AbstractSilicon is the essential trace element. Its regular flow is absolutely necessary for normal body functioning. Lymph nodes and thyroid gland are the leaders in the silicon content. Then follow the connective tissue of the aorta and trachea, tendons, nerves, pituitary gland, bone, and hair respectively. Silicon promotes collagen biosynthesis and is involved in the metabolism of 70 minerals and vitamins, lipid metabolism, and in maintaining its balance with calcium as well. In case of silicon deficiency the calcination of tissues takes place: tissues lose their firmness and elasticity. Silicon nanoparticles have a large active surface. They are chemically and thermally stable, well suspended in aqueous solutions and relatively inert in the environment.
Ailer R. Chemistry of silica Ailer R. Chemistry of silica. Moscow.1922; 2: 712.
Yeliseev A.A., Lukashyn A.V. Functional nanosubstances. Fizmatlit. Moscow. 2010: 456.
Yermolaieva Yu. O., Matvieievska N., Tolmachov O. Obtaining and study of optical properties of hetero-nanoparticles SiO2/PbS. Visnyk Lviv Un-ty. Seriia fizychna. 2008; 41: 158-164.
Tsitterman M. Trace elements in medicine. Arnebia. Moscow. 2006: 290.
Chekman I.S., Malanchuk V.O., Rybachuk A.V. Methods of nanoparticles investigations. Naukovyi visnyk NMU im. O.O. Bohomoltsia. 2010; 2-3: 148-160.
Chekman I.S., Malanchuk V.O., Rybachuk A.V. Fundamentals of nanomedicine. Logos. 2011: 248.
Chuiko A.A., Vlasova N.N., Davydenko N.A. Adsorption interaction of finely-dispersed silica with biomolecules. Meditsinskaya khimiya i klinicheskoe primenenie dioksida kremnia. Naukova dumka. 2003: 116-152.
Shyrobokov V., Yankovskyi D., Dyment H. The world of clay and human health. Svitohliad. 2012; 2: 7-18.
Chung S.H., Lee D.W., Kim M.S.The synthesis of silica and silica-ceria, core-shell nanoparticles in a water-in-oil (W/O) microemulsion composed of heptane and water with the binary surfactants AOT and NP-5. J.Colloid. Interface Sci. 2011; 355(1): 70-75.
Fortina P., Kricka L.J., Surrey S. Nanobiotechnology the promise and reality of new approaches to molecular recognition .Trends Biotechnol. 2005; 23 (5): 168-173.
Knopp D., Tang D., Neissner R. Review: Bioanalytical applications of biomolecule-functionalized nanometer-sized doped silica particles. Analitica Chimica Acta. 2009; 64: 14-30.
Liu S., Han M.Y. Silica-Coated Metal Nanoparcticles. Chem.Asian. J. 2009; 18: 1245-1249.
Murthy S.K. Nanoparcticles in modern medicine: state of the art and future challenges. Int.J.Nanomed. 2007; 2: 129-141.
Na M., Park H., Ahn M. Synthesis of organic-inorganic hybrid sols with nano salica particles and organoalkokysilanes for transparent and high-thermal-resistance coating films using solgel reaction. J.Nanosci Nanotechnol. 2010; 10(10): 6992-6995.
Smitha S., Shojesh P., Mukundan P. Synthesis of biocompatible hydrophobic silica-gelatin nanohybrid by sol-gel process. Colloids Surf B Biointerfaces. 2007; 55(1): 38-43.
Song S., Chen Y., Yan Z. Self-assembled rosette nanotubes for incorporating hydrophobic drugs in physiological environments. Int.J.Nanomedecine. 2011; 6: 101-107.
Tao Z., Toms B.B., Goodisman J. Mesoporosity and Functional Group Dependent Endocytosis and Cytotoxility of Silica Nanomaterials. Chem.Res.Toxical. 2009; 21(9):13-20.
Wang Y., Xu H., Gu H. Synthesis of raspberry-like SiO2 polystyrene nanocomposite particles via miniemulsion polymerization. J.Nanosci. Nanotechnol. 2009; 9(2): 1571-1576.
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