Modeling CSF circulation and the glymphatic system during infusion using subject specific intracranial pressures and brain geometries.

IF 5.9 1区 医学 Q1 NEUROSCIENCES Fluids and Barriers of the CNS Pub Date : 2024-10-15 DOI:10.1186/s12987-024-00582-0
Lars Willas Dreyer, Anders Eklund, Marie E Rognes, Jan Malm, Sara Qvarlander, Karen-Helene Støverud, Kent-Andre Mardal, Vegard Vinje
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Abstract

Background: Infusion testing is an established method for assessing CSF resistance in patients with idiopathic normal pressure hydrocephalus (iNPH). To what extent the increased resistance is related to the glymphatic system is an open question. Here we introduce a computational model that includes the glymphatic system and enables us to determine the importance of (1) brain geometry, (2) intracranial pressure, and (3) physiological parameters on the outcome of and response to an infusion test.

Methods: We implemented a seven-compartment multiple network porous medium model with subject specific geometries from MR images using the finite element library FEniCS. The model consists of the arterial, capillary and venous blood vessels, their corresponding perivascular spaces, and the extracellular space (ECS). Both subject specific brain geometries and subject specific infusion tests were used in the modeling of both healthy adults and iNPH patients. Furthermore, we performed a systematic study of the effect of variations in model parameters.

Results: Both the iNPH group and the control group reached a similar steady state solution when subject specific geometries under identical boundary conditions was used in simulation. The difference in terms of average fluid pressure and velocity between the iNPH and control groups, was found to be less than 6% during all stages of infusion in all compartments. With subject specific boundary conditions, the largest computed difference was a 75% greater fluid speed in the arterial perivascular space (PVS) in the iNPH group compared to the control group. Changes to material parameters changed fluid speeds by several orders of magnitude in some scenarios. A considerable amount of the CSF pass through the glymphatic pathway in our models during infusion, i.e., 28% and 38% in the healthy and iNPH patients, respectively.

Conclusions: Using computational models, we have found the relative importance of subject specific geometries to be less important than individual differences in resistance as measured with infusion tests and model parameters such as permeability, in determining the computed pressure and flow during infusion. Model parameters are uncertain, but certain variations have large impact on the simulation results. The computations resulted in a considerable amount of the infused volume passing through the brain either through the perivascular spaces or the extracellular space.

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利用特定受试者的颅内压和脑几何结构,模拟输液过程中的脑脊液循环和甘液系统。
背景:输液试验是评估特发性正常压力脑积水(iNPH)患者脑脊液阻力的一种成熟方法。阻力增加在多大程度上与甘液系统有关是一个未决问题。在此,我们引入了一个包括甘液系统的计算模型,使我们能够确定(1)大脑几何形状、(2)颅内压和(3)生理参数对输液试验结果和反应的重要性:方法:我们使用有限元库 FEniCS 从磁共振图像中建立了一个具有受试者特定几何形状的七室多网络多孔介质模型。该模型包括动脉、毛细血管和静脉血管、相应的血管周围空间以及细胞外空间(ECS)。在对健康成人和 iNPH 患者进行建模时,使用了特定受试者的大脑几何形状和特定受试者的输液测试。此外,我们还对模型参数变化的影响进行了系统研究:结果:当在相同的边界条件下使用特定受试者的几何形状进行模拟时,iNPH 组和对照组都达到了相似的稳态解决方案。结果发现,iNPH 组和对照组的平均流体压力和速度在所有舱室的所有输注阶段的差异均小于 6%。在受试者特定的边界条件下,计算出的最大差异是 iNPH 组与对照组相比,动脉血管周围空间 (PVS) 中的流体速度高出 75%。在某些情况下,材料参数的改变会使流体速度发生几个数量级的变化。在我们的模型中,相当数量的 CSF 在输注过程中通过了甘回流途径,即在健康和 iNPH 患者中分别为 28% 和 38%:通过使用计算模型,我们发现在确定输液过程中的计算压力和流量时,受试者特定几何形状的相对重要性低于输液试验测得的阻力个体差异和渗透性等模型参数。模型参数是不确定的,但某些变化会对模拟结果产生很大影响。计算结果表明,相当多的输注量通过血管周围空间或细胞外空间流经大脑。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Fluids and Barriers of the CNS
Fluids and Barriers of the CNS Neuroscience-Developmental Neuroscience
CiteScore
10.70
自引率
8.20%
发文量
94
审稿时长
14 weeks
期刊介绍: "Fluids and Barriers of the CNS" is a scholarly open access journal that specializes in the intricate world of the central nervous system's fluids and barriers, which are pivotal for the health and well-being of the human body. This journal is a peer-reviewed platform that welcomes research manuscripts exploring the full spectrum of CNS fluids and barriers, with a particular focus on their roles in both health and disease. At the heart of this journal's interest is the cerebrospinal fluid (CSF), a vital fluid that circulates within the brain and spinal cord, playing a multifaceted role in the normal functioning of the brain and in various neurological conditions. The journal delves into the composition, circulation, and absorption of CSF, as well as its relationship with the parenchymal interstitial fluid and the neurovascular unit at the blood-brain barrier (BBB).
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