SCIENTIFIC AND INFORMATION-ANALYTICAL MAGAZINE

ISSN 1024-6177 (Print), ISSN 2618-9615 (Online)

JOURNAL DESCRIPTION

The Medical Radiology and Radiation Safety journal ISSN 1024-6177 was founded in January 1956 (before December 30, 1993 it was entitled Medical Radiology, ISSN 0025-8334). In 2018, the journal received Online ISSN: 2618-9615 and was registered as an electronic online publication in Roskomnadzor on March 29, 2018. It publishes original research articles which cover questions of radiobiology, radiation medicine, radiation safety, radiation therapy, nuclear medicine and scientific reviews. In general the journal has more than 30 headings and it is of interest for specialists working in thefields of medicine¸ radiation biology, epidemiology, medical physics and technology. Since July 01, 2008 the journal has been published by State Research Center - Burnasyan Federal Medical Biophysical Center of Federal Medical Biological Agency. The founder from 1956 to the present time is the Ministry of Health of the Russian Federation, and from 2008 to the present time is the Federal Medical Biological Agency.

Members of the editorial board are scientists specializing in the field of radiation biology and medicine, radiation protection, radiation epidemiology, radiation oncology, radiation diagnostics and therapy, nuclear medicine and medical physics. The editorial board consists of academicians (members of the Russian Academy of Science (RAS)), the full member of Academy of Medical Sciences of the Republic of Armenia, corresponding members of the RAS, Doctors of Medicine, professor, candidates and doctors of biological, physical mathematics and engineering sciences. The editorial board is constantly replenished by experts who work in the CIS and foreign countries.

Six issues of the journal are published per year, the volume is 13.5 conventional printed sheets, 88 printer’s sheets, 1.000 copies. The journal has an identical full-text electronic version, which, simultaneously with the printed version and color drawings, is posted on the sites of the Scientific Electronic Library (SEL) and the journal's website. The journal is distributed through the Rospechat Agency under the contract № 7407 of June 16, 2006, through individual buyers and commercial structures. The publication of articles is free.

The journal is included in the List of Russian Reviewed Scientific Journals of the Higher Attestation Commission. Since 2008 the journal has been available on the Internet and indexed in the RISC database which is placed on Web of Science. Since February 2nd, 2018, the journal "Medical Radiology and Radiation Safety" has been indexed in the SCOPUS abstract and citation database.

Brief electronic versions of the Journal have been publicly available since 2005 on the website of the Medical Radiology and Radiation Safety Journal: http://www.medradiol.ru. Since 2011, all issues of the journal as a whole are publicly available, and since 2016 - full-text versions of scientific articles. Since 2005, subscribers can purchase full versions of other articles of any issue only through the National Electronic Library. The editor of the Medical Radiology and Radiation Safety Journal in accordance with the National Electronic Library agreement has been providing the Library with all its production since 2005 until now.

The main working language of the journal is Russian, an additional language is English, which is used to write titles of articles, information about authors, annotations, key words, a list of literature.

Since 2017 the journal Medical Radiology and Radiation Safety has switched to digital identification of publications, assigning to each article the identifier of the digital object (DOI), which greatly accelerated the search for the location of the article on the Internet. In future it is planned to publish the English-language version of the journal Medical Radiology and Radiation Safety for its development. In order to obtain information about the publication activity of the journal in March 2015, a counter of readers' references to the materials posted on the site from 2005 to the present which is placed on the journal's website. During 2015 - 2016 years on average there were no more than 100-170 handlings per day. Publication of a number of articles, as well as electronic versions of profile monographs and collections in the public domain, dramatically increased the number of handlings to the journal's website to 500 - 800 per day, and the total number of visits to the site at the end of 2017 was more than 230.000.

The two-year impact factor of RISC, according to data for 2017, was 0.439, taking into account citation from all sources - 0.570, and the five-year impact factor of RISC - 0.352.

Medical Radiology and Radiation Safety. 2017. Vol. 62. No. 3. P. 33-41

DOI: 10.12737/article_5927f40e8f1b58.14975996

Photoneutrons for Radiation Therapy

Yu.A. Kurachenko1, Yu.G. Zabaryansky2, E.A. Onischuk3

1. Obninsk Institute for Nuclear Power Engineering, NRNU «MEPhI», Obninsk, Russia, e-mail: This email address is being protected from spambots. You need JavaScript enabled to view it. ; 2. A.I. Leypunsky Institute for Physics and Power Engineering, Obninsk, Russia; 3. National Research Nuclear University «MEPhI», Moscow

Yu.A. Kurachenko - INPE Chief Researcher, Dr. Sc. Phys.-Math. Prof.; Yu.G. Zabaryansky - IPPE Postgraduate Student; H.A. Onischuk - MRRC Junior Researcher, MEPhI Postgraduate Student

Abstract

Purpose: Show the possibility of neutron therapy with the photoneutron beam produced by the high-power electron accelerator target, when ensuring the required dose in the tumor in a reasonable exposure time and with minimum exposure of normal tissues.

