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Coded aperture and Compton imaging for the development of <sup>225</sup>Ac‐based radiopharmaceuticals

Emily Frame, Kondapa Bobba, Donald Gunter, Lucian Mihailescu, Anil P. Bidkar, Robert R. Flavell, K. Vetter

2023Medical Physics16 citationsDOIOpen Access PDF

Abstract

Abstract Background Targeted alpha‐particle therapy (TAT) has great promise as a cancer treatment. Arguably the most promising TAT radionuclide that has been proposed is 225 Ac. The development of 225 Ac‐based radiopharmaceuticals has been hampered due to the lack of effective means to study the daughter redistribution of these agents in small animals at the preclinical stage. Purpose The ability to directly image the daughters, namely 221 Fr and 213 Bi, via their gamma‐ray emissions would be a boon for preclinical studies. That said, conventional medical imaging modalities, including single photon emission computed tomography (SPECT) based on nonmultiplexed collimation, cannot be employed due to sensitivity limitations. Methods As an alternative, we propose the use of both coded aperture and Compton imaging with the former modality suited to the 218‐keV gamma‐ray emission of 221 Fr and the latter suited to the 440‐keV gamma‐ray emission of 213 Bi. Results This work includes coded aperture images of 221 Fr and Compton images of 213 Bi in tumor‐bearing mice injected with 225 Ac‐based radiopharmaceuticals. Conclusions These results are the first demonstration of visualizing and quantifying the 225 Ac daughters in small animals through the application of coded aperture and Compton imaging.

Topics & Concepts

Collimated lightPhysicsCoded apertureNuclear medicineGamma rayCompton scatteringPhotonMedical physicsOpticsMedicineNuclear physicsDetectorLaserRadiopharmaceutical Chemistry and ApplicationsMedical Imaging Techniques and ApplicationsAdvanced Radiotherapy Techniques
Coded aperture and Compton imaging for the development of <sup>225</sup>Ac‐based radiopharmaceuticals | Litcius