应用临床NaF PET/CT研究定量全身PET/MR成像所需MR骨衰减校正的研究

International Journal of Medical Physics, Clinical Engineering and Radiation Oncology Pub Date : 2018-06-04 DOI:10.4236/IJMPCERO.2018.73023

H. Ai, O. Mawlawi, R. Stafford, J. Bankson, Y. Shao, M. Guindani, R. Wendt

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引用次数: 0

摘要

先前已经提出了基于组织分类的衰减校正策略来校正PET/MR成像中的骨衰减，并使用计算机断层扫描进行模拟。然而，体素平均的复杂性与骨的独特关联在过去没有明确考虑。本研究研究了衰减图像中骨骼和软组织之间体素平均的影响，并确定了在MR图像中检测骨骼的精确度，以便通过使用ct模拟衰减校正对PET数据进行可接受的衰减校正。我们发现，将骨作为软组织处理导致所有119个骨病变的平均量化差异为-9.9%±5.5%。在骨盆和椎骨病变之间没有显著差异。肋骨病变的标称差异明显较低，可能是由于发射和衰减图像之间的空间错配。有趣的是，骨成像能力与PET绝对定量精度之间存在非单调关系，颅骨病变(2.6%±2.1%)的BVF最小量化差异约为40%，非颅骨病变(1.4%±1.1%)和所有病变(1.5%±1.3%)的BVF最小量化差异为30%。本研究表明，为了在全身PET/MR研究中实现最佳量化，基于MR的衰减校正方法需要大约30% BVF的骨分类灵敏度。为此，可能不需要更高的MR骨成像能力。

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An Investigation of the Required MR Bone Attenuation Correction for Quantitative Whole-Body PET/MR Imaging Using Clinical NaF PET/CT Studies

Tissue-classification-based attenuation correction strategies have been previously proposed to correct for bone attenuation in PET/MR imaging and simulated using computed tomography. However, the complication of voxel averaging uniquely associated with bone has not been considered explicitly in the past. This study investigated the effect of voxel averaging between bone and soft tissue in attenuation images and determined how accurately bone must be detected in MR images in order to perform acceptable attenuation correction of PET data by using CT-simulated attenuation correction. We found out that treating bone as soft tissue caused a mean quantification difference of -9.9% ± 5.5% in all 119 bone lesions. There were no significant differences between lesions in the pelvis and the vertebrae. The nominal difference in lesions in the ribs was significantly lower, likely due to the spatial misregistration between the emission and attenuation images. Interestingly, a non-monotonic relationship between the bone imaging ability and the absolute PET quantification accuracy was observed, with the minimal quantification difference achieved at a BVF around 40% for skull lesions (2.6% ± 2.1%), and 30% for non-skull lesions (1.4% ± 1.1%) and all lesions (1.5% ± 1.3%). This study established that a bone classification sensitivity of approximately 30% BVF is required in order for MR-based attenuation correction methods to achieve optimal quantification in whole-body PET/MR studies. For this purpose, higher bone imaging ability of MR may not be necessary.

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International Journal of Medical Physics, Clinical Engineering and Radiation Oncology

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