Real-time quantification of in vivo cerebrospinal fluid velocity using the functional magnetic resonance imaging inflow effect.

IF 2.7 4区 医学 Q2 BIOPHYSICS
NMR in Biomedicine Pub Date : 2024-10-01 Epub Date: 2024-06-16 DOI:10.1002/nbm.5200
Tyler C Diorio, Vidhya Vijayakrishnan Nair, Neal M Patel, Lauren E Hedges, Vitaliy L Rayz, Yunjie Tong
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引用次数: 0

Abstract

In vivo estimation of cerebrospinal fluid (CSF) velocity is crucial for understanding the glymphatic system and its potential role in neurodegenerative disorders such as Alzheimer's disease and Parkinson's disease. Current cardiac or respiratory-gated approaches, such as 4D flow magnetic resonance imaging (MRI), cannot capture CSF movement in real time because of limited temporal resolution and, in addition, deteriorate in accuracy at low fluid velocities. Other techniques like real-time phase-contrast-MRI or time-spatial labeling inversion pulse are not limited by temporal averaging but have limited availability, even in research settings. This study aims to quantify the inflow effect of dynamic CSF motion on functional MRI (fMRI) for in vivo, real-time measurement of CSF flow velocity. We considered linear and nonlinear models of velocity waveforms and empirically fit them to fMRI data from a controlled flow experiment. To assess the utility of this methodology in human data, CSF flow velocities were computed from fMRI data acquired in eight healthy volunteers. Breath-holding regimens were used to amplify CSF flow oscillations. Our experimental flow study revealed that CSF velocity is nonlinearly related to inflow effect-mediated signal increase and well estimated using an extension of a previous nonlinear framework. Using this relationship, we recovered velocity from in vivo fMRI signal, demonstrating the potential of our approach for estimating CSF flow velocity in the human brain. This novel method could serve as an alternative approach to quantifying slow flow velocities in real time, such as CSF flow in the ventricular system, thereby providing valuable insights into the glymphatic system's function and its implications for neurological disorders.

利用功能磁共振成像流入效应实时量化体内脑脊液速度。
脑脊液(CSF)速度的活体估算对于了解淋巴系统及其在阿尔茨海默病和帕金森病等神经退行性疾病中的潜在作用至关重要。目前的心脏或呼吸门控方法,如四维血流磁共振成像 (MRI),由于时间分辨率有限,无法实时捕捉 CSF 运动,此外,在流体速度较低时准确性也会下降。其他技术,如实时相位-对比-磁共振成像或时空标记反转脉冲,不受时间平均的限制,但可用性有限,即使在研究环境中也是如此。本研究旨在量化动态 CSF 运动对功能磁共振成像(fMRI)的流入效应,以在体内实时测量 CSF 流速。我们考虑了速度波形的线性和非线性模型,并根据经验将它们与来自受控流动实验的 fMRI 数据进行了拟合。为了评估这种方法在人体数据中的实用性,我们从八名健康志愿者获得的 fMRI 数据中计算了 CSF 流速。实验中使用了屏气方案来放大脑脊液流动振荡。我们的实验性血流研究表明,脑脊液流速与流入效应介导的信号增加呈非线性关系,并可通过扩展以前的非线性框架进行估算。利用这种关系,我们从体内 fMRI 信号中恢复了速度,证明了我们的方法在估计人脑 CSF 流速方面的潜力。这种新方法可以作为一种替代方法来实时量化缓慢的流速,如脑室系统中的 CSF 流,从而为了解甘液系统的功能及其对神经系统疾病的影响提供有价值的见解。
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来源期刊
NMR in Biomedicine
NMR in Biomedicine 医学-光谱学
CiteScore
6.00
自引率
10.30%
发文量
209
审稿时长
3-8 weeks
期刊介绍: NMR in Biomedicine is a journal devoted to the publication of original full-length papers, rapid communications and review articles describing the development of magnetic resonance spectroscopy or imaging methods or their use to investigate physiological, biochemical, biophysical or medical problems. Topics for submitted papers should be in one of the following general categories: (a) development of methods and instrumentation for MR of biological systems; (b) studies of normal or diseased organs, tissues or cells; (c) diagnosis or treatment of disease. Reports may cover work on patients or healthy human subjects, in vivo animal experiments, studies of isolated organs or cultured cells, analysis of tissue extracts, NMR theory, experimental techniques, or instrumentation.
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