Zawartość azotanów(III) i azotanów(V) w wodzie kranowej na terenie Górnego Śląska oraz ich potencjalny wpływ na zdrowie konsumentów

Pecyna-Utylska, Paulina; Kernert, Joanna; Michalski, Rajmund

Artykuł - szczegóły

Tytuł artykułu

Zawartość azotanów(III) i azotanów(V) w wodzie kranowej na terenie Górnego Śląska oraz ich potencjalny wpływ na zdrowie konsumentów

Autorzy

Pecyna-Utylska Paulina , Kernert Joanna , Michalski Rajmund

Identyfikatory

Warianty tytułu

The content and potential health risk caused by nitrates and nitrites in tap water in Upper Silesia, Poland

Języki publikacji

Abstrakty

Azotany(III) i azotany(V) są typowymi zanieczyszczeniami wody pitnej, które mają negatywny wpływ na zdrowie ludzi. W pracy oceniono poziom azotanów(III) i azotanów(V) w 29 wodach kranowych i jednej studni wiejskiej na terenie Górnego Śląska. Uzyskane wyniki posłużyły do oceny ryzyka zdrowotnego dla miejscowej ludności. Punkty poboru próbek zostały wybrane tak, aby pomóc w identyfikacji źródła w przypadku wystąpienia podwyższonego poziomu azotanów(III) lub azotanów(V). Dawka azotanów pobranych w wyniku spożycia wody pitnej była wyższa dla dzieci i niemowląt niż dla dorosłych. Iloraz zagrożenia dla kobiet, mężczyzn, dzieci i niemowląt był mniejszy od 1.

Nitrates and nitrites are typical and important contaminants of drinking water that negatively affect people’s health. The paper evaluates the levels of nitrates and nitrites in 29 tap waters and one village well in Upper Silesia. The results were used for health risk assessment for the local communities. The sampling points were chosen so that to help identify the source when an elevated level of nitrites and nitrates is observed. The calculated Chronic Daily Intake values were higher for children and infants than for adults. The Hazard Quotient values for women, men, children and infants were below 1.

Słowa kluczowe

ocena ryzyka zdrowotnego azotany azotyny Górny Śląsk woda kranowa

health risk assessment nitrates nitrites Upper Silesia tap water

Wydawca

ELAMED Media Group

Czasopismo

Laboratorium - Przegląd Ogólnopolski

Rocznik

2022

Tom

nr 3

Strony

24--32

Opis fizyczny

Bibliogr. 41 poz., rys., tab., wykr.

