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用于动态葡萄糖增强(DGE)MRI 的数值人体脑模型:关于在 3T 下头部运动的影响。

A numerical human brain phantom for dynamic glucose-enhanced (DGE) MRI: On the influence of head motion at 3T.

机构信息

Department of Medical Radiation Physics, Lund University, Lund, Sweden.

Philips Healthcare, Copenhagen, Denmark.

出版信息

Magn Reson Med. 2023 May;89(5):1871-1887. doi: 10.1002/mrm.29563. Epub 2022 Dec 29.

DOI:10.1002/mrm.29563
PMID:36579955
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9992166/
Abstract

PURPOSE

Dynamic glucose-enhanced (DGE) MRI relates to a group of exchange-based MRI techniques where the uptake of glucose analogues is studied dynamically. However, motion artifacts can be mistaken for true DGE effects, while motion correction may alter true signal effects. The aim was to design a numerical human brain phantom to simulate a realistic DGE MRI protocol at 3T that can be used to assess the influence of head movement on the signal before and after retrospective motion correction.

METHODS

MPRAGE data from a tumor patient were used to simulate dynamic Z-spectra under the influence of motion. The DGE responses for different tissue types were simulated, creating a ground truth. Rigid head movement patterns were applied as well as physiological dilatation and pulsation of the lateral ventricles and head-motion-induced B -changes in presence of first-order shimming. The effect of retrospective motion correction was evaluated.

RESULTS

Motion artifacts similar to those previously reported for in vivo DGE data could be reproduced. Head movement of 1 mm translation and 1.5 degrees rotation led to a pseudo-DGE effect on the order of 1% signal change. B effects due to head motion altered DGE changes due to a shift in the water saturation spectrum. Pseudo DGE effects were partly reduced or enhanced by rigid motion correction depending on tissue location.

CONCLUSION

DGE MRI studies can be corrupted by motion artifacts. Designing post-processing methods using retrospective motion correction including B correction will be crucial for clinical implementation. The proposed phantom should be useful for evaluation and optimization of such techniques.

摘要

目的

动态葡萄糖增强(DGE)MRI 属于一组基于交换的 MRI 技术,其中研究了葡萄糖类似物的动态摄取。然而,运动伪影可能被误认为是真正的 DGE 效应,而运动校正可能会改变真正的信号效应。目的是设计一个数值人脑模型,以模拟在 3T 下进行的真实 DGE MRI 方案,该模型可用于评估在回顾性运动校正之前和之后头部运动对信号的影响。

方法

使用肿瘤患者的 MPRAGE 数据模拟受运动影响的动态 Z 谱。模拟不同组织类型的 DGE 反应,创建一个真实情况。还应用了刚性头部运动模式以及侧脑室的生理扩张和脉动以及存在一阶匀场的头部运动引起的 B 变化。评估了回顾性运动校正的效果。

结果

可以再现类似于先前报道的体内 DGE 数据中的运动伪影。1mm 平移和 1.5 度旋转的头部运动会导致大约 1%的信号变化的伪 DGE 效应。由于头部运动引起的 B 效应改变了由于水饱和谱移位引起的 DGE 变化。刚性运动校正会根据组织位置部分减少或增强伪 DGE 效应。

结论

DGE MRI 研究可能会受到运动伪影的干扰。使用包括 B 校正的回顾性运动校正设计后处理方法对于临床实施至关重要。所提出的模型应有助于评估和优化此类技术。

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Characterisation of Children's Head Motion for Magnetic Resonance Imaging With and Without General Anaesthesia.
Front Radiol. 2021 Dec 3;1:789632. doi: 10.3389/fradi.2021.789632. eCollection 2021.
2
Imaging of sugar-based contrast agents using their hydroxyl proton exchange properties.
NMR Biomed. 2023 Jun;36(6):e4784. doi: 10.1002/nbm.4784. Epub 2022 Jul 24.
3
Dynamic contrast-enhanced CEST MRI using a low molecular weight dextran.
NMR Biomed. 2022 Mar;35(3):e4649. doi: 10.1002/nbm.4649. Epub 2021 Nov 15.
4
Towards robust glucose chemical exchange saturation transfer imaging in humans at 3 T: Arterial input function measurements and the effects of infusion time.
NMR Biomed. 2022 Feb;35(2):e4624. doi: 10.1002/nbm.4624. Epub 2021 Sep 29.
5
Stroke.
Lancet. 2020 Jul 11;396(10244):129-142. doi: 10.1016/S0140-6736(20)31179-X.
6
Altered d-glucose in brain parenchyma and cerebrospinal fluid of early Alzheimer's disease detected by dynamic glucose-enhanced MRI.
Sci Adv. 2020 May 13;6(20):eaba3884. doi: 10.1126/sciadv.aba3884. eCollection 2020 May.
7
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8
Quantification of hydroxyl exchange of D-Glucose at physiological conditions for optimization of glucoCEST MRI at 3, 7 and 9.4 Tesla.
NMR Biomed. 2019 Sep;32(9):e4113. doi: 10.1002/nbm.4113. Epub 2019 Jul 17.
9
T1ρ-based dynamic glucose-enhanced (DGEρ) MRI at 3 T: method development and early clinical experience in the human brain.
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10
Arterial Input Functions and Tissue Response Curves in Dynamic Glucose-Enhanced (DGE) Imaging: Comparison Between glucoCEST and Blood Glucose Sampling in Humans.
Tomography. 2018 Dec;4(4):164-171. doi: 10.18383/j.tom.2018.00025.

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