用于 PET/MRI 体模的骨材料模拟物。

Bone material analogues for PET/MRI phantoms.

机构信息

Department of Radiology and Biomedical Imaging, University of California - San Francisco, San Francisco, CA, 94143, USA.

Department of Radiology, Washington University, St. Louis, MO, 63110, USA.

出版信息

Med Phys. 2020 Jun;47(5):2161-2170. doi: 10.1002/mp.14079. Epub 2020 Mar 13.

DOI:10.1002/mp.14079

PMID:32034945

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7901472/

Abstract

PURPOSE

To develop bone material analogues that can be used in construction of phantoms for simultaneous PET/MRI systems.

METHODS

Plaster was used as the basis for the bone material analogues tested in this study. It was mixed with varying concentrations of an iodinated CT contrast, a gadolinium-based MR contrast agent, and copper sulfate to modulate the attenuation properties and MRI properties (T1 and T2*). Attenuation was measured with CT and Ge transmission scans, and MRI properties were measured with quantitative ultrashort echo time pulse sequences. A proof-of-concept skull was created by plaster casting.

RESULTS

Undoped plaster has a 511 keV attenuation coefficient (~~0.14 cm ) similar to cortical bone (0.10-0.15 cm ), but slightly longer T1 (~~500 ms) and T2* (~1.2 ms) MR parameters compared to bone (T1 ~ 300 ms, T2* ~ 0.4 ms). Doping with the iodinated agent resulted in increased attenuation with minimal perturbation to the MR parameters. Doping with a gadolinium chelate greatly reduced T1 and T2*, resulting in extremely short T1 values when the target T2* values were reached, while the attenuation coefficient was unchanged. Doping with copper sulfate was more selective for T2* shortening and achieved comparable T1 and T2* values to bone (after 1 week of drying), while the attenuation coefficient was unchanged.

CONCLUSIONS

Plaster doped with copper sulfate is a promising bone material analogue for a PET/MRI phantom, mimicking the MR properties (T1 and T2*) and 511 keV attenuation coefficient of human cortical bone.

摘要

目的

开发可用于 PET/MRI 系统同时成像的体模的骨材料模拟物。

方法

本研究中使用石膏作为骨材料模拟物的基础。它与不同浓度的碘基 CT 造影剂、基于钆的磁共振对比剂和硫酸铜混合，以调节衰减特性和 MRI 特性（T1 和 T2*）。衰减通过 CT 和 Ge 透射扫描进行测量，MRI 特性通过定量超短回波时间脉冲序列进行测量。通过石膏浇铸创建了一个颅骨模型。

结果

未掺杂的石膏具有 511keV 的衰减系数（约 0.14cm），类似于皮质骨（0.10-0.15cm），但与骨相比，T1（~~300ms）和 T2*（~~0.4ms）较长（T1500ms，T2*1.2ms）。掺杂碘造影剂会导致衰减增加，而对 MR 参数的干扰最小。掺杂镧系螯合物会大大降低 T1 和 T2*，当达到目标 T2值时，会导致 T1 值极短，而衰减系数保持不变。掺杂硫酸铜对 T2缩短的选择性更高，可实现与骨相当的 T1 和 T2*值（干燥 1 周后），而衰减系数保持不变。

结论

掺杂硫酸铜的石膏是一种有前途的 PET/MRI 体模骨材料模拟物，可模拟人体皮质骨的 MR 特性（T1 和 T2*）和 511keV 衰减系数。

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