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.

Issues journals

Medical Radiology and Radiation Safety. 2016. Vol. 61. No. 1. P. 34-40

RADIATION MEDICINE

Yu.V. Semenova1,2, A.B. Karpov1,3, R.M. Takhauov1,3, E.G. Borisova1, D.E. Maximov1,3, A.B. Trivozhenko1, E.V. Kovalchuk1

Structural and Functional Changes of Vascular System in Individuals Exposed to Occupational Irradiation of Low Intensity

1. Seversk Biophysical Research Center of the FMBA of Russia, Seversk, Russia, e-mail: This email address is being protected from spambots. You need JavaScript enabled to view it. ; This email address is being protected from spambots. You need JavaScript enabled to view it. ; 2. Siberian Federal Research and Clinical Center of the FMBA of Russia, Seversk, Russia; 3. Siberian State Medical University, Tomsk, Russia

ABSTRACT

Purpose: To study the condition of vascular system in employees of nuclear industry exposed to long-term occupational irradiation in a range of low doses.

Material and methods: The object of study is the group of employees of the Siberian Chemical Enterprises, exposed to long-term occupational irradiation (n = 93). Among the employees (44-45 years old) a group of individuals, whose duration of occupational activity was not less than 3 years, was formed by means of randomization. For each person the 65 parameters including the social status characteristics, information on main risk factors, biochemical indices, main clinical data and cumulative dose of the external exposure were evaluated. Using the sphygmograph VaSera VS-1500N (Japan) the following parameters of computer sphygmomanometry in the employees were analyzed : pulse and medium arterial pressure, aortic pulse wave velocity (PWV), cardio ankle vascular index (CAVI), anklebrachial pressure index (ABI).

Results: 48 people had hypertension of 1-2 degrees, 47 people had abdominal obesity, 81 people had dyslipidemia of the total number surveyed. Employees exposed to low levels of radiation did not have asymmetric occlusive and stenosing lesions of arterial system of the upper and lower limbs were not detected. The value of PWV and CAVI characterizing real vascular rigidity did not differ statistically and significantly in the compared groups (health individuals: patients with arterial hypertension; individuals with normal weight and individuals with obesity). Only patients with the second degree of arterial hypertension had the tendency of increasing of vascular rigidity. Perhaps this is due to the protective effect of low doses of ionizing radiation on the vascular wall. Methods of computer Sphygmometria complements the protocol of the periodic medical staff examination of radiation-hazardous facilities. If there are conventional risk factors for the progression of hypertension, occupational exposure is not a significant factor in the pathogenesis of the disease.

Conclusion: The analysis of computer sphygmomanometry parameters did not detect the negative influence of the external exposure in the studied dose range on the vascular wall in the individuals exposed to the occupational irradiation (external γ-radiation). Arterial hypertension pathogenesis of the able-bodied men of 44-55 years old was mainly connected with the increase in body size, abdominal obesity, dyslipidemia, elevation of vascular rigidity.

Key words: occupational irradiation, low doses, arterial hypertension, risk factors, vascular rigidity, computer sphygmomanometry

REFERENCES

  1. Semenova Yu.V., Karpov A.B., Litvinenko T.M. et al. Kontrol' faktorov riska serdechno-sosudistykh zabolevanii v real'noi klinicheskoi praktike. Vrach. 2014. No. 3. P. 85-87. (In Russ.).
  2. Conroy R.M., Pyörälä K., Fitzgerald A.P. et al. Estimation of ten-year risk of fatal cardiovascular disease in Europe: the SCORE project. Eur. Heart J. 2003. Vol. 24. P. 987-1003.
  3. 2012 European guidelines on cardiovascular disease prevention in clinical practice. Eur. Heart J., 2012. Vol. 33. P. 1635-1701.
  4. Drubay D., Caër-Lorho S., Laroche P. et al. Mortality from circulatory system diseases among French uranium miners: a nested case-control study. Radiat. 2015. Vol. 183. No. 5. P. 550-562.
  5. Karpov A.B., Semenova Yu.V., Takhauov R.M. et al. The risk of acute myocardial infarction and arterial hypertension in a cohort of male employees of Siberian Group of Chemical Enterprises exposed to long term irradiation. Health Phys. 2012. Vol. 103. No. 1. P. 15-23.
  6. Zablotska L.B., Little M.P., Cornett R.J. Potential increased risk of ischemic heart disease mortality with significant dose fractionation in the Canadian Fluoroscopy Cohort Study. Am. J. Epidemiol. 2014. No. 1. P. 120-131.
  7. Bychkovskaya I.B., Stepanov R.P., Kirik O.V. Nekotorye novye aspekty problemy radiochuvstvitel'nosti maloobnovlyayushchikhsya tkanei. Medical Radiology and Radiation Safety. 2003. Vol. 48. No. 6. P. 5-15. (In Russ.).
  8. Celermayer D.S. Endothelial dysfunction: Does it matter? Is it reversible? Am. Coll. Cardiol. 1998. Vol. 30. P. 325-332.
  9. Milyagin V.A., Milyagina I.V., Abramenkova N.Yu. et al. Neinvazivnye metody issledovaniya magistral'nykh sosudov. Smolensk: Smolenskaya gor. tipografiya. 2012. 223 p. (In Russ.).

