Star Polymers

Ren, Jing; McKenzie, Thomas G.; Fu, Qiang; Wong, Edgar H. H.; Xu, Jiangtao; An, Zesheng; Shanmugam, Sivaprakash; Davis, Thomas P.; Boyer, Cyrille; Qiao, Greg G.

doi:10.1021/acs.chemrev.6b00008

Cited by 670 publications

(693 citation statements)

References 565 publications

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“…The choice of this copolymer among the series of the branched samples synthesized is based on our previous research. Namely, this sample was the most efficient polymer matrix for the Ag sol in situ synthesis [24,25,29].…”

Section: Polymer Nanocarriermentioning

confidence: 99%

“…The theoretical [22,23] and experimental [24][25][26][27][28][29] studies of branched polymers provide us with a reason to assume that these macromolecules are more efficient in comparison with linear analogs for the nanosystem in situ synthesis, as flocculants and nanocarriers for drugs, because of a higher local concentration of functional groups capable of reacting with some substances. It was proved by our recent research devoted to the encapsulation of cis-Pt into a branched star-like polymer with dextran core and grafted polyacrylamide-co-polyacrylic acid arms.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Aggregation Processes in Hybrid Nanosystem Polymer/Nanosilver/Cisplatin

Kutsevol¹,

Naumenko²,

Chumachenko³

et al. 2018

Ukr. J. Phys.

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AGGREGATION PROCESSES IN HYBRID NANOSYSTEM POLYMER/NANOSILVER/CISPLATINHybrid nanosystems consisting of star-like copolymer Dextran-graft-Polyacrylamide in the anionic form (D-g-PAA(PE)), silver nanoparticles (AgNPs), and cisplatin (cis-Pt) have been synthesized in water and characterized by TEM, DLS, FTIR, and UV-Vis spectroscopies. It is shown that cis-Pt forms a complex with carboxylate groups of the polymer. For the ternary system Polymer/AgNPs/cis-Pt, a change in the hydrophilic-hydrophobic balance of a polymer molecule (due to the complexation with cis-Pt) and the aggregation of macromolecules, as well as to some agglomeration AgNPs, are revealed. The decrease of the antitumor efficiency of the hybrid ternary nanosystem Polymer/AgNPs/cis-Pt in comparison with the Polymer/cis-Pt system is discussed.K e y w o r d s: silver nanoparticles, branched polymer, polyelectrolyte, cisplatin, aggregation.

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Section: Polymer Nanocarriermentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Aggregation Processes in Hybrid Nanosystem Polymer/Nanosilver/Cisplatin

Kutsevol¹,

Naumenko²,

Chumachenko³

et al. 2018

Ukr. J. Phys.

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“…Although topology-changeable molecules have been limited mainly to small molecules until 2000, recent progress in synthetic organic and polymer chemistry has made the topology change of polymer molecules possible, [67][68][69][70] as discussed in the section 'Bimolecular linking directed toward the linear-branched polymer topology transformation'. Compared with linear polymers, corresponding polymers with different topologies, such as star polymers, [71][72][73] cyclic polymers, 12,59,60 dendrimers [74][75][76] and hyperbranched polymers, 16 generally have a smaller hydrodynamic volume, lower solution viscosity and less polymer entanglement in bulk. Therefore, the development of topology-transformable polymers in response to a specific stimulus is particularly attractive to control the polymer properties and to construct novel stimuli-responsive materials.…”

Section: Topology-transformable Polymers T Takata and D Aokimentioning

confidence: 99%

Topology-transformable polymers: linear–branched polymer structural transformation via the mechanical linking of polymer chains

