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

磁共振成像 体内 流入 脑脊液 生物医学工程 流量(数学) 时间分辨率 功能磁共振成像 流速 淋巴系统 核磁共振 神经科学 物理 生物系统 医学 机械 病理 放射科 生物 光学 生物技术
作者
Tyler C. Diorio,Vidhya Vijayakrishnan Nair,Neal Patel,Lauren E. Hedges,Vitaliy L. Rayz,Yunjie Tong
出处
期刊:NMR in Biomedicine [Wiley]
卷期号:37 (10): e5200-e5200 被引量:10
标识
DOI:10.1002/nbm.5200
摘要

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.
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