在 64mT 场强下对新生儿脑组织进行体内 T 映射。

In vivo T mapping of neonatal brain tissue at 64 mT.

机构信息

Center for the Developing Brain, School of Imaging Sciences and Biomedical Engineering, King's College London, London, United Kingdom.

Medical Physics, Guy's & St. Thomas' NHS Foundation Trust, London, United Kingdom.

出版信息

Magn Reson Med. 2023 Mar;89(3):1016-1025. doi: 10.1002/mrm.29509. Epub 2022 Nov 13.

DOI:10.1002/mrm.29509

PMID:36372971

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10099617/

Abstract

PURPOSE

Ultralow-field (ULF) point-of-care MRI systems allow image acquisition without interrupting medical provision, with neonatal clinical care being an important potential application. The ability to measure neonatal brain tissue T is a key enabling technology for subsequent structural image contrast optimization, as well as being a potential biomarker for brain development. Here we describe an optimized strategy for neonatal T mapping at ULF.

METHODS

Examinations were performed on a 64-mT portable MRI system. A phantom validation experiment was performed, and a total of 33 in vivo exams were acquired from 28 neonates with postmenstrual age ranging from 31 to 49 weeks. Multiple inversion-recovery turbo spin-echo sequences were acquired with differing inversion and repetition times. An analysis pipeline incorporating inter-sequence motion correction generated proton density and T maps. Regions of interest were placed in the cerebral deep gray matter, frontal white matter, and cerebellum. Weighted linear regression was used to predict T as a function of postmenstrual age.

RESULTS

Reduction of T with postmenstrual age is observed in all measured brain tissue; the change in T per week and 95% confidence intervals is given by dT = -21 ms/week [-25, -16] (cerebellum), dT = -14 ms/week [-18, -10] (deep gray matter), and dT = -35 ms/week [-45, -25] (white matter).

CONCLUSION

Neonatal T values at ULF are shorter than those previously described at standard clinical field strengths, but longer than those of adults at ULF. T reduces with postmenstrual age and is therefore a candidate biomarker for perinatal brain development.

摘要

目的

超低磁场（ULF）即时护理 MRI 系统允许在不中断医疗服务的情况下进行图像采集，新生儿临床护理是一个重要的潜在应用。测量新生儿脑组织 T 值的能力是后续结构图像对比度优化的关键使能技术，也是大脑发育的潜在生物标志物。本文描述了在 ULF 下进行新生儿 T 映射的优化策略。

方法

在 64-mT 便携式 MRI 系统上进行检查。进行了一项体模验证实验，共对 28 名胎龄为 31 至 49 周的新生儿进行了 33 次体内检查。使用不同的反转和重复时间采集了多个反转恢复涡轮自旋回波序列。一个包含序列间运动校正的分析管道生成了质子密度和 T 图。感兴趣区被放置在大脑深部灰质、额叶白质和小脑。使用加权线性回归预测 T 与胎龄的函数关系。

结果

在所有测量的脑组织中均观察到 T 随胎龄的减少；每周 T 的变化和 95%置信区间为 dT = -21 ms/周 [-25, -16]（小脑），dT = -14 ms/周 [-18, -10]（深部灰质），dT = -35 ms/周 [-45, -25]（白质）。

结论

在 ULF 下，新生儿的 T 值比在标准临床场强下描述的要短，但比 ULF 下的成年人长。T 值随胎龄而减少，因此是围产期大脑发育的候选生物标志物。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/1ca5/10099617/a06f0fb673bd/MRM-89-1016-g007.jpg

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在 64mT 场强下对新生儿脑组织进行体内 T 映射。

In vivo T mapping of neonatal brain tissue at 64 mT.

机构信息

出版信息

PURPOSE

METHODS

RESULTS

CONCLUSION

目的

方法

结果

结论

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