Hostname: page-component-78c5997874-fbnjt Total loading time: 0 Render date: 2024-11-09T22:55:42.818Z Has data issue: false hasContentIssue false
  • English
  • Français

Radioactivity concentrations and dose assessments of therapeutic peloids from some Turkish spas

Published online by Cambridge University Press:  02 January 2018

Muazzez Çelik Karakaya ,
Mahmut Doğru ,
Necati Karakaya ,
Hasibe Cingilli Vural ,
Fatih Kuluöztürk  and
Sultan Şahin Bal
Muazzez Çelik Karakaya*
Affiliation:
Selçuk University Engineering Faculty Geology Engineering, Konya, 42079, Turkey
Mahmut Doğru
Affiliation:
Bitlis Eren University Science Faculty Physic Department, Bitlis, 1300, Turkey
Necati Karakaya
Affiliation:
Selçuk University Engineering Faculty Geology Engineering, Konya, 42079, Turkey
Hasibe Cingilli Vural
Affiliation:
Selçuk University Science Faculty Biology Department, Konya, 42079, Turkey
Fatih Kuluöztürk
Affiliation:
Bitlis Eren University Science Faculty Physic Department, Bitlis, 1300, Turkey
Sultan Şahin Bal
Affiliation:
Bitlis Eren University Science Faculty Physic Department, Bitlis, 1300, Turkey
*
*E-mail: [email protected]
Get access Rights & Permissions [Opens in a new window]

Abstract

The activity concentrations of natural radionuclides in peloids were studied to assess the radiologic hazard from 18 Turkish spas. The peloids are mainly used for therapeutic treatments, rheumatic diseases and aesthetic purposes. The concentrations of the natural radionuclides 226Ra, 232Th, 40K and 137Cs were determined with a gamma ray spectrometer using a HPGe detector. The average activity concentrations of 226Ra, 232Th, 40K, and 137Cs in the peloids studied were 110.69, 71.52, 576.48 and 0.447 Bq/kg, respectively. The radium equivalent activities in the peloid samples ranged from 63.3 to 766.77 Bq/kg. The absorbed dose rate (Dout) varied between 37.52 and 330.67 nGy/h and most of the observed spa doses are greater than the worldwide recommended values. The annual effective dose values range from 0.26 to 2.78 μSv/y. The annual gonadal dose equivalents of the samples vary from 224.07 to 2283.55 with a mean of 821.99 μSv/y.

Keywords

dosepeloidsradionuclidesspaTurkey
Type
Research Article
Information
Clay Minerals , Volume 50 , Issue 2 , June 2015 , pp. 221 - 232
Copyright
Copyright © The Mineralogical Society of Great Britain and Ireland 2015

