LUCAS VERDI ANGELOCCI

LUCAS VERDI ANGELOCCI

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Avaliação do método produtivo de placas de epóxi com fósforo-32 para o tratamento do câncer espinhal e intracranial por braquiterapia
2022 - SILVA, J.T.; NOGUEIRA, B.R.; ANGELOCCI, L.V.; SOUZA, C.D.; TEODORO, L.E.; SOUZA, P.D.; RODRIGUES, B.T.; CORREIA, R.W.; SANTOS, H.N. dos; ZEITUNI, C.A.; ROSTELATO, M.E.
A braquiterapia é uma modalidade de radioterapia utilizada no tratamento do câncer. Nessa modalidade, a fonte radioativa é posiciona junto ao tumor ou bem próxima a ele. A dose de radiação é entregue de forma contínua em um período curto de tempo (fontes temporárias) ou em períodos mais longos durante todo o decaimento radioativo do material (fontes permanentes). A maior vantagem da braquiterapia, é o fato da fonte estar bem próxima ao tumor o que significa que a região alvo recebe a maior parte da dose protegendo os tecidos sadios adjacentes à região tumoral. Shtrombakh et. al. trabalharam com césio-137 e verificaram que o uso do epóxi para a imobilização de fontes radiativas ocorreu sem vazamento por dois anos de testes. Pesquisas realizadas nos Estados Unidos por Folkert et. al. mostraram que placas flexíveis incorporadas com fósforo-32 são alternativas para o tratamento de câncer do sistema nervoso central na fase intraoperatória. No presente trabalho foi avaliada a uniformidade da placa de resina epóxi a partir de uma metodologia desenvolvida no Laboratório de fontes para Braquiterapia do IPEN/CNEN- SP. Vários testes foram realizados para determinar o melhor molde para a fabricação da placa. Concluiu-se que o politetrafluoretileno (PTFE), que comercialmente é conhecido como teflon foi o que obteve melhor resultado, devido a facilidade para desenformar a fonte após o processo de cura da resina. As placas de epóxi foram produzidas a resina 2220 e catalisador 3154 (Avipol), à proporção de 2:1 (massa). Para simular o material radioativo, ácido clorídrico (HCl) equivalente a 5 % da massa total (resina + catalisador) é acrescentado. O processo de cura da resina epóxi foi durante 24 h sob temperatura ambiente. As espessuras das placas foram medidas chegando-se a um valor médio de 0,300 mm ± 0,070. As medidas foram efetuadas com micrômetro medindo-se 10 pontos de cada placa. As medidas de largura e comprimento não foram realizadas, pois esses parâmetros não influenciam na uniformidade da dose. Para que a distribuição da atividade do fósforo-32 fosse estipulada, uma simulação por Método de Monte Carlo utilizando o código MCNP foi realizada. A variação máxima de dose ao longo da placa, considerando uma espessura totalmente uniforme de 0,300 mm, resultou em < 0,5 % até 0,5 cm antes da borda. O resultado da simulação mostra que com uma placa de espessura uniforme, a tendência da distribuição de dose seja homogênea. Pautando-se nos resultados, as placas de polímero epóxi se mostram viáveis para o uso em braquiterapia, sendo que o próximo passo do trabalho será os testes com material radioativo, a avaliação por métodos dosimétricos físicos e computacionais.
Homogeneity evaluation of phosphorus-32 epoxy plaques to be used in the treatment of spinal and intracranial cancer by brachytherapy
2021 - SILVA, JOSE T. da; SOUZA, CARLA D. de; NOGUEIRA, BEATRIZ R.; ANGELOCCI, LUCAS V.; ZEITUNI, CARLOS A.; ROSTELATO, MARIA E.C.M.
