Improving diagnostic precision in amyloid brain PET imaging through data-driven motion correction.

IF 3 2区医学 Q2 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING EJNMMI Physics Pub Date : 2024-06-14 DOI:10.1186/s40658-024-00653-z

Hye Lim Park, Sonya Youngju Park, Mingeon Kim, Soyeon Paeng, Eun Jeong Min, Inki Hong, Judson Jones, Eun Ji Han

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Abstract

Background: Head motion during brain positron emission tomography (PET)/computed tomography (CT) imaging degrades image quality, resulting in reduced reading accuracy. We evaluated the performance of a head motion correction algorithm using ¹⁸F-flutemetamol (FMM) brain PET/CT images.

Methods: FMM brain PET/CT images were retrospectively included, and PET images were reconstructed using a motion correction algorithm: (1) motion estimation through 3D time-domain signal analysis, signal smoothing, and calculation of motion-free intervals using a Merging Adjacent Clustering method; (2) estimation of 3D motion transformations using the Summing Tree Structural algorithm; and (3) calculation of the final motion-corrected images using the 3D motion transformations during the iterative reconstruction process. All conventional and motion-corrected PET images were visually reviewed by two readers. Image quality was evaluated using a 3-point scale, and the presence of amyloid deposition was interpreted as negative, positive, or equivocal. For quantitative analysis, we calculated the uptake ratio (UR) of 5 specific brain regions, with the cerebellar cortex as a reference region. The results of the conventional and motion-corrected PET images were statistically compared.

Results: In total, 108 sets of FMM brain PET images from 108 patients (34 men and 74 women; median age, 78 years) were included. After motion correction, image quality significantly improved (p < 0.001), and there were no images of poor quality. In the visual analysis of amyloid deposition, higher interobserver agreements were observed in motion-corrected PET images for all specific regions. In the quantitative analysis, the UR difference between the conventional and motion-corrected PET images was significantly higher in the group with head motion than in the group without head motion (p = 0.016).

Conclusions: The motion correction algorithm provided better image quality and higher interobserver agreement. Therefore, we suggest that this algorithm be adopted as a routine post-processing protocol in amyloid brain PET/CT imaging and applied to brain PET scans with other radiotracers.

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通过数据驱动的运动校正提高脑淀粉样蛋白 PET 成像的诊断精度。

背景：脑部正电子发射断层扫描（PET）/计算机断层扫描（CT）成像过程中的头部运动会降低图像质量，从而降低阅读准确性。我们利用18F-氟替美托（FMM）脑PET/CT图像评估了头部运动校正算法的性能：方法：回顾性纳入 FMM 脑 PET/CT 图像，并使用运动校正算法重建 PET 图像：(1)通过三维时域信号分析、信号平滑和使用合并相邻聚类法计算无运动区间来估计运动；(2)使用求和树结构算法估计三维运动变换；(3)在迭代重建过程中使用三维运动变换计算最终的运动校正图像。所有常规和运动校正 PET 图像均由两名阅读者进行目视审查。图像质量采用 3 级评分法进行评估，淀粉样蛋白沉积被解释为阴性、阳性或模糊。为了进行定量分析，我们以小脑皮层为参照区，计算了 5 个特定脑区的摄取比（UR）。我们对传统 PET 图像和运动校正 PET 图像的结果进行了统计比较：结果：共纳入了 108 名患者（34 名男性，74 名女性；中位年龄 78 岁）的 108 组 FMM 脑 PET 图像。运动校正后，图像质量明显改善（p 结论：运动校正算法提供了更好的图像质量：运动校正算法提供了更好的图像质量和更高的观察者间一致性。因此，我们建议将该算法作为淀粉样蛋白脑 PET/CT 成像的常规后处理方案，并应用于其他放射性核素的脑 PET 扫描。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

EJNMMI Physics Physics and Astronomy-Radiation

CiteScore

6.70

自引率

10.00%

发文量

审稿时长

13 weeks

期刊介绍： EJNMMI Physics is an international platform for scientists, users and adopters of nuclear medicine with a particular interest in physics matters. As a companion journal to the European Journal of Nuclear Medicine and Molecular Imaging, this journal has a multi-disciplinary approach and welcomes original materials and studies with a focus on applied physics and mathematics as well as imaging systems engineering and prototyping in nuclear medicine. This includes physics-driven approaches or algorithms supported by physics that foster early clinical adoption of nuclear medicine imaging and therapy.