Nonviral Plasmid DNA Carriers Based on N,N'-Dimethylaminoethyl Methacrylate and Di(ethylene glycol) Methyl Ether Methacrylate Star Copolymers.

Star polymers with random and block copolymer arms made of cationic N,N'-dimethylaminoethyl methacrylate (DMAEMA) and nonionic di(ethylene glycol) methyl ether methacrylate (DEGMA) were synthesized via atom transfer radical polymerization (ATRP) and used for the delivery of plasmid DNA in gene therapy. All stars were able to form polyplexes with plasmid DNA. The structure and size of the polyplexes were precisely determined using light scattering and cryo-TEM microscopy. The hydrodynamic radius of a complex of DNA with star was dependent on the architecture of the star arms, the DEGMA content and the number of amino groups in the star compared to the number of phosphate groups of the nucleic acid (N/P ratio). The smallest polyplexes (Rh90°âˆ¼50 nm) with positive zeta potentials (∼15 mV) were formed of stars with N/P=6. The introduction of DEGMA into the star structure caused a decrease of polyplex cytotoxicity in comparison to DMAEMA homopolymer stars. The overall transfection efficiency using HT-1080 cells showed that the studied systems are prospective gene delivery agents. The most promising results were obtained for stars with random copolymer arms of high DEGMA content.

Photocrosslinking of Polyglycidol and Its Derivative: Route to Thermoresponsive Hydrogels.

Hydrogels of biologically well-tolerated, high-molar-mass polyglycidol (PGl) and its thermoresponsive derivative poly(glycidol-co-ethyl glycidyl carbamate) have been obtained by direct UV crosslinking in the solid state. Polymers with molar masses up to 1.45 × 106 g mol-1 were crosslinked in the presence of benzophenone or (4-benzoylbenzyl)trimethylammonium chloride as photosensitizers. The photosensitizer concentration was varied from 2 to 10 wt%. The influence of polymer composition and photosensitizer type and amount on the crosslinking efficiency, swelling and temperature behavior of the obtained hydrogels was investigated. The photocrosslinking of PGl and poly(glycidol-co-ethyl glycidyl carbamate) led to hydrogels with swelling degrees up to 1700%. The swelling degrees of the hydrogels decreased with the increase of the environmental temperature indicating the thermoresponsive nature of gels. The swelling of obtained gels can be controlled by varying the composition of the copolymer precursor and by the network density.

Stable star polymer nanolayers and their thermoresponsiveness as a tool for controlled culture and detachment of fibroblast sheets.

In this study, we describe novel thermoresponsive star copolymer surfaces used for the first time for the culture of fibroblast sheets, followed by their detachment, controlled by a change in temperature. To date, no star polymers, or their layers, have been used for this purpose. A "grafting to" strategy was applied to obtain poly[oligo(ethylene glycol) methacrylate] star layers on functionalized solid supports. Atom transfer radical polymerization of oligo(ethylene glycol) methacrylates and glycidyl methacrylate initiated with modified poly(arylene oxindole) yielded stars with molar masses up to Mn = 380 000 g mol-1. Stars were attached to a glass substrate via the reaction between the functional epoxy groups of the stars with the amine groups of the functionalized substrate. The thickness of the layer was related to the dimensions of isolated stars in solution, which showed that multilayers were obtained. Above the phase transition temperature, polymer nanolayers were hydrophobic, thus enabling the growth of fibroblasts on their surfaces and the formation of a cell sheet. Decreasing the temperature below the phase transition temperature made the star surfaces hydrophilic. This eliminated the affinity of the surface for cells and led to detachment of the intact fibroblast sheet. These observations have shown for the first time that the star polymer architecture favors the detachment of cell sheets as compared to linear polymer analogues grafted onto supports, thus reducing the time of this process. Knowledge of the influence of the polymer topology on layer properties and cell growth and detachment can aid in the development of polymeric materials for tissue culture applications.