Material and methods: Generation of neutrons from the target of electron accelerator takes place in two stages: eγn, and in the selected electron energy range of 20-100 MeV, the bremsstrahlung yield in many times (~3 orders of magnitude) more than “useful” neutron yield. This raises the problem of the selective control “harmful” for photon radiotherapy at the minimum attenuation of the neutron flux in the extracted beam. In order to solve the general problem of the formation of a neutron beam with necessary spectral characteristics and of sufficient intensity a number of computational tasks of the selection optimal configuration of the output beam unit and its composition was resolved. Particular attention is paid to minimizing additional irradiation of the patient from the bremsstrahlung (generated by electrons) and secondary gamma radiation (generated by neutrons) from the accelerator target as well as from materials of the output unit.

Results: The resulting configuration of the output unit provides the required beam quality in relation to the tasks of the neutron capture therapy (NCT), which is the only competitive technology of neutron therapy on the background of the massive invasion of proton therapy and other high-selective techniques that discriminately damage the target with minimal irradiation surrounding tissues and organs. For the accessible accelerator (average current 4 mA and electron energy 35 MeV) the flux density of epithermal photoneutrons (they required for NCT) in the beam at the output is an order of magnitude or higher than typical ones for existing and planned reactor beams.

Conclusion: The proposed scheme of generation and extraction of photoneutrons for NCT has a number of obvious advantages over traditional techniques:

  1. a) the use of electron accelerators for neutron production is much safer and cheaper than the use of conventional reactor beams;
  2. b) the accelerator with the target, the beam output unit with the necessary equipment and tooling can be placed on the territory of the clinic without any problems;
  3. c) the proposed target - liquid gallium, which also serves as a coolant, is an environmentally friendly material: its activation is very low and rapidly (in ~ 4 days) falls to the background level.

Key words: electron accelerator, tungsten-gallium target, bremsstrahlung, photoneutrons, neutron capture therapy, optimization of beam characteristics

