Влияние наночастиц серебра на биологические объекты

Полонский В.И.; Асанова А.А.; Polonsky V.I.; Asanova A.A.

Научные статьи \ Математика. Естественные науки \ Биологические науки в целом \ Общая экология. Биоценология. Гидробиология. Биогеография

Влияние наночастиц серебра на биологические объекты

Автор: Полонский В.И., Асанова А.А.

Журнал: Вестник Красноярского государственного аграрного университета @vestnik-kgau

Рубрика: Биологические науки

Статья в выпуске: 6, 2018 года.

Бесплатный доступ

Сегодня в мире мощное развитие получили нано- технологии, объемы промышленного производства наноматериалов увеличиваются с каждым днем, дости- гая в настоящий момент в развитых странах несколь- ких тысяч тонн в год. В результате такой деятельно- сти человека в окружающей среде появились неестест- венные, очень мелкие частицы техногенного происхож- дения. Наночастицы, создавая беспрецедентный класс промышленных загрязнений окружающей среды, непо- средственно воздействуют практически на все виды организмов. Поэтому риски, вызванные техногенными наноматериалами, как для человека, так и для окру- жающей среды должны быть оценены. Цель работы - анализ мировой литературы по влиянию широко рас- пространенных наночастиц - серебра - на представи- телей разных уровней биологической организации, на- селяющих различные среды обитания. Показано, что проблема безопасности техногенных наночастиц ис- следуется мировым научным сообществом в основном методами биотестирования. При изучении влияния наночастиц на различные биологические объекты в литературе описаны неоднозначные результаты...

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Наночастицы серебра, биотестирование, микромицеты, водоросли, рачки, культуры клеток, растения, размеры и форма наночастиц

Короткий адрес: https://sciup.org/140238165

IDR: 140238165 | УДК: 574.24

The influence of silver nanoparticles on biological objects

At present nanotechnologies have gained powerful devel- opment in the world, the volume of industrial production ofnanomaterials is increasing every day, reaching several thou- sand tons per year in developed countries. Unnatural very small engineered particles are released into the environment as a result of such human activities. Nanoparticles causing an unprecedented type of industrial pollution directly affect all living organisms. Therefore, the risks caused by engineered nanomaterials both to humans and environment have to be evaluated. The purpose of the review is analyzing the world literature about the effects of one of the most widespread silver nanoparticles on living organisms of different levels of biological organization and habitats. It is shown that safety issues with engineered nanoparticles are studied using biotesting methods by the world scientific community. When studying the effect of nanoparticles on various biological ob- jects, the literature describes ambiguous results...

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Список литературы Влияние наночастиц серебра на биологические объекты

