使用优化的波-CAIPI 编码进行高速容积脑检查。
Highly-accelerated volumetric brain examination using optimized wave-CAIPI encoding.
机构信息
Department of Physics and Astronomy, Heidelberg University, Heidelberg, Germany.
Department of Radiology, A. A. Martinos Center for Biomedical Imaging, Massachusetts General Hospital, Charlestown, Massachusetts, USA.
出版信息
J Magn Reson Imaging. 2019 Sep;50(3):961-974. doi: 10.1002/jmri.26678. Epub 2019 Feb 8.
BACKGROUND
Rapid volumetric imaging protocols could better utilize limited scanner resources.
PURPOSE
To develop and validate an optimized 6-minute high-resolution volumetric brain MRI examination using Wave-CAIPI encoding.
STUDY TYPE
Prospective.
POPULATION/SUBJECTS: Ten healthy subjects and 20 patients with a variety of intracranial pathologies.
FIELD STRENGTH/SEQUENCE: At 3 T, MPRAGE, T -weighted SPACE, SPACE FLAIR, and SWI were acquired at 9-fold acceleration using Wave-CAIPI and for comparison at 2-4-fold acceleration using conventional GRAPPA.
ASSESSMENT
Extensive simulations were performed to optimize the Wave-CAIPI protocol and minimize both g-factor noise amplification and potential T /T blurring artifacts. Moreover, refinements in the autocalibrated reconstruction of Wave-CAIPI were developed to ensure high-quality reconstructions in the presence of gradient imperfections. In a randomized and blinded fashion, three neuroradiologists assessed the diagnostic quality of the optimized 6-minute Wave-CAIPI exam and compared it to the roughly 3× slower GRAPPA accelerated protocol using both an individual and head-to-head analysis.
STATISTICAL TEST
A noninferiority test was used to test whether the diagnostic quality of Wave-CAIPI was noninferior to the GRAPPA acquisition, with a 15% noninferiority margin.
RESULTS
Among all sequences, Wave-CAIPI achieved negligible g-factor noise amplification (g ≤ 1.04) and burring artifacts from T /T relaxation. Improvements of our autocalibration approach for gradient imperfections enabled increased robustness to gradient mixing imperfections in tilted-field of view (FOV) prescriptions as well as variations in gradient and analog-to-digital converter (ADC) sampling rates. In the clinical evaluation, Wave-CAIPI achieved similar mean scores when compared with GRAPPA (MPRAGE: Ø = 4.03, Ø = 3.97; T w SPACE: Ø = 4.00, Ø = 4.00; SPACE FLAIR: Ø = 3.97, Ø = 3.97; SWI: Ø = 3.93, Ø = 3.83) and was statistically noninferior (N = 30, P < 0.05 for all sequences).
DATA CONCLUSION
The proposed volumetric brain exam retained comparable image quality when compared with the much longer conventional protocol.
LEVEL OF EVIDENCE
2 Technical Efficacy: Stage 1 J. Magn. Reson. Imaging 2019;50:961-974.
背景
快速容积成像方案可以更好地利用有限的扫描仪资源。
目的
利用 Wave-CAIPI 编码开发和验证一种优化的 6 分钟高分辨率容积脑 MRI 检查。
研究类型
前瞻性。
人群/受试者:10 名健康受试者和 20 名患有各种颅内病变的患者。
磁场强度/序列:在 3T 下,使用 Wave-CAIPI 以 9 倍加速采集 MPRAGE、T2 加权空间、空间 FLAR 和 SWI,以及使用传统 GRAPPA 以 2-4 倍加速采集进行比较。
评估
进行了广泛的模拟以优化 Wave-CAIPI 方案,最大程度地减少 g 因子噪声放大和潜在的 T/T 模糊伪影。此外,还开发了 Wave-CAIPI 的自动校准重建的改进,以确保在存在梯度缺陷的情况下进行高质量的重建。三位神经放射学家以随机和盲法方式评估了优化的 6 分钟 Wave-CAIPI 检查的诊断质量,并使用个体和头对头分析将其与大约 3 倍较慢的 GRAPPA 加速方案进行了比较。
统计检验
使用非劣效检验来检验 Wave-CAIPI 的诊断质量是否不劣于 GRAPPA 采集,非劣效性边界为 15%。
结果
在所有序列中,Wave-CAIPI 实现了可忽略的 g 因子噪声放大(g≤1.04)和 T/T 弛豫引起的模糊伪影。我们对梯度缺陷自动校准方法的改进使得在倾斜视野(FOV)处方以及梯度和模数转换器(ADC)采样率的变化中增加了对梯度混合缺陷的鲁棒性。在临床评估中,与 GRAPPA 相比,Wave-CAIPI 获得了相似的平均评分(MPRAGE:Ø=4.03,Ø=3.97;T2 加权空间:Ø=4.00,Ø=4.00;SPACE FLAIR:Ø=3.97,Ø=3.97;SWI:Ø=3.93,Ø=3.83),且具有统计学非劣效性(N=30,所有序列 P<0.05)。
数据结论
与更长的传统方案相比,所提出的容积脑检查保留了相当的图像质量。
证据水平
2 技术功效:第 1 阶段 J. Magn. Reson. Imaging 2019;50:961-974.
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