In Situ Observations of Blistering of a Metal Irradiated with 2-MeV Protons

Badrutdinov, A. O.; Bykov, Timophey; Gromilov, S. A.; Higashi, Y.; Kasatov, D. A.; Kolesnikov, Iaroslav; Koshkarev, Alexey; Makarov, A. N.; Miyazawa, Tatsuo; Shchudlo, Ivan; Sokolova, Evgeniia; Sugawara, Hirotaka; Taskaev, S. Yu.

doi:10.3390/met7120558

Cited by 23 publications

(6 citation statements)

References 16 publications

(19 reference statements)

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“…Their Alphabeam system includes customizable neutron sources from a fixed beam with beam-shaping assembly, and ceiling-mount robotic couch for patient positioning. It is based on developments from the Russian Budker Institute [ 46 , 47 ] into a state-of-the-art ABNS named Alphabeam. This system consists of a negative ion source, pre-accelerator, tandem accelerator, high-energy beam lines and neutron production targets as part of the neutron beam system.…”

Section: Current Limitations and Future Directionsmentioning

confidence: 99%

A Review of Boron Neutron Capture Therapy: Its History and Current Challenges

Jin

Seldon

Butkus

et al. 2022

International Journal of Particle Therapy

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Mechanism of Action External beam, whether with photons or particles, remains as the most common type of radiation therapy. The main drawback is that radiation deposits dose in healthy tissue before reaching its target. Boron neutron capture therapy (BNCT) is based on the nuclear capture and fission reactions that occur when 10B is irradiated with low-energy (0.0025 eV) thermal neutrons. The resulting 10B(n,α)7Li capture reaction produces high linear energy transfer (LET) α particles, helium nuclei (4He), and recoiling lithium-7 (7Li) atoms. The short range (5-9 μm) of the α particles limits the destructive effects within the boron-containing cells. In theory, BNCT can selectively destroy malignant cells while sparing adjacent normal tissue at the cellular levels by delivering a single fraction of radiation with high LET particles. History BNCT has been around for many decades. Early studies were promising for patients with malignant brain tumors, recurrent tumors of the head and neck, and cutaneous melanomas; however, there were certain limitations to its widespread adoption and use. Current Limitations and Prospects Recently, BNCT re-emerged owing to several developments: (1) small footprint accelerator-based neutron sources; (2) high specificity third-generation boron carriers based on monoclonal antibodies, nanoparticles, among others; and (3) treatment planning software and patient positioning devices that optimize treatment delivery and consistency.

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Section: Current Limitations and Future Directionsmentioning

confidence: 99%

A Review of Boron Neutron Capture Therapy: Its History and Current Challenges

Jin

Seldon

Butkus

et al. 2022

International Journal of Particle Therapy

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“…"Unfortunately, while the 7 Li(p,n) 7 Be reaction is excellent neutronically, the mechanical, chemical, and thermal properties of lithium metal make it a poor candidate for a target", as previously was written in [17] (p. 23). Fortunately, all technical problems have been solved [18][19][20][21] and a lithium target has been developed that provides long-term stable neutron generation with relatively simple and safe maintenance.…”

Section: Lithium Targetmentioning

confidence: 99%

“…The neutron source with specialized targets makes it possible to generate monochromatic γ-quanta [21] and resonance γ-quanta for the development of operational methods of explosives and drugs detection [46], α-particles for investigating promising neutron-less fusion 11 B(p,α)αα reaction [47], and positrons through 19 F(p,αe + e − ) 16 O reaction [48].…”

Section: Other Applicationsmentioning

confidence: 99%

Neutron Source Based on Vacuum Insulated Tandem Accelerator and Lithium Target

Taskaev

Berendeev

Bikchurina

et al. 2021

Biology

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A compact accelerator-based neutron source has been proposed and created at the Budker Institute of Nuclear Physics in Novosibirsk, Russia. An original design tandem accelerator is used to provide a proton beam. The proton beam energy can be varied within a range of 0.6–2.3 MeV, keeping a high-energy stability of 0.1%. The beam current can also be varied in a wide range (from 0.3 mA to 10 mA) with high current stability (0.4%). In the device, neutron flux is generated as a result of the 7Li(p,n)7Be threshold reaction. A beam-shaping assembly is applied to convert this flux into a beam of epithermal neutrons with characteristics suitable for BNCT. A lot of scientific research has been carried out at the facility, including the study of blistering and its effect on the neutron yield. The BNCT technique is being tested in in vitro and in vivo studies, and the methods of dosimetry are being developed. It is planned to certify the neutron source next year and conduct clinical trials on it. The neutron source served as a prototype for a facility created for a clinic in Xiamen (China).

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“…Установлено, что пирометр Optris CT Laser 3ML SF занижает температуру из-за большой области измерения -19 mm и отсутствия технической возможности установить коэффициент эмиссии меньше 0.1, характерного для поверхности полированной меди. Инфракрасная камера FLIR T650SC, наоборот, завышает показания температуры из-за нетеплового свечения, обусловленного люминисценцией меди под действием высокоэнергетичных протонов, которое в работе про изучение блистеринга [10] было охарактеризовано как изменение коэффициента черноты поверхности меди под действием пучка протонов. Также программное обеспечение камеры не позволяет оцифровывать результаты измерений температуры без вмешательства встроенного алгоритма автокалибровки.…”

Section: результаты измерений и обсуждениеunclassified

Исследование влияния пространственного заряда на транспортировку 2 MeV пучка протонов в ускорительном источнике эпитепловых нейтронов

Быков¹,

Касатов²,

Колесников³

et al. 2021

Журнал Технической Физики

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A neutron source comprised of a vacuum insulated tandem accelerator and a solid lithium target is in operation for development of boron neutron capture therapy and other applications. The size of the proton beam on the target surface depending on the proton beam current was measured using an infrared camera and thermocouples inserted inside the target. The absence of a noticeable influence of the space charge on the transportation of the proton beam from the accelerator to the target at a distance of 5 m has been established, which simplifies the operation of the neutron source.

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In Situ Observations of Blistering of a Metal Irradiated with 2-MeV Protons

Cited by 23 publications

References 16 publications

A Review of Boron Neutron Capture Therapy: Its History and Current Challenges

A Review of Boron Neutron Capture Therapy: Its History and Current Challenges

Neutron Source Based on Vacuum Insulated Tandem Accelerator and Lithium Target

Исследование влияния пространственного заряда на транспортировку 2 MeV пучка протонов в ускорительном источнике эпитепловых нейтронов

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