For citation: Semenova YuV, Karpov AB, Takhauov RM, Borisova EG, Maximov DE, Trivozhenko AB, Kovalchuk E.V. Structural and Functional Changes of Vascular System in Individuals Exposed to Occupational Irradiation of Low Intensity. Medical Radiology and Radiation Safety. 2016;61(1):34-40. Russian.

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

Medical Radiology and Radiation Safety. 2016. Vol. 61. No. 1. P. 29-33

RADIATION MEDICINE

N.A. Metlyaeva, O.V. Scherbatich

Features of Social Adaptation of Participants of the Accident on the Nuclear Submarines K-19 and K-27 According to Psychophysiological Inspection

A.I. Burnasyan Federal Medical Biophysical Center of FMBA, Moscow, Russia, e-mail: This email address is being protected from spambots. You need JavaScript enabled to view it.

ABSTRACT

Purpose: To evaluate the personal and current mental status of three participants of the accident on the nuclear submarine K19 (F.U.P) and K27 (R.A.S. and F.A.M.) according to psychophysiological examination.

Material and methods: The results are shown of the psychophysiological examination of three participants of the accident on the nuclear submarine K19 in 1961 (04.07.61) and K27 in 1968 (24.05.68), where the operator of a reactor lieutenant F.U.P. at the age of 23 (year of birth: 1938) had the ARS of the first degree of severity (dose on EPR tooth enamel 1.14 ± 0.10 Gy), sergeant R.A.S. at the age of 23 (year of birth: 1945) had the ARS of the third degree of severity (dose on EPR tooth enamel 3.6-4.0 Gy), a dosimetrist F.A.M. at the age of 22 (year of birth: 1946) had the ARS of the second degree of severity (dose on EPR tooth enamel 1.12 ± 0.05 Gy) from the combined gamm-abeta radiation. Three patients underwent clinical and psychophysiological examination in 2002-2014 at the age of 57 and 56. All three patients were diagnosed with psychosomatic pathology hypertension of the second degree, while F.A.M. had a higher indices of hypertension (BP = 150/90, 140/100 and 200/100 mm Hg). R.A.S. had coronary heart disease, stenocardia, FC II-II and F.A.M. had FC II F.U.P. had diabetes mellitus type 2, insulin dependent form, decompensation, F.A.M. had chronic bronchitis, pneumosclerosis.

Results: The rise of the indicators of MMPI profile above 80 T-points on the scale of 1, 2, 6, 8 and F of both neurological and psychological triad, indicates the mental stress adaptation in three participants of the accident. Major general stress factor of psychophysiological adaptation was caused by protracting the acknowledgement of the victims to be the disable people due to the diseases, connected with the direct participation in the action of the special risk subunit (F.A.M. was recognized after 27 years, R.A.C. after 37 years, F.U.P. 38 years after radiation accident). A positive solution on the issue of indexation of the pension to F.A.M. in the court . resulted in a significant positive dynamics of psychological data in a gradual reduction of the indiceses, characterizing the severity of affective rigidity, fear and self-doubt, original thinking (scale: 6, 7, 8 respectively), the level of anxiety (scale: 2, 9, F, 0), with the maintenance of considerable severity of hypochondriac tendencies, the deterioration of which was due to the long judicial process (during 6 years). Labor activity of R.A.S. was the most favorable condition for the realization of his needs, and his adaptation was full, he could become a very useful member of society.

Conclusions: Patient P.A.S. had ARS of more severe degree (ARS III) than F.A.M. and F.U.P. Despite this fact, the setting and the motivation to work has allowed him to live an active lifestyle, to have a lesser degree of reduction of efficiency of the social adaptation and a less pronounced psychosomatic pathology.

