Magnetization transfer explains most of the $T_1$ variability in the MRI literature

arXiv - PHYS - Medical Physics Pub Date : 2024-09-09 DOI:arxiv-2409.05318

Jakob Assländer

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Abstract

Purpose: To identify the predominant source of the $T_1$ variability described in the literature, which ranges from 0.6 - 1.1 s for brain white matter at 3 T. Methods: 25 $T_1$-mapping methods from the literature were simulated with a mono-exponential and magnetization-transfer (MT) models, each followed by mono-exponential fitting. A single set of model parameters was assumed for the simulation of all methods, and these parameters were estimated by fitting the simulation-based to the corresponding literature $T_1$ values of white matter at 3 T. Results: Mono-exponential simulations suggest good inter-method reproducibility and fail to explain the highly variable $T_1$ estimates in the literature. In contrast, MT simulations suggest that a mono-exponential fit results in a variable $T_1$ and explain up to 62% of the literature's variability. Conclusion: The results suggest that a mono-exponential model does not adequately describe longitudinal relaxation in biological tissue. Therefore, $T_1$ in biological tissue should be considered only a semi-quantitative metric that is inherently contingent upon the imaging methodology; and comparisons between different $T_1$-mapping methods and the use of simplistic spin systems - such as doped-water phantoms - for validation should be viewed with caution.

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磁化传递可解释磁共振成像文献中的大部分 T_1$ 变异性

目的：确定文献中描述的$T_1$变异性的主要来源，文献中描述的3 T脑白质的$T_1$变异性范围为0.6-1.1 s。方法：使用单指数模型和磁化转移（MT）模型模拟文献中的25种$T_1$绘图方法，每种方法都进行了单指数拟合。所有方法的模拟都假定使用一组模型参数，这些参数通过将模拟结果与相应的文献中 3 T 白质的 $T_1$ 值进行拟合来估算：单指数模拟表明方法间具有良好的可重复性，但无法解释文献中高度多变的 $T_1$ 估计值。与此相反，MT 模拟表明单指数拟合会产生可变的 $T_1$，并能解释文献中高达 62% 的可变性。结论结果表明，单指数模型不能充分描述生物组织的纵向松弛。因此，生物组织中的 $T_1$ 应仅被视为一种半定量指标，其本身取决于成像方法；应谨慎看待不同 $T_1$ 绘图方法之间的比较，以及使用简单自旋系统（如掺水模型）进行验证。

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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arXiv - PHYS - Medical Physics

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