Evaluation of qualitative and quantitative data of Y-90 imaging in SPECT/CT and PET/CT phantom studies

Kubik, Agata; Budzyńska, Anna; Kacperski, Krzysztof; Maciak, Maciej; Kuć, Michał; Piasecki, Piotr; Wiliński, Maciej; Konior, Marcin; Dziuk, Mirosław; Iller, E.

doi:10.1371/journal.pone.0246848

Cited by 18 publications

(39 citation statements)

References 25 publications

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“…One challenging aspect with Y-90 dosimetry is imaging quantification. Y-90 SPECT imaging is based on collecting Bremsstrahlung photons generated as a result of the interaction between the electrons originating from the β − decay and the tissue [ 36 ]. Due to this indirect imaging, various disadvantages are observed, such as its low spatial resolution (up to 15 mm) that depends on energy window width, collimator choice and image processing [ 36 ]; attenuation correction, since it depends on the density of the objects through which the photon passes, as well as the photon’s energy [ 37 ]; and overall quantification capability translating into an inaccurate dose-response analysis, despite the possible compensation techniques for attenuation, scatter and collimator detector response [ 38 , 39 ].…”

Section: Instrumentation Developmentsmentioning

confidence: 99%

“…The limited positron-branching ratio is overcome with the improved sensitivity of new digital devices and TOF technology, which enables the acquisition of the annihilation photons, thus obtaining improved resolution images of the microsphere biodistribution. Moreover, Y-90 PET images have been proven to be suitable for quantification and, thus, potential use for post-SIRT dosimetry [ 36 ]. A recently published work, written by an international collaboration of experts, strongly recommends the use of Y-90 PET for post-therapy evaluation, due to its superior quantification capabilities in comparison to Bremsstrahlung SPECT [ 40 ].…”

Section: Instrumentation Developmentsmentioning

confidence: 99%

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New Radionuclides and Technological Advances in SPECT and PET Scanners

Meulen

Strobel

Lima

2021

Cancers

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Developments throughout the history of nuclear medicine have involved improvements in both instrumentation and radionuclides, which have been intertwined. Instrumentation developments always occurred during the search to improving devices’ sensitivity and included advances in detector technology (with the introduction of cadmium zinc telluride and digital Positron Emission Tomography—PET-devices with silicon photomultipliers), design (total body PET) and configuration (ring-shaped, Single-Photon Emission Computed Tomography (SPECT), Compton camera). In the field of radionuclide development, we observed the continual changing of clinically used radionuclides, which is sometimes influenced by instrumentation technology but also driven by availability, patient safety and clinical questions. Some areas, such as tumour imaging, have faced challenges when changing radionuclides based on availability, when this produced undesirable clinical findings with the introduction of unclear focal uptakes and unspecific uptakes. On the other end of spectrum, further developments of PET technology have seen a resurgence in its use in nuclear cardiology, with rubidium-82 from strontium-82/rubidium-82 generators being the radionuclide of choice, moving away from SPECT nuclides thallium-201 and technetium-99m. These continuing improvements in both instrumentation and radionuclide development have helped the growth of nuclear medicine and its importance in the ever-evolving range of patient care options.

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Section: Instrumentation Developmentsmentioning

confidence: 99%

Section: Instrumentation Developmentsmentioning

confidence: 99%

New Radionuclides and Technological Advances in SPECT and PET Scanners

Meulen

Strobel

Lima

2021

Cancers

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“…2). [25][26][27] This superiority is due in large part to the improved spatial resolution of PET compared with SPECT. Standard gamma SPECT imaging has a spatial resolution of around 10 mm (which is even worse when imaging bremsstrahlung radiation), as compared with the roughly 2-mm spatial resolution on most clinical PET scanners.…”

Section: Positron Emission Tomography Versus Single-photon Emission Computed Tomographymentioning

confidence: 99%

Post Yttrium-90 Imaging

Rice

Krosin

Haste

2021

Semin intervent Radiol

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Transarterial radioembolization with yttrium-90 (90Y) is a mainstay for the treatment of liver cancer. Imaging the distribution following delivery is a concept that dates back to the 1960s. As β particles are created during 90Y decay, bremsstrahlung radiation is created as the particles interact with tissues, allowing for imaging with a gamma camera. Inherent qualities of bremsstrahlung radiation make its imaging difficult. SPECT and SPECT/CT can be used but suffer from limitations related to low signal-to-noise bremsstrahlung radiation. However, with optimized imaging protocols, clinically adequate images can still be obtained. A finite but detectable number of positrons are also emitted during 90Y decay, and many studies have demonstrated the ability of commercial PET/CT and PET/MR scanners to image these positrons to understand 90Y distribution and help quantify dose. PET imaging has been proven to be superior to SPECT for quantitative imaging, and therefore will play an important role going forward as we try and better understand dose/response and dose/toxicity relationships to optimize personalized dosimetry. The availability of PET imaging will likely remain the biggest barrier to its use in routine post-90Y imaging; thus, SPECT/CT imaging with optimized protocols should be sufficient for most posttherapy subjective imaging.

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“…3 Christie Medical Physics and Engineering (CMPE), The Christie NHS Foundation Trust, Manchester, UK. 4 The University of Manchester, Manchester, UK. 5 Department of Medical Physics, Royal Surrey NHS Foundation Trust, Guildford, UK.…”

Section: Abbreviationsmentioning

confidence: 99%

“…The microspheres lodge in the blood capillaries of the tumour, delivering a high localised absorbed dose while minimising the dose absorbed by the healthy liver parenchyma. [4,5].…”

Section: Introductionmentioning

confidence: 99%

Frozen Hybrid Kernelised Expectation Maximisation For Bremsstrahlung SPECT Reconstruction

Deidda

Denis-Bacelar

Fenwick

et al. 2021

Preprint

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Background: Selective internal radiation therapy with Yttrium-90 microspheres is an effective therapy for liver cancer and liver metastases. Yttrium-90 is mainly a high-energy beta particle emitter. These beta particles emit Bremsstrahlung radiation during their interaction with tissue making post-therapy imaging of the radioactivity distribution feasible. Nevertheless, image quality and quantification is difficult due to the continuous energy spectrum which makes resolution modelling, and attenuation and scatter estimation challenging. Methods: In this study, a modified hybrid kernelised expectation maximisation is used to improve resolution and contrast and reduce noise. The iterative part of the kernel was frozen at the 72nd sub-iteration to avoid over-fitting of noise and background. A NEMA phantom with spherical inserts was used for the optimisation and validation of the algorithm, and data from 5 patients treated with Selective internal radiation therapy were used as proof of clinical relevance of the method. Results: The results suggest a maximum improvement of 56% for region of interest mean recovery coefficient at fixed coefficient of variation and better identification of the hot volumes in the NEMA phantom. Similar improvements were achieved with patient data, showing 47% mean value improvement over the gold standard used in hospitals. Conclusions: Such quantitative improvements could facilitate improved dosimetry calculations with SPECT when treating patients with Selective internal radiation therapy, as well as provide a more visible position of the cancerous lesions in the liver.

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Evaluation of qualitative and quantitative data of Y-90 imaging in SPECT/CT and PET/CT phantom studies

Cited by 18 publications

References 25 publications

New Radionuclides and Technological Advances in SPECT and PET Scanners

New Radionuclides and Technological Advances in SPECT and PET Scanners

Post Yttrium-90 Imaging

Frozen Hybrid Kernelised Expectation Maximisation For Bremsstrahlung SPECT Reconstruction

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