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稀疏SEMAC:使用稀疏感知加速实现快速且改进的SEMAC金属植入物成像。

Sparse-SEMAC: rapid and improved SEMAC metal implant imaging using SPARSE-SENSE acceleration.

作者信息

Otazo Ricardo, Nittka Mathias, Bruno Mary, Raithel Esther, Geppert Christian, Gyftopoulos Soterios, Recht Michael, Rybak Leon

机构信息

Department of Radiology, NYU School of Medicine, New York, New York, USA.

Siemens Healthcare GmbH, Erlangen, Germany.

出版信息

Magn Reson Med. 2017 Jul;78(1):79-87. doi: 10.1002/mrm.26342. Epub 2016 Jul 25.

DOI:10.1002/mrm.26342
PMID:27454003
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5266741/
Abstract

PURPOSE

To develop an accelerated SEMAC metal implant MRI technique (Sparse-SEMAC) with reduced scan time and improved metal distortion correction.

METHODS

Sparse-SEMAC jointly exploits the inherent sparsity along the additional phase-encoding dimension and multicoil encoding capabilities to significantly accelerate data acquisition. A prototype pulse sequence with pseudorandom k -k undersampling and an inline image reconstruction was developed for integration in clinical studies. Three patients with hip implants were imaged using the proposed Sparse-SEMAC with eight-fold acceleration and compared with the standard-SEMAC technique used in clinical studies (three-fold GRAPPA acceleration). Measurements were performed with SEMAC-encoding steps (SES) = 15 for Sparse-SEMAC and SES = 9 for Standard-SEMAC using high spatial resolution Proton Density (PD) and lower-resolution STIR acquisitions. Two expert musculoskeletal (MSK) radiologists performed a consensus reading to score image-quality parameters.

RESULTS

Sparse-SEMAC enables up to eight-fold acceleration of data acquisition that results in two-fold scan time reductions, compared with Standard-SEMAC, with improved metal artifact correction for patients with hip implants without degrading spatial resolution.

CONCLUSION

The high acceleration enabled by Sparse-SEMAC would enable clinically feasible examination times with improved correction of metal distortion. Magn Reson Med 78:79-87, 2017. © 2016 International Society for Magnetic Resonance in Medicine.

摘要

目的

开发一种加速的SEMAC金属植入物MRI技术(稀疏SEMAC),以减少扫描时间并改善金属畸变校正。

方法

稀疏SEMAC联合利用沿附加相位编码维度的固有稀疏性和多线圈编码能力,以显著加速数据采集。开发了一种具有伪随机k空间欠采样和在线图像重建的原型脉冲序列,用于临床研究。对三名髋关节植入物患者使用提出的八倍加速的稀疏SEMAC进行成像,并与临床研究中使用的标准SEMAC技术(三倍GRAPPA加速)进行比较。使用高空间分辨率质子密度(PD)和低分辨率短TI反转恢复(STIR)采集,对稀疏SEMAC采用SEMAC编码步长(SES)=15,对标准SEMAC采用SES=9进行测量。两名专业肌肉骨骼(MSK)放射科医生进行了一致性读片,以对图像质量参数进行评分。

结果

与标准SEMAC相比,稀疏SEMAC能够将数据采集加速高达八倍,从而使扫描时间减少一半,同时在不降低空间分辨率的情况下,改善了髋关节植入物患者的金属伪影校正。

结论

稀疏SEMAC实现的高加速将使临床上可行的检查时间得以实现,同时改善金属畸变校正。《磁共振医学》78:79 - 87,2017年。©2016国际磁共振医学学会。

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