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Environmental Geochemistry and Health

, Volume 40, Issue 6, pp 2739–2759 | Cite as

Fertilizer usage and cadmium in soils, crops and food

  • M. W. C. Dharma-wardana
Original Paper

Abstract

Phosphate fertilizers were first implicated by Schroeder and Balassa (Science 140(3568):819–820, 1963) for increasing the Cd concentration in cultivated soils and crops. This suggestion has become a part of the accepted paradigm on soil toxicity. Consequently, stringent fertilizer control programs to monitor Cd have been launched. Attempts to link Cd toxicity and fertilizers to chronic diseases, sometimes with good evidence, but mostly on less certain data are frequent. A re-assessment of this “accepted” paradigm is timely, given the larger body of data available today. The data show that both the input and output of Cd per hectare from fertilizers are negligibly small compared to the total amount of Cd/hectare usually present in the soil itself. Calculations based on current agricultural practices are used to show that it will take centuries to double the ambient soil Cd level, even after neglecting leaching and other removal effects. The concern of long-term agriculture should be the depletion of available phosphate fertilizers, rather than the negligible contamination of the soil by trace metals from fertilizer inputs. This conclusion is confirmed by showing that the claimed correlations between fertilizer input and Cd accumulation in crops are not robust. Alternative scenarios that explain the data are presented. Thus, soil acidulation on fertilizer loading and the effect of Mg, Zn and F ions contained in fertilizers are considered using recent \(\hbox {Cd}^{2+}\), \(\hbox {Mg}^{2+}\) and \(\hbox {F}^-\) ion-association theories. The protective role of ions like Zn, Se, Fe is emphasized, and the question of Cd toxicity in the presence of other ions is considered. These help to clarify difficulties in the standard point of view. This analysis does not modify the accepted views on Cd contamination by airborne delivery, smoking, and industrial activity, or algal blooms caused by phosphates.

Keywords

Cadmium Metal toxins Phosphate Crops Fertilizers Soils Food 

Notes

Acknowledgements

The author thanks Dr. Sarath Amarasiri for his comments and drawing attention to some references.

