Well Drinking Water Fluoride Content and Dental Fluorosis in Al-Butana Region of Central Sudan

© 2011 by the Author(s). This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution -Noncommercial 4.0 International License (CC-by the license) ( https://creativecommons.org/licenses/by-nc/4.0/ )

Download PDF

Cite

XML

Abstract

In this study the F– ion concentration levels of 209 well water samples belonging to previous construction analysis (CA) and a total of 121 well water samples belonging to the current study (CS) in Al-Butana region of Central Sudan were investigated and located (mapped) using the geographical information system (GIS). The GISmap indicates that the majority of F– levels ranging between 0.5 and 1.5 mg/l dominates the northern part of the study area and the levels below 0.5 mg/l dominates the southern part of the study area whereas the levels above 1.5 mg/l are limited and are scattered, randomly, throughout the study area.

The results obtained revealed considerable spatial variations in the occurrence of fluoride even within the same community area, F– levels ranging between 0.0 and 6 mg/l were found in boreholes drilled in Rufaa’ Town. The majority of the investigated boreholes viz., 39.71% and 42.98% were found having F– levels below 0.5 mg/l whereas only 0.96% and 3.3% were found beyond the level of 2.5 mg/l, for the CA and CS, respectively. The wide range of F– levels (from 0 to 7 mg/l in the CA and from 0 to 2.6 mg/l in the CS) revealed the variability in the spatial distribution of F– in the study area. 94.26% and 88.43% of the groundwater samples were found below the maximum recommended level of 1.5 mg/l set for F– in drinking water by each of SSMO (2002) whereas only 5.75% and 11.58% were found in excess of this level, for the CA and CS, respectively. The decrease in the mean value of F– in the investigated boreholes from 1.4 mg/l in the CA analysis to 0.6 mg/l in the CS analysis, indicates that F– levels in the investigated boreholes has the tendency to decrease during pumping. Mottled teeth are widely observed among residents in the study area in spite of fluoride compliancy to SSMO standards. Therefore, dental fluorosis, in the study area, is not unlikely to occur.

Keywords

Groundwater fluoride distribution

dental fluorosis

Al-Butana region

Sudan

Conflict of interest

The authors declare they have no competing interests.

References

Abdel-Magid, H.M. (1997). Assessment of drinking water quality in the Al-Gassim Region of Saudi Arabia. Environment International, 23(2): 247–251.

Al-Redhaiman and H.M. Abdel-Magid (2002). The applicability of the local and international water quality guidelines to Al-Gassim Region of Central Saudi Arabia. Water, Air and Soil Pollution, 137: 235–246.

APHA (American Public Health Association) (1998). Standard Methods for the Examination of Water and Wastewater, 20th edition. New York, USA.

Ayyas, A.K., Helen, W. and O. Denis (2004). Determining the optimal concentration of fluoride in drinking water in Pakistan. Community Dentistry and Oral Epidemiology, 32(3): 166–172.

Banzal, R. and S.C. Tiwari (2006). Back pain in chronic renal failure. Nephrology Dialysis Transplantation, 21: 2331–2332.

Birkeland, J.M., Ibrahim, Y.E., Ghandour, I.A. and O. Haugejordan (2005). Severity of dental caries among 12-year-old Sudanese children with different fluoride exposure. Clinical Oral Investigations, 9(1): 46–51.

CDPH (California Department of Public Health) (2010). Fluoridation by Public Water Systems California Water Fluoridation Standards. Details available at http://www.cdph.ca.gov/certlic/drinkingwater/pages/fluoridation.aspx, last accessed on 2 November 2010.

Dasarathy, S. (1996). Gastro-duodenal manifestations in patients with skeletal fluorosis. Journal of Gastroenterology, 31: 333–337.

Dinesh, C. (1998). Fluoride and human health-cause for concern. Ind. J. Environ., 19(2): 81–89.

EEC (Economic European Community) (1992). Standards. In: Hach Water Analysis Handbook, 2nd edn.

Ekstrand, J., Fejerskov, O. and L.M. Silverstone (1988). Fluoride in Dentistry. ISBN 87-16-09962-1.

