Везде

RAS BiologyРастительные ресурсы Vegetation Resources

  • ISSN (Print) 0033-9946
  • ISSN (Online) 3034-5723

Assessment of Total Mineral Content in Raw Materials of Ten Medicinal Plants from Roadside Biotopes (Voronezh Region)

You can
PII
10.31857/S0033994623010053-1
DOI
10.31857/S0033994623010053
Publication type
Status
Published
Authors
N. A. Dyakova
  • Affiliation: Voronezh State University
Volume/ Edition
Volume 59 / Issue number 2
Pages
189-197
Abstract
Abstract— The total mineral content in medicinal plants from the roadside and railside coenoses of the Voronezh region was studied. The pharmacopoeial plant raw materials of 10 species were evaluated: roots of Taraxacum officinale F.H. Wigg and Arctium lappa L.; herb of Polygonum aviculare L., Artemisia absinthium L., Leonurus quinquelobatus Gilib., and Achillea millefolium L.; leaves of Urtica dioica L. and Plantago major L.; flowers of Tanacetum vulgare L. and Tilia cordata Mill. For collecting medicinal plant raw materials, the minimum allowable distances from different types of roads and railways were determined based on the total ash content indicator. For different natural zones, the minimum allowable distance from the heavy traffic motorways is: forest zone – 210 m, forest–steppe zone – 240 m, and steppe zone (devoid of tree and shrub vegetation) – 380 m. For secondary low-speed roads and railways, the minimum recommended distance is 80 m.
Keywords
лекарственные растения <i>Taraxacum officinale</i> <i>Arctium lappa</i> <i>Achillea millefolium</i> <i>Artemisia absinthium</i> <i>Leonurus quinquelobatus</i> <i>Polygonum aviculare</i> <i>Urtica dioica</i> <i>Plantago major</i> <i>Tanacetum vulgare</i> <i>Tilia cordata</i> содержание общей золы придорожные биотопы Воронежская область
Date of publication
01.04.2023
Year of publication
2023
Number of purchasers
0
Views
43