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Ahmad, N., Matiullah, A.J. & Khatibeh, A.H. (1997) Indoor radon levels and natural radioactivity in Jordanian soils. Radiation Protection Dosimetry, 71, 231233.Google Scholar
Akinci, A. & Artir, R. (2008) Characterization of trace elements and radionuclides and their risk assessment in red mud. Materials Characterization, 59, 417421.CrossRefGoogle Scholar
Aközcan, S., Yilmaz, M. & Külahci, F. (2014) Dose rates and seasonal variations of 238U, 232Th, 226Ra, 40K and 137Cs radionuclides in soils along Thrace, Turkey. Journal of Radioanalytical and Nuclear Chemistry. 299, 95101.Google Scholar
Alaamer, A.S. (2008) Assessment of human exposures to natural sources of radiation in soil of Riyadh, Saudi Arabia. Turkish Journal Engineering Environmental Science, 32, 229234.Google Scholar
Appleton, J.D. (2005) Radon in air and water. Pp. 227–262 in: Essentials of Medical Geology: Impacts of the Natural Environment on Public Health (O. Selinus, editor). Elsevier, Amsterdam.Google Scholar
Beretka, J. & Matthew, P.J. (1985) Natural radioactivity of Australian building materials, industrial wastes and by-products. Health Physics, 48, 8795.Google Scholar
Bikit, I., Slivka, J., Čonkić, L.J., Krmar, M., Vesković, M., Žikić-Todorović, N., Varga, E., Curčić, S. & Mrdja, D.N. (2005) Radioactivity of the soil in Vojvodina (northern province of Serbia and Montenegro). Journal of Environmental Radioactivity, 78, 1119.Google Scholar
Bozkurt, A., Yorulmaz, N., Kam, E., Karahan, G. & Osmanlioğlu, A.E. (2007) Assessment of environmental radioactivity for S– anliurfa region of southeastern Turkey. Radiation Measurements, 42, 13871391.Google Scholar
Brai, M., Basile, S., Bellia, S., Hauser, S., Puccio, P., Rizzo, S., Bartolotta, A. & Licciardello, A. (2002) Environmental radioactivity at Stromboli (Aeolian Islands). Applied Radiation and Isotopes, 57, 99107.Google Scholar
Değerlier, M., Karahan, G. & Özger, G. (2008) Radioactivity concentration and dose assessment for soil samples around Adana, Turkey. Journal of Environmental Radioactivity, 99, 10181025.Google Scholar
Doretti, I., Ferrara, D., Barison, G., Gerbasi, R. & Battiston, G. (1992) Natural radionuclides in the muds and water used in thermal therapy in Abano Terme, Italy. Radiation Protection Dosimetry, 45, 175178.Google Scholar
El-Arabi, A.M. (2005) Natural radioactivity in sand used in thermal therapy at the Red Sea Coast. Journal of Environmental Radioactivity, 81, 1119.Google Scholar
Erees, F.S., Aközcan, S., Parlak, Y. & Çam, S. (2006) Assessment of dose rates around Manisa (Turkey). Radiation Measurements, 41, 598601.Google Scholar
Gold, B., Sukenik, S. & Gavra, Z. (1990) Radioactivity and chemical composition of the therapeutic mud and hot spring baths in the Moriah Spa, Dead Sea, Israel. Pp. 625–630 in: Frontiers in Radiation Biology (E. Riklis, editor). Balaban Publishers, Rehovot, Israel.Google Scholar
Gündoğdu, M.N. (1982) Neojen yas–li Bigadiç sedimanter baseninin jeolojik, mineralojik ve jeokimyasal incelenmesi. Ph.D. thesis, Hacettepe University, Ankara, Turkey. Pp. 6971, 386 pp.Google Scholar
Gündoğdu, M.N., Yalçin, H., Temel, A. & Clauer, N. (1996) Geological, mineralogical and geochemical characteristics of zeolite deposits associated with borates in the Bigadiç Emet and Kirka Neogene lacustrine basins, western Turkey. Mineralium Deposita, 31, 492513.Google Scholar
ICRP (International Commission on Radiological Protection) (1993) Quantities and Units in Radiation Protection Dosimetry. ICPR Report 51.Google Scholar
ICRP (International Commission on Radiological Protection) (2007) Recommendations of the International Commission on Radiological Protection. ICRP Publication 103.Google Scholar
