Feasibility of clinical electron beam formation using polymer materials produced by fused deposition modeling

Irina Miloichikova; Angelina Bulavskaya; Yury Cherepennikov; Boris Gavrikov; Elisabetta Gargioni; Dmitrij Belousov; Sergei Stuchebrov

doi:10.1016/j.ejmp.2019.07.014

Feasibility of clinical electron beam formation using polymer materials produced by fused deposition modeling

Standard

Feasibility of clinical electron beam formation using polymer materials produced by fused deposition modeling. / Miloichikova, Irina; Bulavskaya, Angelina; Cherepennikov, Yury; Gavrikov, Boris; Gargioni, Elisabetta; Belousov, Dmitrij; Stuchebrov, Sergei.

in: PHYS MEDICA, Jahrgang 64, 08.2019, S. 188-194.

Publikationen: SCORING: Beitrag in Fachzeitschrift/Zeitung › SCORING: Zeitschriftenaufsatz › Forschung › Begutachtung

Harvard

Miloichikova, I, Bulavskaya, A, Cherepennikov, Y, Gavrikov, B, Gargioni, E, Belousov, D & Stuchebrov, S 2019, 'Feasibility of clinical electron beam formation using polymer materials produced by fused deposition modeling', PHYS MEDICA, Jg. 64, S. 188-194. https://doi.org/10.1016/j.ejmp.2019.07.014

APA

Miloichikova, I., Bulavskaya, A., Cherepennikov, Y., Gavrikov, B., Gargioni, E., Belousov, D., & Stuchebrov, S. (2019). Feasibility of clinical electron beam formation using polymer materials produced by fused deposition modeling. PHYS MEDICA, 64, 188-194. https://doi.org/10.1016/j.ejmp.2019.07.014

Vancouver

Miloichikova I, Bulavskaya A, Cherepennikov Y, Gavrikov B, Gargioni E, Belousov D et al. Feasibility of clinical electron beam formation using polymer materials produced by fused deposition modeling. PHYS MEDICA. 2019 Aug;64:188-194. https://doi.org/10.1016/j.ejmp.2019.07.014

Bibtex

@article{82beedbcd81346b0bc8d1298db3f2602,

title = "Feasibility of clinical electron beam formation using polymer materials produced by fused deposition modeling",

abstract = "The main challenge in electron external beam radiation therapy with clinical accelerators is the absence of integrated systems to form irregular fields. The current approach to provide conformal irradiation is to use additional metallic shaping blocks, with inefficient and expensive workflows. This work presents a simple method to form therapeutic electron fields using 3D printed samples. These samples are manufactured by fused deposition modeling, which can affect crucial properties, such as material homogeneity, due to the presence of residual air-filled cavities. The applicability of this method was therefore investigated with a set of experiments and Monte Carlo simulations aimed at determining the electron depth dose distribution in polymer materials. The results show that therapeutic electron beams with energies 6-20 MeV can be effectively absorbed using these polymeric samples. The model developed in this study provides a way to assess the dose distribution in such materials and to calculate the appropriate thickness of polymer samples for therapeutic electron beam formation. It is shown that for total absorption of 6 MeV electron beams the material thickness should be at least 4 cm, while this value should be at least 8 cm for 12 MeV and 11 cm for 20 MeV, respectively. The results can be used to further develop 3D printing procedures for medical electron beam profile formation, allowing the creation of a collimator or absorber with patient-specific configuration using rapid prototyping systems, thus contributing to improve the accuracy of dose delivery in electron radiotherapy within a short manufacturing time.",

author = "Irina Miloichikova and Angelina Bulavskaya and Yury Cherepennikov and Boris Gavrikov and Elisabetta Gargioni and Dmitrij Belousov and Sergei Stuchebrov",

note = "Copyright {\textcopyright} 2019. Published by Elsevier Ltd.",

year = "2019",

month = aug,

doi = "10.1016/j.ejmp.2019.07.014",

language = "English",

volume = "64",

pages = "188--194",

journal = "PHYS MEDICA",

issn = "1120-1797",

publisher = "Elsevier",

}

RIS

TY - JOUR

T1 - Feasibility of clinical electron beam formation using polymer materials produced by fused deposition modeling

AU - Miloichikova, Irina

AU - Bulavskaya, Angelina

AU - Cherepennikov, Yury

AU - Gavrikov, Boris

AU - Gargioni, Elisabetta

AU - Belousov, Dmitrij

AU - Stuchebrov, Sergei

PY - 2019/8

Y1 - 2019/8

N2 - The main challenge in electron external beam radiation therapy with clinical accelerators is the absence of integrated systems to form irregular fields. The current approach to provide conformal irradiation is to use additional metallic shaping blocks, with inefficient and expensive workflows. This work presents a simple method to form therapeutic electron fields using 3D printed samples. These samples are manufactured by fused deposition modeling, which can affect crucial properties, such as material homogeneity, due to the presence of residual air-filled cavities. The applicability of this method was therefore investigated with a set of experiments and Monte Carlo simulations aimed at determining the electron depth dose distribution in polymer materials. The results show that therapeutic electron beams with energies 6-20 MeV can be effectively absorbed using these polymeric samples. The model developed in this study provides a way to assess the dose distribution in such materials and to calculate the appropriate thickness of polymer samples for therapeutic electron beam formation. It is shown that for total absorption of 6 MeV electron beams the material thickness should be at least 4 cm, while this value should be at least 8 cm for 12 MeV and 11 cm for 20 MeV, respectively. The results can be used to further develop 3D printing procedures for medical electron beam profile formation, allowing the creation of a collimator or absorber with patient-specific configuration using rapid prototyping systems, thus contributing to improve the accuracy of dose delivery in electron radiotherapy within a short manufacturing time.

AB - The main challenge in electron external beam radiation therapy with clinical accelerators is the absence of integrated systems to form irregular fields. The current approach to provide conformal irradiation is to use additional metallic shaping blocks, with inefficient and expensive workflows. This work presents a simple method to form therapeutic electron fields using 3D printed samples. These samples are manufactured by fused deposition modeling, which can affect crucial properties, such as material homogeneity, due to the presence of residual air-filled cavities. The applicability of this method was therefore investigated with a set of experiments and Monte Carlo simulations aimed at determining the electron depth dose distribution in polymer materials. The results show that therapeutic electron beams with energies 6-20 MeV can be effectively absorbed using these polymeric samples. The model developed in this study provides a way to assess the dose distribution in such materials and to calculate the appropriate thickness of polymer samples for therapeutic electron beam formation. It is shown that for total absorption of 6 MeV electron beams the material thickness should be at least 4 cm, while this value should be at least 8 cm for 12 MeV and 11 cm for 20 MeV, respectively. The results can be used to further develop 3D printing procedures for medical electron beam profile formation, allowing the creation of a collimator or absorber with patient-specific configuration using rapid prototyping systems, thus contributing to improve the accuracy of dose delivery in electron radiotherapy within a short manufacturing time.

U2 - 10.1016/j.ejmp.2019.07.014

DO - 10.1016/j.ejmp.2019.07.014

M3 - SCORING: Journal article

C2 - 31515019

VL - 64

SP - 188

EP - 194

JO - PHYS MEDICA

JF - PHYS MEDICA

SN - 1120-1797

ER -