Two-dimensional (2D) materials are of great significance to the materials community for their high surface area and controllable surface properties. However, controlled preparation of 2D structures with biological functions and biodegradable features is considerably hard. In this work, we demonstrate that, by careful selection of building block structures and assembly conditions, the above obstacle can be overcome partially by crystallization-driven self-assembly (CDSA) from PLLA-based diblock glycopolymers. 1D glyco-cylinders and 2D diamond-shaped glyco-platelets with solid or hollow core were achieved, where the latter structures have not been reported in literatures so far. The glyco-platelets further demonstrated exciting macrophage activation efficiency with clear size effect compared to their 1D analogues, which indicated their possible potential in immunological applications.
Glyconanoparticles made by self-assembled glycopolymers currently are practical and efficient mimics of the glycocalyx on cell surfaces. Considering the complexity of the glycocalyx, glyconanoparticles with different sugars on their coronas, i.e., mixed-shell glycomicelles, could be more valuable compared to homoshell micelles. In this paper, we explore the architectural effect of the glyconanoparticle corona on glyconanoparticle macrophage endocytosis and lectin-binding ability. A series of glyconanoparticles composed of a biodegradable polyester backbone functionalized with galactoside or mannoside pendants were designed and prepared. The different architectures explored were single-component (galactoside or mannoside) coronas, homogeneously mixed coronas (MG) made by galactoside-mannoside copolymer chains, and blend-mixed coronas (M/G) constructed from two homoglycopolymers. Nanoparticles with a mixed shell showed a higher efficiency in cellular uptake and lectin-binding than those with a single sugar component. Meanwhile, unexpectedly, MG presented a significantly higher efficiency than M/G, although they had the same particle size and ratio of mannoside to galactoside. We attributed this apparent architectural effect to the difference in the phase behavior between MG and M/G; i.e., the former having a homogeneous corona allowed more sugar-receptor interactions in the contact region, while the latter having phase separation limited the simultaneous interaction of the two kinds of sugar units with the cell receptors.
Immune checkpoint blockade by anti-PD-L1 monoclonal antibody (αPD-L1) has achieved unprecedented clinical benefits in certain cancers, whereas the therapeutic efficacy is often hindered by immunosuppressive tumor microenvironment mediated by tumor-associated macrophages (TAMs), which leads to innate resistance to this approach. To improve checkpoint blockade efficacy, the amphiphilic diblock copolymers poly(mannopyranoside/galactopyranoside methacrylate)- block-polystyrene are prepared by RAFT polymerization, which are sequentially self-assembled into glycocalyx-mimicking nanoparticles (GNPs) to neutralize TAMs. It is shown that GNPs can be specifically internalized by TAMs via lectin receptors, which results in upregulation of immunostimulatory IL-12 and downregulation of immunosuppressive IL-10, arginase 1, and CCL22, indicating functional reversion of protumor TAMs toward antitumor phenotype. The reversion of TAMs is proved to be mainly controlled by suppressing STAT6 and activating NF-κB phosphorylation. In vivo therapeutic studies have demonstrated that GNPs significantly enhance the therapeutic efficacy of αPD-L1 cancer therapy by reduction of tumor burden. Moreover, combination therapies with GNPs and αPD-L1 greatly improve immunosuppressive tumor microenvironment by reciprocal modulation of tumor-infiltrating effector and regulatory T cells. Notably, for the first time, our results demonstrate the reversion of TAMs and improvement of αPD-L1 cancer therapy by synthetic carbohydrate-containing nanomaterials. This research highlights a promising strategy for optimizing immune checkpoint blockade in cancer immunotherapy.
Pt-free cathode catalysts for polymer electrolyte membrane fuel cells have been prepared by multi-step pyrolysis of FePc and PhRs, in the best of which show extensively high initial cell performance and good durability compared to other present precious-metal-free cathode catalysts to date.
We proposed the deprotection-induced block copolymer self-assembly (DISA); that is, the deprotection of hydroxyl groups resulted in in situ self-assembly of glycopolymers. In the previous studies, block copolymers soluble in common organic solvents were employed as the starting material. In this paper, by using the protected glyco-block containing preassembled glycovesicles in water as the starting material, we moved forward and made two exceeding achievements. First, we have observed a deprotection-induced morphology transition triggered by alkali in water. The carbohydrate-carbohydrate interactions were considered to contribute to such a morphology transition during deprotection. Second, lipase was found to be an efficient enzymatic trigger in the sugar deprotection, which motivates the immune-application of this morphology transition process. When lipase and a model antigen, ovalbumin (OVA), were encapsulated inside the glycovesicles, the deprotection of sugars by lipase induced the transition of vesicles to micelles and the lipase and OVA were released accordingly. When glycovesicles were internalized by dentritic cells (DCs), the lipase from lysosomes efficiently induced the release of OVA and presentation of antigen to T cells. During the process, lysosomal lipase performed as a trigger on the deprotection of sugars and the release of protein without any other reagents. The significance of this design is that as a delivery vehicle, the protected glycovesicles not only avoided unnecessary immune activation but also worked with the released OVA together; that is, the glycovehicle successfully activated DCs and improved the presentation efficiency of T cells remarkably.
The molecular weight and temperature dependencies of the intrinsic viscosity [η] were
investigated for poly{2,7-[9,9-bis((S)-3,7-dimethyloctyl)]fluorene} (PDMOF) in tetrahydrofuran (THF).
By analyzing the [η] data in terms of the touched-bead wormlike chain model, we estimated the persistence
length q of PDMOF. It is 9.5 nm at 20 °C and slightly increases with decreasing temperature. The results
of q were compared with the theoretical ones calculated on the basis of the broken wormlike chain (BWC),
rotational isomeric state (RIS), and freely rotating chain (FRC) models. The BWC model for helical polymer
chains gave q much larger than the experimental values, when the excess free energy ΔG
r of the helix
reversal for PDMOF was assumed to be comparable to those for typical synthetic helical polymers reported
so far. On the other hand, the FRC model slightly underestimated the experimental q. A good fit to the
experimental q was obtained for a simple RIS model where each monomer unit takes independently four
rotational states, right- and left-handed 5/2 and 5/1 helical states, and its bond angle fluctuates slightly.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.