Complementary nucleobase‐functionalized polymeric micelles, a combination of adenine‐thymine (A‐U) base pairs and a blend of hydrophilic–hydrophobic polymer pairs, can be used to construct 3D supramolecular polymer networks; these micelles exhibit excellent self‐assembly ability in aqueous solution, rapid pH‐responsiveness, high drug loading capacity, and triggerable drug release. In this study, a multi‐uracil functionalized poly(ε‐caprolactone) (U‐PCL) and adenine end‐capped difunctional oligomeric poly(ethylene glycol) (BA‐PEG) are successfully developed and show high affinity and specific recognition in solution owing to dynamically reversible A‐U‐induced formation of physical cross‐links. The U‐PCL/BA‐PEG blend system produces supramolecular micelles that can be readily adjusted to provide the desired critical micellization concentration, particle size, and stability. Importantly, in vitro release studies show that doxorubicin (DOX)‐loaded micelles exhibit excellent DOX‐encapsulated stability under physiological conditions. When the pH value of the solution is reduced from 7.4 to 5.0, DOX‐loaded micelles can be rapidly triggered to release encapsulated DOX, suggesting these polymeric micelles represent promising candidate pH‐responsive nanocarriers for controlled‐release drug delivery and pharmaceutical applications.
Rapid and efficient side‐chain functionalization of polypeptide with neighboring carboxylgroups is achieved via the combination of ring‐opening polymerization and subsequent thiol‐yne click chemistry. The spontaneous formation of polymersomes with uniform size is found to occur in aqueous medium via electrostatic interaction between the anionic polypeptide and cationic doxorubicin hydrochloride (DOX·HCl). The polymersomes are taken up by A549 cells via endocytosis, with a slightly lower cytotoxicity compared with free DOX ·HCl. Moreover, the drug‐loaded polymersomes exhibit the enhanced therapeutic efficacy, increase apoptosis in tumor tissues, and reduce systemic toxicity in nude mice bearing A549 lung cancer xenograft, in comparison with free DOX ·HCl. 相似文献
A novel ferrocenium capped amphiphilic pillar[5]arene (FCAP) was synthesized and self‐assembled to cationic vesicles in aqueous solution. The cationic vesicles, displaying low cytotoxicity and significant redox‐responsive behavior due to the redox equilibrium between ferrocenium cations and ferrocenyl groups, allow building an ideal glutathione (GSH)‐responsive drug/siRNA co‐delivery system for rapid drug release and gene transfection in cancer cells in which higher GSH concentration exists. This is the first report of redox‐responsive vesicles assembled from pillararenes for drug/siRNA co‐delivery; besides enhancing the bioavailability of drugs for cancer cells and reducing the adverse side effects for normal cells, these systems can also overcome the drug resistance of cancer cells. This work presents a good example of rational design for an effective stimuli‐responsive drug/siRNA co‐delivery system. 相似文献
In this study, an adjustable pH‐responsive drug delivery system using mesoporous silica nanoparticles (MSNs) as the host materials and the modified polypeptides as the nanovalves is reported. Since the polypeptide can self‐assemble via electrostatic interaction at pH 7.4 and be disassembled by pH changes, the modified poly(l ‐lysine) and poly(l ‐glutamate) are utilized for pore blocking and opening in the study. Poly(l ‐lysine)‐MSN (PLL‐MSN) and poly(l ‐glutamate)‐MSN (PLG‐MSN) are synthesized via the ring opening polymerization of N‐carboxyanhydrides onto the surface of mesoporous silica nanoparticles. The successful modification of the polypeptide on MSN is proved by Zeta potential change, X‐ray photoelectron spectroscopy (XPS), solid state NMR, and MALDI‐TOF MS. In vitro simulated dye release studies show that PLL‐MSN and PLG‐MSN can successfully load the dye molecules. The release study shows that the controlled release can be constructed at different pH by adjusting the ratio of PLL‐MSN to PLG‐MSN. Cellular uptake study indicates that the drug is detected in both cytoplasm and nucleus, especially in the nucleus. In vitro cytotoxicity assay indicates that DOX loaded mixture nanoparticles (ratio of PLL‐MSN to PLG‐MSN is 1:1) can be triggered for drug release in HeLa cells, resulting in 88% of cell killing. 相似文献
We report here the noncovalent synthesis of thermosensitive dendrimers. Short oligoguanosine strands were linked to the focal point of a dendron by using “click chemistry”, and quadruplex formation was used to drive the self‐assembly process in the presence of metal ions. The dynamic nature of these noncovalent assemblies can be exploited to create combinatorial libraries of dendrimers as demonstrated by the co‐assembly of two components. These supramolecular dendrimers showed thermoresponsive behavior that can be tuned by varying the templating cations or the number of guanines in the oligonucleotide strand. 相似文献
Amphiphilic Janus dendrimers have attracted increasing attention due to their asymmetric structures and various functional properties compared to the conventional symmetric macromolecules. Herein, a novel ferrocenyl‐terminated amphiphilic Janus dendrimer containing nine hydrophilic triethylene glycol branches was synthesized by two synthetic routes, namely the typical chemo selective coupling method and the mixed modular approach. Chemical redox triggers, namely Fe2(SO4)3 as oxidant and ascorbic acid as reductant, could regulate the self‐assembly behavior of the Janus dendrimer in water through the redox‐switching between ferrocene and ferricinium cations, and the change of micelles formed were investigated and confirmed through scanning electron microscopy and dynamic light scattering. The cargo‐loading property of the micelles self‐assembled by the Janus dendrimer was further proved by the successful fabrication of Rhodamine B (RhB)‐loaded micelles, and the oxidation‐triggered release behavior of the encapsulated RhB could be mediated by changing the concentration of oxidants. This work provides an effective approach to prepare ferrocenyl‐terminated amphiphilic Janus dendrimers and the self‐assembled micelles might be used as a promising molecular carrier in areas such as drug delivery and catalysis. 相似文献
A hyaluronic acid‐based anionic nanogel formed by self‐assembly of cholesteryl‐group‐bearing HA is designed for protein delivery. The HA nanogel spontaneously binds various types of proteins without denaturation, such as recombinant human growth hormone, erythropoietin, exendin‐4, and lysozyme. The HA nanogel shows unique colloidal properties, in particular that an injectable hydrogel is formed by salt‐induced association of the HA nanogel. A pharmacokinetic study in rats shows that an in situ gel formulation, prepared by simply mixing rhGH and HA nanogel in phosphate buffer, maintains plasma rhGH levels within a narrow range over one week. Therefore, HA nanogels offer a simple method for easy formulation of therapeutic proteins and are effective for sustained protein release systems.
In the past decade, polymer vesicles prepared by self‐assembly techniques have attracted increasing scientific interest based on their unique features highlighted with tunable membrane properties, versatility, stability, and capacity of transporting hydrophilic as well as hydrophobic species. Polymersomes exhibit intriguing potential applications such as cell mimicking dimensions and functions, tunable delivery vehicles, for the templating of biomineralization, nanoreactors, and as scaffolds for biological conjugation. In this Feature Article, an overview of the preparation and application of recently developed “smart” polymer vesicles, which can respond to the novel external stimuli, including carbon dioxide (CO2), electrochemical potential, ultrasound, enzyme, near‐infrared light, and magnetic field is given. The response mechanism and morphology change are explored with specific focus on the functionalization of various domains of the polymer vesicles. In addition, the current limitations are explored as well as the challenges facing the development of these nanostructures toward real‐world applications.
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