Effective atomic number and photon buildup factor of bismuth doped tissue for photon and particles beam interaction

IF 0.7 Q4 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING Polish Journal of Medical Physics and Engineering Pub Date : 2022-03-01 DOI:10.2478/pjmpe-2022-0005
Krishnamurthy Srinivasan, E. Samuel
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引用次数: 1

Abstract

Abstract Introduction: The doping of high Z nanoparticles into the tumor tissue increases the therapeutic efficiency of radiotherapy called nanoparticle enhanced radiotherapy (NERT). In the present study, we are identifying the effective types of radiation and effective doping concentration of bismuth radiosensitizer for NERT application by analyzing effective atomic number (Zeff) and photon buildup factor (PBF) of bismuth (Bi) doped soft tissue for the photon, electron, proton, alpha particle, and carbon ion interactions. Material and methods: The direct method was used for the calculation of Zeff for photon and electron beams (10 keV-30 MeV). The phy-X/ZeXTRa software was utilized for the particle beams such as proton, alpha particle, and carbon ions (1-15 MeV). Bismuth doping concentrations of 5, 10, 15, 20, 25 and 30 mg/g were considered. The PBF was calculated over 15 keV-15 MeV energies using phy-X/PSD software. Results: The low energy photon (<100 keV) interaction with a higher concentration of Bi dopped tissue gives the higher values of Zeff. The Zeff increased with the doping concentration of bismuth for all types of radiation. The Zeff was dependent on the type of radiation, the energy of radiation, and the concentration of Bi doping. The particle beams such as electron, proton, alpha particle, and carbon ion interaction gives the less values of Zeff has compared to photon beam interaction. On the other hand, the photon buildup factor values were decreased while increasing the Bi doping concentration. Conclusions: According to Zeff and PBF, the low energy photon and higher concentration of radiosensitizer are the most effective for nanoparticle enhanced radiotherapy application. Based on the calculated values of Zeff, the particle beams such as electron, proton, alpha particle, and carbon ions were less effective for NERT application. The presented values of Zeff and PBF are useful for the radiation dosimetry in NERT.
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掺铋组织中光子与粒子束相互作用的有效原子序数和光子积累因子
摘要简介:将高Z纳米粒子掺杂到肿瘤组织中,提高了放疗的治疗效率,称为纳米粒子增强放疗(NERT)。在本研究中,我们通过分析铋(Bi)掺杂软组织中光子、电子、质子、α粒子和碳离子相互作用的有效原子序数(Zeff)和光子积累因子(PBF),确定了NERT应用中铋(Bi)辐射敏化剂的有效辐射类型和有效掺杂浓度。材料和方法:采用直接法计算光子和电子束(10kv - 30mev)的Zeff。采用phy-X/ZeXTRa软件对质子、α粒子、碳离子(1- 15mev)等粒子束进行了分析。铋掺杂浓度分别为5、10、15、20、25和30 mg/g。利用phy-X/PSD软件计算了15k - 15mev能量下的PBF。结果:低能量光子(<100 keV)与较高浓度Bi掺杂组织的相互作用使Zeff值较高。对于所有类型的辐射,Zeff随铋掺杂浓度的增加而增加。Zeff与辐射类型、辐射能量和铋掺杂浓度有关。与光子束相互作用相比,电子、质子、α粒子和碳离子等粒子束相互作用的Zeff值更小。另一方面,随着铋掺杂浓度的增加,光子积累因子值降低。结论:根据Zeff和PBF,低能量光子和较高浓度的放射增敏剂是纳米粒子增强放疗应用最有效的方法。根据Zeff的计算值,电子、质子、α粒子和碳离子等粒子束对NERT的应用效果较差。给出的Zeff和PBF值可用于NERT的辐射剂量测定。
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来源期刊
Polish Journal of Medical Physics and Engineering
Polish Journal of Medical Physics and Engineering RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING-
CiteScore
1.30
自引率
0.00%
发文量
19
期刊介绍: Polish Journal of Medical Physics and Engineering (PJMPE) (Online ISSN: 1898-0309; Print ISSN: 1425-4689) is an official publication of the Polish Society of Medical Physics. It is a peer-reviewed, open access scientific journal with no publication fees. The issues are published quarterly online. The Journal publishes original contribution in medical physics and biomedical engineering.
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