Key words: submarines, radiation accidents, acute radiation disease, social adaptation, hypertensive disease, ischemic heart disease

REFERENCES

  1. Gus'kova A.K. Bolezn' i lichnost' bol'nogo. Vrach. 2003. No. 5. P. 57-58. (In Russ.).
  2. Lartsev M.A. Psikhofiziologicheskoe obespechenie professional'nykh kontingentov, uchastvuyushchikh v likvidatsii chrezvychainykh situatsii (metodologiya i organizatsiya). Avtorefer. diss. dokt. med. nauk. Moscow: 1998. 34 p. (In Russ.).
  3. Liberman A.N. Radiatsiya i stress. Sotsial'no-psikhologicheskie posledstviya Chernobyl'skoi avarii. Saint Petersburg: 2002. 160 p. (In Russ.).
  4. Martens V.K., Bobrov A.F., Sorokin A.V. et al. Prognozirovanie professional'noi nadezhnosti operativnogo personala Balakovskoi AES. rekomendatsii. Moscow: 1999. 20 p. (In Russ.).
  5. Preobrazhenskii V.N., Ushakov I.B., Lyadov K.V. Aktivatsionnaya terapiya v sisteme meditsinskoi reabilitatsii lits opasnykh professii. Moscow: Paritet Graf. 2000. 320 p. (In Russ.).
  6. Sushkevich A.G. Stress-indutsirovannye faktory riska nevroticheskikh rasstroistv i ratsional'nye podkhody k povysheniyu indeksa kachestva zhizni u likvidatorov posledstvii avarii na Chernobyl'skoi AES. kand. med. nauk. Moscow: 2006. 135 p. (In Russ.).
  7. Ushakov I.B., Karpov V.N. Mozg i radiatsiya (k 100letiyu radioneirobiologii). Moscow: GNIII aviats. i kosmich. meditsiny. 1997. 75 p. (In Russ.).

For citation: Metlyaeva NA, Scherbatich OV. Features of Social Adaptation of Participants of the Accident on the Nuclear Submarines K-19 and K-27 According to Psychophysiological Inspection. Medical Radiology and Radiation Safety. 2016;61(1):29-33. Russian.

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

Medical Radiology and Radiation Safety. 2016. Vol. 61. No. 1. P. 17-21

RADIATION SAFETY

V.I. Rubtsov, V.N. Klochkov, N.A. Surovtsev, A.Yu. Nefedov, E.V. Klochkova, A.B. Trebukhin, I.O. Chibakov

Improving Radiation Safety of Medical Staff during Diagnostic and Treatment Procedures with the Application of Radionuclides

A.I. Burnasyan Federal Medical Biophysical Center of FMBA, Moscow, Russia. Email: This email address is being protected from spambots. You need JavaScript enabled to view it.

ABSTRACT

Purpose: To give recommendations on improving radiation safety of medical staff during diagnostic and treatment procedures with the Application of radionuclides and ionizing radiation sources.

Material and methods: Literature data on doses of medical exposure of the medical staff and patients at domestic and abroad nuclear medicine centers and their contribution to the total collective dose from manmade radiation sources have been analyzed.

Results: Based on results of analysis of literature data and long experience of internal research, general concepts of assuring radiation safety of medical staff, as well as individual protection when performing diagnostic and treatment procedures with the application of radionuclides and ionizing radiation sources are described.

Conclusion: Basic principles of individual protection for assuring radiation safety of medical staff in nuclear medicine have been developed.

Key words: nuclear medicine, medical exposure doses, external and internal exposure, radionuclides, personal protective equipment

