Relaxation-exchange magnetic resonance imaging (REXI): a non-invasive imaging method for evaluating trans-barrier water exchange in the choroid plexus.

IF 5.9 1区医学 Q1 NEUROSCIENCES Fluids and Barriers of the CNS Pub Date : 2024-11-26 DOI:10.1186/s12987-024-00589-7

Xuetao Wu, Qingping He, Yu Yin, Shuyuan Tan, Baogui Zhang, Weiyun Li, Yi-Cheng Hsu, Rong Xue, Ruiliang Bai

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Abstract

Background: The choroid plexus (CP) plays a crucial role in cerebrospinal fluid (CSF) production and brain homeostasis. However, non-invasive imaging techniques to assess its function remain limited. This study was conducted to develop a novel, contrast-agent-free MRI technique, termed relaxation-exchange magnetic resonance imaging (REXI), for evaluating CP-CSF water transport, a potential biomarker of CP function.

Methods: REXI utilizes the inherent and large difference in magnetic resonance transverse relaxation times (T₂s) between CP tissue (e.g., blood vessels and epithelial cells) and CSF. It uses a filter block to remove most CP tissue magnetization (shorter T₂), a mixing block for CP-CSF water exchange with mixing time t_m, and a detection block with multi-echo acquisition to determine the CP/CSF component fraction after exchange. The REXI pulse sequence was implemented on a 9.4 T preclinical MRI scanner. For validation of REXI's ability to measure exchange, we conducted preliminary tests on urea-water proton-exchange phantoms with various pH levels. We measured the steady-state water efflux rate from CP to CSF in rats and tested the sensitivity of REXI in detecting CP dysfunction induced by the carbonic anhydrase inhibitor acetazolamide.

Results: REXI pulse sequence successfully captured changes in the proton exchange rate (from short-T₂ component to long-T₂ component [i.e., k_sl]) of urea-water phantoms at varying pH, demonstrating its sensitivity to exchange processes. In rat CP, REXI significantly suppressed the CP tissue signal, reducing the short-T₂ fraction (f_short) from 0.44 to 0.23 (p < 0.0001), with significant recovery to 0.28 after a mixing time of 400 ms (p = 0.014). The changes in f_short at various mixing times can be accurately described by a two-site exchange model, yielding a steady-state water efflux rate from CP to CSF (i.e., k_bc) of 0.49 s^-1. A scan-rescan experiment demonstrated that REXI had excellent reproducibility in measuring k_bc (intraclass correlation coefficient = 0.90). Notably, acetazolamide-induced CSF reduction resulted in a 66% decrease in k_bc within rat CP.

Conclusions: This proof-of-concept study demonstrates the feasibility of REXI for measuring trans-barrier water exchange in the CP, offering a promising biomarker for future assessments of CP function.

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弛豫交换磁共振成像（REXI）：评估脉络丛跨屏障水交换的无创成像方法。

背景：脉络丛（CP）在脑脊液（CSF）生成和脑平衡中起着至关重要的作用。然而，评估其功能的无创成像技术仍然有限。本研究旨在开发一种新型的、不含造影剂的磁共振成像技术，即弛豫交换磁共振成像（REXI），用于评估 CP-CSF 水运输，这是 CP 功能的潜在生物标志物：方法：REXI 利用 CP 组织（如血管和上皮细胞）与 CSF 之间固有的巨大磁共振横向弛豫时间（T2s）差异。它使用滤波块去除大部分 CP 组织磁化（T2 较短），使用混合块进行混合时间为 tm 的 CP-CSF 水交换，使用多回波采集检测块确定交换后的 CP/CSF 分量。REXI 脉冲序列是在一台 9.4 T 临床前磁共振成像扫描仪上实现的。为了验证 REXI 测量交换的能力，我们在不同 pH 值的脲水质子交换模型上进行了初步测试。我们测量了大鼠从 CP 到 CSF 的稳态水外流率，并测试了 REXI 在检测碳酸酐酶抑制剂乙酰唑胺诱导的 CP 功能障碍方面的灵敏度：REXI脉冲序列成功捕获了不同pH值下尿素-水模型质子交换率（从短-T2分量到长-T2分量[即ksl]）的变化，证明了其对交换过程的敏感性。在大鼠脑脊液中，力士显着抑制了脑脊液组织信号，使短-T2 分量（fshort）从 0.44 降至 0.23（不同混合时间下的 p 短可以用双位交换模型准确描述，得出从脑脊液到脑脊液的稳态水外流速率（即 kbc）为 0.49 s-1。扫描-再扫描实验表明，REXI 在测量 kbc 方面具有极佳的再现性（类内相关系数 = 0.90）。值得注意的是，乙酰唑胺引起的 CSF 减少导致大鼠 CP 内的 kbc 下降了 66%：这项概念验证研究证明了 REXI 测量 CP 跨屏障水交换的可行性，为将来评估 CP 功能提供了一种前景广阔的生物标志物。

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 Neuroscience-Developmental Neuroscience

CiteScore

10.70

自引率

8.20%

发文量

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).