In Brachytherapy, radioactive source is positioned close to the tumor. The most important advantage is that the target region receives most of the dose, protecting the healthy tissues adjacent to the tumor region. In order to use these sources, a high dosimetric uniformity must be achieved, so a homogeneous dose delivery can be delivered to the target. In the present work, the consistency of the epoxy resin plate was evaluated using a methodology developed in the laboratory for the production of radiotherapy sources at IPEN / CNEN - SP. Several tests were carried out to determine the best mold for the source manufacture. It was concluded that polytetrafluoroethylene (PTFE), which is commercially known as teflon, obtained the best result, due to the ease unmold of the source after the resin curing process. The epoxy plaques were produced with resin 2220 and catalyst 3154 (Avipol), at a 2:1 mass ratio. To simulate the radioactive material, hydrochloric acid (HCl) equivalent to 5% of the total mass (resin + catalyst) is added. The epoxy resin cured for 24 h at room temperature. The thickness of the plaques was measured reaching an average value of 0.300 mm ± 0.070. The measurements were made with a micrometer, measuring 10 points of each plaque. The measures of width and length were not performed, as these parameters do not influence the uniformity of the dose. In order for the distribution of phosphorus-32 activity to be stipulated, a Monte Carlo Simulation using the MCNP code was performed. The maximum dose variation along the plaque, considering a totally uniform thickness of 0.300 mm, resulted in <0.5% up to 0.5 cm before the edge. The result of the simulation shows that with a uniformly thick plaque, the dose distribution trend is homogeneous. Based on the results, the epoxy polymer plaques are shown to be viable for use in brachytherapy, and the next step of the work will be the tests with radioactive material.
Assessing Ir-192 as an alternative to I-125 in ophthalmic treatment
2020 - ANGELOCCI, L.; NOGUEIRA, B.R.; SOUZA, C.D. de; ZEITUNI, C.A.; ROSTELATO, M.E.C.M.
Purpose or Objective: Brachytherapy sources for ocular melanoma usually contain Co-60, I-125, Pd-103 or Ru/Rh-106 as radionuclides. Ir-192 is not a preconized radioactive material for this purpose, although it is used for other brachytherapy applications. Higher mean energy from Ir-192 emission (ca. 380 keV) may be a reason for the preference of I-125 (35 keV) or Pd-103 (21 keV) over it, since low penetration is desired on the small structures of the human eye. This is not, however, an excluding criterion, considering Co-60 and Ru/Rh-106 have even higher mean energies. The demand in Brazil for lower-cost seeds to treat ocular melanoma lead to the development of an Ir-192 seed to make treatment more accessible, but since it is not used as an ophthalmic brachytherapy source, before its dosimetry is considered, one should care about the possibility of using it over more stablished materials. Considering this, the aim of this work is to assess the possibility of using Ir-192 seeds as ophthalmic brachytherapy sources by comparing some dosimetric parameters of a new seed model with the most stablished I-125 seed in literature, OncoSeed 6711. Material and Methods: As an initial study on the topic, this work relies only on Monte-Carlo simulations using MCNP4C transport code. Parameters analyzed are air-kerma strength, dose-rate constant and depth-dose curve, attention given to points within the human eye dimensions. The medium considered was homogeneous water, as it is a good approximation to the eye tissues in terms of composition and density and allows for future comparisons with TG-43 based calculations. OncoSeed 6711 is not produced anymore, but its long term as the reference source for dosimetry was considered. A 20 mm COMS ophthalmic applicator was also modeled and considered to be fully loaded with each seed model to compare the same parameters at a realistically clinical approach. Results: As expected, due to the higher energy of the Ir-192 emission spectrum, dose fall-off on the transversal axis of the seeds is less pronounced for the new seed model. The steeper dose gradient for I-125 is also visible on the doserate constant value. The effect of using a COMS applicator only strengthens this characteristic. Depth-dose curves were calculated up to the distance of 5 cm, both for a single seed and for an applicator fully loaded with 24 seeds. All the eye components relevant for dosimetry are located within this range, like the cells of the crystallin and the optical nerve. Conclusion: If one expects to use Ir-192 as an alternative to I-125 in ophthalmic cancer treatment, at least the dosimetry following TG-43 protocol should be carried with utmost attention, as undesirable dose to healthy nearby tissues is unavoidable. Crafting a different applicator most suited for this radionuclide is a possibility that can be taken into account. Another recommendation is to go beyond TG-43 water-based protocol and actually estimate dose to relevant eye components.
