MIRD Pamphlet No. 26: Joint EANM/MIRD Guidelines for Quantitative <sup>177</sup>Lu SPECT Applied for Dosimetry of Radiopharmaceutical Therapy

Ljungberg, Michael; Celler, Anna; Konijnenberg, Mark; Eckerman, K.F.; Dewaraja, Yuni K.; Gleisner, Katarina Sjögreen

doi:10.2967/jnumed.115.159012

Cited by 263 publications

(297 citation statements)

References 58 publications

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“…Zoom of 1, circular radius of rotation of 330 mm (around the phantom surface) and image matrix of 128x128 pixels were set, resulting in a 4.8 mm pixel size image. In acquisition, the energy windows of the two dominant photopeaks of 177 Lu [4] were set at 113keV ± 7.5% and 208.4keV ± 7.5%, as also described in Grassi et al [30]. As regards the lower energy photopeak, the TEW scatter correction was employed and the lower scatter window was set in the range from 87.58keV to 104.53keV (using a default window weight of 0.5), while the upper scatter window from 121.47keV to 130.51keV (using a default window weight of 0.9375).…”

Section: Spect/ct Acquisition and Reconstructionmentioning

confidence: 99%

“…Several investigations have been reported on the performance of such algorithm on radionuclides frequently used in nuclear medicine, for patient imaging as well as patient specific dosimetry. Some of the more pertinent publications include improvements in correction techniques for quantification in SPECT [4,[17][18][19][20], evaluations of the accuracy of quantitative image reconstruction techniques [21][22][23][24][25] and comparisons of resolution between SPECT/CT systems using machine-specific reconstruction algorithms [26][27][28]. In these studies, the OSEM reconstruction parameters (i.e.…”

Section: Introductionmentioning

confidence: 99%

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Impact of a commercial 3D OSEM reconstruction algorithm on the 177Lu activity quantification of SPECT/CT imaging in a Molecular Radiotherapy trial

Grassi¹,

Fioroni²,

Mezzenga³

et al. 2017

Radiol Diagn Imaging

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The purpose of this study was to investigate the influence of the Ordered Subsets Expectation Maximization (OSEM) reconstruction updates implemented in the 177 Lu SPECT/CT imaging processing in molecular radiotherapy. A NEMA IEC Body Phantom TM was used to quantify activity in refillable spheres of five different sizes. Images were obtained with a hybrid dual-head SPECT-CT imaging system (Symbia T2, Siemens Medical System, Germany) with a clinical acquisition protocol, and reconstructed using a commercial 3D OSEM algorithm (Flash 3D). In the reconstruction process, different values of iterations and subsets were considered, along with a 3D Gaussian post-reconstruction filter and scatter and attenuation correction.Activity recovery coefficients were derived from the ratio between total reconstructed counts and the true activity for each sphere at each OSEM update. Recovery coefficients, and average fractional error (i.e. the weighted Root Mean Squared Error) were evaluated.At the same time, also 177 Lu spatial resolution and dead time were investigated, as matter of discussion about activity recovery coefficients.Results for spheres ≤ 5.5 ml in volume were significantly affected by the partial volume effect, causing a great bias in activity estimation for the smallest spheres. Their weighted fractional error was OSEM update dependent, ranging between 85% to 79% and 60% to 50% for the two smallest spheres, referring to values of 8 subsets-8 iterations and 16 subsets-10 iterations for the two extremes, respectively. No dead time was detected.The choice of iterations and subsets is dependent on the object size to investigate and on the desired image quality. Anyway, using a fixed number of iterations and subsets is correct for objects with volumes ≥ 5.5 ml, reaching the total count convergence in the reconstructed volumes, but the use of correction factors for compensating the partial volume effect is needed. For objects with volumes ≤ 5.5 ml the quantification becomes challenging.

