收稿日期: 2021-02-18
网络出版日期: 2022-06-28
基金资助
上海市“科技创新行动计划”产学研医合作领域项目(18DZ1930103)
Application value of new accelerating technology based on constellation shuttling imaging in brain MRI
Received date: 2021-02-18
Online published: 2022-06-28
目的:评估基于光梭成像(constellation shuttling imaging,uCS)技术加速的颅脑MRI图像质量及扫描时间,为其在临床常规化应用提供依据。 方法:20名志愿者每人接受2次颅脑MRI扫描,包括快速自旋回波轴位T1加权成像(T1-weighted imaging, T1WI)、T2-液体抑制反转恢复序列(fluid attenuated inversion recovery sequence, FLAIR)、矢状位T1WI及梯度回波矢状位3D-T1WI序列扫描,分别采用并行采集技术(即常规扫描)和uCS加速技术,记录并比较扫描时间。采用主观(Likert 5级评分法,内容包括图像伪影及整体质量)与客观(定量测定图像信噪比)相结合的方法,对各序列采集的图像质量进行综合评价。 结果:基于uCS技术加速后的颅脑MRI扫描时间均比常规扫描时间缩短约26.3%(542 s比735 s),其中3D序列时间缩短尤为明显,达39.0%。在图像整体质量及伪影评估方面,各项uCS加速序列与常规扫描序列之间差异均无统计学意义(P>0.05)。在信噪比方面,uCS轴位及矢状位T1WI序列的信噪比显著高于常规扫描轴位及矢状位T1WI序列(P<0.05)。uCS加速的FLAIR及3D-T1WI与常规扫描序列相比,信噪比差异没有统计学意义(P>0.05)。 结论:与常规MRI序列扫描相比, uCS技术可以显著缩短脑部MRI的图像采集时长,同时能保证图像质量。
张雪坤, 李彦, 严福华, 赵洪飞, 宋琦 . 基于光梭成像的新型加速技术在颅脑MRI中的应用价值研究[J]. 诊断学理论与实践, 2021 , 20(04) : 378 -383 . DOI: 10.16150/j.1671-2870.2021.04.009
Objective: To evaluate the image quality of brain MRI sequences accelerated by constellation shuttling imaging (uCS) to provide a basis for clinical application. Methods: Twenty volunteers underwent brain MRI scanning (TSE axial T1WI, T2-FLAIR, sagittal T1WI and GRE sagittal 3D-T1WI) twice using parallel imaging (routine scanning) and corresponding uCS accelerated acquisition. The evaluation of images in each sequence was conducted through combining the subjective (Likert five-point scale method, image artifact and overall quality) and objective (signal-to-noise ratio measurement) methods. Results: The scanning time of using uCS in each MRI sequence was shorter than that of conventional scanning. The total scanning time of uCS in each volunteer was 542 s, while that of conventional scanning was 735 s, which decreased 26.3%. The scanning time of 3D sequence was nearly reduced 39%. There is no statistically difference between uCS and conventional sequence in subjective evaluation (overall image quality and image artifact degree). The SNR of uCS axial T1WI and sagittal T1WI sequences was significantly higher than those of conventional axial T1WI and sagittal T1WI sequences(P<0.05). In addition, there was no difference between uCS and conventional scanning in SNR of FLAIR and 3D-T1WI sequences. Conclusions: Compared with conventional scanning, uCS can significantly accelerate the acquisition of brain MR images without loss of image quality.
