2010-2014. Selected publications, short list. S.A.Ostroumov. Environmental science, ecology, toxicology, water, protection of environment, nanomaterials, in English, Russian, some references with abstracts and links;
http://5bio5.blogspot.com/2015/01/2010-2014-selected-publications-short.html
Ostroumov S.A., Poklonov V.A., Kotelevtsev S.V., Orlov S.N. Toxicity of Gold Nanoparticles for Plants in Experimental Aquatic System // Moscow University Biological Sciences Bulletin, 2014, Vol. 69, № 3, p. 108-112; DOI 10.3103/S0096392514030080;
http://link.springer.com/article/10.3103/S0096392514030080;
http://link.springer.com/article/10.3103/S0096392514030080;
Ostroumov S.A. Water quality: new criteria. 2014. // Science in Russia, № 5, p. 37-43.
Соломонова Е.А., Остроумов С.А. Оценка допустимых нагрузок загрязняющих веществ на макрофиты в водной среде с использованием метода рекуррентных добавок // Водное хозяйство России, 2014. № 2, с. 88-101.
Ostroumov S.A. Modern ecotoxicology and its main mistake // Ecological Studies, Hazards, Solutions, 2013. V. 19, p. 29-30.
Остроумов С.А., Джонсон Моника, Тайсон Дж, Шин Б. Иммобилизация химических элементов (Ce, Bi, Gd, Ge; наночастицы, содержащие Ti и Zn) биогенным материалом (Ludwigia palustris, Myriophyllum aquaticum, Egeriadensa, Gingko biloba и другие виды) // Ecological Studies, Hazards, Solutions, 2013. Vol. 19, p. 95-99.
Остроумов С.А. Новое в современном развитии некоторых идей В.И.Вернадского и экологические аспекты использования природных ресурсов // Вестник Самарского государственного экономического университета, 2013. № 3, с. 65-74.
Остроумов С.А., Поклонов В.А., Котелевцев С.В., Шестакова Т.В., Демина Л.Л., Шелейковский В.Л. Средоулучшающие фитотехнологии: Micranthemum umbrosumи другие водные макрофиты как фактор снижения содержания в воде тяжелых металлов // Технологии живых систем, 2013. Т. 10, № 1, с. 53-57.
Остроумов С.А., Соломонова Е.А. Взаимодействие загрязняющих воду веществ с макрофитами: метод определения допустимых нагрузок // Вода: химия и экология, 2012. № 10, с. 53-60.
Жбанов А.Е., Остроумов С.А. Взаимодействие тяжелых металлов (меди и кадмия) с биомассой бриофито-цианобактериального сообщества: на пути к фитотехнологии очищения воды // Водное хозяйство России, 2012. № 1, с. 103-108.
Остроумов С.А., Соломонова Е.А. Воздействие детергента на растения // Успехи наук о жизни, 2012. № 4, с. 82-87.
Johnson M.E., Ostroumov S.A., Tyson J.F., Xing B. Study of the interactions between Elodea canadensis and CuO nanoparticles // Russian Journal of General Chemistry, 2011. V. 81, № 13, P. 2688-2693. DOI 10.1134/s107036321113010x;
http://link.springer.com/article/10.1134%2FS107036321113010X;
http://link.springer.com/article/10.1134%2FS107036321113010X;
Copper is one of the key heavy metals that pollute environment and constitute a serious threat to the health of humans and ecosystems. Copper may enter the aquatic environment in both soluble and nanoparticle form. It was previously found in a series of studies that nanoparticles, including those of several metal oxides, exercise both negative and positive effects on the higher plants which makes necessary further research on the interaction between metal oxide nanoparticles and plants. Interactions between aquatic plants and copper-containing nanoparticles were not sufficiently studied. The goal of this study was to contribute to the investigation of the interactions between CuO nanoparticles and the aquatic plant Elodea canadensis under the conditions of experimental microcosms. It was found that CuO nanoparticles demonstrated some phytotoxicity to Elodea canadensis. After the incubation of Elodea canadensis in the aquatic medium contaminated with CuO nanoparticles there was a significant increase (by two orders of magnitude) of the concentration of copper in the biomass of the plants.
Original Russian Text © M.E. Johnson, S.A. Ostroumov, J.F. Tyson, B. Xing, 2011, published in Ekologicheskaya Khimiya, 2011, Vol. 20, No. 4, pp. 189–194.
Ostroumov S.A. Studying the fate of pollutants in the environment: binding and immobilization of nanoparticles and chemical elements // Ecologica, 2011. Vol. 18, № 62, p. 129-132.
Ostroumov S.A., Kotelevtsev S.V. Toxicology of nanomaterials and environment // Ecologica, 2011. Vol. 18, № 61, p. 3-10.
Остроумов С.А. Биотическая регуляция миграции химических элементов: выявление принципов // Экологическая химия, 2011. Т. 20, № 1, с. 43-50.