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Section: Spect/ct Acquisition and Reconstructionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Impact of a commercial 3D OSEM reconstruction algorithm on the 177Lu activity quantification of SPECT/CT imaging in a Molecular Radiotherapy trial

Grassi¹,

Fioroni²,

Mezzenga³

et al. 2017

Radiol Diagn Imaging

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“…From the results of this work, it can be concluded that PLA-based FDM 3D printing along with an epoxy coating enables the production of chemically stable, fillable phantoms that are sufficiently durable for SPECT/CT calibration studies. Although no significant differences in partial-volume effects were found between the kidney-shaped and the spherically shaped single-compartment phantoms, this conclusion will have to be reevaluated for more realistic kidney geometries, in which a low-activity inner region is typically surrounded by a ring of higher activity (5).…”

Section: Limitations Of and Possible Improvements To Single-compartmementioning

confidence: 99%

Design and Fabrication of Kidney Phantoms for Internal Radiation Dosimetry Using 3D Printing Technology

2016

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Currently, the validation of multimodal quantitative imaging and absorbed dose measurements is impeded by the lack of suitable, commercially available anthropomorphic phantoms of variable sizes and shapes. To demonstrate the potential of 3-dimensional (3D) printing techniques for quantitative SPECT/CT imaging, a set of kidney dosimetry phantoms and their spherical counterparts was designed and manufactured with a fused-deposition-modeling 3D printer. Nuclide-dependent SPECT/CT calibration factors were determined to assess the accuracy of quantitative imaging for internal renal dosimetry. Methods: A set of 4 single-compartment kidney phantoms with filling volumes between 8 and 123 mL was designed on the basis of the outer kidney dimensions provided by MIRD pamphlet 19. After the phantoms had been printed, SPECT/CT acquisitions of 3 radionuclides ( 99m Tc, 177 Lu, and 131 I) were obtained and calibration constants determined for each radionuclide-volume combination. A set of additionally manufactured spheres matching the kidney volumes was also examined to assess the influence of phantom shape and size on the calibration constants. Results: A set of refillable, waterproof, and chemically stable kidneys and spheres was successfully manufactured. Average calibration factors for 99m Tc, 177 Lu, and 131 I were obtained in a large source measured in air. For the largest phantom (122.9 mL), the volumes of interest had to be enlarged by 1.2 mm for 99m Tc, 2.5 mm for 177 Lu, and 4.9 mm for 131 I in all directions to obtain calibration factors comparable to the reference. Although partial-volume effects were observed for decreasing phantom volumes (percentage difference of up to 9.8% for the smallest volume [8.6 mL]), the difference between corresponding spherekidney pairs was small (,1.1% for all volumes). Conclusion: 3D printing is a promising prototyping technique for geometry-specific calibration of SPECT/CT systems. Although the underlying radionuclide and the related collimator have a major influence on the calibration, no relevant differences between kidney-shaped and spherically shaped uniform-activity phantoms were observed. With comparably low costs and submillimeter resolution, 3D printing techniques hold the potential for manufacturing individualized anthropomorphic phantoms in many clinical applications in nuclear medicine.

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“…Peritherapeutic dosimetry in molecular radiotherapies with 177 Lu-labeled compounds, although sometimes limited by the availability of patients for late-time-point measurements, can be easily performed with limited technical difficulties (54). Most importantly, the demonstration of a tumor dose-response relationship (42) and the observation of minimal differences between cycles (12,41) indicate that posttherapeutic dosimetry after a first treatment cycle predicts the absorbed doses in further cycles.…”

Section: Individualized Dosimetry: Necessary Nice To Have or Countementioning

confidence: 99%

Individualized Dosimetry for Theranostics: Necessary, Nice to Have, or Counterproductive?