References

  1. 1. Дьякова Н.А. 2021. Особенности накопления биологически активных веществ в корнях лопуха обыкновенного синантропной флоры Воронежской области. – Традиционная медицина. 2(65). С. 47–52. https://doi.org/10.54296/18186173_2021_2_47
  2. 2. Дьякова Н.А., Сливкин А.И., Чупандина Е.Е., Гапонов С.П. 2020. Выявление допустимых зон заготовки лекарственного растительного сырья вблизи транспортных магистралей. – Хим. растит. сырья. 4: 5–13.
  3. 3. Остроухова Е.Г. 2018. Экологическое состояние ромашки аптечной (Matricaria chamomilla L.), произрастающей на антропогенно преобразованных территориях. – Антропогенная трансформация природной среды. 4: 174–178. https://elibrary.ru/item.asp?id=36549337
  4. 4. Селиванова Ю.А., Вервикина А.А., Дьякова Н.А., Сливкин А.И. 2022. Изучение содержания посторонних минеральных примесей в лекарственном растительном сырье синантропной флоры Ростовской области. – Вестник Воронежского государственного университета. Серия: Химия. Биология. Фармация. 2: 98–103. http://www.vestnik.vsu.ru/pdf/chembio/2022/02/2022-02-14.pdf
  5. 5. Селиванова Ю.А., Дьякова Н.А., Вервикина А.А., Сливкин А.И. 2022. Исследование общего минерального комплекса лекарственного растительного сырья синантропной флоры Ростовской области. – Вестник Смоленской медицинской академии. 4: 205–210. https://elibrary.ru/download/elibrary_50106655_68495004.pdf
  6. 6. Государственная фармакопея Российской Федерации. 2018. Издание XIV. Т. 2. М. 1449 с.
  7. 7. Куркин В.А. 2004. Фармакогнозия. Самара. 1179 с.
  8. 8. Tasić M., Rajšić S., Tomašević M., Mijić Z., Anćić M., Novaković V., Marković D.M., Markovć D.A., Lazić L., Radenković M., Joksić J. 2008. Assessment of Air Quality in an Urban Area of Belgrade, Serbia. – In: Environmental Technologies: New Developments. Vienna. P. 209–244. https://www.academia.edu/23672991/Assessment_of_Air_Quality_in_an_Urban_Area_of_Belgrade_Serbia
  9. 9. Sawidis T., Breuste J., Mitrovic M., Pavlovic P., Tsigaridas K. 2011. Trees as bioindicator of heavy metal pollution in three European cities – Environmental Pollution. 159(12): 3560–3570. https://doi.org/10.1016/j.envpol.2011.08.008
  10. 10. Anagnostatou V.A. 2008. Assessment of Heavy Metals in Central Athens and Suburbs Using Plant Material. Master’s Thesis. Surrey. 45 p.
  11. 11. Rai A., Kulshreshtha K. 2006. Effect of particulates generated from automobile emission on some common plants. – J. Food Agricult. Environ. 4(1): 253–259. https://www.wflpublisher.com/Abstract/813
  12. 12. Gupta G.P., Kumar B., Singh S., Kulshrestha U.C. 2016. Deposition and Impact of Urban Atmospheric Dust on Two Medicinal Plants during Different Seasons in NCR Delhi. – Aerosol Air Qual. Res. 16(11): 2920–2932. https://doi.org/10.4209/aaqr.2015.04.0272
  13. 13. Wang H., Shi H., Li Y. 2011. Leaf Dust Capturing Capacity of Urban Greening Plant Species in Relation to Leaf Micromorphology. – In: International Symposium on Water Resource and Environmental Protection. Xi’an. P. 2198–2201. https://doi.org/10.1109/ISWREP.2011.5893701e
  14. 14. Wang L., Gong H., Liao W., Wang Z. 2015. Accumulation of particles on the surface of leaves during leaf expansion. – Sci. Total Environment. 532(1): 420–434. https://doi.org/10.1016/j.scitotenv.2015.06.014
  15. 15. Youssef N.A., Gurbanov E.M., Haciyeva S.R., Mammedova A., Khalilov R.I. 2013. Antioxidant enzymes, fluctuating asymmetry and morphological changes of urban trees as an ecological indicators of heavy metal stress. – International Journal of Pharmaceutical Science and Health Care. 3(1): 1–11.
  16. 16. Castanheiro A., DeWael K., Samson R. 2016. Urban green as indicator of metal pollution. – 15th Castle Meeting New trends on Paleo, Rock and Environmental Magnetism. Dinant. 15–17. https://www.meteo.be/meteo/download/en/25955897/pdf/abs.11-08-16.pdf
  17. 17. Dadea C., Bacchiocchi S.C., Rocca N.L., Mimmo T., Russo A., Zerbe S. 2016. Heavy metal accumulation in urban soils and deciduous trees in the City of Bolzano, N Italy. – Waldökologie, Landschaftsforschung und Naturschutz. – Forest Ecology, Landscape Research and Nature Protection). 15: 35–42. https://www.afsv.de/download/literatur/waldoekologie-online/waldoekologie-online_heft-15-3.pdf
  18. 18. Kříbek B., Majer V., Knésl I., Nyambe I., Mihaljevič M., Ettler V. 2012. Metals and arsenic in cassava: Indicators of contamination in the Zambian Copperbelt mining district. – In: Environmental and health impacts of mining in Africa: proceedings of the annual workshop. Windhoek. P. 29–34.
  19. 19. Mansour R.S. 2014. The pollution of tree leaves with heavy metal in Syria. – International Journal of ChemTech Research. 6(4): 2283–2290. https://sphinxsai.com/2014/vol6pt4/1/ (2283-2290)Jul-Aug14.pdf
  20. 20. Tomašević M., Rajšić S., Dordević D., Tasić M., Krstić J., Novaković V. 2004. Heavy metals accumulation in tree leaves from urban areas. – Environ. Chem. Lett. 2(3): 151–154. https://doi.org/10.1007/s10311-004-0081-8
  21. 21. Speak A.F., Rothwell J.J., Lindley S.J., Smith C.L. 2012. Urban particulate pollution reduction by four species of green roof vegetation in a UK city. – Atmospheric Environment. 61: 283–293. https://doi.org/10.1016/j.atmosenv.2012.07.043
  22. 22. Castanheiro A., Samson R., DeWael K. 2016. Magnetic- and particle-based techniques to investigate metal deposition on urban green. – Sci. Total Environment. 571: 594–602. https://doi.org/10.1016/j.scitotenv.2016.07.026
  23. 23. Государственная фармакопея Российской Федерации. 2018. Издание XIV. Т. 4. М. 1859 с.
QR
Translate

Индексирование

Scopus

Scopus

Scopus

Crossref

Scopus

Higher Attestation Commission

At the Ministry of Education and Science of the Russian Federation

Scopus

Scientific Electronic Library