Kam, E. & Bozkurt, A. (2007) Environmental radioactivity measurements in the Kastamonu region of northern Turkey. Applied Radiation and Isotopes, 65, 440444.Google Scholar
Karahan, G.A. & Bayülken, A. (2000) Assessment of gamma dose rates around Istanbul (Turkey). Journal of Environmental Radioactivity, 47, 213221.Google Scholar
Karakaya, M.Ç., Karakaya, N., Sariğolan, S. & Koral, M. (2010) Some properties of thermal muds of some spas in Turkey. Applied Clay Science, 48, 531537.CrossRefGoogle Scholar
Karakaya, M.Ç., Karakaya, N., Aydin, M.E., Vural, C.H. & Nalbantçilar, M.T. (2013) Investigation of properties of thermal muds and waters using for therapeutic purposes. TÜBİTAK Project Number 110Y033. Pp 187–214, 238 pp.Google Scholar
Karakelle, B.Ö. ztürk, N., Köse, A., Varinlioğlu, A., Erkol, A.Y. & Yilmaz, F. (2002) Natural radioactivity in soil samples of Kocaeli Basin, Turkey. Journal of Radioanalytical and Nuclear Chemistry, 254, 649651.Google Scholar
Khan, H.M., Ismail, M., Khan, K. & Akhter, P. (2010) Measurement of radionuclides and gamma-ray dose rate in soil and transfer of radionuclides from soil to vegetation, vegetable of some northern area of Pakistan using gamma-ray spectrometry. Water, Air, & Soil Pollution, 219, 129.Google Scholar
Khan, H.M., Ismail, M., Khan, K. & Akhter, P. (2011) Radioactivity levels and gamma-ray dose rate in soil samples from Kohistan (Pakistan) using gamma-ray spectrometry. Chinese Physics Letters, 28, DOI: 1088/0256–307X/28/1/019301–4.Google Scholar
Khan, K., Khalid, M.R., Jabbar, A. & Akhter, P. (2012) Appraisal of radioactivity and associated radiation hazards in sand samples of four rivers of Punjab province, Pakistan. Isotopes in Environmental and Health Studies, 48, 286294.Google Scholar
Kikouama, O.J.R. & Baldé, L. (2010) From edible clay to a clay-containing formulation for optimization of oral delivery of some trace elements: A review. International Journal of Food Sciences and Nutrition, 61, 803822.Google Scholar
Kiliç, O., Belivermis–, M., Topçuoğlu, S., Çotuk, Y., Cos–kun, M., Çayir, A. & Küçer, R. (2007) Radioactivity concentrations and dose assessment in surface soil samples from east and south of Marmara Region, Turkey. Radiation Protection Dosimetry, 128, 324330.Google Scholar
Krieger, R. (1981) Radioactivity of construction materials. Concrete Plant + Precast Technology, Betonwerk Fertigteil Technik, 47, 468473.Google Scholar
Kurnaz, A., Küçükömeroğlu, B., Keser, R., Okumus–oğlu, N.T., Korkmaz, F., Karahan, G. & Çevik, U. (2007) Determination of radioactivity levels and hazards of soil and sediment samples in Firtina Valley (Rize, Turkey). Applied Radiation and Isotopes, 65, 12811289.CrossRefGoogle ScholarPubMed
Legido, J., Medina, C., Mourelle, M., Carretero, M. & Pozo, M. (2007) Comparative study of the cooling rates of bentonite, sepiolite and common clays for their use in pelotherapy. Applied Clay Science, 36, 148160.Google Scholar
Manic, G., Petrovic, S.,Vesna, M., Popovic, D. & Todorovic, D. (2006) Radon concentrations in a spa in Serbia. Environment International, 32, 533537.Google Scholar
Merdanoğlu, B. & Altinsoy, N. (2006) Radioactivity concentrations and dose assessment for soil samples from Kestanbol granite area, Turkey. Radiation Protection Dosimetry, 121, 399405.Google Scholar
Örgün, Y., Altinsony, N., Gultekin, A.H., Karahan, G. & Çelebi, N. (2005) Natural radioactivity levels in granitic plutons and ground waters in southeast part of Eskis–ehir, Turkey. Applied Radiation and Isotopes, 63, 267275.Google Scholar
Papadopoulos, A., Tzamos, E., Giouri, K., Filippidis, A. & Stoulos, S. (2014) Natural radioactivity and trace element composition of natural clays used as cosmetic products in the Greek market. Clay Minerals, 49, 5362.Google Scholar