REFERENCES

  1. Kostylev V.A., Narkevich B.Ya. Radiatsionnaya bezopasnost' v meditsine. Uchebnoe posobie. Moscow: Grovant. 2014. 202 p. (In Russ.).
  2. Radiatsionnaya zashchita v meditsine. Publikatsiya 105 MKRZ. In Valentina D. (ed.). Saint Petersburg, NII radiatsionnoi gigieny im. P.V. Ramzaeva. 2011. 66 p. (In Russ.).
  3. Il'in L.A. Radiobiologiya i radiatsionnaya meditsina problemy i perspektivy ikh vzaimodeistviya v ramkakh reglamentatsii ioniziruyushchikh izluchenii. Medical Radiology and Radiation Safety. 1998. Vol. 43. No. 1. P. 8-17. (In Russ.).
  4. Kirillov V.F., Korenkov I.P., Il'in L.A. Radiatsionnaya gigiena. Moscow: GEOTARMedia. 2010, 384 p. (In Russ.).
  5. Belyaev V.N., Klimanov V.A. Fizika yadernoi meditsiny. Chast' 2. Pozitronno-emissionnye skanery. rekonstruktsiya izobrazhenii v pozitronno-emissionnoi tomografii. kombinirovannye sistemy PET/KT i OFEKT/PET. Kinetika radiofarmpreparatov. radionuklidnaya terapiya. vnutrennyaya dozimetriya. radiatsionnaya bezopasnost'. Uchebnoe posobie. Moscow: NIYaU MIFI. 2012. 248 p. (In Russ.).
  6. Onishchenko G.G. Radiatsionnaya obstanovka na territorii Rossiiskoi Federatsii po rezul'tatam radiatsionno-gigienicheskoi pasportizatsii. Gigiena i sanitariya. 2009. No. 3. P. 4-7. (In Russ.).
  7. Narkevich B.Ya., Kostylev V.A. Problemy obespecheniya radiatsionnoi bezopasnosti v sovremennoi radionuklidnoi diagnostike. Med. radiol. i radiats. bezopasnost'. 2009. Vol. 54. No. 2. P. 166-167. (In Russ.).
  8. Sources and effects of ionizing radiation. United Nations Scientific Committee on the Effects of Atomic Radiation. UNSCEAR 2008. Report to the General Assembly with Scientific Annexes. Volume 1. Annex A. Medical Radiation Exposures. United Nations. New York. 2010.
  9. Mettler F.A. et al. Effective Doses in Radiology and Diagnostic Nuclear Medicine: a Catalog. Radiology. 2008. Vol. 248. No. 1. P. 254-263.
  10. O sostoyanii sanitarno-epidemiologicheskogo blagopoluchiya naseleniya v Rossiiskoi Federatsii v 2013 godu: Gosudarstvennyi doklad. Moscow: Federal'naya sluzhba po nadzoru v sfere zashchity prav potrebitelei i blagopoluchiya cheloveka. 2014. 191 p. (In Russ.).
  11. Popova A.Yu. Ob otsenke radiatsionnoi bezopasnosti naseleniya pri meditsinskom obluchenii i effektivnosti sanitarnogo nadzora. Spravka Federal'noi sluzhby po nadzoru v sfere zashchity prav potrebitelei i blagopoluchiya cheloveka ot 19.12.2013 No. 01/145701332. Moscow. 2014. (In Russ.).
  12. Korsunskii V.N., Kodina G.E., Bruskin A.B. Yadernaya meditsina: sostoyanie i perspektivy razvitiya. Atomnaya strategiya. 2007. No. 21. P. 4-6. (In Russ.).
  13. Rubtsov V.I., Klochkov V.N. Individual'naya zashchita personala ot radiatsionnogo vozdeistviya i voprosy dezaktivatsii. V kn.: «Radiatsionnaya meditsina». Vol. 3. Radiatsionnaya gigiena. Moscow: IzdAT. 2002. P. 335-364. (In Russ.).
  14. Rubtsov V.I., Klochkov V.N., Surovtsev N.A. et al. Razrabotka i vnedrenie kompleksa normativno-metodicheskikh i informatsionnykh materialov po sredstvam individual'noi zashchity. Yubileinyi sbornik, posvyashchennyi 50letiyu Golovnogo tsentra gosudarstvennogo sanitarno-epidemiologicheskogo nadzora Federal'nogo upravleniya «Medbioekstrem». Moscow: Federal'noe upravlenie «Medbioekstrem». 2004. P. 156-160. (In Russ.).
  15. Rubtsov V.I., Klochkov V.N., Surovtsev N.A. et al. Organizatsiya sanitarno-gigienicheskikh i lechebno-profilakticheskikh meropriyatii pri radiatsionnykh avariyakh. Moscow: FGU «VTsMK Zashchita» Roszdrava. 2005. 524 p. (In Russ.).
  16. Romanov V.V., Rubtsov V.I., Klochkov V.N. et al. Gosudarstvennyi sanitarno-epidemiologicheskii nadzor za vyborom i ekspluatatsiei sredstv individual'noi zashchity organov dykhaniya na radiatsionno-opasnykh ob"ektakh. Gigiena i sanitariya. 2006. No. 4. P. 78-81. (In Russ.).
  17. Romanov V.V., Rubtsov V.I., Klochkov V.N. et al. Gosudarstvennyi sanitarno-epidemiologicheskii nadzor za vyborom i ekspluatatsiei sredstv individual'noi zashchity kozhnykh pokrovov na ob"ektakh i territoriyakh. obsluzhivaemykh Federal'nym mediko-biologicheskim agentstvom. Meditsina truda i promyshlennaya ekologiya. 2007. No. 8. P. 42-48. (In Russ.).
  18. Gigienicheskie trebovaniya k razmeshcheniyu i ekspluatatsii uskoritelei elektronov s energiei do 100 MeV. SanPiN 2.6.1.257310. (In Russ.).
  19. Gigienicheskie trebovaniya k ustroistvu i ekspluatatsii rentgenovskikh kabinetov. apparatov i provedeniyu rentgenologicheskikh issledovanii. SanPiN 2.6.1.119203. (In Russ.).
  20. Trebovaniya radiatsionnoi bezopasnosti pri proizvodstve, ekspluatatsii i vyvode iz ekspluatatsii (utilizatsii) meditsinskoi tekhniki, soderzhashchei istochniki ioniziruyushchego izlucheniya. SanPiN 2.6.1.289111. (In Russ.).
  21. Gigienicheskie trebovaniya po obespecheniyu radiatsionnoi bezopasnosti pri provedenii radionuklidnoi diagnostiki s pomoshch'yu radiofarmpreparatov. MU 2.6.1.189204. (In Russ.).
  22. Obespechenie radiatsionnoi bezopasnosti pri provedenii radionuklidnoi diagnostiki metodami radioimmunnogo analiza in vitro. MU 2.6.1.230808. (In Russ.).
  23. Gigienicheskie trebovaniya po obespecheniyu radiatsionnoi bezopasnosti pri provedenii luchevoi terapii s pomoshch'yu otkrytykh radionuklidnykh istochnikov. SanPiN 2.6.1.236808. (In Russ.).
  24. Tekhnicheskii reglament Tamozhennogo soyuza o bezopasnosti sredstv individual'noi zashchity TR TS 019/2011. (In Russ.).

