Short B L, Walker L K, Traystman R J
Department of Pediatrics, George Washington University School of Medicine, Washington, DC.
Crit Care Med. 1994 Aug;22(8):1262-8. doi: 10.1097/00003246-199408000-00010.
To study the effect of severe prolonged hypoxia combined with ligation of the carotid artery and jugular vein (simulating pre-extracorporeal membrane oxygenation [ECMO] events) on cerebral autoregulation in the newborn lamb.
Animal studies, using the newborn lamb, with comparison of two randomized treatment groups.
Newborn lambs of mixed breed, 1 to 7 days of age, were used for the study. Two groups of animals were studied: a normoxic control group (n = 7) and a hypoxic group (n = 8).
Work was conducted in the research laboratories of the Department of Anesthesiology, Critical Care Medicine at The Johns Hopkins Medical Institutions, Baltimore, MD.
Animals were anesthetized (pentobarbital), intubated, and mechanically ventilated. We examined the effect of prolonged severe hypoxia combined with carotid artery and jugular vein ligation on cerebral autoregulation during recovery from this insult. Control animals were maintained in a normoxic state (3 hrs) without carotid artery or jugular vein ligation. Hypoxic animals with carotid artery and jugular vein ligation were exposed to a 2-hr period of hypoxia (arterial oxygen saturation 44 +/- 14%; PaO2 30 +/- 3 torr [4 +/- 0.4 kPa]) followed by a 1-hr normoxic recovery period. Cerebral autoregulation was evaluated at the end of the 1-hr recovery period in hypoxic animals, and after 3 hrs of normoxia in control animals. Cerebral perfusion pressure was decreased by increasing intracranial pressure, with infusion of artificial cerebrospinal fluid into an intracranial pressure catheter in the lateral ventricle of the brain.
Studies were taken at four ranges of cerebral perfusion pressure: > 55 mm Hg; 55 to 40 mm Hg; 39 to 26 mm Hg; and < or = 25 mm Hg. Cerebral blood flow was measured using the radiolabeled microsphere technique. Cerebral oxygen consumption, fractional oxygen extraction, and oxygen transport values were calculated at each study period.
Two hours of severe hypoxia increased cerebral blood flow by 110%, whereas cerebral oxygen consumption was unchanged. In hypoxic animals, cerebral autoregulation was altered, with both cerebral blood flow and cerebral oxygen consumption decreasing at a cerebral perfusion pressure of 39 to 26 mm Hg compared with unchanged cerebral blood flow or cerebral oxygen consumption at a cerebral perfusion pressure of < or = 25 mm Hg in control animals. At the point of loss of autoregulation, significant right-to-left hemispheric cerebral blood flow changes occurred in hypoxic animals. In hypoxic animals, cerebellar cerebral blood flow changes were similar to those changes in the total cerebrum, while brain stem and caudate decreased cerebral blood flow only at a cerebral perfusion pressure of < or = 25 mm Hg.
These findings indicate that cerebral autoregulation is disrupted during the recovery phase from an insult caused by prolonged, severe hypoxia with carotid artery and jugular vein ligation. This insult results in significant differences in right and left hemispheric cerebral blood flow rates when cerebral autoregulation is lost. If these results can be extrapolated to the human state, they may help to explain the role of pre-ECMO hypoxia combined with vessel ligation as a risk factor in cerebral injury in ECMO patients.
研究严重长期缺氧联合颈动脉和颈静脉结扎(模拟体外膜肺氧合[ECMO]前的情况)对新生羔羊脑自动调节功能的影响。
动物研究,使用新生羔羊,比较两个随机治疗组。
1至7日龄的杂种新生羔羊用于本研究。研究了两组动物:常氧对照组(n = 7)和缺氧组(n = 8)。
研究工作在马里兰州巴尔的摩市约翰霍普金斯医疗机构麻醉与重症医学系的研究实验室进行。
动物麻醉(戊巴比妥)、插管并机械通气。我们研究了长期严重缺氧联合颈动脉和颈静脉结扎对这种损伤恢复过程中脑自动调节功能的影响。对照动物维持在常氧状态(3小时),不进行颈动脉或颈静脉结扎。颈动脉和颈静脉结扎的缺氧动物暴露于2小时的缺氧状态(动脉血氧饱和度44±14%;动脉血氧分压30±3托[4±0.4千帕]),随后是1小时的常氧恢复期。在缺氧动物的1小时恢复期结束时以及对照动物常氧3小时后评估脑自动调节功能。通过向脑侧脑室的颅内压导管内注入人工脑脊液来增加颅内压,从而降低脑灌注压。
在四个脑灌注压范围内进行研究:>55毫米汞柱;55至40毫米汞柱;39至26毫米汞柱;以及≤25毫米汞柱。使用放射性微球技术测量脑血流量。在每个研究阶段计算脑氧耗量、氧摄取分数和氧输送值。
两小时的严重缺氧使脑血流量增加了110%,而脑氧耗量未改变。在缺氧动物中,脑自动调节功能发生改变,与对照动物在脑灌注压≤25毫米汞柱时脑血流量或脑氧耗量未改变相比,在脑灌注压为39至26毫米汞柱时,缺氧动物的脑血流量和脑氧耗量均下降。在自动调节功能丧失时,缺氧动物出现了明显的从右向左的半球间脑血流量变化。在缺氧动物中,小脑的脑血流量变化与全脑的变化相似,而脑干和尾状核仅在脑灌注压≤25毫米汞柱时脑血流量下降。
这些发现表明,在长期严重缺氧联合颈动脉和颈静脉结扎所致损伤的恢复阶段,脑自动调节功能受到破坏。这种损伤在脑自动调节功能丧失时导致左右半球脑血流速率出现显著差异。如果这些结果能够外推至人类情况,它们可能有助于解释ECMO前缺氧联合血管结扎作为ECMO患者脑损伤危险因素的作用。
