Song Xue, Fanxuan Liu, Hanzhong Wang, Hong Zhu, Hasan Sari, Marco Viscione, Raphael Sznitman, Axel Rominger, Rui Guo, Biao Li, Kuangyu Shi
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引用次数: 0
摘要
目的正电子发射断层扫描(PET)技术的最新发展通过增加几何覆盖范围而显著提高了有效灵敏度,从而实现了全身 PET 成像。这一令人鼓舞的突破为基于深度学习(DL)方法的超低剂量 PET 成像带来了希望,其效果相当于跨大西洋飞行。然而,传统的深度学习方法在处理 PET 成像的异构领域时面临限制。本研究旨在开发一种基于小波的深度学习方法,该方法能够从超低剂量 PET 扫描中恢复高质量成像。材料与方法与在空间域对图像进行去噪的传统深度学习技术相比,我们引入了 WaveNet,这是一种输入 PET 成像的小波分解频率成分以在频域执行去噪的新方法。为了开发和测试所提出的方法,我们使用了一个数据集,其中包括在伯尔尼和上海使用全身 PET 扫描仪(包括 Biograph Vision Quadra(西门子医疗集团)和 uEXPLORER(联合成像公司))采集的 1447 幅全身 18F -FDG PET 图像。结果我们提出的 WaveNet 在所有剂量减低因子 (DRF) 水平上的表现都优于基线 UNet 模型,而且随着图像质量的降低,表现出更大的改进。统计分析(p < 0.05)和目测验证了 WaveNet 的优越性。结论使用全身 PET 扫描仪开发的 WaveNet 可为恢复超低剂量 PET 成像的图像质量提供一种计算友好且稳健的方法。采用这种方法可以提高基于 DL 的剂量降低技术的可靠性和临床接受度。
A deep learning method for the recovery of standard-dose imaging quality from ultra-low-dose PET on wavelet domain
Purpose
Recent development in positron emission tomography (PET) dramatically increased the effective sensitivity by increasing the geometric coverage leading to total-body PET imaging. This encouraging breakthrough brings the hope of ultra-low dose PET imaging equivalent to transatlantic flight with the assistance of deep learning (DL)-based methods. However, conventional DL approaches face limitations in addressing the heterogeneous domain of PET imaging. This study aims to develop a wavelet-based DL method capable of restoring high-quality imaging from ultra-low-dose PET scans.
Materials and methods
In contrast to conventional DL techniques that denoise images in the spatial domain, we introduce WaveNet, a novel approach that inputs wavelet-decomposed frequency components of PET imaging to perform denoising in the frequency domain. A dataset comprising total-body 18F -FDG PET images of 1447, acquired using total-body PET scanners including Biograph Vision Quadra (Siemens Healthineers) and uEXPLORER (United Imaging) in Bern and Shanghai, was utilized for developing and testing the proposed method. The quality of enhanced images was assessed using a customized scoring system, which incorporated weighted global physical metrics and local indices.
Results
Our proposed WaveNet consistently outperforms the baseline UNet model across all levels of dose reduction factors (DRF), with greater improvements observed as image quality decreases. Statistical analysis (p < 0.05) and visual inspection validated the superiority of WaveNet. Moreover, WaveNet demonstrated superior generalizability when applied to two cross-scanner datasets (p < 0.05).
Conclusion
WaveNet developed with total-body PET scanners may offer a computational-friendly and robust approach to recover image quality from ultra-low-dose PET imaging. Its adoption may enhance the reliability and clinical acceptance of DL-based dose reduction techniques.
期刊介绍:
The European Journal of Nuclear Medicine and Molecular Imaging serves as a platform for the exchange of clinical and scientific information within nuclear medicine and related professions. It welcomes international submissions from professionals involved in the functional, metabolic, and molecular investigation of diseases. The journal's coverage spans physics, dosimetry, radiation biology, radiochemistry, and pharmacy, providing high-quality peer review by experts in the field. Known for highly cited and downloaded articles, it ensures global visibility for research work and is part of the EJNMMI journal family.
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