烟雾病旁路移植术中荧光造影在血流动力学评估中的应用

摘要/Abstract

摘要：

目的探讨术中吲哚菁绿（indocyanine green，ICG）荧光造影技术及Flow800分析软件对行颞浅-大脑中动脉（superficial temporal artery to middle cerebral artery，STA-MCA）旁路移植手术的烟雾病（moyamoya disease，MMD）患者和颅内动脉粥样硬化（atherosclerotic cerebrovascular disease，ACVD）所致烟雾综合征患者旁路移植前后的皮层血流动力学特点并评估旁路移植手术对皮层血流灌注的改善情况。方法本研究连续入选首都医科大学附属北京天坛医院脑血管3病房2013年4月～2014年9月拟行STA-MCA旁路移植手术的34例MMD（19例）和ACVD所致烟雾综合征患者（15例），通过术中ICG造影技术记录旁路移植前后皮层血管造影资料，分别选取MMD组、ACVD组和13例无颅内血管狭窄、闭塞的对照组患者的皮层动脉、静脉，拟受体动脉、受体动脉分支动脉、邻近区域动脉、远隔区域动脉管辖皮层血管进行荧光强度曲线分析获得血管最大荧光强度、上升斜率、达峰时间、动脉-皮层通过时间、皮层-静脉通过时间、局部循环时间（microvascular transit time，MVTT），分析上述区域皮层血流动力学特点和旁路移植手术后皮层灌注的改善情况。结果 MMD组、ACVD组、对照组的皮层血流动力学参数slope值分别为44.21±11.59、101.00±52.40、163.20±12.19，3组间两两比较差异均具有显著性（P均＜0.01）；MVTT值分别为（5.75±0.23）s、（4.57±1.21）s、（3.27±0.57）s，3组间两两比较差异均具有显著性（P均＜0.01）。行旁路移植后受体血管分支动脉区域的皮层ICG曲线slope较旁路移植前显著增加，其中受体动脉旁路移植前：45.61±13.05，旁路移植后89.32±5.41；受体分支动脉slope值旁路移植前43.70±11.57，旁路移植后96.66±15.82，邻近动脉slope值旁路移植前45.92±14.92，旁路移植后77.80±14.30。旁路移植前后各组slope值比较差异均具有显著性（P＜0.05）。旁路移植后区域内MVTT缩短，受体分支动脉旁路移植前MVTT（5.75±0.58）s，旁路移植后MVTT（2.04±0.54）s，其中邻近动脉旁路移植前MVTT为（5.54±0.26）s，旁路移植后MVTT（2.97±0.73）s，旁路移植前后各组MVTT值差异均具有显著性（P＜0.05）。结论术中ICG联合Flow800软件进行血流动力学分析有助于了解MMD和ACVD皮层血流动力学特点，在行STA-MCA旁路移植手术中有助于受体血管的选择，可以快速判断旁路移植通畅程度及旁路移植后皮层血流灌注改善程度。

文章导读： 本文通过术中ICG联合Flow800软件进行血流动力学分析，有助于了解MMD和ACVD皮层血流动力学特点，在STA-MCA旁路移植手术中有助于选择受体血管，并快速判断旁路移植通畅程度及旁路移植后皮层血流灌注改善程度。

关键词: 烟雾病; 吲哚菁绿荧光造影; 皮层血流动力学

Abstract:

Objective For patients with moyamoya disease (MMD) and atherosclerosis cerebrovascular disease (ACVD), we used intraoperative indocyanine green (ICG) angiography with Flow 800 software to analyze the hemodynamic feature and changes of the regional cortex in superficial temporal artery to middle cerebral artery (STA-MCA) bypass surgery. Compared with normal control group, to explore the hemodynamics of the cortex and whether the STA-MCA bypass surgery can improve the regional cortex blood flow. Methods Thirty-four patients with MMD or ACVD admitted to the Third Department of Cerebralvascular Disease of Beijing Tiantan Hospital between April 2013 and September 2014 were retrospectively analyzed. All patients underwent STA-MCA bypass surgery. Cortical ICG angiography data before and after bypass surgery were recorded by intraoperative ICG angiography technique. Thirteen patients with no cerebrovascular stenosis or occlusion were selected as control group. Cortical hemodynamic features were compared among the three groups. The following hemodynamic parameters were assessed via analyzing the ICG transit curves of fluorescence intensities in interest vessels (cortical artery, vein, receptor artery, receptor arterial branches, adjacent cortical arteries, remote cortical arteries):maximum intensity, slope of ICG curve, time to half-maximal fluorescence and cortical transit times. Explore whether the perfusion was increased in the above areas before and after bypass surger. Results Cortical hemodynamic parameter slope value in MMD group was 44.21±11.59, which was lower than 101.00±52.40 in ACVD group and 163.20±12.19 in control group. The MVTT in MMD, ACVD and control group were (5.75±0.23) s, (4.57±1.21) s, and (3.27±0.57) s respectively. There are statistical differences in the slope value and MVTT of cortical artery between patients with MMD, ACVD and control group (P<0.05). The slope value of receptor arterial branches was significantly increased after bypass:surgery receptor artery (45.61±13.05 vs 89.32±5.41), receptor arterial branches (43.70±11.57 vs 96.66±15.82), adjacent arteries (45.92±14.92 vs 77.80±14.30). There are statistical differences in the slope value before and after bypass surgery in above groups (P<0.05). After bypass surgery, the local MVTT become shorter:receptor artery ([5.75±0.58] s vs [2.04±0.54] s), adjacent arteries ([5.54±0.26] s vs [2.97±0.73] s) (P<0.05). Conclusion Intraoperative ICG angiography combined with hemodynamic parameter analysis obtained by Flow 800 software is a convenient and effective method to evaluate the hemodynamic features of MMD and ACVD. For patients with MMD or ACVD underwent STA-MCA bypass surgery, ICG angiography and hemodynamic parameter analysis can provide a rapid estimation for whether the anastomosis is opened, and whether the cortex perfusion is improved after revascularization.

Key words: Moyamoya disease; Indocyanine green videoangiography; Cortical blood flow

叶迅，刘兴炬，刘灵童，张东，张岩，赵元立，马力，王昊，陈晓霖，王嵘. 烟雾病旁路移植术中荧光造影在血流动力学评估中的应用[J]. 中国卒中杂志, 2015, 10(06): 469-474.

Intraoperative Blood Flow Analysis with Indocyanine Green Angiography in STA-MCA Bypass Surgery for Moyamoya Disease. Intraoperative Blood Flow Analysis with Indocyanine Green Angiography in STA-MCA Bypass Surgery for Moyamoya Disease[J]. Chinese Journal of Stroke, 2015, 10(06): 469-474.

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