Hanzhong Wang, Yue Wang, Qiaoyi Xue, Yu Zhang, Xiaoya Qiao, Zengping Lin, Jiaxu Zheng, Zheng Zhang, Yang Yang, Min Zhang, Qiu Huang, Yanqi Huang, Tuoyu Cao, Jin Wang, Biao Li
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引用次数: 0
摘要
为了解决由于CT位置不匹配和对准问题而导致的PET/MR中基于MR的衰减校正(MRAC)验证的挑战,本研究在PET/CT扫描期间利用平板插入和手臂向下定位来实现精确的MR-CT匹配,以准确评估MRAC。方法对21例患者进行全身[18F]FDG PET/CT和[18F]FDG PET/MR验证数据集。平板插入确保了一致的定位,允许直接比较四种MRAC方法-四组织和五组织模型,具有离散和连续μ图-基于ct的衰减校正(CTAC)。基于深度学习的框架,在300名患者的数据集上训练,用于从MR图像生成合成ct,形成所有MRAC方法的基础。在全身、感兴趣区域和病变水平上进行定量分析,病变距离分析评估骨接近对标准化摄取值(SUV)量化的影响。结果不同的MRAC方法在脊柱和股骨区域有明显差异。联合直方图分析显示,MRAC-4(连续μ图)与CTAC密切相关。病变距离分析显示,MRAC-4可最大限度地减少骨诱导的SUV干扰(r = 0.01, p = 0.8643)。然而,与MRAC-2 (2D骨分割,离散μ图)和MRAC-3 (3D骨分割,离散μ图)相比,易受骨分割干扰的组织,如脊柱和肝脏,在MRAC-4中表现出更大的SUV变异性和更低的重复性。结论采用平板插入片,验证了MRAC具有较高的精度。连续μ值MRAC方法(MRAC-4)具有优异的准确性和最小的骨相关SUV误差,但在重复性方面面临挑战,特别是在富骨区域。
Optimizing MR-based attenuation correction in hybrid PET/MR using deep learning: validation with a flatbed insert and consistent patient positioning
Purpose
To address the challenges of verifying MR-based attenuation correction (MRAC) in PET/MR due to CT positional mismatches and alignment issues, this study utilized a flatbed insert and arms-down positioning during PET/CT scans to achieve precise MR-CT matching for accurate MRAC evaluation.
Methods
A validation dataset of 21 patients underwent whole-body [18F]FDG PET/CT followed by [18F]FDG PET/MR. A flatbed insert ensured consistent positioning, allowing direct comparison of four MRAC methods—four-tissue and five-tissue models with discrete and continuous μ-maps—against CT-based attenuation correction (CTAC). A deep learning-based framework, trained on a dataset of 300 patients, was used to generate synthesized-CTs from MR images, forming the basis for all MRAC methods. Quantitative analyses were conducted at the whole-body, region of interest, and lesion levels, with lesion-distance analysis evaluating the impact of bone proximity on standardized uptake value (SUV) quantification.
Results
Distinct differences were observed among MRAC methods in spine and femur regions. Joint histogram analysis showed MRAC-4 (continuous μ-map) closely aligned with CTAC. Lesion-distance analysis revealed MRAC-4 minimized bone-induced SUV interference (r = 0.01, p = 0.8643). However, tissues prone to bone segmentation interference, such as the spine and liver, exhibited greater SUV variability and lower reproducibility in MRAC-4 compared to MRAC-2 (2D bone segmentation, discrete μ-map) and MRAC-3 (3D bone segmentation, discrete μ-map).
Conclusion
Using a flatbed insert, this study validated MRAC with high precision. Continuous μ-value MRAC method (MRAC-4) demonstrated superior accuracy and minimized bone-related SUV errors but faced challenges in reproducibility, particularly in bone-rich regions.
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.