References

  1. Amarasiri, S. L. (2016). Private communication based on: District-based Technical Recommendations of the Department of Agriculture, Sri Lanka for Fertilizer inputs for paddy cultivation.Google Scholar
  2. Aravinna, P., Priyantha, N., Pitawala, A., & Yatigammana, S. K. (2017). Use pattern of pesticides and their predicted mobility into shallow groundwater and surface water bodies of paddy lands in Mahaweli river basin in Sri Lanka. Journal of Environmental Science and Health, Part B, 52(1), 37–47.  https://doi.org/10.1080/03601234.2016.1229445.CrossRefGoogle Scholar
  3. ARL. (2012). Cadmium toxicity and Zn. Tech. rep., Analytical Research labs, Inc., Phoenix, Arizona, USA. http://www.arltma.com/Articles/CadmiumToxDoc.htm.
  4. Arora, P., Vasa, P., Brenner, D., Iglar, K., McFarlane, P., Morrison, H., et al. (2013). Prevalence estimates of chronic kidney disease in Canada: Results of a nationally representative survey. Canadian Medical Association Journal, 185, E417–E423.CrossRefGoogle Scholar
  5. ASTDR, U. (2008). Notice of the revised priority list of hazardous substances that will be the subject of toxicological profiles. https://www.atsdr.cdc.gov/ToxProfiles/TP.asp?id=191&tid=34
  6. ATSDR, U. (2013). Cadmium toxicity US standards for cadmium exposure. https://www.atsdr.cdc.gov/csem/csem.asp?csem=6&po=7
  7. Baldwin, R. L. (1996). How Hofmeister ion interactions affect protein stability. Biophysical Journal, 71, 2056–2063.CrossRefGoogle Scholar
  8. Bandara, J., Wijewardena, H., Liyanege, J., Upul, M., & Bandara, J. (2010). Chronic renal failure in Sri Lanka caused by elevated dietary cadmium: Trojan horse of the green revolution. Toxicology Letters, 198(1), 33–39.  https://doi.org/10.1016/j.toxlet.2010.04.016. Epub 2010 Apr 27.CrossRefGoogle Scholar
  9. Bech, J., Suarez, M., Reverter, F., Tume, P., Sánchez, P., Roca, N., et al. (2010). Selenium and other trace element in phosphorites: A comparison between those of the Bayovar-Sechura and other provenances. Journal of Geochemical Exploration, 107, 146–160.  https://doi.org/10.1016/j.gexplo.2010.04.002.CrossRefGoogle Scholar
  10. Bickmore, B., Bosbach, D., Hochella, M., Charlet, L., & Rufe, E. (2001). In situ atomic force microscopy study of hectorite and nontronite dissolution: Implications for phyllosilicate edge surface structures and dissolution mechanisms. American Mineralogist, 86(4), 411–423.CrossRefGoogle Scholar
  11. Brzóska, M. M., & Moniuszko-Jkoniuk, J. (2001). Interactions between cadmium and zinc in the orgnism. Food and Chemical Toxicology, 39, 967–980.CrossRefGoogle Scholar
  12. CCF12. (2018). Codex alimentarius, codex committee on contaminants in food. Tech. rep., FAO, RomeGoogle Scholar
  13. CTAHR-Hawaii U (2018) Fertilizer material. Tech. rep., College of Tropical Agriculture and Human Resources, University of Hawaii, https://www.ctahr.hawaii.edu/mauisoil/c_material.aspx
  14. Chaney, R. L. (2012). Chapter 2: Food safety issues for mineral and organic fertilizers. Advances in Agronomy, 117, 51–116.CrossRefGoogle Scholar
  15. Chen, Y., Wang, S., Nan, Z., Ma, J., Zhang, F., Li, Y., et al. (2017). Effect of fluoride and cadmium stress on the uptake and translocation of fluoride and cadmium and other mineral nutrition elements in radish in single element or co-taminated sierozem. Environmental and Experimental Botany, 134, 54–61.CrossRefGoogle Scholar
  16. Dharma-wardana, M. W. C. (2017). Chronic kidney disease of unknown etiology and the effect of multiple-ion interactions. Environmental Geochemistry and Health.  https://doi.org/10.1007/s10653-017-0017-4.CrossRefGoogle Scholar
  17. Dharma-wardana, M. W. C., Amarasiri, S. L., Dharmawardene, N., & Panabokke, C. R. (2015). Chronic kidney disease of unknown aetiology and ground-water ionicity: Study based on Sri Lanka. Environmental Geochemistry and Health, 37, 221–231.CrossRefGoogle Scholar