2017

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In 2005, the term theragnostics (theranostics) was introduced for describing the use of imaging for therapy planning in radiation oncology. In nuclear medicine, this expression describes the use of tracers for predicting the absorbed doses in molecular radiotherapy and, thus, the safety and efficacy of a treatment. At present, the most successful groups of isotopes for this purpose are 123 In2005,t he term theragnostics (theranostics) was first used for describing the use of imaging for therapy planning in radiation oncology. It is defined as the use of information from medical images to determine the optimal therapy for an individual patient (1). In nuclear medicine, this expression describes the use of tracers for predicting the absorbed doses in molecular radiotherapy and, thus, the safety and efficacy of a treatment. At present, the most successful groups of isotopes for theranostics are 123 I/ 124 I/ 131 I (2), 68 Ga/ 177 Lu, and 111 In/ 86 Y/ 90 Y (3).In recent years, numerous reports providing pre-and peritherapeutic dosimetry data for molecular radiotherapies with 131 I-sodium iodide (4-8) and 177 Lu-labeled (9-16) and 90 Y-labeled (13,(17)(18)(19)(20) compounds have been published. The purpose of this review is to introduce the concept of theranostics, present available data on the dosimetry and dose-response relationships of theranostic compounds, and discuss whether individualized dosimetry for theranostics is necessary, nice to have, or counterproductive. Special focus is given to the provision of radioiodine therapy for differentiated thyroid cancer and peptide receptor radionuclide therapy (PRRT) with 177 Luand 90 Y-labeled peptides. INTERNAL DOSIMETRY Dosimetry in Nuclear MedicineThe basic methodology for calculating the absorbed doses from the administration of a radiopharmaceutical was developed by the MIRD Committee (21):Eq. 1 where• Dðr T Þ is the mean absorbed dose to target region r T delivered by the cumulated activity in source region r S .•Ãðr S Þ is the time-integrated activity in source region r S .Ã denotes the total number of radioactive decays (determined by integrating the time-activity curve from time 0 to infinity) occurring within an accumulating organ.Ã is determined by quantitative imaging at several time points after the administration of a radiopharmaceutical for an assessment of organor voxel-specific pharmacokinetics. A proposal for choosing optimal time points is given in MIRD Pamphlet No. 16 (22). • A 0 is the administered activity.•ãðr S Þ is the time-integrated activity coefficient, which is the time-integrated activity divided by the administered activity.• Sðr T )r S Þ is the radionuclide specific absorbed dose rate per unit of activity in target region r T delivered by source region r S (formerly called S value).For calculation of the absorbed dose, therefore, several steps are essential.The first step is to perform quantitative imaging at different time points to assess the activity in the organs of interest over time. The established method for quantitative imagi...

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MIRD Pamphlet No. 26: Joint EANM/MIRD Guidelines for Quantitative ¹⁷⁷Lu SPECT Applied for Dosimetry of Radiopharmaceutical Therapy

Cited by 263 publications

References 58 publications

Impact of a commercial 3D OSEM reconstruction algorithm on the 177Lu activity quantification of SPECT/CT imaging in a Molecular Radiotherapy trial

Impact of a commercial 3D OSEM reconstruction algorithm on the 177Lu activity quantification of SPECT/CT imaging in a Molecular Radiotherapy trial

Design and Fabrication of Kidney Phantoms for Internal Radiation Dosimetry Using 3D Printing Technology

Individualized Dosimetry for Theranostics: Necessary, Nice to Have, or Counterproductive?

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MIRD Pamphlet No. 26: Joint EANM/MIRD Guidelines for Quantitative 177Lu SPECT Applied for Dosimetry of Radiopharmaceutical Therapy

Cited by 263 publications

References 58 publications

Impact of a commercial 3D OSEM reconstruction algorithm on the 177Lu activity quantification of SPECT/CT imaging in a Molecular Radiotherapy trial

Impact of a commercial 3D OSEM reconstruction algorithm on the 177Lu activity quantification of SPECT/CT imaging in a Molecular Radiotherapy trial

Design and Fabrication of Kidney Phantoms for Internal Radiation Dosimetry Using 3D Printing Technology

Individualized Dosimetry for Theranostics: Necessary, Nice to Have, or Counterproductive?

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MIRD Pamphlet No. 26: Joint EANM/MIRD Guidelines for Quantitative ¹⁷⁷Lu SPECT Applied for Dosimetry of Radiopharmaceutical Therapy