Amir Gabriel, Ramamoorthy Chandra, Riemer R Kirk, Davis Corrine R, Hanley Frank L, Reddy V Mohan
Division of Pediatric Cardiac Surgery, LPCH, Stanford Medical Center, Stanford, Calif, USA.
J Thorac Cardiovasc Surg. 2006 Dec;132(6):1307-13. doi: 10.1016/j.jtcvs.2006.04.056. Epub 2006 Nov 16.
Regional low-flow perfusion has been used to minimize ischemic brain injury during complex heart surgery in children. However, optimal regional low-flow perfusion remains undetermined. Visible light spectroscopy is a reliable method for continuous determination of capillary oxygen saturation (SgvO2). We used visible light spectroscopy to follow deep and superficial brain SgvO2 during cardiopulmonary bypass, regional low-flow perfusion, and deep hypothermic circulatory arrest.
Visible light spectroscopy probes were inserted into the superficial and deep brain of neonatal (3.9-4.5 kg) piglets, targeting the caudate and thalamic nuclei. The piglets were subjected to cardiopulmonary bypass and cooled to a rectal temperature of 18 degrees C using pH stat. Regional low-flow perfusion was initiated through the innominate artery at 18 degrees C, and pump flows were adjusted to 40, 30, 20, and 10 mL/kg/min for 10-minute intervals followed by 30 minutes of deep hypothermic circulatory arrest. Regional low-flow perfusion was reestablished, and flows were increased in a stepwise manner from 10 to 40 mL/kg/min. SgvO2 was continuously monitored. Carotid flow was measured using a flow probe, and cerebral blood flow (milliliters per kilogram body weight per minute) was calculated.
There were no significant differences between the deep and superficial brain tissue oxygenation during regional low flow brain perfusion before deep hypothermic circulatory arrest. However, after deep hypothermic circulatory arrest, the superficial brain SgvO2 was lower than the deep brain SgvO2 (24 +/- 12 vs 55.3 +/- 8, P = .05, at flows of 30 mL/kg/min, and 34.2 +/- 17 vs 62.5 + 8, P = .06, at a flow rate of 40 mL/kg/min). During regional low-flow perfusion, SgvO2 was maintained at flows of 30 to 40 mL/kg/min (cerebral blood flows of 15 to 21 mL/kg/min and 19 to 24 mL/kg/min, respectively), but was significantly lower at pump flows of 20 mL/kg/min (cerebral blood flow of 10 to 14 mL/kg/min) and 10 mL/kg/min (cerebral blood flow of 5 to 9 mL/kg/min) compared with the values obtained just before regional low-flow perfusion (pre-deep hypothermic circulatory arrest, 37 +/- 6 vs 65.5 +/- 4.4, P < .05, and 21.6 +/- 3.7 vs 65.5 +/- 4.4, P < .01, respectively; and post-deep hypothermic circulatory arrest, 32 +/- 4.5 vs 65.5 +/- 4.4, P < .05, and 16.6 +/- 4.7 vs 65.5 +/- 4.4, P < .01, respectively).
Regional low-flow perfusion at pump flows of 30 to 40 mL/kg/min with resulting cerebral blood flows of 14 to 24 mL/kg/min was adequate in maintaining both deep and superficial brain oxygenation. However, lower pump flows of 20 and 10 mL/kg/min, associated with cerebral blood flow of 9 to 14 mL/kg/min, resulted in significantly reduced SgvO2 values.
在儿童复杂心脏手术期间,区域低流量灌注已被用于将缺血性脑损伤降至最低。然而,最佳区域低流量灌注仍未确定。可见光光谱法是连续测定毛细血管氧饱和度(SgvO2)的可靠方法。我们使用可见光光谱法在体外循环、区域低流量灌注和深低温停循环期间监测深部和浅部脑SgvO2。
将可见光光谱探头插入新生仔猪(3.9 - 4.5千克)的浅部和深部脑内,目标为尾状核和丘脑核。仔猪接受体外循环,并使用pH稳态法将直肠温度降至18摄氏度。在18摄氏度时通过无名动脉开始区域低流量灌注,泵流量调整为40、30、20和10毫升/千克/分钟,每个流量维持10分钟,随后进行30分钟的深低温停循环。重新建立区域低流量灌注,并将流量从10毫升/千克/分钟逐步增加至40毫升/千克/分钟。持续监测SgvO2。使用流量探头测量颈动脉血流,并计算脑血流量(毫升/千克体重/分钟)。
在深低温停循环前的区域低流量脑灌注期间,深部和浅部脑组织氧合无显著差异。然而,深低温停循环后,浅部脑SgvO2低于深部脑SgvO2(在30毫升/千克/分钟流量时,分别为24 ± 12与55.3 ± 8,P = 0.05;在40毫升/千克/分钟流量时,分别为34.2 ± 17与62.5 + 8,P = 0.06)。在区域低流量灌注期间,SgvO2在30至40毫升/千克/分钟流量时得以维持(脑血流量分别为15至21毫升/千克/分钟和19至24毫升/千克/分钟),但与区域低流量灌注前(深低温停循环前,分别为37 ± 6与65.5 ± 4.4,P < 0.05;21.6 ± 3.7与65.5 ± 4.4,P < 0.01)以及深低温停循环后(分别为32 ± 4.5与65.5 ± 4.4,P < 0.05;16.6 ± 4.7与65.5 ± 4.4,P < 0.01)获得的值相比,在20毫升/千克/分钟(脑血流量为10至14毫升/千克/分钟)和10毫升/千克/分钟(脑血流量为5至9毫升/千克/分钟)的泵流量时显著降低。
泵流量为30至40毫升/千克/分钟、脑血流量为14至24毫升/千克/分钟的区域低流量灌注足以维持深部和浅部脑氧合。然而,20和10毫升/千克/分钟的较低泵流量,伴随着9至14毫升/千克/分钟的脑血流量,导致SgvO2值显著降低。
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