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      Stable and pH-responsive polyamidoamine based unimolecular micelles capped with a zwitterionic polymer shell for anticancer drug delivery

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          Abstract

          Zwitterionic dendrimer based unimolecular micelles for anticancer drug delivery were prepared, exhibiting excellent stability in complex biological media.

          Abstract

          To improve the circulation stability of polyamidoamine (PAMAM) based drug delivery systems in complex biological microenvironments, a series of generation-3.0 PAMAM- graft-poly[3-dimethyl(methacryloyloxyethyl)ammonium propanesulfonate] (PAMAM3.0- g-PDMAPS) copolymers are synthesized via atom transfer radical polymerization. The zwitterionic PDMAPS segments serve as a shell to stabilize the unimolecular micelles, whereas the PAMAM3.0 dendrimers constitute a hydrophobic core. The sizes of the PAMAM3.0- g-PDMAPS unimolecular micelles range from 6.5 to 8.5 nm. Furthermore, PAMAM3.0- g-PDMAPS can keep the micelle-like structure when it is diluted by large volumes of fluids. More importantly, the PDMAPS shell layer can suppress non-specific protein adsorption on the surface of the micelles. The excellent stability to dilution and anti-biofouling are beneficial for prolonged circulation time in a complex biological microenvironment. In addition, anticancer doxorubicin (DOX) can be encapsulated both in the PAMAM3.0 core via hydrophobic interactions and the PDMAPS shell layer via hydrogen bonds. Drug release studies confirm the pH-responsive nature of PMAMA3.0- g-PDMAPS micelles by achieving 65.23% DOX release at pH 5.1 as compared to 16.38% at pH 7.4. Based on these results, the cytotoxicity and anticancer effects against human hepatocellular carcinoma cells (HepG2) of the PAMAM3.0- g-PDMAPS system loaded with DOX are investigated. The results suggest that the PDMAPS shell layer can significantly decrease the cytotoxicity via decreasing/shielding of the positive charges on the PAMAM dendrimers. After internalization by HepG2 cells, DOX is released from the micelles to the nucleus and further inhibits the proliferation of HepG2. Therefore, these PAMAM3.0- g-PDMAPS unimolecular micelles are a potential platform for anticancer drug delivery.

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          Most cited references46

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          Poly(amidoamine) (PAMAM) dendrimers: from biomimicry to drug delivery and biomedical applications.

          Poly(amidoamine) (PAMAM) dendrimers are the first complete dendrimer family to be synthesized, characterized and commercialized. Based on this extensive activity, they are recognized as a unique new class of synthetic nanostructures. Dendrimers allow the precise control of size, shape and placement of functional groups that is desirable for many life science applications. From this perspective, this review focuses on crucial properties of biomimetic dendrimers that will broaden the potential for their use as macromolecular vectors in novel drug delivery and biomedical applications.
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            A Survey of Structure−Property Relationships of Surfaces that Resist the Adsorption of Protein

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              Structure and design of polymeric surfactant-based drug delivery systems.

              The review concentrates on the use of polymeric micelles as pharmaceutical carriers. Micellization of biologically active substances is a general phenomenon that increases the bioavailability of lipophilic drugs and nutrients. Currently used low-molecular-weight pharmaceutical surfactants have low toxicity and high solubilization power towards poorly soluble pharmaceuticals. However, micelles made of such surfactants usually have relatively high critical micelle concentration (CMC) and are unstable upon strong dilution (for example, with the blood volume upon intravenous administration). On the other hand, amphiphilic block co-polymers are also known to form spherical micelles in solution. These micelles have very high solubilization capacity and rather low CMC value that makes them very stable in vivo. Amphiphilic block co-polymers suitable for micelle preparation are described and various types of polymeric micelles are considered as well as mechanisms of their formation, factors influencing their stability and disintegration, their loading capacity towards various poorly soluble pharmaceuticals, and their therapeutic potential. The basic mechanisms underlying micelle longevity and steric protection in vivo are considered with a special emphasis on long circulating drug delivery systems. Advantages and disadvantages of micelles when compared with other drug delivery systems are considered. New polymer-lipid amphiphilic compounds such as diacyillipid-polyethylene glycol, are described and discussed. These compounds are very attractive from a practical point of view, since they easily micellize yielding extremely stable micelles with very high loading capacity. Micelle passive accumulation in the areas with leaky vasculature (tumors, infarct zones) is discussed as an important physiology-based mechanism of drug delivery into certain target zones. Targeted polymeric micelles prepared by using thermo- or pH-sensitive components or by attaching specific targeted moieties (such as antibodies) to their outer surface are described as well as their preparation and some in vivo properties. The fast growing field of diagnostic micelles is analyzed. Polymeric micelles are considered loaded with various agents for gamma, magnetic resonance, and computed tomography imaging. Their in vitro and in vivo properties are discussed and the results of the initial animal experiments are presented.
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                Author and article information

                Journal
                RSCACL
                RSC Advances
                RSC Adv.
                Royal Society of Chemistry (RSC)
                2046-2069
                2016
                2016
                : 6
                : 21
                : 17728-17739
                Affiliations
                [1 ]School of Chemical Engineering and Technology
                [2 ]Tianjin University
                [3 ]Tianjin 300072
                [4 ]China
                [5 ]Department of Advanced Interdisciplinary Studies
                [6 ]Institute of Basic Medical Sciences and Tissue Engineering Research Center
                [7 ]Academy of Military Medical Science
                [8 ]Beijing 100850
                [9 ]School of Science
                [10 ]Tianjin University of Commerce
                [11 ]Tianjin 300134
                [12 ]Collaborative Innovation Center of Chemical Science and Engineering (Tianjin)
                Article
                10.1039/C5RA25505H
                89d44bb0-c147-4bc2-ac6f-422c43640d55
                © 2016
                History

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