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人脑的二维J分辨激光和半激光光谱学。

Two-dimensional J-resolved LASER and semi-LASER spectroscopy of human brain.

作者信息

Lin Meijin, Kumar Anand, Yang Shaolin

机构信息

Department of Psychiatry, University of Illinois at Chicago, Chicago, Illinois, USA.

出版信息

Magn Reson Med. 2014 Mar;71(3):911-20. doi: 10.1002/mrm.24732.

DOI:10.1002/mrm.24732
PMID:23605818
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4082480/
Abstract

PURPOSE

Two-dimensional J-resolved localized and semi-localized by adiabatic selective refocusing (LASER and semi-LASER) spectroscopy, named "J-resolved LASER" and "J-resolved semi-LASER", were introduced to suppress chemical shift artifacts, additional J-refocused artifactual peaks from spatially dependent J-coupling evolution, and sensitivity to radiofrequency (RF) field inhomogeneity.

METHODS

Three pairs of adiabatic pulses were employed for voxel localization in J-resolved LASER and two pairs in J-resolved semi-LASER. The first half of t1 period was inserted between the last pair of adiabatic pulses, which was proposed in this work to obtain two-dimensional adiabatic J-resolved spectra of human brain for the first time. Phantom and human experiments were performed to demonstrate their feasibility and advantages over conventional J-resolved spectroscopy (JPRESS).

RESULTS

Compared to JPRESS, J-resolved LASER or J-resolved semi-LASER exhibited significant suppression of chemical shift artifacts and additional J-refocused peaks from spatially dependent J-coupling evolution, and demonstrated insensitivity to the change of RF frequency offset over large bandwidth.

CONCLUSION

Experiments on phantoms and human brains verified the feasibility and strengths of two-dimensional adiabatic J-resolved spectroscopy at 3T. This technique is expected to advance the application of in vivo two-dimensional MR spectroscopy at 3T and higher field strengths for more reliable and accurate quantification of metabolites.

摘要

目的

引入二维绝热选择性重聚焦定位和半定位J分辨谱(LASER和半LASER),即“J分辨LASER”和“J分辨半LASER”,以抑制化学位移伪影、空间依赖性J耦合演化产生的额外J重聚焦伪峰以及对射频(RF)场不均匀性的敏感性。

方法

在J分辨LASER中使用三对绝热脉冲进行体素定位,在J分辨半LASER中使用两对绝热脉冲。在最后一对绝热脉冲之间插入t1期的前半部分,这是本研究首次提出的,用于获取人脑的二维绝热J分辨谱。进行了体模和人体实验,以证明其可行性以及相对于传统J分辨谱(JPRESS)的优势。

结果

与JPRESS相比,J分辨LASER或J分辨半LASER显著抑制了化学位移伪影和空间依赖性J耦合演化产生的额外J重聚焦峰,并在大带宽范围内对RF频率偏移的变化表现出不敏感性。

结论

体模和人脑实验验证了3T下二维绝热J分辨谱的可行性和优势。该技术有望推动3T及更高场强下体内二维磁共振波谱在代谢物更可靠、准确量化方面的应用。

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