Twórcy

autor

Pecyna-Utylska Paulina

Instytut Podstaw Inżynierii Środowiska PAN, Zabrze

autor

Kernert Joanna

Instytut Podstaw Inżynierii Środowiska PAN, Zabrze

autor

Michalski Rajmund

Instytut Podstaw Inżynierii Środowiska PAN, Zabrze

Bibliografia

1. Li P. et al: Sources and Consequences of Groundwater Contamination. "Arch Environ Contam Toxicol", 2015, 80, 1-10.
2. Li P., He X., Guo W.: Spatial groundwater quality and potential health risks due to nitrate ingestion through drinking water. A case study in Yan'an City on the Loess Plateau of northwest China. "Hum Ecol Risk Assess", 2019, 25(1-2), 11-31.
3. Wu J., Zhang Y., Zhou H.: Groundwater chemistry and groundwater quality index incorporating health risk weighting in Dingbian County, Ordos basin of northwest China. "Geochemistry", 2020, 80 (4), 125607.
4. Wu J. et al.: Comprehensive understanding of groundwater quality for domestic and agricultural purposes in terms of health risks in a coal mine area of the Ordos basin, north of the Chinese Loess Plateau. "Environ. Earth Sci", 2019, 78 (15), 1-10.
5. European Commission: Council Directive No 91/676/EEC of 12 December 1991 concerning the protection of waters against pollution caused by nitrates from agricultural sources. [In:] "Official Journal of the European Union", L375, pp. 1-8.
6. IARC Working Group on the Evaluation of Carcinogenic Risk to Humans: Ingested nitrate and nitrite, and cyanobacterial peptide toxins. IARC Monographs 94, International Agency for Research on Cancer, Lyon, France 2010.
7. Gardolinski P.C. et al: Comparison of sample storage protocols for the determination of nutrients in natural waters. "Water Res " 2001, 35 (15), 3670-3678.
8. Bryan N.S., van Grinsven H.: The Role of Nitrate in Human Health. "Adv Agron", 2013 119153-182.
9. Brender J.D. et al.: Prenatal Nitrate Intake from Drinking Water and Selected Birth Defects in Offspring of Participants in the National Birth Defects Prevention Study. "Environ Health Perspect", 2013, 121 (9), 1083-1089.
10. Temme E.H.M. et al: Average daily nitrate and nitrite intake in the Belgian population older than 15 years. "Food Addit Contam Part A Chem Anal Control Expo Risk Assess" 2011, 28(9) 1193-1204.
11. Ward M.H. et al: Drinking Water Nitrate and Human Health: An Updated Review. "Int J Environ Res Public Health", 2018, 15 (7), 1-31.
12. World Health Organization: Guidelines for drinking-water quality 4th ed. World Health Organization, Geneva 2017.
13. Regulation of the Minister of Health of December 7, 2017 regarding the quality of water intended for human consumption.
14. Czekaj J. et al Identification of nitrate sources in groundwater and potential impact on drinking water reservoir (Goczałkowice Poland). "Phys Chem Earth", 2016, 94, 35-46.
15. Królak E., Raczuk J.: Nitrate concentration-related safety of drinking water from various sources intended for consumption by neonates and infants. "Arch Environ Prot", 2018, 44, 3-9.
16. Ji Y. et al. Seasonal Variation of Drinking Water Quality and Human Health Risk Assessment Hancheng City of Guanzhong Plain, China. Expos. "Health", 2020, 12 (3) 469-485.
17. Baran A., Tarnawski M., Koniarz T.: Spatial distribution of trace elements and ecotoxicity of bottom sediments in Rybnik reservoir, Silesian-Poland. "Environ Sci Pollut Res", 2016, 23 (17), 17255-17268.
18. Google Maps a. https://www.google.com/maps@50.2951254,186921281,11z?hl=pl.
19. Google Maps b. https://www.google.pl/maps/@52.0122001,29.5346949,3z/data-=!5m1!1e4?hl=en.
20. Office of Emergency and Remedial Response: Risk Assessment Guidance for Superfund. Human Health Evaluation Manual, Part A. Vol. I. United States Environmental Protection Agency Washington, USA 1989.
21. Ghaderpoori M. et al.: Data on fluoride concentration and health risk assessment of drinking water in Khorasan Razavi province, lran. "Data Br", 2018, 18, 1596-1601.
22. Guissourna W., Tarhouni J.: Fluoride in Tunisian drinking tap water. "J. Water Resour Prot , 2015, 7 (11), 860-870.
23. Office of Water U.S. Environmental Protection Agency: Edition of the drinking water standards and health advisories. United States Environmental Protection Agency, Washington, USA,2018.
24. Integrated Risk Information System Assessments. https://cfpub.epa gov/ncea/iris_drafts/atoz.cfm.
25. Zhang Y., Wu J., Xu B.: Human health risk assessment of groundwater nitrogen pollution in Jinghui canal irrigation area of the loess region, northwest China. "Environ Earth Sci", 2018, 77 (7), 1-12.
26. Paradis D. et al. Groundwater nitrate concentration evolution under climate change and agricultural adaptation scenarios: Prince Edward Island, Canada. "Earth Syst Dyn", 2016, 7 (1), 183-202.
27. Selek Z., Yetis A.D.: Assessment of nitrate contamination in a transnational groundwater basin: a case study in the Ceylanpinar Plain, Turkey. "Environ EarthSci Turkey", 2017, 76 (20), 1-11.
28. Thomson B.M., Nokes C.J., Cressey P.J.: Intake and risk assessment if nitrate and nitrite from New Zealand foods and drinking water. "Food Addit Contam", 2007, 24 (2), 113-121.
29. Alabdula’aly A.I. et al.: Assessment of nitrate concentration in groundwater in Saudi Arabia. "Environ Monit Assess", 2010, 161 (1-4), 1-9.
30. Li J. et al.: Analysis of spatial-temporal distributions of nitrate-N concentration in Shitoukoumen catchment in northeast China. "Environ Monit Assess", 2010, 169 (1-4), 335-345.
31. Soomro F. et al.: Occurrence and delineation of high nitrate contamination in the groundwater of Mithi sub-district, Thar Desert, Pakistan. "Environ Earth Sci", 2017, 76 (10), 1-9.
32. Fathmawati F. et al.: Origin and distribution of nitrate in water well of settlement areas in Yogyakarta Indonesia. "Environ Monit Assess", 2018, 190 (11), 1-11.
33. Akber M.A. et al.: Nitrate contamination of water in dug wells and associated health risks of rural communities in southwest Bangladesh. "Environ Monit Assess", 2020, 192 (3), 1-12.
34. Karunanidhi D. et al.: Evaluation of non-carcinogenic risk due to fluoride and nitrate contaminations in a groundwater of an urban part (Coimbatore region) of south India. "Environ Monit Assess", 2020, 192 (2), 1-16.
35. Manassaram D.M., Backer L.C., Moll D.M.: A Review of Nitrates in Drinking Water: Maternal Exposure and Adverse Reproductive and Developmental Outcomes. "Environ Health Perspect", 2006 114 (3), 320-327.
36. van den Brand A.D. et al.: Assessment of the combined nitrate and nitrite exposure from food and drinking water: application of uncertainty around the nitrate to nitrite conversion factor. Food Addit Contam Part A Chem Anal Control Expo Risk Assess'', 2020, 37 (4), 568-582.
37. Karimi B., Samadi S.: Health risk assessment for exposure to nitrate and nitrite in drinking water in Iran: a systematic review and meta-analysis. "Desalin Water Treat", 2018, 136, 369-394.
38. Karimi B.: Nitrate health risk assessment and its spatial distribution in drinking water in Arak, Iran. "Desalin Water Treat", 2020, 175, 141-151.
39. Radfarda M. et al.: Health risk assessment to fluoride and nitrate in drinking water of rural residents Iiving in the Bardaskan city, arid region, southeastern Iran. "Desalin Water Treat", 2019, 145, 249-256.
40. Sadler R. et al.: Health risk assessment for exposure to nitrate in drinking water from village wells in Semarang, Indonesia , "Environ. Pollut", 2016, 216, 738-745.
41. Zimoch I., Paciej J.: Spatial risk assessment of drinking water contamination by nitrates from agricultural areas in the Silesia province. "Desalin Water Treat", 2916, 57 (3), 1084-1097.

Uwagi

Opracowanie rekordu ze środków MEiN, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2022-2023).

Typ dokumentu

Bibliografia

Identyfikator YADDA

bwmeta1.element.baztech-9ce0400a-4bc9-4cc6-8820-be7247cde601