For citation: Rubtsov VI, Klochkov VN, Surovtsev NA, Nefedov AYu, Klochkova EV, Trebukhin AB, Chibakov IO. Improving Radiation Safety of Medical Staff during Diagnostic and Treatment Procedures with the Application of Radionuclides. Medical Radiology and Radiation Safety. 2016;61(1):17-21. Russian.

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

Medical Radiology and Radiation Safety. 2016. Vol. 61. No. 1. P. 22-28

RADIATION SAFETY

A.L. Polyudin

Forms of Technogenic Uranium in the Soil of the Shore of the Lake Cinara, Kaslinsky District, Chelyabinsk Region

E.I. Zababakhin Russia Research Institute of Technical Physics, Snezhinsk, Russia, e-mail: This email address is being protected from spambots. You need JavaScript enabled to view it.

ABSTRACT

Purpose: To study the modes of occurrence, accumulation, distribution of uranium in the soil of the area of influence of Russian Federal Nuclear Center, to study the features, determining the peculiarities of the soil as the main storage medium.

Material and methods: Soil profiles were laid according to the elementary geochemical landscapes. In the samples consecutively selective recovery of physical and chemical forms of uranium and the subsequent analysis by spectrophotometry with the usage of tributyl phosphate and arsenazo III were carried out. Also soil acidity, redox potential, particle size distribution, soil density, the density of the solid phase of the soil were determined and filtration coefficient in the soil was calculated as well.

Results: Actual acidity is in the range from 5.5 to 7.4. Redox is in the range from 273 to 348 mV. The indicator shows the intensity of the processes (rH2), and characterizes the soil as an environment, periodically reducing atmosphere. Under these conditions uranium, has a strong migratory ability. And the elements that affect the ability of soils to capture the element (iron and manganese) are in transitional oxidation. The soils that were studied have an easy size distribution and bad detained pollutants, the predominant fraction of the soils is a fine sand (0.25-0.05 mm). Filtration coefficient can be assessed as a high one for the soil of the eluvial and transeluvial position and extremely high for the soil of the superaqual position. The uranium content was 20 mg/kg in the soil of the transeluvial position, its characterizing anthropogenic component in the soils of the transeluvial position came to 93 %. Uranium was concentrated mainly in the soils of the transeluvial position and tied to water-soluble carbonates and clay minerals. In the soils of the eluvial and superaqual position uranium is in a stable and minimal migration of the acid (tied to sesquioxide), and also in the remaining forms. Potentially movable mold of the total content of uranium is in the range of 25 to 89 %. The maximum content is observed at the depth of 20-25 cm in the form predominantly connected to the sesquioxide and mineral components of the soil. Potentially mobile forms in the structure of the extraction criterion is the content of the peak at the depth of 8-12 cm, owning to the forms of uranium tied to the water-soluble carbonates and clay minerals.

