1.5 T 临床磁共振成像高度加速螺旋桨扩散的改进重构

IF 2 4区 医学 Q3 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING Magnetic Resonance Materials in Physics, Biology and Medicine Pub Date : 2024-02-22 DOI:10.1007/s10334-023-01142-7
Uten Yarach, Itthi Chatnuntawech, Kawin Setsompop, Atita Suwannasak, Salita Angkurawaranon, Chakri Madla, Charuk Hanprasertpong, Prapatsorn Sangpin
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引用次数: 0

摘要

目的螺旋桨快速自旋回波弥散磁共振成像(FSE-dMRI)对胆脂瘤的诊断至关重要。然而,在临床 1.5 T 磁共振成像中,其信噪比(SNR)仍然相对较低。为了获得足够的信噪比,通常会使用信号平均(激发次数,NEX),但代价是延长扫描时间。在这项工作中,我们利用局部低秩重构(LLR)的优势来提高信噪比。此外,我们还在 1.5 T 临床扫描仪上使用卷积神经网络(CNN)来加速螺旋桨 FSE-dMRI 扫描,从而提高了扫描速度和信噪比。训练该网络预测通过局部低秩 (LLR) 约束重建获得的 2-NEX 图像,并使用通过简化重建获得的 1-NEX 图像作为输入。对健康志愿者和胆脂瘤患者的脑部扫描进行了模型训练和测试。用归一化均方根误差(NRMSE)、结构相似性指数(SSIM)和峰值 SNR(PSNR)评估了训练网络的性能。离线 LLR 可以抑制噪声并发现一些小结构。与 LLR 相比,RU-Net 的 PSNR 提高了 18.87%,SSIM 提高了 2.11%,NRMSE 降低了 53.84%,显示出进一步的改进。此外,RU-Net 比 LLR 快约 1500 倍(0.03 对 47.59 秒/片)。此外,RU-Net 在 PSNR、SSIM 和 NRMSE 方面也改善了螺旋桨 FSE-dMRI。它只需要 1-NEX 数据,扫描时间缩短了 2 倍。此外,其速度比 LLR 约束重建快约 1500 倍。
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Improved reconstruction for highly accelerated propeller diffusion 1.5 T clinical MRI

Purpose

Propeller fast-spin-echo diffusion magnetic resonance imaging (FSE-dMRI) is essential for the diagnosis of Cholesteatoma. However, at clinical 1.5 T MRI, its signal-to-noise ratio (SNR) remains relatively low. To gain sufficient SNR, signal averaging (number of excitations, NEX) is usually used with the cost of prolonged scan time. In this work, we leveraged the benefits of Locally Low Rank (LLR) constrained reconstruction to enhance the SNR. Furthermore, we enhanced both the speed and SNR by employing Convolutional Neural Networks (CNNs) for the accelerated PROPELLER FSE-dMRI on a 1.5 T clinical scanner.

Methods

Residual U-Net (RU-Net) was found to be efficient for propeller FSE-dMRI data. It was trained to predict 2-NEX images obtained by Locally Low Rank (LLR) constrained reconstruction and used 1-NEX images obtained via simplified reconstruction as the inputs. The brain scans from healthy volunteers and patients with cholesteatoma were performed for model training and testing. The performance of trained networks was evaluated with normalized root-mean-square-error (NRMSE), structural similarity index measure (SSIM), and peak SNR (PSNR).

Results

For 4 × under-sampled with 7 blades data, online reconstruction appears to provide suboptimal images—some small details are missing due to high noise interferences. Offline LLR enables suppression of noises and discovering some small structures. RU-Net demonstrated further improvement compared to LLR by increasing 18.87% of PSNR, 2.11% of SSIM, and reducing 53.84% of NRMSE. Moreover, RU-Net is about 1500 × faster than LLR (0.03 vs. 47.59 s/slice).

Conclusion

The LLR remarkably enhances the SNR compared to online reconstruction. Moreover, RU-Net improves propeller FSE-dMRI as reflected in PSNR, SSIM, and NRMSE. It requires only 1-NEX data, which allows a 2 × scan time reduction. In addition, its speed is approximately 1500 times faster than that of LLR-constrained reconstruction.

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来源期刊
CiteScore
4.60
自引率
0.00%
发文量
58
审稿时长
>12 weeks
期刊介绍: MAGMA is a multidisciplinary international journal devoted to the publication of articles on all aspects of magnetic resonance techniques and their applications in medicine and biology. MAGMA currently publishes research papers, reviews, letters to the editor, and commentaries, six times a year. The subject areas covered by MAGMA include: advances in materials, hardware and software in magnetic resonance technology, new developments and results in research and practical applications of magnetic resonance imaging and spectroscopy related to biology and medicine, study of animal models and intact cells using magnetic resonance, reports of clinical trials on humans and clinical validation of magnetic resonance protocols.
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