Use of voxelized thyroid models to develop a physical-anthropomorphic phantom for 3D printing

Tayrine Moratelli da Silva; Alexandre Barbosa Soares; Eder Augusto de Lucena; Ana Letícia Almeida Dantas; Bruno Melo Mendes; Paulo Sergio Silveira Felix Junior; Felipe Lima Bourguignon; Márcia de Melo Dórea; Eric Cardona Romani; Bernardo Maranhão Dantas

doi:10.15392/bjrs.v9i2C.1673

Authors

Tayrine Moratelli da Silva Instituto de Radioproteção e Dosimetria
Alexandre Barbosa Soares Instituto de Radioproteção e Dosimetria
Eder Augusto de Lucena Instituto de Radioproteção e Dosimetria
Ana Letícia Almeida Dantas Instituto de Radioproteção e Dosimetria
Bruno Melo Mendes Centro de Desenvolvimento da Tecnologia Nuclear da CNEN
Paulo Sergio Silveira Felix Junior SENAI/FIRJAN
Felipe Lima Bourguignon SENAI/FIRJAN
Márcia de Melo Dórea SENAI/FIRJAN
Eric Cardona Romani SENAI/FIRJAN
Bernardo Maranhão Dantas Instituto de Radioproteção e Dosimetria https://orcid.org/0000-0002-2388-6073

DOI:

https://doi.org/10.15392/bjrs.v9i2C.1673

Keywords:

Simulador Tireoide-pescoço, Modelo Voxelizados, 131I, Impressão 3D.

Abstract

The monitoring of the intake os radionuclides by workers and public individuals, using in vivo measurements, requires the application of calibration factors obtained with physical-anthropomorphic phantoms. In the case of ¹³¹I, the lack of anatomical realism of the phantom might impair the quality and reliability of the monitoring result. Thus, in order to develop a thyroid phantom by means of 3D printing, images of the voxelized models provided in ICRP 110 were used. The superposition of the images of the original model and the treated model demonstrate the maintenance of morphological characteristics. Therefore, image manipulation techniques applied in this work aimed to smooth the sharp angles of the original image and the prototype printing were considered effective.

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References

INTERNATIONAL ATOMIC ENERGY AGENCY (IAEA) (2014). Radiation Protection and Safety of Radiation Sources: International Basic Safety Standards. General Safety Requirements Part 3No. GSR Part 3.

INTERNATIONAL ATOMIC ENERGY AGENCY (IAEA). (1999) Assessment of Occupational Exposure Due to Intakes of Radionuclides - Safety Standards Series, no.RS-G-1.2, IAEA.

MILLER, K.L.; BOTT, S.M.; VELKLEY, D. E.(1979) “Review of contamination and exposure hazards associated with therapeutic uses of radioiodine”. J. Nucl. Med. Technology, v.7, p. 163-166.

OLIVEIRA, R. S., LEÃO, A. M. A. C. (2008) “História da Radiofarmácia e as implicações da Emenda Constitucional N. 49”. Revista Brasileira de Ciências Farmacêuticas, v. 44, n. 3, p. 377-382.

ICRP, 1993, Age-dependent Doses to Members of the Public from Intake of Radionuclides -Part 2 Ingestion Dose Coefficients. ICRP Publication 67. Ann. ICRP 23 (3-4).

ICRP, 1997. Individual Monitoring for Internal Exposure of Workers (preface and glossary missing). ICRP Publication 78. Ann. ICRP 27 (3-4).

INTERNATIONAL ATOMIC ENERGY AGENCY (IAEA). (1996). Direct methods for measuring radionuclides in the human body. Safety Series n. 114.

ZHANG, B.; MILLE, M.; XU, X. G.(2008)"An analysis of dependency of counting efficiency on worker anatomy for in vivo measurements: whole-body counting". Phys. Med. Biol. 53 3463–75.

DANTAS, B. M. (1998) “Bases para a calibração de contadores de corpo inteiro utilizando simuladores físicos antropomórficos”. Tese de doutorado. Universidade do Estado do Rio de Janeiro.

BROGGIO, D.; ZHANG, B.; DE CARLAN, L.; DESBRÉE, A.; LAMART, S.; LE GUEN, B.; BAILLOEUIL, C.; FRANCK, D. (2009) "Analytical and Monte Carlo assessment of activity and local dose after a wound contamination by activation products". Health Phys. 96 155–63.

LAMART, S.; BLANCHARDON, E.; MOLOKANOV, A.; KRAMER, G. H.; BROGGIO, D.; FRANCK, D. (2009) "Study of the influence of radionuclide biokinetics on the efficiency of in vivo counting using Monte Carlo simulation". Health Phys. 96 558–67.

ZOU, W. et al (2015)"Potential of 3D printing technologies for fabrication of electron bolus and proton compensators". J. Appl. Clin. Med. Phys. 16 90–8.

RUITERS, S.; SUN, Y.; DE JONG, S.; POLITIS, C.; MOMBAERTS, I. (2016) "Computer-aided design and three-dimensional printing in the manufacturing of an ocular prosthesis" Br. J. Ophthalmol. 100 879–81.

ZUNIGA, J. M.; PECK, J.; SRIVASTAVA, R.; KATSAVELIS, D.; CARSON, A. (2016)"An open source 3D-printed transitional hand prosthesis for children". J. Prosthet. Orthot. At press (https://doi.org/10.1097/ JPO.0000000000000097).

TAN, E. T. W.; LING, J. M. AND DINESH, S. K. (2016) "The feasibility of producing patient-specific acrylic cranioplasty implants with a low-cost 3D printer". J. Neurosurg. 124 1531–7.

BEAUMONT, T.; IDEIAS, P. C.; RIMLINGER, M.; BROGGIO, D.; FRANCK, D. (2017) "Development and test of sets of 3D printed age-specific thyroid phantoms for 131I measurements". Phys. Med. Biol. 62 4673.

LUCENA, E. A.; REBELO, A. M. O.; ARAÚJO, F.; SOUSA, W. O.; DANTAS, A. L. A.; DANTAS, B. M.; CORBO, R. (2007)Evaluation of internal exposure of nuclear medicine staff through in vivo and in vitro bioassay techniques. Radiation Protection Dosimetry, v.127, p.465 468.

OLIVEIRA, S. M.; DANTAS, A. L. A.; DANTAS, B. M. (2016) Comparison of surface contamination monitors for in vivo measurement of 131I in the thyroid. Journal of Physics: Conference Series, Volume 733, Number 1.

ICRP, 2002, Basic Anatomical and Physiological Data for Use in Radiological Protection Reference Values. ICRP Publication 89. Ann. ICRP 32 (3-4).

ICRP Publication 110. Adult Reference Computational Phantoms. Ann ICRP, v. 39(2), p. 1-166, 2009.

RASBAND, W.S., (2016) ImageJ, U. S. National Institutes of Health, Bethesda, Maryland, USA. Disponível em: http://imagej.nih.gov/ij/. Acessado em Setembro (2016).

JUNQUEIRA, L. C.; CARNEIRO J. Histologia Básica: 10. ed. São Paulo: Guanabara Koogan, 2004.

MACIEL, L. M.Z. (2007) O exame físico da tireoide. Medicina (Ribeirão Preto); 40 (1): 72-77.