Quintela, A., Terroso, D., Ferreira Da Silva, E. & Rocha, F. (2012) Certification and quality criteria of peloids used for therapeutic purposes. Clay Minerals, 47, 441451.Google Scholar
Ramli, A.T., Wahab, M.A., Hussein, A. & Wood, K. (2005) Environmental 238U and 232Th concentration measurements in an area of high level natural background radiation at Palong, Johor, Malaysia. Journal of Environmental Radioactivity, 80, 287304.Google Scholar
Saad, H.R., & Al-Azmi, D. (2002) Radioactivity concentrations in sediments and their correlation to the coastal structure in Kuwait. Applied Radiation and Isotopes, 56, 991997.CrossRefGoogle Scholar
Saleh, I.H., Hafez, A.F., Elanany, N.H., Motaweh, H.A. & Naim, M.A. (2007) Radiological study on soils, foodstuff and fertilizers in the Alexandria region. Egypt. The Turkish Journal of Engineering and Environmental Sciences, 31, 917.Google Scholar
Selvasekarapandian, S., Sivakumar, R., Manikandan, N.M., Meenakshisundaram, V., Raghunath, V.M. & Gajendran, V. (2000) Natural radionuclide distribution in soils of Gudlaore, India. Applied Radiation and Isotopes, 52, 299306.Google Scholar
Silva, P.S.C., Soliveira, M.B.O., Farias, L., Fávaro, D.I.T. & Mazzilli, B.P. (2011) Chemical and radiological characterization of clay minerals used in pharmaceutics and cosmetics. Applied Clay Science, 52, 145149.Google Scholar
Somlai, J., Jobbágy, V., Kovács, J., Tarján, S. & Kovács, T. (2008) Radiological aspects of the usability of red mud as building material additive. Journal of Hazardous Materials, 150, 541545.Google Scholar
Tas–kin , H.M., Karavus–, P., Ay, A., Topuzoğlu, S., Hidiroğlu, S. & Karahan, G. (2009) Radionuclide concentrations in soil and lifetime cancer risk due to the gamma radioactivity in Kirklareli, Turkey. Journal of Environmental Radioactivity, 100, 4953.Google Scholar
Tzortzis, M., Svoukis, E. & Tsertos, H. (2004) A comprehensive study of natural gamma radioactivity levels and associated dose rates from surface soils in Cyprus. Radiation Protection Dosimetry, 109, 217224.Google Scholar
UNSCEAR (1993) Sources and Effects of Ionizing Radiation. United Nations, New York.Google Scholar
UNSCEAR (2000) Sources, effects and risks of ionization radiation. Report to The General Assembly, with Scientific Annexes B: Exposures from Natural Radiation Sources. United Nations, New York.Google Scholar
UNSCEAR (2008) Sources and Effects of Ionizing Radiation, Annex B: Exposures of the public and workers from various sources of radiation. United Nations Scientific Committee on the Effects of Atomic Radiation, New York.Google Scholar
Viseras, C., Aguzzi, C., Cerezo, P. & Lopez-Galindo, A. (2007) Uses of clay minerals in semisolid health care and therapeutic products. Applied Clay Science, 36, 3750.Google Scholar
Whitney, D.L. & Evans, B.W. (2010) Abbreviations for names of rock-forming Minerals. American Mineralogist, 95, 185187.Google Scholar
Yousef, M.I., Abu El-Ela, A. & Yousef, H.A. (2007) Natural radioactivity levels in surface soil of Kitchener Drain in the Nile Delta of Egypt. Journal of Nuclear and Radiation Physics, 2, 6168.Google Scholar
Yüce, G. & Gasparon, M. (2013) Preliminary risk assessment of radon in groundwater: a case study from Eskisehir, Turkey. Isotopes in Environmental and Health Studies, 49, 163179.Google Scholar
Yüce, G., Uğurluoğlu, D., Dilaver, A.T., Eser, T., Sayin, M., Dönmez, M., Özçelik, S. & Aydin, F. (2009) The effects of lithology on water pollution: Natural radioactivity and trace elements in water resources of Eskisehir Region (Turkey). Journal of Water, Air and Soil Pollution, 202, 6989.Google Scholar