Takata

Aoki

2017

Polym J

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In this review article, we discuss the synthesis and dynamic nature of macromolecular systems that have mechanically linked polymer chains capable of undergoing a topology transformation driven by a rotaxane molecular switch. The rotaxane linking of polymer chains plays a crucial role in these systems. A linear polymer possessing a crown ether/sec-ammonium salt-type [1] rotaxane moiety at the axle chain terminal was prepared via the rotaxane linking of a single polymer chain. A linear-cyclic polymer topology transformation was achieved via the movement of the wheel component from one end to the other end of the axle component using the rotaxane macromolecular switch function. The successful synthesis of a macromolecular [2]rotaxane (M2R) possessing a single polymer axle and one crown ether wheel led to a variety of unique applications, such as the development of topology-transformable polymers and the synthesis of rotaxane crosslinked polymers (RCPs). The introduction of a polymer chain to the wheel component of M2R (rotaxane linking of two polymer chains) produced a rotaxane-linked AB block copolymer that transformed its topology from linear to branched. Furthermore, a rotaxane-linked three-component polymer and an ABC triblock copolymer were synthesized and transformed to the corresponding 3-arm star (co)polymers, and the transformation was confirmed by measuring the hydrodynamic volume change. The structural transformation of 4-arm and 6-arm star polymers was also accomplished using the dynamic mobility of a similar rotaxane. As a useful application, M2R-based vinylic crosslinkers (RCs) were prepared and applied to the synthesis of RCPs, whereby the addition of RCs into radical polymerization systems of vinyl monomers afforded polymers with excellent toughness by enhancing both of tradeoff properties that cannot be achieved using typical covalent crosslinkers.

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“…In comparison with linear polymers of similar molecular weight, star polymers have considerably lower viscosity and as such are useful as rheology control agents. [3,4] Moreover, star polymers are finding increasing application in nanomedicine, and as nanocontainers and nanoreactors. [5] Although star polymers can be prepared via cationic or anionic polymerization, [6,7] the reaction conditions required are challenging and have limited the extent to which star polymers have found widespread application.…”

Section: Introductionmentioning

confidence: 99%

Synthesis of Star Polymers by RAFT Polymerization as Versatile Nanoparticles for Biomedical Applications

Qiao

Whittaker

et al. 2017

Aust. J. Chem.

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The precise control of polymer chain architecture has been made possible by developments in polymer synthesis and conjugation chemistry. In particular, the synthesis of polymers in which at least three linear polymeric chains (or arms) are tethered to a central core has yielded a useful category of branched architecture, so-called star polymers. Fabrication of star polymers has traditionally been achieved using either a core-first technique or an arm-first approach. Recently, the ability to couple polymeric chain precursors onto a functionalized core via highly efficient coupling chemistry has provided a powerful new methodology for star synthesis. Star syntheses can be implemented using any of the living polymerization techniques using ionic or living radical intermediates. Consequently, there are innumerable routes to fabricate star polymers with varying chemical composition and arm numbers. In comparison with their linear counterparts, star polymers have unique characteristics such as low viscosity in solution, prolonged blood circulation, and high accumulation in tumour regions. These advantages mean that, far beyond their traditional application as rheology control agents, star polymers may also be useful in the medical and pharmaceutical sciences. In this account, we discuss recent advances made in our laboratory focused on star polymer research ranging from improvements in synthesis through to novel applications of the product materials. Specifically, we examine the core-first and arm-first preparation of stars using reversible addition-fragmentation chain transfer (RAFT) polymerization. Further, we also discuss several biomedical applications of the resulting star polymers, particularly those made by the arm-first protocol. Emphasis is given to applications in the emerging area of nanomedicine, in particular to the use of star polymers for controlled delivery of chemotherapeutic agents, protein inhibitors, signalling molecules, and siRNA. Finally, we examine possible future developments for the technology and suggest the further work required to enable clinical applications of these interesting materials.

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Star Polymers

Cited by 670 publications

References 565 publications

Aggregation Processes in Hybrid Nanosystem Polymer/Nanosilver/Cisplatin

Aggregation Processes in Hybrid Nanosystem Polymer/Nanosilver/Cisplatin

Topology-transformable polymers: linear–branched polymer structural transformation via the mechanical linking of polymer chains

Synthesis of Star Polymers by RAFT Polymerization as Versatile Nanoparticles for Biomedical Applications

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