Key words: long-lived radionuclides, uranium, forms of occurrence, soil Emissions

REFERENCES

  1. Polyudin A.L., Faizrakhmanov F.F. Issledovanie kontsentratsii radionuklidov v vozdushnoi srede opytnykh polei pri gazodinamicheskikh issledovaniyakh. V sb.: «Promyshlennaya bezopasnost' i ekologiya». Sarov. 2010. P. 3-8. Razreshenie 2115. (In Russ.).
  2. SanPiN 2.6.1.07-03. Gigienicheskie trebovaniya k proektirovaniyu predpriyatii i ustanovok atomnoi promyshlennosti. Moscow: Atomizdat. 2003. 32 p. (In Russ.).
  3. Bezuglaya E.Yu. Meteorologicheskii potentsial i klimaticheskie osobennosti zagryazneniya vozdukha gorodov. Leningrad: Gidrometeoizdat. 1980. 183 p. (In Russ.).
  4. Malashenko A.V. Rak legkogo u shakhterov uranovykh rudnikov osadochnogo mestorozhdeniya // Med. radiol. i radiats. bezopasnost'. 2007. Vol. 50, no. 6. P. 10-12. (In Russ.).
  5. Evseeva L.S. Geokhimiya urana v zone gipergeneza. Moscow: Gos. publ. literatury v oblasti nauki i tekhniki. 1962. 239 p. (In Russ.).
  6. Andreeva O.S., Bad'in V.N., Kornilov A.N. Prirodnyi i obogashchennyi uran. Radiatsionno-gigienicheskie aspekty. Moscow: Atomizdat. 1979. 216 p. (In Russ.).
  7. Vinogradov A.P. Osnovnye cherty geokhimii urana. Moscow: AN SSSR. 1963. 352 p. (In Russ.).
  8. Mamontov V.G., Panov N.P., Kaurichev I.S. Obshchee pochvovedenie. Moscow: KolosS. 2006. 456 p. (In Russ.).
  9. Kozachenko V.P. Obosnovanie priemov ratsional'nogo ispol'zovaniya. obrabotki i melioratsii zemel' sel'skokhozyaistvennogo naznacheniya Chelyabinskoi oblasti. Chelyabinsk: ChelGU. 1999. 134 p. (In Russ.).
  10. Protasov N.A. Geokhimiya prirodnykh landshaftov. Voronezh. Poligraf. tsentr Voronezhskogo gos. un-ta. 2008. 36 p. (In Russ.).
  11. Dospekhov B.A. Metodika polevogo opyta. Moscow: Agropromizdat. 1985. 351 p. (In Russ.).
  12. Vadyunina A.F., Korchagina V.A. Metody opredeleniya fizicheskikh svoistv i gruntov. Moscow: Vysshaya shkola. 1961. 345 p. (In Russ.).
  13. Sinyavskii V.A. Fizicheskie, fiziko-khimicheskie i khimicheskie metody analiza v ekologii pochv. Chelyabinsk: ChelGU. 2004. 36 p. (In Russ.).
  14. Istochniki, effekty i opasnost' ioniziruyushchei radiatsii. Doklad nauchnogo komiteta OON po deistviyu atomnoi radiatsii General'noi assamblee za 1988 g. NKDAR OON. Moscow: Mir. 1993. 728 p. (In Russ.).
  15. Uralbekov B.M., Satybaldiev B.S., Nazarkulova Sh.N. Uran i radii v mineral'nykh sostavlyayushchikh pochv mestorozhdeniya Kurdai. V sb.: «Materialy mezhdunarodnoi konferentsii po analiticheskoi khimii i ekologii». Almaty: KazNU. 2010. P. 86-93. (In Russ.).
  16. Tessier A. Sequential extraction procedure for the speciation of particulate trace metals // Analit. Chem. 1979. Vol. 51. P. 844-851.
  17. Marei N.A., Zykova A.S. Metodicheskie rekomendatsii po sanitarnomu kontrolyu za soderzhaniem radioaktivnykh veshchestv v ob"ektakh vneshnei sredy. Moscow: Vtoraya tipografiya. 1980. 336 p. (In Russ.).
  18. Aleksakhin R.M., Arkhipov N.P., Barkhudarov R.M. Tyazhelye estestvennye radionuklidy v biosfere: migratsiya i biologicheskoe deistvie na populyatsii i biotsenozy. Moscow: Nauka. 1990. 368 p. (In Russ.).
  19. Kovalevskii A.L. O fiziologicheskikh bar'erakh pogloshcheniya u rastenii po otnosheniyu k bol'shim kontsentratsiyam urana v pitatel'noi srede. V sb.: «Teoreticheskie i prakticheskoe deistvie malykh doz ioniziruyushchei radiatsii». 1973. P. 92-94. (In Russ.).