  18. Dissanayake, C., & Rohana, C. (2005). Groundwater fluoride as a geochemical marker in the etiology of chronic kidney disease of unknown origin in Sri Lanka. Ceylon Journal of Science, 46, 43–17.Google Scholar
  19. Diyabalanage, S., Abekoon, S., Watanabe, I., et al. (2016a). Has irrigated water from Mahaweli river contributed to the kidney disease of uncertain etiology in the dry zone of Sri Lanka? Environmental Geochemistry and Health, 38, 439–454.  https://doi.org/10.1007/s10653-015-9749-1.CrossRefGoogle Scholar
  20. Diyabalanage, S., Navarathna, T., Abeysundara, T. A., et al. (2016b). Trace elements in native and improved paddy rice from different climatic regions of Sri Lanka: Implications for public health. Springer Plus, 5, 1684.  https://doi.org/10.1186/s40064-016-3547-9.CrossRefGoogle Scholar
  21. DOA-SL (2016). Department of Agriculture, Sri Lanka (2017) Private communication.Google Scholar
  22. Edirisinghe, E. A. N. V., Manthrithilake, H., Pitawala, H. M. T. G. A., Dharmagunawardhane, H. A., & Wijayawardane, R. L. (2017). Geochemical and isotopic evidences from groundwater and surface water for understanding of natural contamination in chronic kidney disease of unknown etiology (CKDu) endemic zones in Sri Lanka. Isotopes in Environmental and Health Studies, 26, 1–18.Google Scholar
  23. Eriksson, J. (2001). Critical load set to ‘no further increase in Cd content of agricultural soils’ consequences. In Proceedings soil science and conservation research institute Bratislava, Slovak Republic, ad hoc international expert group on effect-based critical limits for heavy metals pp 54–58, Bratislavia. Slovak Republic 11th 13th Oct 2000.Google Scholar
  24. Eriksson, J., Andersson, A., & Andersson, R. (1997). Current status of Swedish arable soils. Tech. rep., Swedish Environmental Protection Agency, Report 4778, Solna. (in Siwedish with English summary).Google Scholar
  25. Gifford, F. J., Gifford, R. M., Eddleston, M., & Dhaun, N. (2017). Endemic nephropathy around the world. Kidney Int Rep, 2,  https://doi.org/10.1016/j.ekir.2016.11.003.CrossRefGoogle Scholar
  26. Grant, C., Harapiak, B. J. T. L. D., & Flore, N. A. (2002). Effect of phosphate source, rate and cadmium content and use of Penicillium bilaii on phosphorus, zinc, and cadmium concentration in durum wheat. Journal of the Science of Food and Agriculture, 82, 301–308.CrossRefGoogle Scholar
  27. Grant, C. A., & Sheppard, S. C. (2008). Fertilizer impacts on cadmium availability in agricultural soils and crops. Human and Ecological Risk Assessment, 14, 210–228.CrossRefGoogle Scholar
  28. Illeperuma, O. A., Dharmagunawardhane, H. A., & Herath, K. R. P. (2009). Dissolution of aluminium from substandard utensils under high fluoride stress: A possible risk factor for chronic renal failures in the North-Central province. Journal of the National Science Foundation of Sri Lanka, 37, 219–222.CrossRefGoogle Scholar
  29. Jacobs, R. M., Jones, A. O. L., Fry, B. E. J., & Fox, R. M. S. (1978). Decreased long term retention of cadmium in Japanese quail produced by a combined supplement of zinc, copper and manganese. The Journal of Nutrition, 108, 901–910.CrossRefGoogle Scholar
  30. Jansson, G. (2002). Cadmium in arable crops. Ph.D thesis, Uppsala University of Agricultural Science, SwedenGoogle Scholar
  31. Jarup, L., Berglund, M., Elinder, C. G., et al. (1998). Health effects of cadmium exposure: A review of the literature and a risk estimate. Scandinavian Journal of Work, Environment & Health, 24, 1–51.CrossRefGoogle Scholar
  32. Jayasinghe, P., Herath, B., & Wickremasinghe, N. (2015). Technical review report based on visit to Anuradhapura CKDu affected areas; review of input-output water of reverse-osmosis installtions. Tech. rep., COSTI (Coordinating Office for Science and Technology Innovation, Sri Lanka), https://dh-web.org/placenames/posts/COSTI-Jaysinghe-RO.pdf