New model for an epoxy-based brachytherapy source to be used in spinal cancer treatment
2021 - SILVA, JOSE T.; SOUZA, CARLA D. de; ANGELOCCI, LUCAS V.; ROSERO, WILMMER A.A.; NOGUEIRA, BEATRIZ R.; CORREIA, RUANYTO W.; ZEITUNI, CARLOS A.; ROSTELATO, MARIA E.C.M.
The present work described the cold fabrication of a P-32 radioactive source to be used in CNS cancer using epoxy resin. The epoxy plaque fabricated with Teflon mold presented better agreement. MCNP simulation evaluated the radiation dose. Special attention was given to factors that can impact dose distribution. Average dose was 16.44 ± 2.89% cGy/s. Differences of less than 0.01 cm in thickness within the plaque lead to differences of up to 12% in the dose rate.
Monte Carlo simulation to assess free space and end-weld thickness variation effects on dose rate for a new Ir-192 brachytherapy source
2021 - ANGELOCCI, LUCAS V.; SOUZA, CARLA D. de; PANTELIS, EVAGGELOS; NOGUEIRA, BEATRIZ R.; ZEITUNI, CARLOS A.; ROSTELATO, MARIA E.C.M.
A new Iridium-192 seed for brachytherapy is under development. Specific dose rate contribution by two different factors were evaluated: the effect from movement of the core in the free space within the seed and the effect of the end-weld thickness variation. Both were investigated through use of the Monte Carlo radiation transport code MCNP6 and an in-house routine programmed with MATLAB. Differences greater than 15% compared to results from the nominal seed were found near the source, indicating a significant dose variation.
New core configuration for the fabrication of 125I radioactive sources for cancer treatment
2020 - SOUZA, CARLA D. de; ZEITUNI, CARLOS A.; FEHER, ANSELMO; MOURA, JOÃO A.; COSTA, OSVALDO L. da; ANGELOCCI, LUCAS V.; ROSTELATO, MARIA E.C.M.
In order to provide prostate brachytherapy treatment for more Brazilian men, IPEN is building a laboratory for the manufacture of radioactive sources. The new methodology for the production of iodine-125 seeds with yield 71.7% ± 5.3%. Points of importance were evaluated/discussed: photo-sensibility, reaction vial type, the substitution for iodine-131, pH, and solution volume. The surface was analyzed by FTIR and EDS. At the end, a Monte Carlo-MCNP6 simulation was performed to evaluate the TG-43 parameters.
Efficiancy of hydrogen peroxide for cleaning production areas and equipments in the Laboratory for Brachyterapy Sources Production
2017 - BAPTISTA, T.; ROSTELATO, M.C.M.; ZEITUNI, C.; PERINI, E.A.; SOUZA, C.D. de; MARQUES, J. de O.; NOGUEIRA, B.R.; ANGELOCCI, L.V.
Purpose: A great challenge in the brachytherapy sources production is to fulfill the Good Manufacturing Practices (GMPs) requirements, involving the process validation and of all supporting activities such as cleaning and sanitization. The increasingly strict requirements for quality assurance system, with several norms, normative resolutions and rules that must follow both medical products and radiochemical requirements, has led to a constant validation concerns. The main goal of GMP is to reduce inherent risks such as product contamination with microorganisms and cross-contamination. Methods: In the Laboratory for Brachytherapy Sources Production it was established a cleaning program for cleanrooms and hot cells using a hydrogen peroxide solution (6%). This work aims to assess the effectiveness of this cleaning agent in reducing and/or eliminating microbial load into the cleanrooms and equipments to acceptable levels in accordance with the current legislation. Results: The analysis was conducted using the results of the environmental monitoring program with settling contact plates in cleanrooms after the cleaning procedures. Furthermore, it was possible to evaluate the action of the sanitizing agent on the microbial population at the equipment and cleanrooms’ surfaces. It was also evaluated the best way to accomplish the cleaning program considering the dosimetry factor in each production process, hence the importance of radiological contamination. All the following environmental monitoring procedures presented satisfactory results, showing that the cleaning procedures was able to reduce and maintain the acceptable levels of viable and non-viable particles for the cleanroom classification (ISO 5 and ISO 7). The cleaning process with this sanitizer (hydrogen peroxide) can be performed quickly right before the production; allowing the production of brachytherapy sources without after use residues. Conclusion: This data will help the production of a clean and reliable product.