| [1] | Toledano-Massiah S, Sayadi A, de Boer R, et al. Accuracy of the compressed sensing accelerated 3D-FLAIR sequence for the detection of MS plaques at 3T[J]. AJNR Am J Neuroradiol, 2018,39(3):454-458. |
| [2] | Bratke G, Rau R, Weiss K, et al. Accelerated MRI of the lumbar spine using compressed sensing: quality and efficiency[J]. J Magn Reson Imaging, 2019,49(7):e164-e175. |
| [3] | Chopde N. 10 Times Faster MRI constellation shuttling imaging technology showcased at ISMRM 2018[DB/OL]. 2018[2021-02-18]. https://indiamedtoday.com/10-times-faster-mri-constellation-shuttling-imaging-technology-show-cased-at-ismrm-2018/. |
| [4] | Sharma SD, Fong CL, Tzung BS, et al. Clinical image quality assessment of accelerated magnetic resonance neuroimaging using compressed sensing[J]. Invest Radiol, 2013,48(9):638-645. |
| [5] | Sartoretti T, Reischauer C, Sartoretti E, et al. Common artefacts encountered on images acquired with combined compressed sensing and SENSE[J]. Insights Imaging, 2018,9(6):1107-1115. |
| [6] | Vranic JE, Cross NM, Wang Y, et al. Compressed sen-sing-sensitivity encoding (CS-SENSE) accelerated brain imaging: reduced scan time without reduced image quality[J]. AJNR Am J Neuroradiol, 2019,40(1):92-98. |
| [7] | American College of Radiology. MRI accreditation program clinical image quality guide[R/OL]. 2013-05-22[2021-02-18]. https://www.docin.com/p-671276537.html. |
| [8] | 王思敏, 李彦, 严福华, 等. 不同医用磁共振成像设备在中枢神经系统的临床图像质量评价与比较研究[J]. 磁共振成像, 2019,10(2):83-88. |
| [9] | 康立丽, 江倩, 何秀坚. MR图像信噪比不同测试方法对比研究[J]. 实用放射学杂志, 2009,25(5):729-732. |
| [10] | Pruessmann KP, Weiger M, Scheidegger MB, et al. SENSE: sensitivity encoding for fast MRI[J]. Magn Reson Med, 1999,42(5):952-962. |
| [11] | Jaspan ON, Fleysher R, Lipton ML. Compressed sensing MRI: a review of the clinical literature[J]. Br J Radiol, 2015,88(1056):20150487. |
| [12] | Lustig M, Donoho D, Pauly JM. Sparse MRI: The application of compressed sensing for rapid MR imaging[J]. Magn Reson Med, 2007,58(6):1182-1195. |
| [13] | Tam LK, Galiana G, Stockmann JP, et al. Pseudo-random center placement O-space imaging for improved incohe-rence compressed sensing parallel MRI[J]. Magn Reson Med, 2015,73(6):2212-2224. |
| [14] | Otazo R, Kim D, Axel L, et al. Combination of compressed sensing and parallel imaging for highly accelera-ted first-pass cardiac perfusion MRI[J]. Magn Reson Med, 2010,64(3):767-776. |
| [15] | Liang D, Liu B, Wang J, et al. Accelerating SENSE using compressed sensing[J]. Magn Reson Med, 2009,62(6):1574-1584. |
| [16] | Mönch S, Sollmann N, Hock A, et al. Magnetic resonance imaging of the brain using compressed Sensing- Quality Assessment in Daily Clinical Routine[J]. Clin Neuroradiol, 2020,30(2):279-286. |
| [17] | 张晓东, 朱丽娜, 马帅, 等. 压缩感知技术在头MRA的初步应用探索[J]. 放射学实践, 2018,33(3):252-255. |
| [18] | 李爽, 陆敏杰, 赵世华. 压缩感知技术及其在心脏磁共振中的应用进展[J]. 磁共振成像, 2018,9(4):299-302. |
| [19] | Feng L, Benkert T, Block KT, et al. Compressed sensing for body MRI[J]. J Magn Reson Imaging, 2017,45(4):966-987. |
| [20] | Ding Y, Ying L, Zhang N, et al. Noise behavior of MR brain reconstructions using compressed sensing[J]. Annu Int Conf IEEE Eng Med Biol Soc, 2013,2013:5155-5158. |
| [21] | Eichinger P, Hock A, Schön S, et al. Acceleration of double inversion recovery sequences in multiple sclerosis with compressed sensing[J]. Invest Radiol, 2019,54(6): 319-324. |
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