Deep Learning-Based Denoising for High b-Value at 2000 s/mm2 Diffusion-Weighted Imaging.

Q3 Engineering Critical Reviews in Biomedical Engineering Pub Date : 2021-01-01 DOI:10.1615/CritRevBiomedEng.2022040279

Seema S Bhat, Pavan Poojar, Chennagiri Rajarao Padma, Rishi Kashyap Ananth, M C Hanumantharaju, Sairam Geethanath

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Abstract

Diffusion-weighted imaging (DWI) allows white matter quantification of the white matter tracts of the brain. However, at a high b-value (≥ 2000 s/mm2), DWI acquisition suffers from noise due to longer acquisition times obscuring white matter interpretation. DWI denoising techniques can be used to acquire high b-value DWI without increasing the number of signal averages. We used a residual learning-based convolutional neural network (DnCNN) to reduce noise in high b-value DWI based on the literature review. We applied the proposed denoising method on high b-value, retrospectively collected DWI data with multiple noise levels. Experimental results show an improved image quality after denoising in retrospective DWI (average PSNR before and after denoising: 27.63 ± 1.06 dB and 51.76 ± 1.95 dB, respectively). The prospective DWI included one and two signal averages for denoising. DWI with four signal averages was used as the reference. Representative images show high b-value prospective DW images denoised using the DnCNN. We demonstrated DnCNN for cases of multiple noise levels and signal averages. For the prospective study, the PSNR values for 1-NEX before and after denoising were 27.39 ± 3.75 dB and 27.68 ± 3.75 dB. For 2-NEX, the PSNR values before and after denoising were 27.51 ± 4.18 dB and 27.75 ± 4.05 dB.

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基于深度学习的2000 s/mm2弥散加权成像高b值去噪。

弥散加权成像(DWI)可以对脑白质束进行白质量化。然而，在高b值(≥2000 s/mm2)时，由于较长的采集时间模糊了白质解释，DWI采集受到噪声的影响。DWI去噪技术可以在不增加信号平均次数的情况下获得高b值DWI。在文献综述的基础上，采用基于残差学习的卷积神经网络(DnCNN)对高b值DWI进行降噪。我们将提出的去噪方法应用于高b值，回顾性收集的具有多个噪声水平的DWI数据。实验结果表明，去噪后的回顾性DWI图像质量得到了改善(去噪前后的平均PSNR分别为27.63±1.06 dB和51.76±1.95 dB)。预期DWI包括一个和两个信号平均去噪。以四次信号平均的DWI作为参考。代表性图像显示使用DnCNN去噪的高b值前瞻性DW图像。我们在多个噪声水平和信号平均的情况下演示了DnCNN。前瞻性研究中，1-NEX去噪前后的PSNR分别为27.39±3.75 dB和27.68±3.75 dB。2-NEX去噪前后的PSNR分别为27.51±4.18 dB和27.75±4.05 dB。

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来源期刊

Critical Reviews in Biomedical Engineering Engineering-Biomedical Engineering

CiteScore

1.80

自引率

0.00%

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期刊介绍： Biomedical engineering has been characterized as the application of concepts drawn from engineering, computing, communications, mathematics, and the physical sciences to scientific and applied problems in the field of medicine and biology. Concepts and methodologies in biomedical engineering extend throughout the medical and biological sciences. This journal attempts to critically review a wide range of research and applied activities in the field. More often than not, topics chosen for inclusion are concerned with research and practice issues of current interest. Experts writing each review bring together current knowledge and historical information that has led to the current state-of-the-art.