Aliphatic and Olefinic Fat Suppression in the Orbit Using Polarity-altered Spectral and Spatial Selective Acquisition (PASTA) with Opposed Phase.

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
ACS Applied Bio Materials Pub Date : 2024-04-01 Epub Date: 2023-03-23 DOI:10.2463/mrms.mp.2022-0073
Vadim Malis, Won C Bae, Asako Yamamoto, Yoshimori Kassai, Marin A McDonald, Mitsue Miyazaki
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引用次数: 0

Abstract

Purpose: Fatty acid composition of the orbit makes it challenging to achieve complete fat suppression during orbit MR imaging. Implementation of a fat suppression technique capable of suppressing signals from saturated (aliphatic) and unsaturated (olefinic or protons at double-bonded carbon sites) fat would improve the visualization of an optical nerve. Furthermore, the ability to semi-quantify the fractions of aliphatic and olefinic fat may potentially provide valuable information in assessing orbit pathology.

Methods: A phantom study was conducted on various oil samples on a clinical 3 Tesla scanner. The imaging protocol included three 2D fast spin echo (FSE) sequences: in-phase, polarity-altered spectral and spatial selective acquisition (PASTA), and a combination of PASTA with opposed phase in olefinic and aliphatic chemical shift. The results were validated against high-resolution 11.7T NMR and compared with images acquired with spectral attenuated inversion recovery (SPAIR) and chemical shift selective (CHESS) fat suppression techniques. In-vivo data were acquired on eight healthy subjects and were compared with the prior histological studies.

Results: PASTA with opposed phase achieved complete suppression of fat signals in the orbits and provided images of well-delineated optical nerves and muscles in all subjects. The olefinic fat fraction in the olive, walnut, and fish oil phantoms at 3T was found to be 5.0%, 11.2%, and 12.8%, respectively, whereas 11.7T NMR provides the following olefinic fat fractions: 6.0% for olive, 11.5% for walnut, and 12.6% for fish oils. For the in-vivo study, on average, olefinic fat accounted for 9.9% ± 3.8% of total fat while the aliphatic fat fraction was 90.1% ± 3.8%, in the normal orbits.

Conclusion: We have introduced a new fat suppression technique using PASTA with opposed phase and applied it to human orbits. The purposed method achieves an excellent orbital fat suppression and the quantification of aliphatic and olefinic fat signals.

利用相位相反的极性改变光谱和空间选择性采集(PASTA)抑制轨道上的脂肪族和烯烃族脂肪。
目的:眼眶的脂肪酸组成使得在眼眶磁共振成像中实现完全的脂肪抑制具有挑战性。采用一种脂肪抑制技术,能够抑制饱和脂肪(脂肪族)和不饱和脂肪(烯烃或双键碳位点上的质子)的信号,从而改善光神经的可视化。此外,半量化脂肪和烯烃脂肪的能力可能会为评估轨道病变提供有价值的信息:方法:在临床 3 特斯拉扫描仪上对各种油脂样本进行了模型研究。成像方案包括三种二维快速自旋回波(FSE)序列:同相、极性改变光谱和空间选择性采集(PASTA),以及 PASTA 与烯烃和脂肪化学位移对相的组合。结果与高分辨率 11.7T NMR 进行了验证,并与光谱衰减反转恢复(SPAIR)和化学位移选择(CHESS)脂肪抑制技术获得的图像进行了比较。对八名健康受试者采集了体内数据,并与之前的组织学研究进行了比较:结果:采用对置相位的 PASTA 技术完全抑制了眼眶中的脂肪信号,并为所有受试者提供了界限清晰的光学神经和肌肉图像。在 3T 下,橄榄油、核桃油和鱼油模型中的烯烃脂肪比例分别为 5.0%、11.2% 和 12.8%,而 11.7T NMR 可提供以下烯烃脂肪比例:橄榄油为 6.0%,核桃油为 11.5%,鱼油为 12.6%。在体内研究中,烯烃脂肪平均占总脂肪的 9.9% ± 3.8%,而脂肪族脂肪在正常眼眶中占 90.1% ± 3.8%:我们引入了一种新的脂肪抑制技术--PASTA 对置相位,并将其应用于人体眼眶。该方法能很好地抑制眼眶脂肪,并对脂肪和烯烃脂肪信号进行量化。
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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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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