  33. Jayasumana, C., Fonseka, S., Fernando, A., Jayalath, K., Amarasinghe, M., Siribaddana, S., et al. (2015). Phosphate fertilizer is a main source of arsenic in areas affected with chronic kidney disease of unknown etiology in Sri Lanka. Springer Plus, 4, 90.CrossRefGoogle Scholar
  34. Jayatilake, N. S. M., Maheepala, P., Metha, R. F., CKDu National Research Project Team. (2013). Chronic kidney disease of uncertain aetiology, prevalence and causative factors in a developing country. BMC Nephrology, 14, 180.CrossRefGoogle Scholar
  35. JECFA. (2011). Joint FAO/WHO food standards programme CODEX committee on contaminants in foods fifth session. Tech. rep., WHO-FAO, Joint FAO/WHO Expert Committee on Food Additives (JECFA) http://www.fao.org/tempref/codex/Meetings/CCCF/CCCF5/cf05_INF.pdf.
  36. Jorhem, L., & Slanima, P. (2000). Does organic farming reduce content of Cd and certain other trace metals in plant foods? Journal of the Science of Food and Agriculture, 80, 43–48.CrossRefGoogle Scholar
  37. Keller, A., & Schulin, R. (2003). Modeling heavy metal and phosphorus balances for farming systems. Nutrient Cycling in Agroecosystems, 66, 271–284.CrossRefGoogle Scholar
  38. Kim, D. W., Kim, K.-Y., Choi, B. S., Youn, P., Ryu, D. Y., Klassen, C. E., et al. (2007). Regulation of metal transporters by dietary iron, and the relationship between body iron levels and cadmium uptake. Archives of Toxicology, 81, 327–334.CrossRefGoogle Scholar
  39. Kjellstrom, T. (1979). Exposure and accumulation of cadmium in populations from Japan, the United States, and Sweden. Environ Health Perspectives, 28, 169–197.CrossRefGoogle Scholar
  40. Lechenet, M., Dessaint, F., Py, G., Makowski, D., & Munier-Jolain, N. (2017). Reducing pesticide use while preserving crop productivity and profitability on arable farms. Nature Plants, 3(17), 008.  https://doi.org/10.1038/nplants.2017.8.CrossRefGoogle Scholar
  41. Levine, K. E., Redmon, J. H., Elledge, M. F., Wanigasuriya, K. P., Smith, K., Munoz, B., et al. (2016). Quest to identify geochemical risk factors associated with chronic kidney disease of unknown etiology (CKDu) in an endemic region of Sri Lanka - a multimedia laboratory analysis of biological, food, and environmental samples. Environmental Monitoring and Assessment, 188, 548.CrossRefGoogle Scholar
  42. Loganathan, P., Headly, M. J., & Grace, N. D. (2008). Pasture soils contaminated with fertilizer-derived cadmium and fluorine. Reviews of Environmental Contamination and Toxicology, 129, 29–66.CrossRefGoogle Scholar
  43. Liu, J., Li, K., Xu, J., Liang, J., Lu, X., Yang, J., et al. (2003). Interaction of Cd and five mineral nutrients for uptake and accumulation in different rice cultivars and genotypes. Field Crops Research, 83, 271–281.CrossRefGoogle Scholar
  44. Manoharan, V., Loganathan, P., Tillman, R. W., & Parfitt, R. L. (2007). Interactive effects of soil acidity and fluorine on soil solution aluminum chemistry and barley (hordeum vulgare l.) root growth. Environmental Pollution, 145, 778–786.CrossRefGoogle Scholar
  45. Matović, V., Buha, A., Bulat, Z., & Dukić-Ćosić, D. (2011). Cadmium toxicity revisited: Focus on oxidative stress induction and interactions with, Zn and Mg. Archives of Industrial Hygiene and Toxicology, 62, 65–76.CrossRefGoogle Scholar
  46. McLaughlin, M. J., & Singh, B. R. (1999). Cadmium in soils and plants. Dordect, Holland: Kluwer.CrossRefGoogle Scholar
  47. McLaughlin, M. J., Tiller, K. G., Beech, T. A., & Smart, M. K. (1994). Soil salinity causes elevated cadmium concentrations in field-grown potato tubers. Journal of Environmental Quality, 34, 1013–1018.CrossRefGoogle Scholar
  48. McLaughlin, M. J., Tiller, K. G., Naidu, R., & Stevens, D. P. (1996). Review: the behaviour and environmental impact of contaminants in fertilizers. Australian Journal of Soil Research, 34, 1–54.CrossRefGoogle Scholar
