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Evaluation of Sinus/Edge-Corrected Zero-Echo-Time-Based Attenuation Correction in Brain PET/MRI.基于脑PET/MRI中鼻窦/边缘校正零回波时间的衰减校正评估
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Deep Learning in Medical Image Analysis.医学图像分析中的深度学习
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MR-based synthetic CT generation using a deep convolutional neural network method.基于磁共振成像利用深度卷积神经网络方法生成合成CT图像
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Clinical Evaluation of Zero-Echo-Time Attenuation Correction for Brain 18F-FDG PET/MRI: Comparison with Atlas Attenuation Correction.脑 18F-FDG PET/MRI 的零回波时间衰减校正的临床评估:与图谱衰减校正的比较
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Design Features and Mutual Compatibility Studies of the Time-of-Flight PET Capable GE SIGNA PET/MR System.基于飞行时间技术的正电子发射断层扫描/磁共振成像系统的设计特点及相互兼容性研究。
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Dixon Sequence with Superimposed Model-Based Bone Compartment Provides Highly Accurate PET/MR Attenuation Correction of the Brain.具有叠加基于模型的骨腔室的狄克逊序列可实现对大脑高度准确的PET/MR衰减校正。
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Evaluation of Atlas-Based Attenuation Correction for Integrated PET/MR in Human Brain: Application of a Head Atlas and Comparison to True CT-Based Attenuation Correction.基于图谱的衰减校正用于人体脑部PET/MR一体机的评估:头部图谱的应用及与基于真实CT的衰减校正的比较
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零回波时间和 Dixon 深度伪 CT(ZeDD CT):使用多参数 MRI 的深度卷积神经网络直接生成用于骨盆 PET/MRI 衰减校正的伪 CT 图像。

Zero-Echo-Time and Dixon Deep Pseudo-CT (ZeDD CT): Direct Generation of Pseudo-CT Images for Pelvic PET/MRI Attenuation Correction Using Deep Convolutional Neural Networks with Multiparametric MRI.

机构信息

Department of Radiology and Biomedical Imaging, University of California San Francisco, San Francisco, California

UC Berkeley-UCSF Graduate Program in Bioengineering, UC Berkeley, Berkeley, California, and UCSF, San Francisco, California.

出版信息

J Nucl Med. 2018 May;59(5):852-858. doi: 10.2967/jnumed.117.198051. Epub 2017 Oct 30.

DOI:10.2967/jnumed.117.198051
PMID:29084824
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5932530/
Abstract

Accurate quantification of uptake on PET images depends on accurate attenuation correction in reconstruction. Current MR-based attenuation correction methods for body PET use a fat and water map derived from a 2-echo Dixon MRI sequence in which bone is neglected. Ultrashort-echo-time or zero-echo-time (ZTE) pulse sequences can capture bone information. We propose the use of patient-specific multiparametric MRI consisting of Dixon MRI and proton-density-weighted ZTE MRI to directly synthesize pseudo-CT images with a deep learning model: we call this method ZTE and Dixon deep pseudo-CT (ZeDD CT). Twenty-six patients were scanned using an integrated 3-T time-of-flight PET/MRI system. Helical CT images of the patients were acquired separately. A deep convolutional neural network was trained to transform ZTE and Dixon MR images into pseudo-CT images. Ten patients were used for model training, and 16 patients were used for evaluation. Bone and soft-tissue lesions were identified, and the SUV was measured. The root-mean-squared error (RMSE) was used to compare the MR-based attenuation correction with the ground-truth CT attenuation correction. In total, 30 bone lesions and 60 soft-tissue lesions were evaluated. The RMSE in PET quantification was reduced by a factor of 4 for bone lesions (10.24% for Dixon PET and 2.68% for ZeDD PET) and by a factor of 1.5 for soft-tissue lesions (6.24% for Dixon PET and 4.07% for ZeDD PET). ZeDD CT produces natural-looking and quantitatively accurate pseudo-CT images and reduces error in pelvic PET/MRI attenuation correction compared with standard methods.

摘要

准确的 PET 图像摄取量定量取决于重建中的准确衰减校正。目前,用于体部 PET 的基于 MRI 的衰减校正方法使用源自双回波 Dixon MRI 序列的脂肪和水图,其中忽略了骨骼。超短回波时间或零回波时间 (ZTE) 脉冲序列可以捕获骨骼信息。我们提出使用由 Dixon MRI 和质子密度加权 ZTE MRI 组成的患者特定多参数 MRI 直接通过深度学习模型合成伪 CT 图像:我们将这种方法称为 ZTE 和 Dixon 深度伪 CT(ZeDD CT)。26 名患者使用集成的 3-T 飞行时间 PET/MRI 系统进行扫描。患者的螺旋 CT 图像分别采集。训练了一个深度卷积神经网络,将 ZTE 和 Dixon MR 图像转换为伪 CT 图像。使用 10 名患者进行模型训练,16 名患者进行评估。识别骨和软组织病变,并测量 SUV。使用均方根误差 (RMSE) 比较基于 MRI 的衰减校正与真实 CT 衰减校正。总共评估了 30 个骨病变和 60 个软组织病变。骨病变的 PET 定量 RMSE 降低了 4 倍(Dixon PET 为 10.24%,ZeDD PET 为 2.68%),软组织病变降低了 1.5 倍(Dixon PET 为 6.24%,ZeDD PET 为 4.07%)。ZeDD CT 生成自然逼真且定量准确的伪 CT 图像,并与标准方法相比,降低了骨盆 PET/MRI 衰减校正中的误差。