Verhaegen M J, Todd M M, Hindman B J, Warner D S
Department of Anesthesia, University of Iowa College of Medicine, Iowa City.
Stroke. 1993 Mar;24(3):407-14. doi: 10.1161/01.str.24.3.407.
Little is known about the effects of hypothermia on cerebral autoregulation. The present study was designed to examine cerebral blood flow responses to controlled hemorrhagic hypotension in normothermic and hypothermic rats.
Cortical blood flow was measured with a laser-Doppler flowmeter in halothane-anesthetized rats assigned to one of three groups: normothermic group 1 (n = 8) with a pericranial temperature of approximately 36.5 degrees C or hypothermic group 2 (n = 8) or group 3 (n = 8) with a pericranial temperature of approximately 30.5 degrees C. In group 2, a PaCO2 of approximately 40 mm Hg was maintained without correction for body temperature. To evaluate the role of PaCO2, in group 3 animals PaCO2 was kept at approximately 40 mm Hg as corrected for body temperature. In all animals, the mean arterial blood pressure was reduced by hemorrhage in increments of 10 mm Hg every 2 minutes.
In group 1 animals, a typical autoregulatory curve was observed with cerebral blood flow first falling at or below 75% of baseline at a mean arterial pressure of 57 +/- 15 mm Hg (mean +/- SD). Absolute normotensive cerebral blood flow in group 2 fell to < or = 75% of baseline at a mean arterial pressure of 73 +/- 21 mm Hg. In group 3, no evidence of autoregulation was seen. Cerebral blood flow reached values < or = 75% of baseline at a mean arterial pressure of 82 +/- 14 mm Hg, whereas calculated cerebrovascular resistance failed to show any compensatory vasodilation as the mean arterial pressure decreased.
Different PaCO2 management schemes used during hypothermia may have profound effects on cerebral blood flow and on autoregulation. If PaCO2 is maintained at 40 mm Hg after correction for temperature, autoregulation is abolished. If uncorrected PaCO2 is maintained at approximately 40 mm Hg, some degree of autoregulation is preserved, albeit with a right-shifted "knee."
关于低温对脑自动调节功能的影响,人们了解甚少。本研究旨在检测正常体温和低温大鼠在控制性出血性低血压状态下的脑血流反应。
采用激光多普勒血流仪测量氟烷麻醉大鼠的皮质血流,将大鼠分为三组:正常体温组1(n = 8),颅周温度约为36.5℃;低温组2(n = 8)和低温组3(n = 8),颅周温度约为30.5℃。在组2中,维持动脉血二氧化碳分压(PaCO₂)约40 mmHg,且不根据体温进行校正。为评估PaCO₂的作用,在组3动物中,将校正体温后的PaCO₂维持在约40 mmHg。在所有动物中,通过每2分钟以10 mmHg的增量出血来降低平均动脉血压。
在组1动物中,观察到典型的自动调节曲线,当平均动脉血压为57±15 mmHg(平均值±标准差)时,脑血流在基线的75%或以下开始下降。组2中正常血压时的绝对脑血流在平均动脉血压为73±21 mmHg时降至基线的≤75%。在组3中,未观察到自动调节的证据。当平均动脉血压为82±14 mmHg时,脑血流降至基线的≤75%,而随着平均动脉血压降低,计算得出的脑血管阻力未显示出任何代偿性血管舒张。
低温期间采用的不同PaCO₂管理方案可能对脑血流和自动调节功能产生深远影响。如果校正体温后将PaCO₂维持在40 mmHg,则自动调节功能消失。如果未校正的PaCO₂维持在约40 mmHg,则可保留一定程度的自动调节功能,尽管“拐点”右移。
