To afford chiral polyisocyanides with thermoresponsiveness may open new gates to enhance their functionality and to broaden their applications. Herein, we report the synthesis of a series of novel polyisocyanides carrying oligoethylene glycols (OEGs) modified dipeptides as the pendent groups. These polyisocyanides not only show different chiroptical properties but also possess characteristic thermoresponsive behavior. The corresponding monomers carrying different OEG units in the periphery are water-soluble, thus allowing their polymerization feasible in aqueous medium with NiCl 2 as the catalyst. For comparison, polyisocyanides were also prepared in organic solvents, such as dichloromethane and tetrahydrofuran. The effects of solvent and polymerization temperature as well as chemical structures of the pendants on the chiroptical properties of the resulting polymers were examined. The characteristic thermoresponsive behavior of these chiral polymers was investigated by 1 H NMR spectroscopy and turbidity measurements using UV/vis spectroscopy. The thermally induced aggregation processes were also followed by dynamic light scattering. It was found that the phase transition temperatures of these polymers were significantly influenced not only by the overall hydrophilicity but also by their secondary structures.
Thermoresponsive dendronized polymers, displaying remarkable phase behavior, are currently being studied for their potential exploitation as polymeric sensors and biomaterials.Understanding the conformational transitions occurring at the LCST is essential for improved design and translation of these polymers. The combination of NMR and molecular dynamics simulations opens a unique window onto the thermal behavior, showing that the peripheries of the dendrons, while driving the thermal properties, largely retain mobility above the critical temperature. The cores of the dendrons and the polymeric main chain are highly rigid below the thermal transition and increasingly so above the LCST. Both the experimental and computational studies reveal stretching of the interior segments of the dendrons with associated changes in spatial arrangements of the structural units. Furthermore, diffusion-ordered NMR and DLS below and above the LCST show a further hierarchy of dynamics within different size aggregates. The combination of the detailed experimental study and molecular dynamics simulations provides a detailed understanding of thermoresponsive behavior of these dendronized polymers.
The synthesis and thermoresponsive behavior of two structural novel comblike polymers are presented, which are constituted by polymethacrylates main chain with dendritic oligoethylene glycol (OEG) side groups spaced with a linear hydrophobic alkyl [PG1(A)] or hydrophilic OEG unit [PG1(G)]. The design of this comblike architecture is to retain the unique thermoresponsive behavior of OEG-based dendritic polymers and, on the other side, to eliminate the tremendous synthesis effort for the dendronized polymer analogues. Their thermoresponsive behavior was investigated with UV/vis and temperature-varied 1H NMR spectroscopy to determine their apparent LCSTs and follow chain dehydration process, respectively. These polymers show sharp and fast transitions with small hystereses. The phase transition temperatures are located in between 27 and 34 °C, which is in the vicinity of physiological temperature, and these transition temperatures are independent of polymer concentration. The thermoresponsiveness of these polymers is also compared with the corresponding macromonomers as well as the densely packed dendronized polymer analogues reported previously, focusing on chemical structure and architecture effects. It was found that the more hydrophobic polymer PG1(A) could form denser aggregates than that of the more hydrophilic polymer PG1(G). On the basis of the exceptional thermoresponsive behavior of these comblike polymers, this architecture is utilized for fabricating polymer sensors. Random copolymerization of the macromonomers with the monomer bearing solvatochromic dye moiety (Disperse Red 1) affords the thermoresponsive copolymers which act as sensitive dual-sensors for both temperature and pH value.
Protein allostery, a chemical-to-mechanical effect that can precisely regulate protein structure, exists in many proteins. Herein, we demonstrate that protein allostery can be used to drive self-assembly for the construction of tunable protein architectures. Calmodulin (CaM) was chosen as a model allosteric protein. Ca -mediated contraction of CaM to a closed state can activate CaM and its ligand to self-assemble into a 1D protein helical microfilament. Conversely, relaxation of CaM to the open state can unwind and further dissociate the helical assemblies. Fine regulation of the protein conformation by tuning the external Ca level allows us to obtain various protein helical nanostructures with tunable helicity. This study offers a new approach toward chemomechanically controlled protein self-assembly.
The first (G1) and second generation (G2) of dendronized copolymers carrying solvatochromic dyes were synthesized, and their thermoresponsive properties investigated. These copolymers were constituted with oligoethylene glycol (OEG)‐based dendrons to afford the thermoresponsiveness and disperse red 1 to act as the dye probe. The possible architecture and structure effects on sensoring were investigated by changing dendron generation from G1 to G2, and the interior structures of G2 polymers from hydrophilic OEG into hydrophobic alkyl chain. The sensoring ability of these copolymers to temperature and solution pH was examined with UV/Vis spectroscopy. Combined with the supports from fluorescence spectroscopy, remarkable thickness effects of dendronized polymers were discovered on the transitions of the dye moieties during the thermally‐induced aggregation process. This work enriches the field of thermoresponsive colorimetric polymeric sensors, and provides an in‐depth understanding of state changes of the dye probe during the thermally‐induced phase transitions within these bulky dendronized polymers. © 2014 Wiley Periodicals, Inc. J. Polym. Sci., Part A: Polym. Chem. 2014, 52, 1706–1713
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