Piccinno F. Gottschalk F., Seeger S. . Industrial production quantities and uses of ten engineered nanomaterials in Europe and the world//Journal of Nanoparticle Research. -2012. -V. 14. -№ 9. -P. 1109-1120.
Talreja N., Kumar D. Engineered Nanoparticles' Toxicity: Environmental Aspects//In: Nanotechnology in Environmental Science. Editors: C.M. Hussain, A.K. Mishra. Wiley-VCH Verlag GmbH and Co. KGaA. -2018. -Chapter 23. -P. 737-758.
Carbone M., Donia D., Sabbatella G. . Silver nanoparticles in polymeric matrices for fresh food packaging//Journal of King Saud University Science. -2016. -V. 28. -№ 4. -P. 273-279.
Ovais M., Ahmad I., Khalil A. . Wound healing applications of biogenic colloidal silver and gold nanoparticles: recent trends and future prospects//Applied Microbiology and Biotechnology. -2018. -V. 102. -№ 1. -P. 1-14.
Monteiro D.R., Gorup L. F., Silva S. . Silver colloidal nanoparticles: antifungal effect against adhered cells and biofilms of Candida albicans and Candida glabrata//Biofouling. -2011. -V. 27. -№ 7. -P. 711-719.
Blaser S., Scheringer M., MacLeod M. . Estimation of cumulative aquatic exposure and risk due to silver: contribution of nanofunctionalized plastics and textiles//Science of the Total Environment. -2008. -V. 390. -№ 2-3. -P. 396-409.
Lombi E., Donner E., Scheckel K.G. . Silver speciation and release in commercial antimicrobial textiles as influenced by washing//Chemosphere. -2014. -V. 111. -№ 2. -P. 352-358.
Praveena S., Karuppiah K., Than L. Potential of Cellulose paper coated with silver nanoparticles: a benign option for emergency drinking water filter//Cellulose. -2018 -P. 1-12.
Benn T., Westerhoff P. Nanoparticle silver released into water from commercially available sock fabrics//Environmental Science and Technology. -2008. -V. 42. -№ 11. -P. 4133-4139.
Forster H., Thajudeen T., Funk C. . Separation of nanoparticles: Filtration and scavenging from waste incineration plants//Waste Management. -2016. -V. 52. -P. 346-352.
Albuquerque P., Gomes J., Pereira C. . Assessment and control of nanoparticles exposure in welding operations by use of a Control Banding Tool//Journal of Cleaner Production. -2015. -V. 89. -P. 296-300.
Thakur S., Kumar R. Bio-Nanotechnology and its Role in Agriculture and Food Industry//Journal of Molecular and Genetic Medicine. -2018. -V. 12. -№ 1. -P. 324-329.
Ogar A., Tylko G., Turnau K. Antifungal properties of silver nanoparticles against indoor mould growth//Science of the Total Environment. -2015. -V. 521. -P. 305-314.
Hedberg J., Skoglund S., Karlsson M. . Sequential studies of silver released from silver nanoparticles in aqueous media simulating sweat, laundry detergent solutions and surface water//Environmental Science and Technology. -2014. -V. 48. -№ 13. -P. 7314-7322.
McGillicuddy E., Murray I., Kavanagh S. . Silver nanoparticles in the environment: Sources, detection and ecotoxicology//Science of the Total Environment. -2017. -V. 575. -P. 231-246.
Liu R., Lal R. Potentials of engineered nanoparticles as fertilizers for increasing agronomic productions//Science of the Total Environment. -2015. -V. 514. -P. 131-139.
Kim K., Sung W., Moon S. . Antifungal effect of silver nanoparticles on dermatophytes//Journal of Microbiology and Biotechnology. -2008. -V. 18. -№ 8. -P. 1482-1484.
Panacek A., Kolar M., Vecerova R. . Antifungal activity of silver nanoparticles against Candida spp//Biomaterials. -2009. -V. 30. -№ 31. -P. 6333-6340.
Xia Z., Ma Q., Li S. . The antifungal effect of silver nanoparticles on Trichosporon asahii//Journal of Microbiology, Immunology and Infection. -2016. -V. 49. -№ 2. -P. 182-188.
Mishra S., Singh H. Silver nanoparticles mediated altered gene expression of melanin biosynthesis genes in Bipolaris sorokiniana//Microbiological Research. -2015. -V. 172. -P. 16-18.
Ribeiro F., Gallego-Urrea J.A., Jurkschat K. . Silver nanoparticles and silver nitrate induce high toxicity to Pseudokirchneriella subcapitata, Daphnia magna and Danio rerio//Science of the Total Environment. -2014. -V. 466. -P. 232-241.
Ivask A., Kurvet I., Kasemets K. . Size-dependent toxicity of silver nanoparticles to bacteria, yeast, algae, crustaceans and mammalian cells in vitro//PloS ONE. -2014. -V. 9. -№ 7. -P. 102-108.
Yin L., Colman B., McGill B. . Effects of silver nanoparticle exposure on germination and early growth of eleven wetland plants//PLoS ONE. -2012. -V. 7. -№ 10. -P. 47-67.
