Toward the standardization of radiopharmaceutical therapies: a technical note evaluating a clinical dosimetry workflow for single-time-point 177Lu SPECT/CT-based therapies

Toward the standardization of radiopharmaceutical therapies: a technical note evaluating a clinical dosimetry workflow for single-time-point 177Lu SPECT/CT-based therapies

Abstract Purpose The lack of standardized dosimetry workflows in lutetium-177 ( $$^{177}$$ 177 Lu) radiopharmaceutical therapies results in inconsistent absorbed doses and limits treatment planning. This study aims to evaluate the accuracy and variability of a single-time-point 177Lu SPECT/CT commer...

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Bibliographic Details
Main Authors: Taehyung Peter Kim, Wendy Siman, Vivek Mishra, Santiago Aguirre, Siju C. George
Format: Article
Language:English
Published: SpringerOpen 2025-08-01
Series:EJNMMI Physics
Subjects:
Radiopharmaceutical therapies
Theranostics
$$^{177}$$ 177 Lu
Dosimetry
Treatment planning
Standardization
Online Access:https://doi.org/10.1186/s40658-025-00764-1
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Summary:Abstract Purpose The lack of standardized dosimetry workflows in lutetium-177 ( $$^{177}$$ 177 Lu) radiopharmaceutical therapies results in inconsistent absorbed doses and limits treatment planning. This study aims to evaluate the accuracy and variability of a single-time-point 177Lu SPECT/CT commercial workflow to help harmonize its protocol. Methods The dosimetry workflow evaluated in this study predominatly followed that of MIM SurePlanTM MRT. 177Lu SPECT/CT images of a Jaszczak and a NEMA phantoms were acquired in GE 670 DR scanner. Absorbed dose (Gy/MBq/s) was calculated in the background and sphere inserts with varied reconstruction iterations, calibrations, voxel-based dosimetry methods, and target volume segmentations. Ground truth absorbed doses were created using CT images and voxel S-value (VSV) water kernels. The validity of the density-corrected (DC) kernel for use in ground-truth dosimetry evaluations was further investigated. The accuracy and variability of the dosimetry workflow were evaluated using percent error and the coefficient of variation (CV) of mean absorbed doses. Results Mean absorbed dose accuracy improved for both the voxel-based VSV and local deposition (LD) methods until 480 equivalent iterations for all target volumes. DC kernel was found viable for creating reference absorbed doses. The calibration CV was 5.18% when phantom and calibration regions were varied. The VSV method demonstrated absorbed doses that were 10 to 150% higher than those calculated with the LD method. The overall variability in absorbed dose reached up to 84% when reconstruction, calibration, dosimetry, and segmentation methods were varied. Conclusions A single dosimetry workflow has demonstrated markedly large variability in absorbed dose accuracy. By evaluating the accuracy of absorbed dose, our study helped to propose a harmonized MIM SurePlanTM MRT workflow for single-time-point $$^{177}$$ 177 Lu SPECT/CT-based therapies.
ISSN:2197-7364

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