Beyond Nyquist: A Comparative Analysis of 3D Deep Learning Models Enhancing MRI Resolution.

IF 2.7 Q3 IMAGING SCIENCE & PHOTOGRAPHIC TECHNOLOGY Journal of Imaging Pub Date : 2024-08-23 DOI:10.3390/jimaging10090207

Soumick Chatterjee, Alessandro Sciarra, Max Dünnwald, Anitha Bhat Talagini Ashoka, Mayura Gurjar Cheepinahalli Vasudeva, Shudarsan Saravanan, Venkatesh Thirugnana Sambandham, Pavan Tummala, Steffen Oeltze-Jafra, Oliver Speck, Andreas Nürnberger

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Abstract

High-spatial resolution MRI produces abundant structural information, enabling highly accurate clinical diagnosis and image-guided therapeutics. However, the acquisition of high-spatial resolution MRI data typically can come at the expense of less spatial coverage, lower signal-to-noise ratio (SNR), and longer scan time due to physical, physiological and hardware limitations. In order to overcome these limitations, super-resolution MRI deep-learning-based techniques can be utilised. In this work, different state-of-the-art 3D convolution neural network models for super resolution (RRDB, SPSR, UNet, UNet-MSS and ShuffleUNet) were compared for the super-resolution task with the goal of finding the best model in terms of performance and robustness. The public IXI dataset (only structural images) was used. Data were artificially downsampled to obtain lower-resolution spatial MRIs (downsampling factor varying from 8 to 64). When assessing performance using the SSIM metric in the test set, all models performed well. In particular, regardless of the downsampling factor, the UNet consistently obtained the top results. On the other hand, the SPSR model consistently performed worse. In conclusion, UNet and UNet-MSS achieved overall top performances while RRDB performed relatively poorly compared to the other models.

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超越奈奎斯特：增强核磁共振成像分辨率的三维深度学习模型比较分析》（Beyond Nyquist: A Comparative Analysis of 3D Deep Learning Models Enhancing MRI Resolution.

高空间分辨率磁共振成像可产生丰富的结构信息，从而实现高度准确的临床诊断和图像引导治疗。然而，由于物理、生理和硬件方面的限制，获取高空间分辨率核磁共振成像数据的代价通常是空间覆盖范围较小、信噪比（SNR）较低和扫描时间较长。为了克服这些限制，可以利用基于深度学习的超分辨率磁共振成像技术。在这项工作中，针对超分辨率任务比较了不同的先进三维卷积神经网络模型（RRDB、SPSR、UNet、UNet-MSS 和 ShuffleUNet），目的是找到性能和鲁棒性最佳的模型。我们使用了公开的 IXI 数据集（仅结构图像）。数据被人为降采样，以获得较低分辨率的空间磁共振成像（降采样因子从 8 到 64 不等）。在测试集中使用 SSIM 指标评估性能时，所有模型都表现良好。特别是，无论采用何种下采样因子，UNet 的结果都一直名列前茅。另一方面，SPSR 模型的表现一直较差。总之，UNet 和 UNet-MSS 总体表现优异，而 RRDB 与其他模型相比表现相对较差。

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