Nanotoxicity Assays in Plant Models//Nanotoxicity. -25. 2012. -V. 926. -Р. 399-4
Song U., Jun H., Waldman B. . Functional analyses of nanoparticle toxicity: a comparative study of the effects of TiO2 and Ag on tomatoes (Lycopersicon esculentum)//Ecotoxicology and Environmental Safety. -2013. -V. 93. -P. 60-67.
Kuamri M., Ernest V., Mukherjee A. . In Vivo El-Temsah Y. Joner E. Impact of Fe and Ag nanoparticles on seed germination and differences in bioavailability during exposure in aqueous suspension and soil//Environmental Toxicology. -2012. -V. 27. -№ 1. -P. 42-49.
Patlolla A., Berry A., May L. . Genotoxicity of silver nanoparticles in Vicia faba: a pilot study on the environmental monitoring of nanoparticles//International Journal of Environmental Research and Public Health. -2012. -V. 9. -№ 5. -P. 1649-1662.
Mirzajani F., Askari H., Hamzelou S. . Effect of silver nanoparticles on Oryza sativa L. and its rhizosphere bacteria//Ecotoxicology and Environmental Safety. -2013. -V. 88. -P. 48-54.
Sharma P., Bhatt D., Zaidi M. . Silver nanoparticle-mediated enhancement in growth and antioxidant status of Brassica juncea//Applied Biochemistry and Biotechnology. -2012. -V. 167. -№ 8. -P. 2225-2233.
Vannini C., Domingo G., Onelli E. . Morphological and proteomic responses of Eruca sativa exposed to silver nanoparticles or silver nitrate//PLoS ONE. -2013. -V. 8. -№ 7. -P. 68-75.
Salama H. Effects of silver nanoparticles in some crop plants, common bean (Phaseolus vulgaris L.) and corn (Zea mays L.)//International Research Journal of Bio-technology. -2012. -V. 3. -№ 10. -P. 190-197.
Connolly M., Fernandez-Cruz M., Quesada-Garcia A. . Comparative cytotoxicity study of silver nanoparticles (AgNPs) in a variety of rainbow trout cell lines (RTL-W1, RTH-149, RTG-2) and primary hepatocytes//International Journal of Environmental Research and Public Health. -2015. -V. 12. -№ 5. -P. 5386-5405.
Greulich C., Braun D., Peetsch A. . The toxic effect of silver ions and silver nanoparticles towards bacteria and human cells occurs in the same concentration range//RSC Advances. -2012. -V. 2. -№ 17. -P. 6981-6987.
Farkas J., Christian P., Gallego-Urrea J. . Uptake and effects of manufactured silver nanoparticles in rainbow trout (Oncorhynchus mykiss) gill cells//Aquatic Toxicology. -2011. -V. 101. -№ 1. -P. 117-125.
Massarsky A., Abraham R., Nguyen K.C. . Nanosilver cytotoxicity in rainbow trout (Oncorhynchus mykiss) erythrocytes and hepatocytes//Comparative Biochemistry and Physiology. Part C: Toxicology and Pharmacology. -2014. -V. 159. -P. 10-21.
Chernousova, S., Epple M. Silver as antibacterial agent: ion, nanoparticle, and metal//Angewandte Chemie International Edition. -2013. -V. 52. -№ 6. -P. 1636-1653.
Vazquez-Munoz R., Borrego B., Juarez-Moreno K. . Toxicity of silver nanoparticles in biological systems: Does the complexity of biological systems matter?//Toxicology Letters. -2017. -V. 276. -P. 11-20.
Cvjetko P., Milosic A., Domijan A. . Toxicity of silver ions and differently coated silver nanoparticles in Allium cepa roots//Ecotoxicology and Environmental Safety. -2017. -V. 137. -P. 18-28.
McShan D., Ray C., Yu H. Molecular Toxicity Mechanism of Nanosilver//Journal of Food and Drug Analysis. -2014. -V. 22. -№ 1. -P. 116-127.
Kennedy A.J., Hull M.S., Bednar A.J. . Fractionat-ing nanosilver: importance for determining toxicity to aquatic test organisms//Environmental Science and Technology. -2010. -V. 44. -№ 24. -P. 9571-9577.
Thuesombat P., Hannongbua S., Akasit S. . Effect of silver nanoparticles on rice (Oryza sativa L. cv. KDML 105) seed germination and seedling growth//Ecotoxicology and Environmental Safety. -2014. -V. 104. -P. 302-309.
Sohn E., Johar S., Kim T. . Aquatic toxicity comparison of silver nanoparticles and silver nanowires//BioMed Research International. -2015. -V. 2015. -P. 1-12.
George S., Lin S., Ji Z. . Surface defects on plate-shaped silver nanoparticles contribute to its hazard potential in a fish gill cell line and zebrafish embryos//ACS Nano. -2012. -V. 6. -№ 5. -P. 3745-3759.
Asghari S., Johari S., Lee J. . Toxicity of various silver nanoparticles compared to silver ions in Daphnia magna//Journal of Nanobiotechnology. -2012. -V. 10. -№ 1. -P. 14-25.

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