Nezha Badi

Liquid-Phase Synthesis of Block Copolymers Containing Sequence-Ordered Segments

Monodisperse sequence-defined oligomers have been synthesized in solution in the absence of protecting groups. These structures have been prepared stepwise using two consecutive chemoselective reactions: 1,3-dipolar cycloaddition of terminal alkynes and azides and amidification of carboxylic acids with primary amines. These oligomers were efficiently constructed on either a conventional solid support (commercial Wang resin) or tailor-made soluble polystyrene supports synthesized by atom-transfer radical polymerization. The latter approach was found to be very versatile. Indeed, well-defined soluble macromolecular supports allowed not only the synthesis and cleavage of defined oligomers (i.e., sacrificial support) but also the preparation of noncleavable block copolymers containing sequence-defined segments.

PEG-based thermogels: Applicability in physiological media

Novel biocompatible thermogels have been synthesized and characterized. The hydrogelators were synthesized by atom transfer radical copolymerization of 2-(2-methoxyethoxy)ethyl methacrylate (MEO(2)MA) and oligo(ethylene glycol) methyl ether methacrylate (OEGMA(475), M(n)=475 g mol(-1) or OEGMA(300), M(n)=300 g mol(-1)) in the presence of a 4-arm star poly(ethylene glycol) (PEG) macroinitiator. The formed macromolecules possess a permanently hydrophilic PEG core and thermoresponsive P(MEO(2)MA-co-OEGMA) outer-blocks. These star-block architectures exhibit an inverse thermogelation behavior in aqueous medium. Typically, above their lower critical solution temperature (LCST), the thermoresponsive P(MEO(2)MA-co-OEGMA) precipitate, thus forming physical crosslinks, which are stabilized in water by hydrophilic PEG bridges. This thermo-induced sol-gel transition can be adjusted within a near-physiological range of temperature by simply varying the composition of the thermoresponsive segments. Moreover, these novel hydrogelators formed free-standing gels in various buffer solutions (e.g., PBS, Tris, MOPS, bicine and HEPES) and in cell culture media. In saline solutions, a weak salting-out effect was observed. However, other components of physiological media (e.g., buffering agents, amino acids, vitamins, proteins) did not hinder the thermogelation process. Hence, these novel thermogels appear as highly attractive candidates for applications in biosciences.

Smart bioactive surfaces

The purpose of this highlight is to define the emerging field of bioactive surfaces. In recent years, various types of synthetic materials capable of “communicating” with biological objects such as nucleic acids, proteins, polysaccharides, viruses, bacteria or living cells have been described in the literature. This novel area of research certainly goes beyond the traditional field of smart materials and includes different types of sophisticated interactions with biological entities, such as reversible adhesion, conformational control, biologically-triggered release and selective permeation. These novel materials may be 2D planar surfaces as well as colloidal objects or 3D scaffolds. Overall, they show great promise for numerous applications in biosciences and biotechnology. For instance, practical applications of bioactive surfaces in the fields of bioseparation, cell engineering, biochips and stem-cell differentiation are briefly discussed herein.

Well-defined synthetic polymers with a protein-like gelation behavior in water

Homopolymers of N-acryloyl glycinamide were prepared by reversible addition-fragmentation chain transfer polymerization in water. The formed macromolecules exhibit strong polymer-polymer interactions in aqueous milieu and therefore form thermoreversible physical hydrogels in pure water, physiological buffer or cell medium.

Smart Polymer Surfaces: Concepts and Applications in Biosciences

Stimuli-responsive macromolecules (i.e., pH-, thermo-, photo-, chemo-, and bioresponsive polymers) have gained exponential importance in materials science, nanotechnology, and biotechnology during the last two decades. This chapter describes the usefulness of this class of polymer for preparing smart surfaces (e.g., modified planar surfaces, particles surfaces, and surfaces of three-dimensional scaffolds). Some efficient pathways for connecting these macromolecules to inorganic, polymer, or biological substrates are described. In addition, some emerging bioapplications of smart polymer surfaces (e.g., antifouling surfaces, cell engineering, protein chromatography, tissue engineering, biochips, and bioassays) are critically discussed.

Precision PEGylated Polymers Obtained by Sequence‐Controlled Copolymerization and Postpolymerization Modification

Copolymers containing water-soluble poly(ethylene glycol) (PEG) side chains and precisely controlled functional microstructures were synthesized by sequence-controlled copolymerization of donor and acceptor comonomers, that is, styrene derivatives and N-substituted maleimides. Two routes were compared for the preparation of these structures: a) the direct use of a PEG-styrene macromonomer as a donor comonomer, and b) the use of an alkyne-functionalized styrenic comonomer, which was PEGylated by copper-catalyzed alkyne-azide cycloaddition after polymerization. The latter method was found to be the most versatile and enabled the synthesis of high-precision copolymers. For example, PEGylated copolymers containing precisely positioned fluorescent (e.g. pyrene), switchable (e.g. azobenzene), and reactive functionalities (e.g. an activated ester) were prepared.