Recent advances in the solution self‐assembly of amphiphilic “rod‐coil” copolymers

Block and graft poly(macrolactone)‐poly(α‐amino acid) copolymers made of l‐alanine and pentadecalactone or globalide respectively, are prepared. A sequential ring‐opening polymerization (ROP) copolymerization route consisting of two stages, the first devoted to the preparation of the amino‐functionalized poly(macrolactone) and the second to the amino‐initiated polymerization of l‐alanine N‐carboxyanhydride (Ala‐NCA), is followed for the synthesis of both types of copolymers. Poly(l‐alanine) segment lengths are accurately controlled by adjusting the macroitiator/Ala‐NCA ratio used for reaction in the second stage. Block copolymers are semicrystalline with the poly(pentadecalactone) block crystallizes well in a separate phase and the poly(α‐amino acid) block arranged in either the α‐helical or β‐sheet structure in a ratio that is depending on composition and temperature. Graft copolymers are amorphous but with the poly(α‐amino acid) side chains arranged in a more or less regular conformation. Nanoparticles with a diameter of around 300 nm and moderate positive Z‐potential can be obtained from the block copolymers by self‐assembling in water whereas graft copolymers are unable to render recognizable objects of nanometer‐dimension under similar conditions.

Section: Introductionmentioning

confidence: 99%

Block and Graft Copolymers Made of 16‐Membered Macrolactones and l‐Alanine: A Comparative Study

Tinajero‐Díaz

Ilarduya

Muñoz‐Guerra

2019

“…Special self-assembled nanostructures are generated in solution by amphiphilic copolymers, in which the hydrophilic and hydrophobic moieties interact separately and very differently with each other and with the external environment. [1][2][3][4] www.advancedsciencenews.com www.mcp-journal.de specialized nanocompartments would allow for unique activities and functions. [26][27][28][29] Therefore, there is a growing interest in understanding the capabilities of amphiphilic random copolymers to self-assemble in different structures in solution.…”

Section: Introductionmentioning

confidence: 99%

Prolate and Temperature‐Responsive Self‐Assemblies of Amphiphilic Random Copolymers with Perfluoroalkyl and Polyoxyethylene Side Chains in Solution

Martinelli

Guazzelli

Galli

et al. 2018

Two amphiphilic random copolymers, PEGMAx‐co‐FAy (x = 90 and 70 mol%), are synthesized by ATRP and their solutions are investigated as a function of solvent, concentration, and temperature by DLS and SANS analyses. Both copolymers self‐assemble in nanostructures by single‐chain folding in water solutions over a wide range of temperatures. The values of the DLS hydrodynamic radius and the SANS radius of gyration are found to be ≈4 nm and ≈3.4–3.7 nm, respectively. Moreover, SANS shows the self‐folded nanoassemblies to be prolated spheroids with a ratio of polar/equatorial axes of ≈5:1 for PEGMA90‐co‐FA10 and ≈2:1 for PEGMA70‐co‐FA30. On heating above a critical temperature Tc, multichain microassemblies are formed that revert back to nanoassemblies on cooling below Tc. This temperature‐responsive transition is fully and sharply reversible.

“…In past decades, advanced achievements have been witnessed in the field of block copolymers . Block copolymers provide extensive scientific interests because of the potential applications in the field of biotechnology, organic electronics, drug delivery, and advanced plastics .…”

Section: Introductionmentioning

confidence: 99%

“…Block copolymers provide extensive scientific interests because of the potential applications in the field of biotechnology, organic electronics, drug delivery, and advanced plastics . In general, the categories of manufacture block copolymers can be summarized in three types: “coil–coil,” “rod–rod,” and “rod–coil” copolymers . Different from common structures, rod–coil copolymers, the ordered polymer manufactures with rigid rod segments, present unusual structures like helices, ribbons, rings, and tubules compared with the flexible counterparts .…”

Section: Introductionmentioning

confidence: 99%

“…In order to construct the needed polymers, precise synthetic strategies are created, for instance, living radical, anionic and cationic polymerizations, ring‐opening polymerization, and functional chain‐ends connection of telechelic polymers . By the prosperity of those establishments, “rod–coil” flourished, however, to obtain rod–coil copolymers with low dispersity and high yield still remains a great challenge to scientists …”

Section: Introductionmentioning

confidence: 99%

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Facile Synthesis of Helical Rod–Coil Block Polymers by the Combination of ATRP and Pd(II)‐Initiated Isocyanides Polymerizations

Liu

Jiang

et al. 2019

A bifunctional initiator containing propargyl bromoisobutyrate and alkyne‐Pd(II) (PBB‐Pd(II)) is designed and synthesized. The propargyl bromoisobutyrate unit of PBB‐Pd(II) can initiate the atom transfer radical polymerization (ATRP) of vinyl monomers, while the Pd(II) complex can initiate the polymerization of phenyl isocyanides. Both the ATRP and Pd(II)‐mediated isocyanide polymerization are proceeded in living/controlled manner. Thus, combining the two living polymerizations, a series of well‐defined block copolymers bearing rod poly(phenyl isocyanide)s and coil poly(acrylate) segments can be facilely prepared in high yield with tunable composition, controlled molar masses (Mns), and narrow molar mass distributions (Mw/Mns). What is more, benefiting from this synthetic strategy, well‐defined core cross‐linked star polymers are readily synthesized. Optically active block copolymers and star polymers can be facilely obtained by using chiral isocyanide monomers due to the formation of predominated one‐handed helix. The chiral star polymers show excellent enantioselective recognition ability in enantioselective crystallization of racemic compounds.