Functionalization of PEG-PMPC-based polymers for potential theranostic applications

Ning CHEN, Sidi LI, Xueping LI, Lixia LONG, Xubo YUAN, Xin HOU, Jin ZHAO

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Front. Mater. Sci. ›› 2021, Vol. 15 ›› Issue (2) : 280-290. DOI: 10.1007/s11706-021-0554-8
RESEARCH ARTICLE
RESEARCH ARTICLE

Functionalization of PEG-PMPC-based polymers for potential theranostic applications

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Abstract

The synergistic effect of polyethylene glycol (PEG) and poly(2-methacryloyloxyethyl phosphorylcholine) (PMPC) can effectively reduce the protein absorption, which is beneficial to theranostics. However, PEG–PMPC-based polymers have rarely been used as nanocarriers in the theranostic field due to their limited modifiability and weak interaction with other materials. Herein, a plain method was proposed to endow them with the probable ability of loading small active agents, and the relationship between the structure and the ability of loading hydrophobic agents was explored, thus expanding their applications. Firstly, mPEG–PMPC or 4-arm-PEG–PMPC polymer was synthesized by atom transfer radical polymerization (ATRP) using mPEG-Br or 4-arm-PEG-Br as the macroinitiator. Then a strong hydrophobic segment, poly(butyl methacrylate) (PBMA), was introduced and the ability to load small hydrophobic agents was further explored. The results showed that linear mPEG–PMPC–PBMA could form micelles 50–80 nm in size and load the hydrophobic agent such as Nile red efficiently. In contrast, star-like 4-arm-PEG–PMPC–PBMA, a monomolecular micelle (10–20 nm), could hardly load any hydrophobic agent. This work highlights effective strategies for engineering PEG–PMPC-based polymers and may facilitate the further application in numerous fields.

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polyethylene glycol / poly(2-methacryloyloxyethyl phosphorylcholine) / atom transfer radical polymerization / self-assembly / monomolecular micelles

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Ning CHEN, Sidi LI, Xueping LI, Lixia LONG, Xubo YUAN, Xin HOU, Jin ZHAO. Functionalization of PEG-PMPC-based polymers for potential theranostic applications. Front. Mater. Sci., 2021, 15(2): 280‒290 https://doi.org/10.1007/s11706-021-0554-8

