The Involvement of Heavy Metals in the Main Trophic Chains in Agrophytocenoses of the Sterlitamak Region of the Republic of Bashkortostan

  • Abstract
  • Keywords
  • References
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  • Abstract

    The work was aimed at evaluating the involvement of heavy metals in the biogeochemical cycle in the soil-plant system in the setting of agrophytocenoses. The elemental composition of soil and plants was determined by atomic absorption. The sanitary-hygienic and ecological assessment of the condition of soils and plants in the region by heavy metals content has been provided for the first time; for individual items, the health risk of soil contamination and used agricultural products has been assessed.

    For the first time, background concentrations of priority pollutants in the soil and plants have been found at different sites from contamination sources; the annual average volumes of removal of Cd, Pb, Zn, Cu, Ni, Cr, and Mn from the soil have been established; the antagonistic-synergistic interactions have been revealed at the introduction of macro- and microelements into plants.



  • Keywords

    Anthropogenic Load, Xenobiotics, Heavy Metals, Antagonism and Synergism Of Ions, Risk Assessment.

  • References

      [1] Avtsyn AP, Zhavoronkov AA, Rish MA, Strochkova LS (1991), Mikroelementozy cheloveka [Human trace elements]. Moscow: Meditsyna, 496.

      [2] Kovalskiy VV, Gribovskaya IF, Grinkevich NI (1974), Rol geokhimicheskikh usloviĭ sredy v kontsentrirovanii mikroelementov rasteniyami [The role of geochemical environmental conditions in the concentration of trace elements by plants]. Moscow: Nauka, 144-179.

      [3] Roberts TL (2014), Cadmium and phosphorous fertilizers: the issues and the science. Procedia Engineering, 83, 52-59.

      [4] Tyler G (2017), Metal concentrations in moss, leaves and other indicators of metal exposure in the environment. International conference on environmental sensing and assess.

      [5] Khanipova ER, Zubkova VM (2017), Evaluation of health's risk of daily use vegetable products obtained under the anthropogenic load. Contemporary Problems of Social Work, 1(9), 168-175.

      [6] Yagodin BA (2002), Koltso zhizni [Ring of life]. Мoscow: Independent Institute of Expertise and Certification, 135.

      [7] Asylbayev IG (2015), Otsenka geokhimicheskogo sostoyaniya pochv Yuzhnogo Urala [Assessment of the geochemical state of the soils of the Southern Urals]. PhD (biological sciences 03.02.13 / İlgiz Gallyamovich Asylbaev. – Ufa, 2015. – pp: 516

      [8] Barsukova VS (1997), Fiziologo-geneticheskiye aspekty ustoychivosti rasteniy k tyazhelym metallam [Physiological and genetic aspects of plant resistance to heavy metals]. Novosibirsk, 63.

      [9] Ilyin VB (1985), Elementnyy khimicheskiy sostav rasteniy [Elemental chemical composition of plants]. Novosibirsk: Nauka, 129.

      [10] Kabata-Pendias A, Pendias Kh (1989), Mikroelementy v pochvakh i rasteniyakh [Trace elements in soils and plants]. Moscow: Mir, 439.

      [11] GOST 12.1.007-76. Classification and general safety requirements. State standard. Moscow: Federal State Unitary Enterprise "Standartinform", (2007), 7.

      [12] Guidelines for assessing the risk to public health when exposed to chemicals that pollute the environment. Moscow: Federal Center for State Sanitary and Epidemiological Surveillance of the Ministry of Health of Russia, (2004), 143.

      [13] Khanipova ER, Lebedeva MV, Zubkova VM (2018), Opredeleniye antagonisticheski-sinergicheskikh vzaimodeystviy elementov v rasteniyakh s primeneniyem korrelyatsionnogo analiza [Determination of antagonistic-synergistic interactions of elements in plants using correlation analysis]. In the book: Ratsionalnaya ekspluatatsiya bioresursov: problemy i vozmozhnosti v kontekste Tseley Ustoychivogo Razvitiya OON. [Rational exploitation of bioresources: challenges and opportunities in the context of the UN Sustainable Development Goals.]. Moscow: Pero Publishing House, 560-565.

      [14] Bowen HJM (1979), Essenciality dificiences and toxicities of the elements. London: Acad. Press, 333.

      [15] SanPiN Hygienic requirements for safety and nutritional value of food. Sanitary-epidemiological rules and regulations [Electronic resource].

      [16] SanPiN 42-123-4089-86. Maximum permissible concentrations of heavy metals and arsenic in food raw materials and food products [Electronic Source].

      [17] Soshenko MV, Nadezhkina EV, Larina MO, Molodova OV (2013),. Proizvodstvo ekologicheski bezopasnoy ovoshchnoy produktsii kak osnova povysheniya kachestva zhizni (na primere rayonov federalnykh avtomagistraley) [Production of ecologically safe vegetable products as the basis for improving the quality of life (by the example of areas of federal highways)]. Social policy and sociology, 6-2(101), 99-106.

      [18] Torshin SP, Udelnova TM, Yagodin BA (1990), Trace elements, ecology and human health. Successes of modern biology, 2, 279-292.




Article ID: 27538
DOI: 10.14419/ijet.v7i4.38.27538

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