic outcome can be achieved by this technique with minimal adverse effects. Because of its ease of application, selective brain cooling may prove to be an effective, inexpensive method of cerebral resuscitation during pediatric CPR.
验证在婴儿心脏骤停及复苏模型中可进行选择性脑冷却而不改变核心体温这一假设,并研究其对局部器官血流、脑代谢及全身血流动力学的急性影响。
前瞻性、随机、对照研究。
大学医学中心的研究实验室。
14头健康仔猪,体重3.5至6.0千克。
仔猪麻醉并机械通气,置入血管导管。监测顶叶皮质(脑浅表)、尾状核(脑深部)、食管及直肠温度。所有动物均经历6分钟室颤诱导的心脏骤停、6分钟体外心肺复苏(CPR)、除颤及2小时再灌注。所有动物的正常核心体温(直肠温度)均得到调控。7只对照动物(第1组)未对脑温进行处理。7只实验动物(第2组)在CPR期间开始进行选择性脑冷却,使用装有-30℃溶液的冷却帽。选择性脑冷却持续至再灌注45分钟,之后允许被动复温。在心脏骤停前、CPR期间以及再灌注10分钟、45分钟和2小时时测量局部血流(微球法)以及动脉血和矢状窦血气。
两组的直肠温度均未随时间变化。在第1组中,脑温保持恒定,仅在再灌注10分钟时下降了0.6℃。在第2组中,到再灌注15分钟时,脑浅表和深部温度分别降至32.8±0.7(SEM)℃和34.9±0.4℃。再灌注45分钟时,脑浅表和深部温度进一步分别降至27.8±0.8℃和31.1±0.3℃。两个温度在120分钟时均恢复至基线水平。在任何时间点,两组间的脑血流均无差异,尽管在再灌注10分钟时第2组的血流有高于第1组的趋势(为基线的314%),而第1组为基线的230%。再灌注45分钟时,第2组的脑氧摄取低于第1组(分别为基线的69%和44%,p = 0.02)。在CPR期间,第2组的主动脉舒张压低于第1组(27±1对23±1 mmHg,p = 0.007)。CPR期间第2组的心肌血流也较低(80±7对43±7 mL/min/100 g,p = 0.002)。两组在CPR期间肾脏和肠道血流均减少;然而,在再灌注45分钟和120分钟时,第2组动物的肠道血流也低于第1组。
在婴儿心脏骤停及复苏动物模型中,通过表面冷却可迅速实现选择性脑冷却而不改变核心体温。通过该技术可达到已知能改善神经学转归的脑温,且副作用最小。由于其易于应用,选择性脑冷却可能被证明是小儿CPR期间一种有效且廉价的脑复苏方法。
