Mercedes Perez Mendez
Institute of Polymer Science and Technology, Spain
Posters & Accepted Abstracts: J Material Sci Eng
Cholesteric Liquid Crystal Polymers (ChLCP), synthetized in our laboratory through a stereoselective polycondensation reaction, as multifunctional optically active materials, have been extensively characterized by NMR, Raman spectroscopy, steady-state fluorescence, molecular modeling, and SAXS/WAXS. These ChLCP behave both as thermotropic and lyotropic, confering interesting macromolecular properties indicative of potential application on the biomedical and engineering field. The amphiphilic nature of their monomers makes them polymerize along helical chains, being able to entrap smaller molecules inside, such as Lycopene. They have shown to be biocompatible against macrophages and fibroblasts cellular lines, and able to interact with biomacromolecules such as lipids (both neutral and cationic) and nucleic acids, the structures of the complexes being identified by synchrotron radiation source. Cationic liposomial/surfactant systems based on our CLCP were developed which entrapped DNA plasmids, acting as non viral cationic vectors for gene therapy, which successfully transfected in several tumor cell lines. Cationic functionalized ChLCP have been synthesized, dispersed in TAE and directly complexed with commercial DNA of increasing complexity: [Poly-A]; [Poly-C]; [Poly-G]; [PolydT]; [PolyC-PolyG]; [PolyAC-PolydT]; commercial calf thymus DNA and plasmid. Three different proportions ChLCP:DNA were prepared: (1:2), (1:1), and (2:1) respectively by mixing and digesting for 12h in a swinging shaker. The structure of the cationic complexes has been studied by SAXS at the BM16 beamline at ESRF, at room temperature. Neutron scattering experiments, had shown sufficient contrast (scattering length density difference) between new cholesteric PTOBEE-Ammonium (1.5 to 1.9x1010/ cm2) and polynucleotide [PolyC-PolyG] (3.32x1010/cm2) for contrast variation SANS experiments. This experiment was successfully performed at NIST. These ChLCP also show optoelectronic behavior. When dispersed in solution, directly self-organize on metal and semiconductor surfaces, such as: Si(111); Pt / TiO2 / SiO2 /Si(001), Ag, Au, either colloidal spheres or thin layers. Under spin coating controlled conditions growth has been obtained in multilayer ordered structures. Their helical macromolecules, uncoil and get adsorbed on the metal surface, via Ï?-interaction, with the aromatic rings extended parallel to the interface and the aliphatic chains directed towards the bulk solution. The interaction of these ChLCP with metals could be applied to the design of functionalized surfaces provided with physico-chemical properties of interest.
Email: perezmendez@ictp.csic.es
Journal of Material Sciences & Engineering received 3677 citations as per Google Scholar report
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