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Molecular Imaging and Biology
Published in: Molecular Imaging and Biology 5/2013

01-10-2013 | Research Article

Assessment of S Values in Stylized and Voxel-Based Rat Models for Positron-Emitting Radionuclides

Authors: Tianwu Xie, Habib Zaidi

Published in: Molecular Imaging and Biology | Issue 5/2013

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Abstract

Purpose

Positron emission tomography (PET) is a powerful tool in small animal research, enabling noninvasive quantitative imaging of biochemical processes in living subjects. However, the dosimetric characteristics of small animal PET imaging are usually overlooked, although the radiation dose may be significant. The variations of anatomical characteristics between the various computational models may result in differences in the dosimetric outcome.

Methods

We used five different anatomical rat models (two stylized and three voxel based) to compare calculated absorbed fractions and S values for eight positron-emitting radionuclides (C-11, N-13, O-15, F-18, Cu-64, Ga-68, Y-86, and I-124) commonly used to label various probes for small animal PET imaging. The MCNPX radiation transport code was used for radiation dose calculations.

Results

For most source/target organ pairs, O-15 and Ga-68 produce the highest self-absorbed S values because of the high-energy and high-frequency of positron emissions, while Y-86 produces the highest cross-absorbed S values because of the high energy and high frequency of γ-rays emission. Anatomical models produced from different rat strains or modeling techniques exhibit different organ masses, volumes, and thus give rise to different S values and absorbed dose. The variations of absorbed fractions between models of the same type are less than those between models with different types. The calculated S values depend strongly on organ mass, and as such, different models produce similar S values for organs of comparable masses. In most source organs presenting with high cumulated activity, the absorbed dose is less affected by model difference compared with other organs.

