The first ferrocene-containing epoxide monomer, ferrocenyl glycidyl ether (fcGE), is introduced. The monomer has been copolymerized with ethylene oxide (EO). This leads to electroactive, water-soluble, and thermoresponsive poly(ethylene glycol) (PEG) derived copolyethers. Anionic homo-and copolymerization of fcGE with EO was possible. Molecular weights could be varied from 2000 to 10 000 g mol −1 , resulting in polymers with narrow molecular weight distribution (M w /M n = 1.07−1.20). The ferrocene (fc) content was varied from 3 to 30 mol %, obtaining watersoluble materials up to 10 mol % incorporation of the apolar ferrocenyl comonomer. Despite the steric bulk of fcGE, random copolymers were obtained, as confirmed via detailed 1 H NMR kinetic measurements as well as 13 C NMR studies of the polymer microstructure, including detailed triad characterization. In addition, the poly(fcGE) homopolymer has been prepared. All water-soluble copolyethers with fc side chains exhibited a lower critical solution temperature (LCST) in the range 7.2−82.2 °C in aqueous solution, depending on the amount of fcGE incorporated. The LCST is further tunable by oxidation/reduction of ferrocene, as demonstrated by cyclic voltammetry. Investigation of the electrochemical properties by cyclovoltammetry revealed that the iron centers can be oxidized reversibly. Further, to evaluate the potential for biomedical application, cell viability tests of the fc-containing PEG copolymers were performed on a human cervical cancer cell line (HeLa), revealing good biocompatibility only in the case of low amounts of fcGE incorporated (below 5%). Significant cytotoxic behavior was observed with fcGE content exceeding 5%. The ferrocenesubstituted copolyethers are promising for novel redox sensors and create new options for the field of organometallic (co)polymers in general.
Natural macromolecules, i.e., sequence-controlled polymers, build the basis for life. In synthetic macromolecular chemistry, reliable tools for the formation of sequence-controlled macromolecules are rare. A robust and efficient chain-growth approach based on the simultaneous living anionic polymerization of sulfonamide-activated aziridines for sequence control of up to five competing monomers resulting in gradient copolymers is presented. The simultaneous azaanionic copolymerization is monitored by real-time (1) H NMR spectroscopy for each monomer at any time during the reaction. The monomer sequence can be adjusted by the monomer reactivity, depending on the electron-withdrawing effect by the sulfonamide (nosyl-, brosyl-, tosyl-, mesyl-, busyl) groups. This method offers unique opportunities for sequence control by competing copolymerization: a step forward to well-engineered synthetic polymers with defined microstructures.
Detailed understanding of the monomer sequence distribution in carbanionic copolymerization was achieved by direct online monitoring of copolymerizations in an NMR tube. Obtaining detailed knowledge of the changing monomer concentration in stock during the reaction, this technique permits to determine the incorporation probability for each monomer at every position of the polymer chain. An in situ kinetic study of two different carbanionic copolymerizations has been carried out. On the one hand, the copolymerization of the structurally similar, protected hydroxystyrene derivatives, p-(1-ethoxy ethoxy)styrene (pEES) and 4-tert-butoxystyrene (tBuOS), and on the other hand the copolymerization of the chemically different monomers, styrene (S) and pEES, have been studied. Whereas in the first case a slight deviation from an ideal random copolymerization was observed, the latter copolymerization leads to gradient copolymers. Real-time 1 H NMR spectroscopy gave detailed insight into the reaction behavior at every stage of the copolymerization and leads to precise understanding of the resulting gradient structures.
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