Джонсон М., Остроумов С.А., Тайсон Дж Ф., Шин Б. Изучение взаимодействий Elodea canadensis и наночастиц CuO // Экологическая химия, 2011, Т. 20, № 4, с. 189-194 .
Остроумов С.А. О типологии основных видов вещества в биосфере // Экологическая химия, 2011. Т. 20, № 3, с. 179-188 .
Поклонов В.А., Котелевцев С.А., Шестакова Т.В., Остроумов С.А. Снижение концентраций тяжелых металлов в водных растворах при взаимодействии с макрофитами // Экологическая химия, 2011. Т. 20, № 4, с. 200-203.
Остроумов С.А. Совершенствование системы критериев экологической опасности химических веществ // Прикладная токсикология, 2011, Т. 2, № 2, с. 18-27.
Ostroumov S.A. Biocontrol of Water Quality: Multifunctional Role of Biota in Water Self-Purification // Russian Journal of General Chemistry, 2010, Vol. 80, № 13, p. 2754-2761. DOI 10.1134/s1070363210130086; http://link.springer.com/content/pdf/10.1134%2FS1070363210130086; http://link.springer.com/article/10.1134/S1070363210130086;
The experimental data analysis, concepts, and generalizations in this article provide the fundamental elements of the qualitative theory of biocontrol (biological community-dependent control ) of water quality in a systematized form. The theory covers and explains the complex natural processes of improving water quality and running water self-purification in freshwater and marine ecosystems. The theory is supported by the results of the author’s experimental studies of the effects exerted by some chemical pollutants - including synthetic surfactants, detergents, and other xenobiotics - on aquatic organisms. The theory provides a basis for remediation of polluted aquatic ecosystems including purification of water bodies and streams. This paper is both a review and an opinion paper that present the scientific basis for innovative, energy-saving, greenhouse gase absorbing technologies for water treatment and purification, phytoremediation, and other types of ecotechnologies.
Ostroumov S.A., Kolesov G.M. The Aquatic Macrophyte Ceratophyllum demersum Immobilizes Au Nanoparticles after Their Addition to Water // Doklady Biological Sciences, 2010. Vol. 431, P. 124-127. DOI 10.1134/S0012496610020158;
PMID: 20506851;
http://link.springer.com/article/10.1134%2FS0012496610020158;
Translated from thePMID: 20506851;
http://link.springer.com/article/10.1134%2FS0012496610020158;
Original Russian Text © S.A. Ostroumov, G.M. Kolesov, 2010, published in Doklady Akademii Nauk, 2010, Vol. 431, No. 4, pp. 566–569. Bibliogr. 15 refs. Presented by Academician M.A. Fedonkin July 31, 2009. Received February 11, 2009. DOI: 10.1134/S0012496610020158. http://scipeople.com/publication/69766/. In the paper, it was discovered that the aquatic plant (macrophyte) Ceratophyllum demersum immobilized gold (Au) nanoparticles after their addition to water. This is the first time it was shown that the nanoparticles of gold (Au) in substantial amount bind to the living biomass of the aquatic macrophyte, Ceratophyllum demersum. The concentrations of Au were measured in the samples of the phytomass using neutron activation analysis (NAA). As a result of the binding and/or immobilization of the nanoparticles, the amount of Au in the samples of the phytomass increased manifold (by a factor of 430) above the background level of gold in the plant tissues. The increase was by two orders of magnitude. The new data added some new information to the modern vision of the multifunctional role of the biota in the migration of elements in aquatic ecosystems. Also, the result added new information to the studies of interactions of Au with organisms that may contribute to new biotechnologies. http://www.ncbi.nlm.nih.gov/pubmed/20506851; PMID: 20506851 [PubMed]; http://www.springerlink.com/content/j487667871w02h28/; Key words: nanotechnology, nanoparticles, Au, gold, biogeochemistry, biotechnology, aquatic plants, macrophyte, Ceratophyllum demersum, Immobilization, water quality, monitoring, environmental science, ecology, nanoparticles in aquatic environment; www.springerlink.com/index/J487667871W02H28.pdf ;
Остроумов С.А., Демина Л.Л. Роль биогенного детрита водных систем в аккумуляции металлов и металлоидов на примере восьми тяжелых металлов и мышьяка // Водное хозяйство России, 2010 № 1, с. 60-69.
Остроумов С. А. Токсичные элементы в биосфере,экологические вопросы детоксикациии совершенствование экологического мониторинга (Toxic elements in biosphere, ecological problems of detoxication and advance of ecological monitoring) // Прикладная токсикология. 2012. № 2(8). С.28-41. http://velt-media.ru/?page_id=3089;
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More information on publications by the same author:
PubMed. Articles. environmental science, protection of environment, ecology, ecotoxicology, toxicology, water quality, pollution control.
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Evidence of merit: Citation.
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