最佳收缩去噪打破高分辨率弥散核磁共振成像的噪声底限

IF 6.7 Q1 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE

Patterns Pub Date : 2024-03-14 DOI:10.1016/j.patter.2024.100954

Khoi Huynh, Wei-Tang Chang, Ye Wu, Pew-Thian Yap

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引用次数: 0

摘要

扩散磁共振（MR）成像所能达到的空间分辨率本身就受到噪声的限制。由于磁共振幅值信号的非高斯性质，与较小体素尺寸相关的较弱信号，尤其是在高弥散敏化水平时，往往被掩盖在噪声底之下。在这里，我们展示了如何通过对来自多个接收通道的复值 k 空间数据中与噪声相关的奇异值进行优化收缩来显著抑制噪声底。我们探索并比较了不同的低秩信号矩阵恢复策略，以利用来自多个信道的固有冗余信息。结合背景相位去除，最佳策略可将本底噪声降低 11 倍。我们的框架大大提高了成像的分辨率，无需依赖昂贵的硬件升级和耗时的重复采集，就能精确表征组织微观结构和白质通路，其性能优于其他相关的去噪方法。

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Optimal shrinkage denoising breaks the noise floor in high-resolution diffusion MRI

The spatial resolution attainable in diffusion magnetic resonance (MR) imaging is inherently limited by noise. The weaker signal associated with a smaller voxel size, especially at a high level of diffusion sensitization, is often buried under the noise floor owing to the non-Gaussian nature of the MR magnitude signal. Here, we show how the noise floor can be suppressed remarkably via optimal shrinkage of singular values associated with noise in complex-valued k-space data from multiple receiver channels. We explore and compare different low-rank signal matrix recovery strategies to utilize the inherently redundant information from multiple channels. In combination with background phase removal, the optimal strategy reduces the noise floor by 11 times. Our framework enables imaging with substantially improved resolution for precise characterization of tissue microstructure and white matter pathways without relying on expensive hardware upgrades and time-consuming acquisition repetitions, outperforming other related denoising methods.

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