How Does the Branching Effect of Macromonomer Influence the Polymerization, Structural Features, and Solution Properties of Long-Subchain Hyperbranched Polymers?

Hao, Nairong; Duan, Xiaozheng; Yang, Hongjun; Umair, Ahmad; Zhu, Mo; Zaheer, Muhammad; Yang, Jinxian; Li, Lianwei

doi:10.1021/acs.macromol.8b02364

Cited by 24 publications

(28 citation statements)

References 85 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…According to the viscosity trend and microstructure analysis, it seemed that only V3 could be considered as a true hyperbranched copolyester while both V1 and V2 could be regarded more as branched copolyesters only. [25] Figure 3b shows the size distribution profiles of the copolyesters studied at different pH (3)(4)(5)(6)(7)(8)(9). Distribution profile of linear PVA molecules at pH 7 was also included for reference.…”

Section: Analysis Of Intrinsic Viscosity and Hydrodynamic Sizementioning

confidence: 99%

Branched/Hyperbranched Copolyesters from Poly(vinyl alcohol) and Citric Acid as Delivery Agents and Tissue Regeneration Scaffolds

Sengupta

Singh

Dutta

et al. 2021

Macro Chemistry & Physics

View full text Add to dashboard Cite

Multifunctional branched/hyperbranched copolymers from poly(vinyl alcohol) (PVA) and citric acid (CA) are synthesized by varying the mole compositions of PVA and CA and are used as a prospective vehicle for encapsulation and release of bioactive molecules and as a potential scaffold for cell adhesion and growth. The branched architecture is established from spectroscopy and rheological measurements. All the copolymers have shown a lower hydrodynamic size and viscosity than the linear, high molecular weight PVA because of spherical and more compact architecture. Importantly, the size of the highly branched copolymer is found independent of pH which proved that the branch ends are capped with OH groups. Lower viscosity at equivalent solid content, biocompatibility, high antibacterial property, and presence of adequate macromolecular voids make the branched/hyperbranched copolymers a potential platform for encapsulation and release of gentamicin and other bioactive molecules. The macromolecular voids and chain end functionality also promote adhesion and growth of differentiated primary cells as well as undifferentiated stem cells implying that the copolyester can also be used as a potential 2D/3D scaffold for tissue engineering applications.

show abstract

Section: Analysis Of Intrinsic Viscosity and Hydrodynamic Sizementioning

confidence: 99%

Branched/Hyperbranched Copolyesters from Poly(vinyl alcohol) and Citric Acid as Delivery Agents and Tissue Regeneration Scaffolds

Sengupta

Singh

Dutta

et al. 2021

Macro Chemistry & Physics

View full text Add to dashboard Cite

show abstract

“…[26][27][28] In addition, we synthesized the AB n (n > 2) LHPs with AB n (n > 2) macromonomer for the first time, and studied the relationship between branching pattern and solution properties. [29,30] It is worth mentioning that in our recent work, AB 2 hyperbranched polystyrenesulfonate were successfully synthesized by soft sulfonation with acetyl sulfate as the the sulfonating reagent, using AB 2 hyperbranched polystyrene with total carbon branching linkage as the precursor. [31] The results clearly prove that the total carbon branching linkage has an incomparable stability advantage over ester linkage under the condition of sulfonated PPM, indicating that the stability of the branch point in the PPM process is very important.…”

Section: Introductionmentioning

confidence: 99%

“…Long‐subchain hyperbranched polymers (LHPs) with long linear chains between every two branching points have received considerable attention in the past two decades, since it can combine the excellent mechanical properties of linear polymers with the special physical properties of hyperbranched polymers. Three main methods have been reported to synthesize LHPs: (1) A 2 +B 3 approach, (2) self‐condensing vinyl polymerization (SCVP) approach, and (3) macromonomer AB n approach . In vein of the A 2 +B 3 approach, Long et al.…”

Section: Introductionmentioning

confidence: 99%

“…Three main methods have been reported to synthesize LHPs: (1) A 2 + B 3 approach, [20,21] (2) self-condensing vinyl polymerization (SCVP) approach, [22,23] and (3) macromonomer AB n approach. [24][25][26][27][28][29][30][31][32] In vein of the A 2 + B 3 approach, Long et al synthesized a series of LHPs such as hyperbranched poly(ether ester)s, and polysulfone ionomers by polycondensation of an A 2 chain and a B 3 monomer. [21] Alternatively, Gao et al [22] synthesized hyperbranched poly(tertiary amino methacrylate)s with hydrophilic core and hydrophobic shell via SCVP methodology.…”

Section: Introductionmentioning

confidence: 99%

“…adopted this AB 2 macromonomer approach to construct a number of LHPs model systems by the Williamson coupling reaction, and they established a few structure‐property relationships about the rheological properties and the phase behavior of LHPs; Our group synthesized LHPs with controllable branched subchain length by using the seesaw‐type macromonomer . In addition, we synthesized the AB n (n>2) LHPs with AB n (n>2) macromonomer for the first time, and studied the relationship between branching pattern and solution properties . It is worth mentioning that in our recent work, AB 2 hyperbranched polystyrenesulfonate were successfully synthesized by soft sulfonation with acetyl sulfate as the the sulfonating reagent, using AB 2 hyperbranched polystyrene with total carbon branching linkage as the precursor .…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Preparation of Functional Long‐Subchain Hyperbranched Polystyrenes via Post‐polymerization Modification: Study on the Critical Role of Chemical Stability of Branching Linkage

et al. 2020

Self Cite

View full text Add to dashboard Cite

Post-polymerization modification (PPM) is one of the most powerful strategy for preparing polymers with functional groups that cannot be synthesized by direct polymerization. So far, numerous experimental efforts have been devoted to the stability issue of monomer structures during the PPM process, but little attention was paid to chemical linkages. However, for hyperbranched polymers, a minor change of linkage unit could lead to a significant influence on the overall stability and performance of polymer materials. In this work, we investigated the chemical stability of long-subchain hyperbranched polystyr-enes with ester, aryl ether, and carbon-carbon bonds as branching linkages under a few most popular PPM conditions, including NaOH hydrolysis reaction, TFA-promoted hydrolysis reaction, BBr 3-catalyzed methoxy-hydroxyl conversion reaction, and LiAlH 4 carbonyl reduction reaction. Related results are summarized into a synthetic route map that can provide practical and intuitive guidance for preparing functional longsubchain hyperbranched polystyrenes and other type of polymers by PPM for future applications.

show abstract

Polyelectrolyte Complexes between Hyperbranched and Linear Polysaccharides: Fucoidan/Chitosan

Gasilova,

Poshina,

Sitnikova

et al. 2023

Chin J Polym Sci

View full text Add to dashboard Cite

How Does the Branching Effect of Macromonomer Influence the Polymerization, Structural Features, and Solution Properties of Long-Subchain Hyperbranched Polymers?

Cited by 24 publications

References 85 publications

Branched/Hyperbranched Copolyesters from Poly(vinyl alcohol) and Citric Acid as Delivery Agents and Tissue Regeneration Scaffolds

Branched/Hyperbranched Copolyesters from Poly(vinyl alcohol) and Citric Acid as Delivery Agents and Tissue Regeneration Scaffolds

Preparation of Functional Long‐Subchain Hyperbranched Polystyrenes via Post‐polymerization Modification: Study on the Critical Role of Chemical Stability of Branching Linkage

Polyelectrolyte Complexes between Hyperbranched and Linear Polysaccharides: Fucoidan/Chitosan

Contact Info

Product

Resources

About