  49. Meharg, A. A., Norton, G., Deacon, V., Williams, P., Adomako, E., Price, A., et al. (2013). Variation in rice cadmium related to human exposure. Environmental Science & Technology, 47, 5613–5618.CrossRefGoogle Scholar
  50. Moolenaar, S. (1999). Heavy metal balances, part II. management of cadmium, copper, lead and zinc in European agro-ecosystems. Journal of Industrial Ecology, 3, 41–53.CrossRefGoogle Scholar
  51. Mott, S., Hoy, W., Gobe, G., Satarug, S., & Abeysekera, T. (2013). Assessment of cadmium load in renal biopsies from Sri Lankan people with chronic kidney disease of unknown origin. Nephrology Journal, 18, 15–17.CrossRefGoogle Scholar
  52. Mulla, D. J., Page, A. L., & Ganje, T. J. (1980). Cadmium accumulations and bioavailability in soils from long-term phosphorus fertilization. Journal of Environmental Quality, 9, 408–12.CrossRefGoogle Scholar
  53. Onyatta, J., & Huang, P. (2005). Phosphate-induced cadmium release from soils. Enfield: Science Publishers.Google Scholar
  54. Paddy Statistics. (2015). 2014/2015 Maha Season, Dept. of Census and Statistics. ISBN 978-955-577-966-1, Battaramulla. Sri Lanka.Google Scholar
  55. Premarathne, H. M. P. L. (2006). Soil and crop contamination by toxic trace elements. Master’s thesis, Post Graduate Institute of Agriculture, University of Peradeniya, Sri Lanka, Technical Report.Google Scholar
  56. Pullakhandam, I. R. V., & Nair, K. P. M. (2009). Iron-zinc interaction during uptake in human intestinal Caco-2 cell line: Kinetic analyses and possible mechanism. Indian Journal of Biochemistry and Biophysics, 46, 299–306.Google Scholar
  57. Rietra, R., Mol, G., Rietjens, I., & Römkens, P. (2017). Cadmium in soil, crops and resultant dietary exposure. Tech. rep., Wageningen Environmental Research, Alterra- sustainable soil management, Wageningen Environmental Research Rapport 2784.Google Scholar
  58. Roberts, T. L. (2014). Cadmium and phosphorous fertilizers: The issues and the science. Procedia Engineering, 83, 52–57.CrossRefGoogle Scholar
  59. Rohana Chandrajith, T. A., & Dissanayake, C. B. (2012). The status of cadmium in the geo-environment of Sri Lanka. Ceylon Journal of Science (Physical Sciences), 16, 47–53.Google Scholar
  60. Rosen, C. J., & Bierman, P. M. (2018). Potato fertilization on irrigated soils. Minnesota: University of Minnesota Agriculture Extension Service.Google Scholar
  61. Sheppard, S. C., Grant, C. A., Sheppard, M. A., de Jong, R., & Long, J. (2009). Risk indicator for agricultural inputs of trace elements to Canadian soils. Journal of Environmental Quality, 38, 919–932.CrossRefGoogle Scholar
  62. Schroder, H. A., & Balassa, J. J. (1963). Cadmium: Uptake by vegetables from superphosphate in soil. Science, 140(3568), 819–820.CrossRefGoogle Scholar
  63. Sillanpää, M., & Jansson, H. (1992). Status of cadmium, lead, cobolt, and selenium in soils and plants of thirty countries. Tech. rep., FAO, GenevaGoogle Scholar
  64. Singh, B. R. (1994). Trace element availability to plants in agricultural soils, with special emphasis on fertilizer inputs. Environmental Reviews, 2, 133–146.  https://doi.org/10.1139/a94-009.CrossRefGoogle Scholar
  65. Sirot, V., Sarnieri, C., Volatier, J. L., & LeBlanc, J. C. (2008). Cadmium dietary intake and biomarker data in French high seafood consumers. Journal of Exposure Science and Environmental Epidemiology, 28, 400–409.CrossRefGoogle Scholar
  66. SLSI. (2016). Private communication. https://www.iso.org/member/2091.html
  67. Smolders, E. (2001). Cadmium uptake by plants. International Journal of Occupational Medicine and Environmental Health, 14, 177–183.Google Scholar
  68. Smolders, E., & Six, L. (2013). Revisiting and updating the effect of phosphate fertilizers to cadmium accumulation in European agricultural soils. Tech. rep., KU Leuven, Belgium, http://ec.europa.eu/health/scientific_committees/environmental_risks/docs/scher_o_168_rd_en.pdf
