Differences in 3D dose distributions due to calculation method of voxel S-values and the influence of image blurring in SPECT

Pacilio, Massimiliano; Amato, Ernesto; Lanconelli, Nico; Basile, Chiara; Torres, Leonel; Botta, Francesca; Ferrari, Mahila; Díaz, N. Cornejo; Perez, Marco Coca; Fernández, María Soledad; Laßmann, Michael; Gil, Alberto; Cremonesi, Marta

doi:10.1088/0031-9155/60/5/1945

Cited by 41 publications

(43 citation statements)

References 55 publications

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“…A recent paper by Pasciak et al [37] demonstrated in 90 Y PET that as long as the full-width at half-maximum point spread function (FWHM PSF ) is wider than the dose point kernel FHWM dose kernel , the LDM is in closer agreement with the Fig. 5d in [38]). In other words, the energy transport among neighbouring voxels is simulated by the blurring effect of the PSF, which actually constitutes a first convolution, intrinsic in the imaging process itself.…”

Section: Local Deposition Methodssupporting

confidence: 54%

Radioembolization of hepatocarcinoma with 90Y glass microspheres: development of an individualized treatment planning strategy based on dosimetry and radiobiology

Chiesa

Mira

Maccauro

et al. 2015

Eur J Nucl Med Mol Imaging

146

183

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Section: Local Deposition Methodssupporting

confidence: 54%

Radioembolization of hepatocarcinoma with 90Y glass microspheres: development of an individualized treatment planning strategy based on dosimetry and radiobiology

Chiesa

Mira

Maccauro

et al. 2015

Eur J Nucl Med Mol Imaging

146

183

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“…9,[17][18][19][20][21][22][23] Image-based 3D dosimetry can be performed in several ways: direct Monte Carlo (MC) simulation, which is considered the gold standard; 9,[24][25][26][27][28][29][30] convolution calculations by voxel S-values, reliable in nearly uniform density tissue; 19,[31][32][33][34][35][36] local energy deposition method. 18,20,[36][37][38][39] Activity distribution quantification by SPECT is the major concern, due to physical and clinical degrading factors of the images. Physical factors [i.e., attenuation, scatter, partial volume effects (PVEs), noise] require well known corrections for attenuation and scatter, whereas presently, corrections for PVE (on a voxel-by-voxel basis) are still under investigation.…”

Section: Introductionmentioning

confidence: 99%

“…The relative calibration plays an important role, imposing the area under an activity-volume-histogram to be the total activity theoretically present in the volume-of-interest (VOI). Considering that with spatial resolution of 10-13 mm, the local energy deposition is almost equivalent to convolution dosimetry, 36 the absorbed dose to voxel can be considered linearly related to the voxel activity. So, with respect to an absolute calibration, the relative calibration causes a shift of the obtained cDVHs toward higher absorbed doses, making T III.…”

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confidence: 99%

Impact of SPECT corrections on 3D‐dosimetry for liver transarterial radioembolization using the patient relative calibration methodology