Fadle, H.A. (2004). Assessment of Fluoride Concentration in Drinking Water in Gedaref Town and its Uptake by Some Vegetables Plants. M.Sc thesis, Institute of Environmental Studies, University of Khartoum.

Fawell, J., Bailey, K., Chilton, J., Dahi, E., Fewtrell, L. and Y. Magara (2006). Fluoride in drinking water (WHO), Handbook. ISBN: 1900222965.

GCCS (Gulf Corporation Council Standards) (1993). Unbottled Drinking Water Standards, Standardization and Metrology Organization for the Gulf Corporation Council Countries #GS 149/193, Riadh, Saudi Arabia.

Guo, Z. (2001). Study on neurobehavioral function of workers occupationally exposed to fluoride. Industrial Health and Occupational Disease, 27: 346–348.

Helmut, K. and T.H. Redda (1999). Distribution of fluoride and fluorosis in Ethiopia and prospects for control. Tropical Medicine & International Health, 4(5): 355–364.

Linda, G.W. (2001). Bleaching techniques in restorative dentistry. First edn. Martin Dunitz Ltd. The Livery House 7-9 Pratt Street, London NWI OAE; p. 26–27, 193.

Luke, J. (1997). The Effect of Fluoride on the Physiology. PhD Thesis. University of Surrey, Guildford.

Marier, J. and D. Rose (1977). Environmental Fluoride. National Research Council of Canada. Associate Committee on Scientific Criteria for Environmental Quality. NRCC No. 16081.

Meenakshi and Maheshwari (2006). Fluoride in drinking water and its removal. Journal of Hazardous Materials, 1(137): 456–463.

NRC (National Research Council) (2006a). Fluoride in Drinking Water: A Scientific Review EPA’s Standards. National Academic Press, Washington D.C. 221–222.

NRC (National Research Council) (2006b). Fluoride in Drinking Water: A Scientific Review EPA’s Standards. National Academic Press, Washington D.C. 197.

SASO (Saudi Arabian Standards Organization) (1984). Bottled and Unbottled Drinking Water, SSA 409/1984, 2nd edn, 1996-03-13, ISSN: 1319-2302: 1–8.

Shommo, E.I. (2007). The applicability of the local, regional and international water quality guidelines in the Southern Suburb of Omdurman City. M.Sc. Thesis, UNESCO chair in Water Resources, Omdurman Islamic University, Sudan.

SSMO (Sudanese Standards and Metrology Organization) (2002). Unbottled drinking water standard No. 044-First edition, March 2002.

Susheela, A.K. (1993). Prevalence of endemic fluorosis with gastrointestinal manifestations in people living in some North-India villages. Fluoride, 26: 97–104.

Susheela, A.K. and M. Bhatnagar (2002). Reversal of fluoride included cell injury through elimination of fluoride and consumption of diet rich in essential nutrients and antioxidants. Molecular and Cellular Biochemistry, 234–235: 335–340.

USEPA (US Environmental Protection Agency) (1976). National Interim Primary Drinking Water Regulations, Publication EPA/S 709-76-003. Government Printing Office, Washington, D.C.

WHO (World Health Organization) (1984a). Fluorine and Fluorides. Environmental Health Criteria No. 36, Geneva.

WHO (World Health Organization) (1984b). Guidelines for Drinking Water Quality, vol. 2. Health Criteria and Other Supporting Information, Geneva.

WHO (2008). Guidelines for Drinking-water Quality, Third edition. Incorporating the first and second addenda, Volume 1, Recommendations, Geneva, 2008.

Xiangquan, L., Xinwei, H., Zhichao, Z. and L. Lingxial (2010). Geochemical provenance and spatial distribution of fluoride in groundwater of Taiyuan basin, China. Environmental Earth Sciences. DOL: 10.1007/s12665-010-0648-6.

Yasir, I.A. (2004). Domestic Water Supply in Al-Butana and Umelghura Provinces. Quantitative and Qualitative Analysis, M.Sc. Thesis. University of Gezira, Sudan.

Previous article in this issue

Next article in this issue

Asian Journal of Water, Environment and Pollution, Electronic ISSN: 1875-8568 Print ISSN: 0972-9860, Published by AccScience Publishing