Conclusions

The produced S values for common positron-emitting radionuclides can be exploited in the assessment of radiation dose to rats from different radiotracers used in small animal PET experiments. This work contributes to a better understanding of the influence of different computational models on small animal dosimetry.
Appendix
Available only for authorised users
Literature
1.
Nanni C, Rubello D, Khan S, Al-Nahhas A, Fanti S (2007) Role of small animal PET in stimulating the development of new radiopharmaceuticals in oncology. Nucl Med Commun 28:427–429PubMedCrossRef
2.
Chatziioannou AF (2002) Molecular imaging of small animals with dedicated PET tomographs. Eur J Nucl Med Mol Imaging 29:98–114PubMedCrossRef
3.
Aboagye EO (2005) Positron emission tomography imaging of small animals in anticancer drug development. Mol Imaging Biol 7:53–58PubMedCrossRef
4.
Levin CS, Zaidi H (2007) Current trends in preclinical PET system design. PET Clinics 2:125–160CrossRef
5.
Russell LB (1971) Definition of functional units in a small chromosomal segment of the mouse and its use in interpreting the nature of radiation-induced mutations. Mutat Res 11:107–123PubMedCrossRef
6.
Funk T, Sun M, Hasegawa BH (2004) Radiation dose estimate in small animal SPECT and PET. Med Phys 31:2680–2686PubMedCrossRef
7.
Mather SJ (2006) Design of radiolabelled ligands for the imaging and treatment of cancer. Mol Biosyst 3:30–35PubMedCrossRef
8.
Boutaleb S, Pouget JP, Hindorf C et al (2009) Impact of mouse model on preclinical dosimetry in targeted radionuclide therapy. Proc IEEE 97:2076–2085CrossRef
9.
Keenan MA, Stabin MG, Segars WP, Fernald MJ (2010) RADAR realistic animal model series for dose assessment. J Nucl Med 51:471–476PubMedCrossRef
10.
Hui TE, Fisher DR, Kuhn JA et al (1994) A mouse model for calculating cross-organ beta doses from yttrium-90-labeled immunoconjugates. Cancer 73:951–957PubMedCrossRef
11.
Flynn AA, Green AJ, Pedley RB, Boxer GM, Boden R, Begent RH (2001) A mouse model for calculating the absorbed beta-particle dose from (131)I- and (90)Y-labeled immunoconjugates, including a method for dealing with heterogeneity in kidney and tumor. Radiat Res 156:28–35PubMedCrossRef
12.
Yoriyaz H, Stabin M (1997) Electron and photon transport in a model of a 30 g mouse. J Nucl Med 38:967–967
13.
Hindorf C, Ljungberg M, Strand SE (2004) Evaluation of parameters influencing S values in mouse dosimetry. J Nucl Med 45:1960–1965PubMed
14.
Bitar A, Lisbona A, Bardies M (2007) S-factor calculations for mouse models using Monte-Carlo simulations. Q J Nucl Med Mol Imaging 51:343–351PubMed
15.
Konijnenberg MW, Bijster M, Krenning EP, De Jong M (2004) A stylized computational model of the rat for organ dosimetry in support of preclinical evaluations of peptide receptor radionuclide therapy with (90)Y, (111)In, or (177)Lu. J Nucl Med 45:1260–1269PubMed
16.
Miller WH, Hartmann-Siantar C, Fisher D et al (2005) Evaluation of beta-absorbed fractions in a mouse model for 90Y, 188Re, 166Ho, 149Pm, 64Cu, and 177Lu radionuclides. Cancer Biother Radiopharm 20:436–449PubMedCrossRef
17.
Kolbert KS, Watson T, Matei C, Xu S, Koutcher JA, Sgouros G (2003) Murine S factors for liver, spleen, and kidney. J Nucl Med 44:784–791PubMed
18.
Segars WP, Tsui BMW, Frey EC, Johnson GA, Berr SS (2004) Development of a 4-D digital mouse phantom for molecular imaging research. Mol Imaging Biol 6:149–159PubMedCrossRef
19.
Stabin MG, Peterson TE, Holburn GE, Emmons MA (2006) Voxel-based mouse and rat models for internal dose calculations. J Nucl Med 47:655–659PubMed
20.
Dogdas B, Stout D, Chatziioannou AF, Leahy RM (2007) Digimouse: a 3D whole body mouse atlas from CT and cryosection data. Phys Med Biol 52:577–587PubMedCrossRef
21.
Bitar A, Lisbona A, Thedrez P et al (2007) A voxel-based mouse for internal dose calculations using Monte Carlo simulations (MCNP). Phys Med Biol 52:1013–1025PubMedCrossRef
22.
Peixoto PH, Vieira JW, Yoriyaz H, Lima FR (2008) Photon and electron absorbed fractions calculated from a new tomographic rat model. Phys Med Biol 53:5343–5355PubMedCrossRef
23.
Wu L, Zhang G, Luo Q, Liu Q (2008) An image-based rat model for Monte Carlo organ dose calculations. Med Phys 35:3759–3764PubMedCrossRef
24.
Zhang G, Xie T, Bosmans H, Liu Q (2009) Development of a rat computational phantom using boundary representation method for Monte Carlo simulation in radiological imaging. Proc IEEE 97:2006–2014CrossRef
25.
Xie T, Zhang G, Li Y, Liu Q (2010) Comparison of absorbed fractions of electrons and photons using three kinds of computational phantoms of rat. Appl Phys Lett 97:33702–33704CrossRef
26.
Beekman FJ, Vastenhouw B, van der Wilt G et al (2009) 3-D rat brain phantom for high-resolution molecular imaging. Proc IEEE 97:1997–2005CrossRef
27.
Mohammadi A, Kinase S (2011) Monte Carlo simulations of photon specific absorbed fractions in a mouse voxel phantom. Prog Nucl Sci Technol 1:126–129
28.
Zhang X, Xie X, Cheng J et al (2012) Organ dose conversion coefficients based on a voxel mouse model and MCNP code for external photon irradiation. Radiat Prot Dosimetry 148:9–19PubMedCrossRef
29.
Taschereau R, Chatziioannou AF (2007) Monte Carlo simulations of absorbed dose in a mouse phantom from 18-fluorine compounds. Med Phys 34:1026–1036PubMedCrossRef
30.
Larsson E, Strand SE, Ljungberg M, Jonsson BA (2007) Mouse S-factors based on Monte Carlo simulations in the anatomical realistic moby phantom for internal dosimetry. Cancer Biother Radiopharm 22:438–442PubMedCrossRef
31.
Larsson E, Ljungberg M, Strand SE, Jonsson BA (2011) Monte Carlo calculations of absorbed doses in tumours using a modified MOBY mouse phantom for pre-clinical dosimetry studies. Acta Oncologica 50:973–980PubMedCrossRef
32.
Xie T, Liu Q, Zaidi H (2012) Evaluation of S-values and dose distributions for (90)Y, (131)I, (166)Ho, and (188)Re in seven lobes of the rat liver. Med Phys 39:1462–1472PubMedCrossRef
33.
Xie T, Zaidi H (2013) Monte Carlo-based evaluation of S-values in mouse models for positron-emitting radionuclides. Phys Med Biol 58:169–182PubMedCrossRef
34.
Xie T, Han D, Liu Y, Sun W, Liu Q (2010) Skeletal dosimetry in a voxel-based rat phantom for internal exposures to photons and electrons. Med Phys 37:2167–2178PubMedCrossRef
35.
Theis C, Buchegger KH, Brugger M, Forkel-Wirth D, Roesler S, Vincke H (2006) Interactive three-dimensional visualization and creation of geometries for Monte Carlo calculations. Nucl Instrum Meth A 562:827–829CrossRef
36.
Bolch WE, Eckerman KF, Sgouros G, Thomas SR (2009) MIRD pamphlet No. 21: a generalized schema for radiopharmaceutical dosimetry–standardization of nomenclature. J Nucl Med 50:477–484PubMedCrossRef
37.
Waters LS, McKinney GW, Durkee JW et al (2007) The MCNPX Monte Carlo radiation transport code. Hadronic Shower Simulation Workshop 896:81–90254
38.
39.
ICRP Publication 89 (2002) Basic anatomical and physiological data for use in radiological protection: reference values. A report of age- and gender-related differences in the anatomical and physiological characteristics of reference individuals. Ann ICRP 32:5–265CrossRef
40.
ICRU Report 44 (1989) Tissue substitutes in radiation dosimetry and measurement. International Commission on Radiological Units and Measurements, Bethesda
41.
Stabin MG (2008) Uncertainties in internal dose calculations for radiopharmaceuticals. J Nucl Med 49:853–860PubMedCrossRef
42.
Wilson AA, Ginovart N, Hussey D, Meyer J, Houle S (2002) In vitro and in vivo characterisation of [11C]-DASB: a probe for in vivo measurements of the serotonin transporter by positron emission tomography. Nucl Med Biol 29:509PubMedCrossRef
Metadata
Title
Assessment of S Values in Stylized and Voxel-Based Rat Models for Positron-Emitting Radionuclides
Authors
Tianwu Xie
Habib Zaidi
Publication date
01-10-2013
Publisher
Springer US
Published in
Molecular Imaging and Biology / Issue 5/2013
Print ISSN: 1536-1632
Electronic ISSN: 1860-2002
DOI
https://doi.org/10.1007/s11307-013-0632-0

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