For citation: Polyudin AL. Forms of Technogenic Uranium in the Soil of the Shore of the Lake Cinara, Kaslinsky District, Chelyabinsk Region. Medical Radiology and Radiation Safety. 2016;61(1):22-8. Russian.

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

Medical Radiology and Radiation Safety. 2016. Vol. 61. No. 1. P. 11-16

RADIATION BIOLOGY

V.Yu. Soloviev, A.E. Baranov

The Model Post-Radiation Kinetics of Cell Populations in Bone Marrow Syndrome

A.I. Burnasyan Federal Medical Biophysical Center of FMBA, Moscow, Russia, e-mail: This email address is being protected from spambots. You need JavaScript enabled to view it.

ABSTRACT

Purpose: Development of a mathematical model of recovery number of stem cell after acute total body irradiation.

Material and methods: The object of study is the data from a database of human acute radiation syndrome of A.I. Burnasyan Federal Medical Biophysical Center of FMBA on the post-radiation dynamics of the concentration of granulocytes in the peripheral blood of the victims of the Chernobyl accident in 1986.

Results: A model with mathematical description for the evaluation of post-radiation dynamics of stem cell pool and formed elements (granulocytes) in human peripheral blood is proposed. It is shown that the hypothetical idea of the trigger mechanism of the inclusion of several different modes of post-radiation recovery of stem cells pool and the existence of so-called critical level of the prohibition on differentiation does not contradict to the observed pattern of clinical data. A hypothesis is proposed about the possibility of external interference in the biological program of natural post-radiation recovery. It can lead to a less pronounced acute period of bone marrow syndrome in a dose range of 3-5 Gy. It may cause some reduction in agranulocytosis duration (at 2-4 days).

Conclusion: If the fundamental theoretical constructions are correct, we hope to find out some targeted therapies that can to some extent block the access to the differentiation of hematopoietic stem cells in a certain way and change the course of the clinical picture of bone marrow syndrome and, consequently, reduce some risk of death with severe and extremely severe bone marrow syndrome.

Key words: bone marrow syndrome, cell populations, granulocytes, model, gamma irradiation, dose

