Quantification and dosimetry of small volumes including associated uncertainty estimation

Background Accurate quantification of radioactivity in a source of interest relies on accurate registration between SPECT and anatomical images, and appropriate correction of partial volume effects (PVEs). For small volumes, exact registration between the two imaging modalities and recovery factors...

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Bibliographic Details
Published in:EJNMMI physics 2022-12, Vol.9 (1), p.86-16, Article 86
Main Authors: Carnegie-Peake, Lily, Taprogge, Jan, Murray, Iain, Flux, Glenn D., Gear, Jonathan
Format: Article
Language:English
Subjects:
Applied and Technical Physics
Computational Mathematics and Numerical Analysis
Dosimeters
Dosimetry
Engineering
I-131
Imaging
Imaging and dosimetry for radionuclide based therapy
Lesions
Medicine
Medicine & Public Health
Metastasis
Nuclear Medicine
Original Research
Quantification
Radioactivity
Radiology
Spatial resolution
Uncertainty
Uncertainty estimation
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Summary:Background Accurate quantification of radioactivity in a source of interest relies on accurate registration between SPECT and anatomical images, and appropriate correction of partial volume effects (PVEs). For small volumes, exact registration between the two imaging modalities and recovery factors used to correct for PVE are unreliable. There is currently no guidance relating to quantification or the associated uncertainty estimation for small volumes. Material and methods A method for quantification of small sources of interest is proposed, which uses multiple oversized volumes of interest. The method was applied to three Na[ 131 I]I activity distributions where a Na[ 131 I]I capsule was situated within a cylindrical phantom containing either zero background, uniform background or non-uniform background and to a scenario with small lesions placed in an anthropomorphic phantom. The Na[ 131 I]I capsule and lesions were quantified using the proposed method and compared with measurements made using two alternative quantification methods. The proposed method was also applied to assess the absorbed dose delivered to a bone metastasis following [ 131 I]mIBG therapy for neuroblastoma including the associated uncertainty estimation. Results The method is accurate across a range of activities and in varied radioactivity distributions. Median percentage errors using the proposed method in no background, uniform backgrounds and non-uniform backgrounds were − 0.4%, − 0.3% and 1.7% with median associated uncertainties of 1.4%, 1.4% and 1.6%, respectively. The technique is more accurate and robust when compared to currently available alternative methods. Conclusions The proposed method provides a reliable and accurate method for quantification of sources of interest, which are less than three times the spatial resolution of the imaging system. The method may be of use in absorbed dose calculation in cases of bone metastasis, lung metastasis or thyroid remnants.
ISSN:2197-7364
2197-7364
DOI:10.1186/s40658-022-00512-9