REFERENCES

  1. Kurachenko Yu.A., Voznesensky N.K., Goverdovsky A.A., Rachkov V.I. Novyi intensivnyi istochnik nejtronov dlya medicinskih prilozhenij [New intensive neutron source for medical application]. Medicinskaya fizika. 2012. No. 2(38). P. 29-38. (in Russian).
  2. Kurachenko Yu.A. Fotonejtrony dlya nejtronozahvatnoj terapii [Photoneutrons for neutron capture therapy]. Izvestiya vuzov. Yadernaya energetika. 2014. No. 4. P. 41-51. (in Russian).
  3. Zamenhof R.G., Murray B.W., Brownell G.L. et al. Boron neutron capture therapy for the treatment of cerebral gliomas. 1: Theoretical Evaluation of the Efficacy of Various Neutron Beams. Med. Phys. 1975. Vol. 2. P. 47-60.
  4. Blue T.E., Yanch J.C. Accelerator-based epithermal neutron sources for boron neutron capture therapy of brain tumors. J. Neurooncol. 2003. Vol. 62. P. 19-31.
  5. Zhou Y., Gao Z., Li Y., Guo C., Liu X. Design and construction of the in-hospital neutron irradiator-1(HNI). In Proc. 12th ICNCT - Advances in Neutron Capture Therapy. 2006. October 9-13. Takamatsu. Japan. Eds. Nakagawa Y., Kobayashi T., Fukuda H. 2006. P. 557-560.
  6. Nigg D.W. Neutron sources and applications in radiotherapy - A brief history and current trends. In: Advances in Neutron Capture Therapy 2006. Proc. 12th Cong Neutron Capture Therapy. Oct 9-13. Eds. Nakagawa Y., Kobayashi T., Fukuda H. Takamatsu. Japan. 2006. P. 623-626.
  7. Kurachenko Yu.A. Optimizatciya bloka vyvoda reaktornogo puchka dlya luchevoj therapii [The reactor beam’s removal block optimization for radiation therapy]. Izvestiya vuzov. Yadernaya energetika. 2008. No. 1. P. 129-138. (in Russian).
  8. Tanaka H., Sakurai Y., Suzuki M. et al. Experimental verification of beam characteristics for cyclotron-based epithermal neutron source (C-BENS). Appl. Radiat. Isot. 2011. Vol. 69. P. 1642-1645.
  9. The Basics of Boron Neutron Capture Therapy. http://web.mit.edu/nrl/www/bnct/facilities/facilities.html.
  10. MIT BNCT Facilities. Fission Converter Beam (FCB). http://web.mit.edu/nrl/www/bnct/facilities/MIT BNCT Facilities.htm.
  11. Reattore TAPIRO: ENEA Internal Document, DISP/TAP/85-1, 1985. In: Design of neutron beams for boron neutron capture therapy in a fast reactor. Current status of neutron capture therapy. IAEA-TECDOC-1223, 2001.
  12. Rosi G. et al. Role of the TAPIRO fast research reactor in neutron capture therapy in Italy. Calculations and measurements. IAEA-CN-100/97. In: Research Reactor Utilization, Safety, Decommissioning, Fuel and Waste Management Proc. Internat. Conf. 10-14 November 2003 Santiago, Chile. P. 325-338.
  13. Carta M., Palomba M. TRIGA RC-1 and TAPIRO ENEA Research Reactors. https://www.iaea.org/OurWork/ST/NE/NEFW/Technical-Areas/RRS/documents/ TM_Innovation/Carta_ENEA.pdf.
  14. General information and technical data of TAPIRO research reactor. http://www.enea.it/en/research-development/documents/nuclear-fission/tapiro-eng-pdf.
  15. Nuclear Research Reactor: TAPIRO. http://old.enea.it/com/ingl/ New_ingl/research/energy/nucleare_fission/pdf/TAPIRO-ENG.pdf.
  16. Kurachenko Yu.A., Kazanskij Yu.A., Levchenko A.B., Matusevich E.S. Vyvod nejtronnyh puchkov i zaschita meditcinskogo reaktora MARS [Neutron beam’s removing and protection for the medical MARS reactor]. Izvestiya vuzov. Yadernaya energetika. 2006. No. 4. P. 36-48. (in Russian).
  17. Kurachenko Yu.A., Moiseenko D.N. MARS i TAPIRO: reaktory maloj moschnosti dlya nejtrono-zahvatnoj terapii [MARS & TAPIRO: small-capacity reactors for neutron capture therapy]. Izvestiya vuzov. Yadernaya energetika. 2010. No. 1. P. 153-163. (in Russian).
  18. Kurachenko Yu.A., Kazanskij Yu.A., Matusevich E.S. Kriterii kachestva nejtronnyh puchkov dlya luchevoj terapii [Neutron beams’ quality criteria for radiation therapy]. Izvestiya vuzov. Yadernaya energetika. 2008. No. 1. P. 139-149. (in Russian).
  19. Kurachenko Yu.A. Reaktornye puchki dlya luchevoj terapii: kriterii kachestva i raschyotnye tekhnologii [Reactor beams for the radiation therapy: quality criteria and computation technologies]. Medicinskaya fizika. 2008. No. 2 (38). P. 20-28. (in Russian).
  20. Kurachenko Yu.A. Reaktornye puchki dlya luchevoj terapii. Raschyotnye modeli i vychislitel’nye tekhnologii [Reactor beams for radiation therapy. Calculation models and computation technologies]. - Saarbrücken, Deutschland: Palmarium Academic Publishing, OmniScriptum GmbH&Co. RG, (ISBN: 978-3-8473-9842-4) 2013. 372 p. (in Russian).
  21. Burn K.W. et al. Final design and construction issues of the TAPIRO epithermal column, Report at ICNCT-XII, Oct. 9-13, 2006. http://icnct-12.umin.jp/beams for boron neutron capture therapy in a fast reactor/Current status of neutron capture therapy. IAEA-TECDOC-1223, 2001.
  22. Liu Hungyuan B., Brugger R.M., Rorer D.C. Upgrades of the epithermal neutron beam at the Brookhaven Medical Research Reactor BNL-63411. http://www.iaea.org/inis/collection/NCLCollectionStore/Public/28/014/28014354.pdf
  23. Riley K.J., Binns P.J., Harling O.K. Performance characteristics of the MIT fission converter based epithermal neutron beam. Phys. Med. Biol. 2003. Vol. 48. P. 943-958,
  24. Harling O.K., Riley K.J., Newton T.H. et al. The new fission converter based epithermal neutron irradiation facility at MIT. Nuclear Reactor Laboratory. MIT. http://www.iaea.org/inis/collection/NCLCollectionStore/Public/36/026/36026570.pdf.
  25. MCNP - A General Monte Carlo N-Particle Transport Code. Version 5. Vol. I: Overview and Theory. Authors: X-5 Monte Carlo Team. LA-UR-03-1987. April 24. 2003.
  26. Pelowitz D.B. MCNPX user’s manual. Version 2.4.0 - LA-CP-07-1473.
  27. STAR-CD®. CD-adapco Engineering Simulation Software - CAE and CFD Software.

For citation: Kurachenko YuA, Zabaryansky YuG, Onischuk EA. Photoneutrons for Radiation Therapy. Medical Radiology and Radiation Safety. 2017;62(3):33-41. Russian. DOI: 10.12737/article_5927f40e8f1b58.14975996

PDF (RUS) Full-text article (in Russian)

Contact Information

 

46, Zhivopisnaya st., 123098, Moscow, Russia Phone: +7 (499) 190-95-51. E-mail: This email address is being protected from spambots. You need JavaScript enabled to view it.

Journal location

Attendance

2927928
Today
Yesterday
This week
Last week
This month
Last month
For all time
554
2390
5165
33458
26223
113593
2927928
Forecast today
4632

Your IP:216.73.216.82
Visitor Counter

© Журнал "Медицинская радиология и радиационная безопасность" 2020г.

Яндекс.Метрика

Наверх