References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]
Fang Z, Sun Y, Cai C, . Targeted delivery of DOX by transferrin conjugated DSPE-PEG nanoparticles in leukemia therapy. International Journal of Polymeric Materials and Polymeric Biomaterials, 2021, 70(1): 27–36
CrossRef Google scholar
[2]
Cabral H, Miyata K, Osada K, . Block copolymer micelles in nanomedicine applications. Chemical Reviews, 2018, 118(14): 6844–6892
CrossRef Pubmed Google scholar
[3]
Masoumi S, Esmaeili A. New method of creating hybrid of buprenorphine loaded rifampin/polyethylene glycol/alginate nanoparticles. International Journal of Biological Macromolecules, 2020, 159: 204–212
CrossRef Pubmed Google scholar
[4]
Baharifar H, Khoobi M, Arbabi Bidgoli S, . Preparation of PEG-grafted chitosan/streptokinase nanoparticles to improve biological half-life and reduce immunogenicity of the enzyme. International Journal of Biological Macromolecules, 2020, 143: 181–189
CrossRef Pubmed Google scholar
[5]
Chien H W, Yu J, Li S T, . An in situ poly(carboxybetaine) hydrogel for tissue engineering applications. Biomaterials Science, 2017, 5(2): 322–330
CrossRef Pubmed Google scholar
[6]
Mondini S, Leonzino M, Drago C, . Zwitterion-coated iron oxide nanoparticles: Surface chemistry and intracellular uptake by hepatocarcinoma (HepG2) cells. Langmuir, 2015, 31(26): 7381–7390
CrossRef Pubmed Google scholar
[7]
Chu H, Liu N, Wang X, . Morphology and in vitro release kinetics of drug-loaded micelles based on well-defined PMPC-b-PBMA copolymer. International Journal of Pharmaceutics, 2009, 371(1‒2): 190–196
CrossRef Pubmed Google scholar
[8]
Müllner M, Cui J, Noi K F, . Surface-initiated polymerization within mesoporous silica spheres for the modular design of charge-neutral polymer particles. Langmuir, 2014, 30(21): 6286–6293
CrossRef Pubmed Google scholar
[9]
Zhou L, Tan G X, Ning C Y. Modification of biomaterials surface by mimetic cell membrane to improve biocompatibility. Frontiers of Materials Science, 2014, 8(4): 325–331
CrossRef Google scholar
[10]
Nie S. Understanding and overcoming major barriers in cancer nanomedicine. Nanomedicine, 2010, 5(4): 523–528
CrossRef Pubmed Google scholar
[11]
Zhou H, Fan Z, Li P Y, . Dense and dynamic polyethylene glycol shells cloak nanoparticles from uptake by liver endothelial cells for long blood circulation. ACS Nano, 2018, 12(10): 10130–10141
CrossRef Pubmed Google scholar
[12]
Wang C. Bio-cluster nano-bomb for cancer drug delivery: Efficacious fire at the target. Science Bulletin, 2015, 60(3): 403–404
CrossRef Google scholar
[13]
Ou H, Cheng T, Zhang Y, . Surface-adaptive zwitterionic nanoparticles for prolonged blood circulation time and enhanced cellular uptake in tumor cells. Acta Biomaterialia, 2018, 65: 339–348
CrossRef Pubmed Google scholar
[14]
Pombo-Garcia K, Weiss S, Zarschler K, . Zwitterionic polymer-coated ultrasmall superparamagnetic iron oxide nanoparticles with low protein interaction and high biocompatibility. ChemNanoMat, 2016, 2(10): 959–971
CrossRef Google scholar
[15]
Wang J, Asghar S, Yang L, . Chitosan hydrochloride/hyaluronic acid nanoparticles coated by mPEG as long-circulating nanocarriers for systemic delivery of mitoxantrone. International Journal of Biological Macromolecules, 2018, 113: 345–353
CrossRef Pubmed Google scholar
[16]
Raut P W, Shitole A A, Khandwekar A, . Engineering biomimetic polyurethane using polyethylene glycol and gelatin for blood-contacting applications. Journal of Materials Science, 2019, 54(14): 10457–10472
CrossRef Google scholar
[17]
Bae W G, Kim J, Choung Y H, . Bio-inspired configurable multiscale extracellular matrix-like structures for functional alignment and guided orientation of cells. Biomaterials, 2015, 69: 158–164
CrossRef Pubmed Google scholar
[18]
Lowe S, O'Brien-Simpson N M, Connal L A. Antibiofouling polymer interfaces: Poly(ethylene glycol) and other promising candidates. Polymer Chemistry, 2015, 6(2): 198–212
CrossRef Google scholar
[19]
Wei H, Bruns O T, Chen O, . Compact zwitterion-coated iron oxide nanoparticles for in vitro and in vivo imaging. Integrative Biology, 2013, 5(1): 108–114
CrossRef Pubmed Google scholar
[20]
Park H H, Sun K, Seong M, . Lipid-hydrogel-nanostructure hybrids as robust biofilm-resistant polymeric materials. ACS Macro Letters, 2019, 8(1): 64–69
CrossRef Google scholar
[21]
Chen K, Zhou S, Wu L. Self-repairing nonfouling polyurethane coatings via 3D-grafting of PEG-b-PHEMA-b-PMPC copolymer. RSC Advances, 2015, 5(127): 104907–104914
CrossRef Google scholar
[22]
Kakimoto Y, Tachihara Y, Okamoto Y, . Morphology and physical properties of hydrophilic-polymer-modified lipids in supported lipid bilayers. Langmuir, 2018, 34(24): 7201–7209
CrossRef Pubmed Google scholar
[23]
Blanazs A, Warren N J, Lewis A L, . Self-assembly of double hydrophilic block copolymers in concentrated aqueous solution. Soft Matter, 2011, 7(14): 6399–6403
CrossRef Google scholar
[24]
Zhao W, Zhu Y, Zhang J, . A comprehensive study and comparison of four types of zwitterionic hydrogels. Journal of Materials Science, 2018, 53(19): 13813–13825
CrossRef Google scholar
[25]
Jankova K, Chen X Y, Kops J, . Synthesis of amphiphilic PS-b-PEG-b-PS by atom transfer radical polymerization. Macromolecules, 1998, 31(2): 538–541
CrossRef Google scholar
[26]
Karanam S, Goossens H, Klumperman B, . “Controlled” synthesis and characterization of high molecular weight methyl methacrylate/tert-butyl methacrylate diblock copolymers via ATRP. Macromolecules, 2003, 36(22): 8304–8311
CrossRef Google scholar
[27]
Dwyer A B, Chambon P, Town A, . Is methanol really a bad solvent for poly(n-butyl methacrylate)? Low dispersity and high molecular weight polymers of n-butyl methacrylate synthesised via ATRP in anhydrous methanol. Polymer Chemistry, 2014, 5(11): 3608–3616
CrossRef Google scholar
[28]
Li X, Zhan Q, Qi H, . Paclitaxel formulation with stable sustained-release behavior and its biological safety evaluation. Science China: Technological Sciences, 2019, 62(7): 1151–1159
CrossRef Google scholar
[29]
Xu B, Yao W, Li Y, . Perfluorocyclobutyl aryl ether-based ABC amphiphilic triblock copolymer. Scientific Reports, 2016, 6(1): 39504
CrossRef Pubmed Google scholar
[30]
Zhang X, Zhao M, Cao N, . Construction of a tumor microenvironment pH-responsive cleavable PEGylated hyaluronic acid nano-drug delivery system for colorectal cancer treatment. Biomaterials Science, 2020, 8(7): 1885–1896
CrossRef Pubmed Google scholar
[31]
Pang X, Zhao L, Akinc M, . Novel amphiphilic multi-arm, star-like block copolymers as unimolecular micelles. Macromolecules, 2011, 44(10): 3746–3752
CrossRef Google scholar

Disclosure of potential conflicts of interests

The authors declare no conflicts of interest.

Acknowledgements

This study was financially supported by the National Natural Science Foundation of China (Grant Nos. 51673146, 51673144 and 51773151).

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2021 Higher Education Press
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