  69. Sparrow, L. A., Chapman, K. S. R., Parsley, D., Hardman, P. R., & Cullen, B. (1992). Response of potatoes (Sotanum tuberosum cv. Russet Burbank) to band-placed and broadcast high cadmium fertiliser on heavily cropped krasnozems in north-western Tasmania. Australian Journal of Experimental Agriculture, 32, 113–19.CrossRefGoogle Scholar
  70. Sparrow, L. A., Salardini, A. A., & Johnstone, J. (1993). Field studies of cadmium in potatoes (Solanum tuberosum L.). III. Australian Journal of Agricultural Research, 45(1), 243–249.CrossRefGoogle Scholar
  71. Sposito, G. (2008). The chemistry of soils (2nd ed.). Oxford, UK: Oxford University Press.Google Scholar
  72. Thammitiyagodage, M., Gunatillaka, M., Ekanayaka, N., Rathnayake, C., Horadagoda, N., Jayathissa, R., et al. (2017). Ingestion of dug well water from an area with high prevalence of chronic kidney disease of unknown etiology (CKDu) and development of kidney and liver lesions in rats. Ceylon Medical Journal, 62, 20–24.  https://doi.org/10.4038/cmj.v62i1.8428.CrossRefGoogle Scholar
  73. Tombacz, E., & Szekeres, M. (2004). Colloidal behavior of aqueous montmorillonite suspensions: The specific role of pH in the presence of indifferent electrolytes. Applied Clay Science, 27, 75–94.CrossRefGoogle Scholar
  74. Tòth, G., Hermann, T., Da Silva, M. R., & Montanarella, L. (2016). Heavy metals in agricultural soils of the European Union with implications for food safety. Environment International, 88, 299–309.CrossRefGoogle Scholar
  75. Uraguchi, S., & Fujiwara, T. (2012). Cadmium transport and tolerance in rice: Perspectives for reducing grain cadmium accumulation. Rice (N Y)., 5(1), 5.CrossRefGoogle Scholar
  76. Van Kauwenbergh, S. J. (1997). Cadmium and other minor elements in world resources of phosphate rock. The Fertiliser Society, 400; Proceedings, The Peterborough Fertiliser Society, P. O. Box 04, York, UK.Google Scholar
  77. Wales University, E. (2013). Science for environmental policy in-depth report: Soil contamination: Impacts on human health. Tech. rep., EU, via Science Communication Unit, University of Wales UK, http://ec.europa.eu/environment/integration/research/newsalert/pdf/IR5_en.pdf.
  78. Wanigasuriya, K. (2012). Aetiological factors of chronic kidney disease in the north central province of Sri Lanka: A review of evidence to-date. Journal of the College of Community Physicians of Sri Lanka, 17, 17–20.CrossRefGoogle Scholar
  79. Wasana, H. M. S., Perera, G. D. R. K., De Panduka, S., Gunawardena, P. S., Fernando, P. S., & Bandara, J. (2017). WHO water quality standards vs synergic effect(s) of fluoride, heavy metals and hardness in drinking water on kidney tissues. Nature-Scientific Reports.  https://doi.org/10.1038/srep42516.CrossRefGoogle Scholar
  80. Weerasooriya, R., Wijesekara, H. K. D. K., & Bandara, A. (2002). Surface complexation modeling of cadmium adsorption on gibbsite. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 207, 13–24.CrossRefGoogle Scholar
  81. World Bank. (2016). Fertilizer consumption (kilograms per hectare of arable land). Tech. rep., Food and Agriculture Organization, website: http://data.worldbank.org/indicator/AG.CON.FERT.ZS.
  82. Zapata, F., & Roy, R. N. (2004). Use of phosphate rocks for sustainable agriculture. Fertilizer and plant nutrition, bulletin 13, FAO, Rome, Italy. Tech. rep., Food and Agriculture Organization of the United Nations.Google Scholar
  83. Zhou, C.-F., Wang, Y.-J., Sun, R.-J., Liu, C., Fan, G.-P., Qin, W.-X., et al. (2014). Inhibition effect of glyphosate on the acute and subacute toxicity of cadmium to earthworm Eisenia fetida. Environmental Toxicology and Chemistry, 33, 2351–2357.CrossRefGoogle Scholar

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© Springer Nature B.V. 2018

Authors and Affiliations

  1. 1.National Research CouncilOttawaCanada
  2. 2.Université de MontrealMontrealCanada

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