基于CT和MR的神经PET衰减校正比较。

A comparison of CT- and MR-based attenuation correction in neurological PET.

作者信息

Dickson John C, O'Meara Celia, Barnes Anna

机构信息

Institute of Nuclear Medicine, University College London Hospitals, Euston Road, London, NW1 2BU, UK,

出版信息

Eur J Nucl Med Mol Imaging. 2014 Jun;41(6):1176-89. doi: 10.1007/s00259-013-2652-z. Epub 2014 Jan 15.

DOI:10.1007/s00259-013-2652-z

PMID:24425423

Abstract

PURPOSE

To assess the quantitative accuracy of current MR attenuation correction (AC) methods in neurological PET, in comparison to data derived using CT AC.

METHODS

This retrospective study included 25 patients who were referred for a neurological FDG PET examination and were imaged sequentially by PET/CT and simultaneous PET/MR. Differences between activity concentrations derived using Dixon and ultrashort echo time (UTE) MR-based AC and those derived from CT AC were compared using volume of interest and voxel-based approaches. The same comparisons were also made using PET data represented as SUV ratios (SUVr) using grey matter cerebellum as the reference region.

RESULTS

Extensive and statistically significant regional underestimations of activity concentrations were found with both Dixon AC (P < 0.001) and UTE AC (P < 0.001) in all brain regions when compared to CT AC. The greatest differences were found in the cortical grey matter (Dixon AC 21.3%, UTE AC 15.7%) and cerebellum (Dixon AC 19.8%, UTE AC 17.3%). The underestimation using UTE AC was significantly less than with Dixon AC (P < 0.001) in most regions. Voxel-based comparisons showed that all cortical grey matter and cerebellum uptake was underestimated with Dixon AC compared to CT AC. Using UTE AC the extent and significance of these differences were reduced. Inaccuracies in cerebellar activity concentrations led to a mixture of predominantly cortical underestimation and subcortical overestimation in SUVr PET data for both MR AC methodologies.

CONCLUSION

MR-based AC results in significant underestimation of activity concentrations throughout the brain, which makes the use of SUVr data difficult. These effects limit the quantitative accuracy of neurological PET/MR.

摘要

目的

与使用CT衰减校正（AC）得出的数据相比，评估当前神经PET中MR衰减校正（AC）方法的定量准确性。

方法

这项回顾性研究纳入了25例因神经FDG PET检查而就诊的患者，这些患者先后接受了PET/CT和同步PET/MR成像。使用感兴趣体积和基于体素的方法，比较了使用基于Dixon和超短回波时间（UTE）MR的AC得出的活度浓度与CT AC得出的活度浓度之间的差异。还使用以小脑灰质为参考区域的SUV比率（SUVr）表示的PET数据进行了相同的比较。

结果

与CT AC相比，在所有脑区中，Dixon AC（P < 0.001）和UTE AC（P < 0.001）均发现活度浓度存在广泛且具有统计学意义的区域低估。最大差异出现在皮质灰质（Dixon AC为21.3%，UTE AC为15.7%）和小脑（Dixon AC为19.8%，UTE AC为17.3%）。在大多数区域，UTE AC的低估明显小于Dixon AC（P < 0.001）。基于体素的比较显示，与CT AC相比，Dixon AC低估了所有皮质灰质和小脑的摄取。使用UTE AC，这些差异的程度和显著性降低。小脑活度浓度的不准确导致两种MR AC方法的SUVr PET数据中主要是皮质低估和皮质下高估的混合情况。

结论

基于MR的AC导致全脑活度浓度显著低估，这使得SUVr数据的使用变得困难。这些影响限制了神经PET/MR的定量准确性。

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基于CT和MR的神经PET衰减校正比较。

A comparison of CT- and MR-based attenuation correction in neurological PET.

作者信息

机构信息

出版信息

PURPOSE

METHODS

RESULTS

CONCLUSION

目的

方法

结果

结论

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