Sara Ponticorvo, Antonietta Canna, Steen Moeller, Mehmet Akcakaya, Gregory J Metzger, Pavel Filip, Lynn E Eberly, Shalom Michaeli, Silvia Mangia
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RFR acquisitions at 3 T were obtained from eight healthy participants (seven males and one female) aged 52 ± 20 years, including adiabatic T1ρ, T2ρ, and nonadiabatic Relaxation Along a Fictitious Field (RAFF) in the rotating frame of rank n = 4 (RAFF4) with both 1.6 x 1.6 x 3.6 mm<sup>3</sup> and 1.25 x 1.25 x 2 mm<sup>3</sup> image resolutions. We compared RFR values and their confidence intervals (CIs) obtained from fitting the denoised versus nondenoised images, at both voxel and regional levels separately for each resolution and RFR metric. The comparison of metrics obtained from denoised versus nondenoised images was performed with a two-sample paired t-test and statistical significance was set at p less than 0.05 after Bonferroni correction for multiple comparisons. The use of T-NORDIC on the RFR images prior to the fitting procedure decreases the uncertainty of parameter estimation (lower CIs) at both spatial resolutions. 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引用次数: 0
摘要
旋转框架弛豫(RFR)时间常数的定量图是评估体内组织完整性的灵敏而有用的磁共振成像工具。然而,迄今为止,只有 1.6 x 1.6 x 3.6 mm3 的中等图像分辨率被用于 3 T 下的人体全脑覆盖 RFR 地图绘制。要进行更精确的形态学检查,需要更高的空间分辨率。为了实现在不增加扫描时间的情况下提高 RFR 图谱空间分辨率的长期目标,我们探索使用最近推出的变换域降噪与分布校正主成分分析(T-NORDIC)算法来降低热噪声。我们对八名健康参与者(七男一女)进行了 3 T 的 RFR 采集,他们的年龄在 52 ± 20 岁之间,采集内容包括绝热 T1ρ、T2ρ 和非绝热沿虚构场松弛(RAFF),旋转框架的等级为 n = 4 (RAFF4),图像分辨率分别为 1.6 x 1.6 x 3.6 mm3 和 1.25 x 1.25 x 2 mm3。我们比较了去噪与非去噪图像拟合得到的 RFR 值及其置信区间 (CI),在体素和区域层面分别针对每种分辨率和 RFR 指标进行了比较。去噪图像与非去噪图像的指标比较采用双样本配对 t 检验,经 Bonferroni 多重比较校正后,统计显著性设定为 p 小于 0.05。在拟合程序之前对 RFR 图像使用 T-NORDIC 可降低两种空间分辨率下参数估计的不确定性(CI 值降低)。在 RAFF4 的高空间分辨率下,这种效果尤为突出。此外,T-NORDIC 不会降低地图质量,对 RFR 值的影响也很小。使用 T-NORDIC 对 RFR 图像进行去噪可改善参数估计,同时保持所有 RFR 地图的图像质量和准确性,最终使高分辨率 RFR 地图的扫描时间适合临床应用。
Reducing thermal noise in high-resolution quantitative magnetic resonance imaging rotating frame relaxation mapping of the human brain at 3 T.
Quantitative maps of rotating frame relaxation (RFR) time constants are sensitive and useful magnetic resonance imaging tools with which to evaluate tissue integrity in vivo. However, to date, only moderate image resolutions of 1.6 x 1.6 x 3.6 mm3 have been used for whole-brain coverage RFR mapping in humans at 3 T. For more precise morphometrical examinations, higher spatial resolutions are desirable. Towards achieving the long-term goal of increasing the spatial resolution of RFR mapping without increasing scan times, we explore the use of the recently introduced Transform domain NOise Reduction with DIstribution Corrected principal component analysis (T-NORDIC) algorithm for thermal noise reduction. RFR acquisitions at 3 T were obtained from eight healthy participants (seven males and one female) aged 52 ± 20 years, including adiabatic T1ρ, T2ρ, and nonadiabatic Relaxation Along a Fictitious Field (RAFF) in the rotating frame of rank n = 4 (RAFF4) with both 1.6 x 1.6 x 3.6 mm3 and 1.25 x 1.25 x 2 mm3 image resolutions. We compared RFR values and their confidence intervals (CIs) obtained from fitting the denoised versus nondenoised images, at both voxel and regional levels separately for each resolution and RFR metric. The comparison of metrics obtained from denoised versus nondenoised images was performed with a two-sample paired t-test and statistical significance was set at p less than 0.05 after Bonferroni correction for multiple comparisons. The use of T-NORDIC on the RFR images prior to the fitting procedure decreases the uncertainty of parameter estimation (lower CIs) at both spatial resolutions. The effect was particularly prominent at high-spatial resolution for RAFF4. Moreover, T-NORDIC did not degrade map quality, and it had minimal impact on the RFR values. Denoising RFR images with T-NORDIC improves parameter estimation while preserving the image quality and accuracy of all RFR maps, ultimately enabling high-resolution RFR mapping in scan times that are suitable for clinical settings.
期刊介绍:
NMR in Biomedicine is a journal devoted to the publication of original full-length papers, rapid communications and review articles describing the development of magnetic resonance spectroscopy or imaging methods or their use to investigate physiological, biochemical, biophysical or medical problems. Topics for submitted papers should be in one of the following general categories: (a) development of methods and instrumentation for MR of biological systems; (b) studies of normal or diseased organs, tissues or cells; (c) diagnosis or treatment of disease. Reports may cover work on patients or healthy human subjects, in vivo animal experiments, studies of isolated organs or cultured cells, analysis of tissue extracts, NMR theory, experimental techniques, or instrumentation.
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