Authors: A. Yavar, S. Sarmani, K. S. Khoo

Abstract:

The analysis of trace elements in human hair provides crucial insights into an individual's nutritional status and environmental exposure. This research aimed to examine the levels of toxic and essential elements in the scalp hair of school children aged 12-17 from three villages (Anglong Romiot (AR), Svay Romiot (SR), and Kampong Kong (KK)) in Cambodia's Kandal province, a region where residents are especially vulnerable to toxic elements, notably arsenic (As), due to their dietary habits, lifestyle, and environmental conditions. The scalp hair samples were analyzed using the k0-Instrumental Neutron Activation method (k0-INAA), with a six-hour irradiation period in the Malaysian Nuclear Agency (MNA) research reactor followed by High Purity Germanium (HPGe) detector use to identify the gamma peaks of radionuclides. The analysis identified 31 elements in the human hair from the study area, including As, Au, Br, Ca, Ce, Co, Dy, Eu-152m, Hg-197, Hg-203, Ho, Ir, K, La, Lu, Mn, Na, Pa, Pt-195m, Pt-197, Sb, Sc-46, Sc-47, Sm, Sn-117m, W-181, W-187, Yb-169, Yb-175, Zn, and Zn-69m. The accuracy of the method was verified through the analysis of ERM-DB001-human hair as a Certified Reference Material (CRM), with the results demonstrating consistency with the certified values. Given the prevalent arsenic pollution in the research area, the study also examined the relationship between the concentration of As and other elements using Pearson's correlation test. The outcomes offer a comprehensive resource for future investigations into toxic and essential element presence in the region. In the main body of the paper, a more extensive discussion on the implications of arsenic pollution and the correlations observed is provided to enhance understanding and inform future research directions.

Keywords: Human scalp hair, toxic and essential elements, Kandal Province, Cambodia, k0-Instrumental Neutron Activation Method.

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References:

[1] M. Szynkowska, A. Pawlaczyk, E. Wojciechowska, S. Sypniewski, T. Paryjczak. “Human hair as a biomarker in assessing exposure to toxic metals.” Polish Journal of Environmental Studies 18(6), pp. 1151-1161, 2009.
[2] T. Naguchi, T. Itai, M. Kawaguchi, S. Takahashi, S. Tanabe. “Applicability of human hair as a bioindicator for trace elements exposure”. Interdisciolinary studies on environmental chemistry, environmental pollution and ecotoxicology. pp. 73-77, 2012.
[3] H. Sela, Z. Karpas, H. Cohen, A. Tal, Y. Zeiri. “Trace element concentration in hair samples as an indicator of exposure of population in the Negev, Israel”. Biol Trace Elem Res 155, pp. 209-220, 2013.
[4] M. Carneiro, Mc. Moresco, G. Chagas, S. Oliveira, C. Rhoden, F. Barbosa. “Assessment of Trace Elements in Scalp Hair of a Young Urban Population in Brazil”. Biol Trace Elem Res vol. 143, pp. 815-824, 2011.
[5] Y. Ming-Ho. “Environmental toxicology: biological and health effects of pollutants”. CRC Press, Boca Raton, USA (2005).
[6] A. Fido, S. Al-Saad. “Toxic trace elements in the hair of children with autism”. Autism vol. 9, pp. 290-298, 2005.
[7] P. Bhattacharya, G. Jacks, S. Frisbie, E. Smith, R. Naidu, B. Sarkar. “Arsenic in the environment: a global perspective”. In Sarkar B (ed) Handbook of Heavy Metals in the Environment. Dekker, New York, pp. 147–215, 2002.
[8] A. Hamzah, K. Wong, F. Hasan, S. Mustafa, K. Khoo, S. Sarmani. “Determination of total arsenic in soil and arsenic-resistant bacteria from selected ground water in Kandal Province, Cambodia”. J of Radioanal and Nucl Chem vol. 297, pp. 291-296, 2013.
[9] M. Berg, C. Stengel, T. Pham, H. Pham, M. Sampson, M. Leng, S. Samreth, D. Fredericks. “Magnitude of arsenic pollution in the Mekong and Red River Deltas – Cambodia and Vietnam”. Sci Total Environ vol. 372, pp. 413–425, 2007.
[10] K. Phan, S. Sthiannopkao, K. Kim, M. Wong, V. Sao, J. Hashim, M. Yasin, S. Aljunid. “Health risk assessment of inorganic arsenic intake of Cambodia residents through groundwater drinking pathway”. Water Research, vol. 44, pp. 5777-5788, 2010.
[11] H. Rowland, R. Pederick, D. Polya, R. Pancost, B. Dongen, A. Gault, C. Bryant, B. Anderson, J. Charnock, D. Vaughan, J. Lloyd. “Control of organic matter type of microbially mediated release of arsenic from contrasting shallow aquifer sediments from Cambodia”. Geobiology vol. 5, pp. 281–292, 2007.
[12] S. Sthiannopkao, K. Kim, K. Cho, K. Wantala, S. Sotham, C. Sokuntheara, J. Kim. “Arsenic levels in human hair, Kandal Province, Cambodia: The influences of groundwater arsenic, consumption period, age and gender”. Appl Geochemi vol. 25, pp. 81-90, 2010.
[13] F. De Corte, A. Simonits, F. Bellemans, C. Freitas, S. Jovanovic, B. Smodis, G. Erdtmann, H. Petri, A. De Wispelaere. “Recent advances in the k0-standardization of neutron activation analysis: Extensions, applications, prospects”. Journal of Radioanal. Nucl. Chem. vol. 169, pp. 125-158, 1993.
[14] A. Yavar, S. Sarmani, A. Wood, N. Zainal, K. Khoo. “Development and implementation of Høgdahl convention and Westcott formalism for k0-INAA application at Malaysian Nuclear Agency reactor”. J of Radioanal and Nucl Chem vol. 291, pp. 521-527, 2011.
[15] D. Nordstokke, B. Zumbo, S. Cairns, D. Saklofske. “The operating characteristics of the nonparametric Levene test for equal variances with assessment and evaluation data”. Practical Assessment, Research & Evaluation vol. 16, pp. 1-8, 2011.
[16] S. Sarmani. “A study of trace element concentrations in human hair of some local population in Malaysia”. J of Radioanal and Nucl Chem vol. 110, pp. 627-632, 1987.