粒径对肝脏 MRI 弛豫率的影响：蒙特卡罗模拟和体模研究。

Effect of particle size on liver MRI relaxometry: Monte Carlo simulation and phantom studies.

机构信息

School of Biomedical Engineering, Anhui Medical University, Hefei, China.

College of Mathematics and Computer Sciences, Gannan Normal University, Ganzhou, China.

出版信息

Magn Reson Med. 2024 Oct;92(4):1743-1754. doi: 10.1002/mrm.30154. Epub 2024 May 9.

DOI:10.1002/mrm.30154

PMID:38725136

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11262983/

Abstract

PURPOSE

To investigate the effect of particle size on liver by Monte Carlo simulation and phantom studies at both 1.5 T and 3.0 T.

METHODS

Two kinds of particles (i.e., iron sphere and fat droplet) with varying sizes were considered separately in simulation and phantom studies. MRI signals were synthesized and analyzed for predicting , based on simulations by incorporating virtual liver model, particle distribution, magnetic field generation, and proton movement into phase accrual. In the phantom study, iron-water and fat-water phantoms were constructed, and each phantom contained 15 separate vials with combinations of five particle concentrations and three particle sizes. measurements in the phantom were made at both 1.5 T and 3.0 T. Finally, differences in predictions or measurements were evaluated across varying particle sizes.

RESULTS

In the simulation study, strong linear and positively correlated relationships were observed between predictions and particle concentrations across varying particle sizes and magnetic field strengths ( ). The relationships were affected by iron sphere size ( ), where smaller iron sphere size yielded higher predicted , whereas fat droplet size had no effect on predictions ( ) for constant total fat concentration. Similarly, the phantom study showed that measurements were relatively sensitive to iron sphere size ( ) unlike fat droplet size ( ).

CONCLUSION

Liver is affected by iron sphere size, but is relatively unaffected by fat droplet size. These findings may lead to an improved understanding of the underlying mechanisms of relaxometry in vivo, and enable improved quantitative MRI phantom design.

摘要

目的

通过蒙特卡罗模拟和 1.5T 和 3.0T 体模研究探讨粒径对肝脏的影响。

方法

分别在模拟和体模研究中考虑了两种不同粒径的颗粒（即铁球和脂肪液滴）。通过将虚拟肝脏模型、颗粒分布、磁场生成和质子运动纳入相位积累进行模拟，合成和分析 MRI 信号，以预测弛豫率。在体模研究中，构建了铁水和油水体模，每个体模包含 15 个单独的小瓶，其中包含 5 种颗粒浓度和 3 种颗粒大小的组合。在体模中，在 1.5T 和 3.0T 下分别进行了弛豫率测量。最后，评估了不同粒径下弛豫率预测或测量的差异。

结果

在模拟研究中，观察到在不同粒径和磁场强度下，弛豫率预测值与颗粒浓度之间存在很强的线性正相关关系（）。这种关系受到铁球尺寸的影响（），其中较小的铁球尺寸产生更高的预测弛豫率，而脂肪液滴尺寸对恒定总脂肪浓度的弛豫率预测没有影响（）。同样，体模研究表明，弛豫率测量值对铁球尺寸相对敏感（），而对脂肪液滴尺寸不敏感（）。

结论

肝脏的弛豫率受铁球尺寸的影响，但受脂肪液滴尺寸的影响相对较小。这些发现可能有助于深入了解体内弛豫率的潜在机制，并能够改进定量 MRI 体模设计。

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