脑血管痉挛对脑血流的影响及诱导性高血压的影响:一项数学建模研究。
The Effects of Cerebral Vasospasm on Cerebral Blood Flow and the Effects of Induced Hypertension: A Mathematical Modelling Study.
作者信息
Bhogal Pervinder, Yeo Leonard Leong, Müller Lucas O, Blanco Pablo J
机构信息
Department of Interventional Neuroradiology, The Royal London Hospital, London, United Kingdom.
Division of Neurology, Department of Medicine, National University Health System, Singapore, Singapore.
出版信息
Interv Neurol. 2020 Jan;8(2-6):152-163. doi: 10.1159/000496616. Epub 2019 Apr 2.
BACKGROUND
Induced hypertension has been used to promote cerebral blood flow under vasospastic conditions although there is no randomised clinical trial to support its use. We sought to mathematically model the effects of vasospasm on the cerebral blood flow and the effects of induced hypertension.
METHODS
The Anatomically Detailed Arterial Network (ADAN) model is employed as the anatomical substrate in which the cerebral blood flow is simulated as part of the simulation of the whole body arterial circulation. The pressure drop across the spastic vessel is modelled by inserting a specific constriction model within the corresponding vessel in the ADAN model. We altered the degree of vasospasm, the length of the vasospastic segment, the location of the vasospasm, the pressure (baseline mean arterial pressure [MAP] 90 mm Hg, hypertension MAP 120 mm Hg, hypotension), and the presence of collateral supply.
RESULTS
Larger decreases in cerebral flow were seen for diffuse spasm and more severe vasospasm. The presence of collateral supply could maintain cerebral blood flow, but only if the vasospasm did not occur distal to the collateral. Induced hypertension caused an increase in blood flow in all scenarios, but did not normalise blood flow even in the presence of moderate vasospasm (30%). Hypertension in the presence of a complete circle of Willis had a marginally greater effect on the blood flow, but did not normalise flow.
CONCLUSION
Under vasospastic condition, cerebral blood flow varies considerably. Hypertension can raise the blood flow, but it is unable to restore cerebral blood flow to baseline.
背景
尽管尚无随机临床试验支持,但诱导性高血压已被用于在血管痉挛状态下促进脑血流。我们试图通过数学模型来模拟血管痉挛对脑血流的影响以及诱导性高血压的作用。
方法
采用解剖学详细动脉网络(ADAN)模型作为解剖学基础,将脑血流模拟为全身动脉循环模拟的一部分。通过在ADAN模型的相应血管内插入特定的狭窄模型来模拟痉挛血管两端的压力降。我们改变了血管痉挛的程度、痉挛段的长度、血管痉挛的位置、压力(基线平均动脉压[MAP]90mmHg、高血压时MAP 120mmHg、低血压)以及侧支供应的情况。
结果
弥漫性痉挛和更严重的血管痉挛导致脑血流下降幅度更大。侧支供应的存在可以维持脑血流,但前提是血管痉挛不在侧支远端发生。在所有情况下,诱导性高血压都会使血流增加,但即使存在中度血管痉挛(30%)也不能使血流恢复正常。在Willis环完整的情况下,高血压对血流的影响略大,但也不能使血流恢复正常。
结论
在血管痉挛状态下,脑血流变化很大。高血压可以增加血流,但无法将脑血流恢复到基线水平。
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