et al. 2016

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Purpose: Many centers aim to plan liver transarterial radioembolization (TARE) with dosimetry, even without CT-based attenuation correction (AC), or with unoptimized scatter correction (SC) methods. This work investigates the impact of presence vs absence of such corrections, and limited spatial resolution, on 3D dosimetry for TARE. Methods: Three voxelized phantoms were derived from CT images of real patients with different body sizes. Simulations of 99m Tc-SPECT projections were performed with the SIMIND code, assuming three activity distributions in the liver: uniform, inside a "liver's segment," or distributing multiple uptaking nodules ("nonuniform liver"), with a tumoral liver/healthy parenchyma ratio of 5:1. Projection data were reconstructed by a commercial workstation, with OSEM protocol not specifically optimized for dosimetry (spatial resolution of 12.6 mm), with/without SC (optimized, or with parameters predefined by the manufacturer; dual energy window), and with/without AC. Activity in voxels was calculated by a relative calibration, assuming identical microspheres and 99m Tc-SPECT counts spatial distribution. 3D dose distributions were calculated by convolution with lesions and healthy parenchyma from different reconstructions were compared with those obtained from the reference biodistribution (the "gold standard," GS), assessing differences for D95%, D70%, and D50% (i.e., minimum value of the absorbed dose to a percentage of the irradiated volume). γ tool analysis with tolerance of 3%/13 mm was used to evaluate the agreement between GS and simulated cases. The influence of deep-breathing was studied, blurring the reference biodistributions with a 3D anisotropic gaussian kernel, and performing the simulations once again. Results: Differences of the dosimetric indicators were noticeable in some cases, always negative for lesions and distributed around zero for parenchyma. Application of AC and SC reduced systematically the differences for lesions by 5%-14% for a liver segment, and by 7%-12% for a nonuniform liver. For parenchyma, the data trend was less clear, but the overall range of variability passed from −10%/40% for a liver segment, and −10%/20% for a nonuniform liver, to −13%/6% in both cases. Applying AC, SC with preset parameters gave similar results to optimized SC, as confirmed by γ tool analysis. Moreover, γ analysis confirmed that solely AC and SC are not sufficient to obtain accurate 3D dose distribution. With breathing, the accuracy worsened severely for all dosimetric indicators, above all for lesions: with AC and optimized SC, −38%/−13% in liver's segment, −61%/−40% in the nonuniform liver. For parenchyma, D50% resulted always less sensitive to breathing and sub-optimal correction methods (difference overall range: −7%/13%). Conclusions: Reconstruction protocol optimization, AC, SC, PVE and respiratory motion corrections should be implemented to obtain the best possible dosimetric accuracy. On the other side, thanks to the relative calibration, D50% inaccuracy for the healthy paren...

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“…The 90 Y dose calculation used the local deposition method (LDM),20, 21 which was previously demonstrated to be the most accurate when using SPECT imaging 22. In this technique, 90 Y β‐particles released by decay within a voxel deposit all energy locally with the same voxel.…”

Section: Methodsmentioning

confidence: 99%

SPECT/CT image‐based dosimetry for Yttrium‐90 radionuclide therapy: Application to treatment response

Potrebko

Shridhar

Biagioli

et al. 2018

J Applied Clin Med Phys

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This work demonstrates the efficacy of voxel‐based 90Y microsphere dosimetry utilizing post‐therapy SPECT/CT imaging and applies it to the prediction of treatment response for the management of patients with hepatocellular carcinoma (HCC). A 90Y microsphere dosimetry navigator (RapidSphere) within a commercial platform (Velocity, Varian Medical Systems) was demonstrated for three microsphere cases that were imaged using optimized bremsstrahlung SPECT/CT. For each case, the 90Y SPECT/CT was registered to follow‐up diagnostic MR/CT using deformable image registration. The voxel‐based dose distribution was computed using the local deposition method with known injected activity. The system allowed the visualization of the isodose distributions on any of the registered image datasets and the calculation of dose‐volume histograms (DVHs). The dosimetric analysis illustrated high local doses that are characteristic of blood‐flow directed brachytherapy. In the first case, the HCC mass demonstrated a complete response to treatment indicated by a necrotic region in follow‐up MR imaging. This result was dosimetrically predicted since the gross tumor volume (GTV) was well covered by the prescription isodose volume (V150 Gy = 85%). The second case illustrated a partial response to treatment which was characterized by incomplete necrosis of an HCC mass and a remaining area of solid enhancement in follow‐up MR imaging. This result was predicted by dosimetric analysis because the GTV demonstrated incomplete coverage by the prescription isodose volume (V470 Gy = 18%). The third case demonstrated extrahepatic activity. The dosimetry indicated that the prescription (125 Gy) isodose region extended outside of the liver into the duodenum (178 Gy maximum dose). This was predictive of toxicity as the patient later developed a duodenal ulcer. The ability to predict outcomes and complications using deformable image registration, calculated isodose distributions, and DVHs, points to the clinical utility of patient‐specific dose calculations for 90Y radioembolization treatment planning.

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Differences in 3D dose distributions due to calculation method of voxel S-values and the influence of image blurring in SPECT

Cited by 41 publications

References 55 publications

Radioembolization of hepatocarcinoma with 90Y glass microspheres: development of an individualized treatment planning strategy based on dosimetry and radiobiology

Radioembolization of hepatocarcinoma with 90Y glass microspheres: development of an individualized treatment planning strategy based on dosimetry and radiobiology

Impact of SPECT corrections on 3D‐dosimetry for liver transarterial radioembolization using the patient relative calibration methodology

SPECT/CT image‐based dosimetry for Yttrium‐90 radionuclide therapy: Application to treatment response

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