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Abstract

Purpose:

We evaluated the possibility to assess ⁹⁰Y-PET/CT imaging quantification for dosimetry in ⁹⁰Y-peptide receptor radionuclide therapy.

Methods:

Tests were performed by Discovery 710 Elite (GE) PET/CT equipment. A body-phantom containing radioactive-coplanar-spheres was filled with ⁹⁰Y water solution to reproduce different signal-to-background-activity-ratios (S/N). We studied minimum detectable activity (MDA) concentration, contrast-to-noise ratio (CNR), and full-width-at-half-maximum (FWHM). Subsequently, three recovery coefficients (RC)-based correction approaches were evaluated: maximum-RC, resolution-RC, and isovolume-RC. The analysis of the volume segmentation thresholding method was also assessed to derive a relationship between the true volume of the targets and the threshold to be applied to the PET images. ⁹⁰Y-PET/CT imaging quantification was then achieved on some patients and related with preclinical tests. Moreover, the dosimetric evaluation was obtained on the target regions.

Results:

CNR value was greater than 5 if the MDA was greater than 0.2 MBq/mL with no background activity and 0.5–0.7 MBq/mL with S/N ranging from 3 to 6. FWHM was equal to 7 mm. An exponential fitting of isovolume RCs-based correction technique was adopted for activity quantification. Adaptive segmentation thresholding exponential curves were obtained and applied for target volume identification in three signal-to-background-activity-ratios. The imaging quantification study and dosimetric evaluations in clinical cases was feasible and the results were coherent with those obtained in preclinical tests.

Conclusions:

⁹⁰Y-PET/CT imaging quantification is possible both in phantoms and in patients. Absorbed dose evaluations in clinical applications are strongly related to targets activity concentration.

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References

Strigari

, Konijnenberg

, Chiesa

, et al. The evidence base for the use of internal dosimetry in the clinical practice of molecular radiotherapy. Eur J Nucl Med Mol Imaging, 2014; 41:1976.

Shen

, De Nardo

, Yuan

, et al. Planar gamma-camera imaging and quantitation of Yttrium-90 Bremsstrahlung. J Nucl Med, 1994; 35:1381.

Fabbri

, Sarti

, Cremonesi

, et al. Quantitative analysis of ⁹⁰Y Bremsstrahlung SPECT/CT images for application to 3D patient specific dosimetry. Cancer Biother Radiopharm, 2009; 24:145.

Fabbri

, Sarti

, Agostini

, et al. SPECT-CT ⁹⁰Y-Bremsstrahlung images for dosimetry during therapy. Ecancermedicalscience, 2008; 2:106.

Pasciak

, Bourgeois

, Mckinney

, et al. Radioembolization and the dynamic role of ⁹⁰Y PET/CT. Front Oncol, 2014; 4:38.

D'Arienzo

, Chiaramida

, Chiaccherelli

, et al. ⁹⁰Y PET-based dosimetry after selective internal radiotherapy treatments. Nucl Med Commun, 2012; 33:633.

Bagni

, D'Arienzo

, Chiaramida

, et al. ⁹⁰Y for the assessment of microsphere biodistribution after selective internal radiotherapy. Nucl Med Commun, 2011; 33:117.

Lhommel

, Van Elmbt

, Goffette

, et al. Feasability of ⁹⁰Y TOF PET-based dosimetry in liver metastasis therapy using SIR-Spheres. Eur J Nucl Med Mol Imaging, 2010; 37:1654.

Werner

, Brechtel

, Beyer

, et al. PET/CT for the assessment and quantification of ⁹⁰Y biodistribution after selective internal radiotherapy (SIRT) of liver metastases. Eur J Nucl Med Mol Imaging, 2010; 37:407.

10.

van Elmbt

, Vanderberghe

, Walrand

, et al. Comparison of yttrium-90 quantitative imaging by TOF and non TOF PET in a phantom of liver selective internal radiotherapy. Phys Med Biol, 2011; 56:6759.