REFERENCES

  1. Solov'ev V.Yu., Baranov A.E. Otsenka kriticheskogo urovnya «zapreta na differentsirovku» chislennosti stvolovykh krovetvornykh kletok cheloveka. 1989. Vol. 29. P. 835-838. (In Russ.).
  2. Wichmann N.E., Loeffer M., Schmith S.A. Conception of haemopoietic regulation and its biomathematical realization. In: Blood Cells. SpringerVerlag. New York. 1988. P. 411-429.
  3. Lajtha L.G. On the concept of the cell cycle. J. Cell Comp. Physiol. 1963. Vol. 62. No. 1. P. 143-145.
  4. Lajtha L.G. Cytokinetics and regulation of progenitors cell. J. Cell Comp. Physiol. 1966. Vol. 67. No. 1. P. 133-148.
  5. Lajtha L.G., Pozzi L.V., Schofield R., Fox M. Kinetic Properties of Haemopoietic Stem Cells. Cell Tiss. Kinet. 1969. No. 2. P. 39-49.
  6. Lajtha L.G. Stem Cell Concepts. Differentiation. 1979. Vol. 14. P. 23-34.
  7. Terskikh V.V. Periody pokoya v normal'nykh i malignizirovannykh kletochnykh sistemakh. V sb.: «Kletochnyi tsikl. Problemy regulyatsii». In Epifanovoi O.E. (ed.). Moscow: Nauka. 1973. P. 165-189. (In Russ.).
  8. Konoplyannikov A.G. Radiobiologiya stvolovykh kletok. Moscow: Energoatomizdat. 1984. 120 p. (In Russ.).
  9. Gruzdev G.P. Problema porazheniya krovetvornoi tkani pri ostroi luchevoi patologii. Moscow: Meditsina. 1968. 139 p. (In Russ.).
  10. Gozenbuk V.L., Keirim-Markus I.B., Savinskii A.K., Chernov E.N. Dozovaya nagruzka na cheloveka v polyakh gamma-neitronnogo izlucheniya. Moscow: Atomizdat. 1978. 166 p. (In Russ.).
  11. Gozenbuk V.L., Keirim-Markus I.B. Dozimetricheskie kriterii tyazhesti ostrogo oblucheniya cheloveka. Moscow: Energoatomizdat. 1988. 183 p.
  12. Chervenick P.A., Boggs D.R. Patterns of proliferation and differentiation of hematopoetic stem cells after compartment depletion. Blood. 1971. Vol. 37. No. 5. P. 568-580.
  13. Boggs S.S., Chervenick P.A., Boggs D.R. The effect of postirradiation bleeding or endotoxin on proliferation and differentiation of haematopoietic stem cells. Blood. 1972. Vol. 40. P. 375-379.
  14. Boggs S.S., Boggs D.R. Relationship of stem cell poll size to onset differentiation. Radiat. Res. 1974. Vol. 59. P. 50-56.
  15. Baranov A.E., Konchalovski M.V., Soloviev W.Ju., Guskova A.K. Use of blood cell count changes after radiation exposure in dose assessment and evaluation of bone marrow function. In: The Medical Basis for Radiation Accident Preparedness II. Clinical Experience and Followup since. In Ricks R.C., Fry S.A. (Eds.). 1979. P. 427-443.
  16. Gruzdev G.P., Ivanova T.A., Gordeeva A.A., Shcherbova E.N. O funktsional'noi mozaichnosti kostnogo mozga («pul'siruyushchii klon»). gematol. 1980. No. 5. P. 36-39. (In Russ.).
  17. Solov'ev V.Yu., Baranov A.E., Konchalovskii M.V., Chistopol'skii A.S. Prognozirovanie postradiatsionnoi dinamiki kontsentratsii neitrofilov v perifericheskoi krovi cheloveka pri neravnomernom obluchenii. Medical Radiology and Radiation Safety. 1997. Vol. 42. No. 3. P. 17-23. (In Russ.).
  18. Solov'ev V.Yu., Baranov A.E., Khamidulin T.M. Baza dannykh po ostrym luchevym porazheniyam cheloveka. Soobshchenie 2. Prognozirovanie postradiatsionnoi dinamiki kontsentratsii neitrofilov perifericheskoi krovi cheloveka pri neravnomernom po telu avariinom obluchenii. Medical Radiology and Radiation Safety. 2011. Vol. 56. No. 4. P. 24-31. (In Russ.).
  19. Semenkova I.V. Radiochuvstvitel'nost' mezenkhimal'nykh stvolovykh kletok i poluchaemykh iz nikh dlya tselei kletochnoi terapii kletok-predshestvennikov kardiomiotsitov. Obninsk. Avtoref. diss. kand. bilog. nauk. 2008. 16 p. (In Russ.).
  20. Kilmen S.A. Rukovodstvo po radiatsionnoi gematologii. Moscow: Meditsina. 1974. P. 77-85. (In Russ.).
  21. Pyatkin E.K., Baranov A.E. Biologicheskaya indikatsiya dozy s pomoshch'yu aberratsii khromosom i kolichestva kletok v perifericheskoi krovi. Itogi nauki i tekhniki VINITI AN SSSR. Ser. «Radiatsionnaya biologiya». 1980. Vol. 3. P. 103-179. (In Russ.).
  22. Konchalovskii M.V., Baranov A.E., Solov'ev V.Yu. Dozovye krivye neitrofilov i limfotsitov pri obshchem otnositel'no ravnomernom gamma-obluchenii cheloveka (po materialam avarii na ChAES). Medical Radiology and Radiation Safety. 1991. Vol. 36. No. 1. P. 29-33. (In Russ.).
  23. Solov'ev V.Yu., Baranov A.E., Khamidulin T.M., Zinov'eva N.V. Baza dannykh po ostrym luchevym porazheniyam cheloveka. Soobshchenie 3. Osobennosti prognozirovaniya postradiatsionnoi dinamiki kontsentratsii neitrofilov v perifericheskoi krovi pri kostnomozgovom sindrome, otyagoshchennom luchevymi ozhogami, a takzhe pri neravnomernom obluchenii.Medical Radiology and Radiation Safety. 2013. Vol. 58. No. 6. P. 30-35. (In Russ.).

For citation: Soloviev VYu, Baranov AE. The Model Post-Radiation Kinetics of Cell Populations in Bone Marrow Syndrome. Medical Radiology and Radiation Safety. 2016;61(1):11-6. Russian.

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

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