Ormosil

Ormosil is a shorthand phrase for organically modified silica or organically modified silicate.[1] In general, ormosils are produced by adding silane to silica-derived gel during the sol-gel process. They are engineered materials that show great promise in a wide range of applications[2] such as:

  • alternative to viral vectors for gene delivery, with higher transient transfection efficiencies[3][4]
  • suspension media and substrates for next generation solar cells (quantum dots)and photocatalytic oxidation of water[5]
  • matrix material for UV-protection coating[6]
  • matrix material for laser dye-doped organic-inorganic solid state dye lasers[7]

This technology has been demonstrated as a nonviral vector to successfully deliver DNA loads to specifically targeted cells in living animals. Confirmation of results demonstrated that new DNA was working and expressed genes in the animal.

Sono-Ormosil

Sono-Ormosils are organically modified silicates, which were prepared by using high-performance ultrasound during the sol-gel process. High-power ultrasound is an efficient tool for the synthesis of polymers.[8] When high intense ultrasound is introduced in liquid, cavitation is produced. Due to the cavitational shear forces, molecular weight is lowered by particle size reduction and polydispersity is achieved. Multiphase systems are dispersed and emulsified very efficiently, so that very fine mixtures are prepared. This means that ultrasound accelerates the polymerization significantly over conventional stirring. The resulting polymer shows a higher molecular weight with a lower polydispersity. The product is a molecular-scaled composite material with improved mechanical properties. Sono-Ormosils are distinguished in comparison with conventional gels by a higher density as well as improved thermal stability. This may be a result from the higher degree of polymerization.[9]

See also

References
  1. Li CY, et al. (1992). "ORMOSILS as matrices in inorganic-organic nanocomposites for various optical applications". Proc. SPIE. Sol-Gel Optics II. 1758 — Sol-Gel Optics II: 410–9. Bibcode:1992SPIE.1758..410L. doi:10.1117/12.132033.
  2. For biotechnological applications of nanoparticles in general, see e.g.
    Salata O (April 2004). "Applications of nanoparticles in biology and medicine". Journal of Nanobiotechnology. 2 (1): 3. doi:10.1186/1477-3155-2-3. PMC 419715. PMID 15119954..
  3. Ellen Goldbaum, Using nanoparticles, in vivo gene therapy activates brain stem cells; Medical News Today, 2005 July. Accessed 2007 May.
  4. Yin, F.; et al. (2015). "Folic acid-conjugated organically modified silica nanoparticles for enhanced targeted delivery in cancer cells and tumor in vivo". Journal of Materials Chemistry B. 3 (29): 6081–6093. doi:10.1039/C5TB00587F.
  5. Scandura, G.; et al. (2016). "Nanoflower‐like Bi2WO6 encapsulated in ORMOSIL as a novel photocatalytic antifouling and foul‐release coating". Chemistry: A European Journal. 22 (21): 7063–7067. doi:10.1002/chem.201600831. PMID 26945837.
  6. Crombie JF (5 May 2006). "Coating protects organic materials from photodegradation". Chemical Technology.
    Parejo PG, Zayat M, Levy D (2006). "Highly efficient UV-absorbing thin-film coatings for protection of organic materials against photodegradation". J. Mater. Chem. 16 (22): 2165–9. doi:10.1039/b601577h.
  7. F. J. Duarte, Solid-state multiple-prism grating dye-laser oscillator, Appl. Opt. 33, 3857-3860 (1994).
  8. "Sonochemical Reaction and Synthesis".
  9. Rosa-Fox, N. de la; Pinero, M.; Esquivias, L. (2002): Organic-Inorganic Hybrid Materials from Sonogels. 2002nd
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