11.

Willowson

, Forwood

, Jakoby

, et al. Quantitative ⁹⁰Y image reconstruction in PET. Med Phys, 2012; 39:7153.

12.

Walrand

, Jamar

, Van Elmbt

, et al. 4-Step renal dosimetry dependent on cortex geometry applied to ⁹⁰Y peptide receptor radiotherapy; evaluation using a fillable kidney phantom imaged by ⁹⁰Y PET. J Nucl Med, 2010; 51:1969.

13.

Fabbri

, Mattone

, Casi

, et al. Quantitative evaluation on [90Y] DOTATOC PET and SPECT imaging by phantom acquisitions and clinical applications in locoregional and systemic treatments. Q J Nucl Med Mol Imaging, 2012; 56:522.

14.

Fabbri

, Mattone

, Sarti

, et al. ⁹⁰Y-based PET and SPECT/CT imaging in locoregional brain treatment for high-grade gliomas: Retrospective fusion with MRI. Eur J Nucl Med Mol Imaging, 2012; 39:1822.

15.

Carlier

, Eugene

, Bodet-Milin

, et al. Assessment of acquisition protocols for routine imaging of Y-90 using PET/CT. EJNMMI Res, 2013; 3:11.

16.

Bao

, Chatziioannou

. Estimation of the minimum detectable activity of preclinical PET imaging systems with an analytical method. Med Phys, 2010; 37:6070.

17.

Elschot

, Vermolen

, Lam

MGEH

, et al. Quantitative comparison of PET and Bremsstrahlung SPECT for imaging the in vivo yttrium-90 microsphere distribution after liver radioembolization. PLoS One, 2013; 8:e55742.

18.

Bright

, Newbury

, Steel

. Visibility of object in computer simulations of noisy micrographs. J Microsc, 1997; 189:25.

19.

Rose

. The sensitivity performance of human eye on absolute scale. J Opt Soc Am, 38:196–208

20.

National Electrical Manufacturers Association (NEMA). Performance measurement of positron emission tomographs. In: NEMA Standards Publication NU 2-2007 Edited by NEMA. Rosslyn: National Electrical Manufacturers Association. 2007; 11.

21.

Jentzen

. Experimental investigation of factors affecting the absolute recovery coefficients in iodine-124 PET lesion imaging. Phys Med Bio, 2010; 55:2365.

22.

Jentzen

, Freudenberg

, Eising

, et al. Segmentation of PET volumes by iterative image thresholding. J Nucl Med, 2007; 48:104.

23.

Pacilio

, Basile

, Shcherbinin

, et al. An innovative iterative thresholding algorithm for tumor segmentation and volumetric quantification on SPECT images: Monte Carlo-based methodology and validation. Med Phys, 2008; 38:3050.

24.

Nehmeh

, El-Zeftawy

, Greco

, et al. An iterative technique to segment PET lesions using a Monte Carlo based mathematical model. Med Phys, 2009; 36:4803.

25.

Aristophanus

, Penney

, Pellizzari

. The development and testing of a digital PET phantom for the evaluation of tumor volume segmentation techniques. Med Phys, 2008; 35:3331.

26.

Fang

YHD

, Lin

, Shih

, et al. Development and evaluation of an open-source software package “CGITA” for quantifying tumor heterogeneity with molecular images. Biomed Res Int, 2014; 2014:248505.

27.

Dewaraja

, Frey

, Sgouros

, et al. MIRD pamphlet No. 23: Quantitative SPECT for patient-specific 3-dimensional dosimetry in internal radionuclide therapy. J Nucl Med, 2012; 53:1310.

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90 Y-PET/CT Imaging Quantification for Dosimetry in Peptide Receptor Radionuclide Therapy: Analysis and Corrections of the Impairing Factors

Abstract

Purpose:

Methods:

Results:

Conclusions:

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References

Supplementary Material