Recent advances in natural polysaccharides-based controlled release nanosystems for anti-cancer phototherapy.

Phototherapy, which relies on light to trigger phototherapeutic agents (PAs) to generate cytotoxic reactive oxygen species or hyperthermia, has received much attention in cancer treatment. However, traditional PAs have shortcomings such as low water solubility, easy aggregation-induced fluorescence quenching and low target site accumulation efficiency, which severely limit clinical anticancer applications. Naturally derived polysaccharides have attracted great attention in the scientific community in nano-drug delivery systems (NDDS) due to their abundant resources, biocompatibility, targeting ability, bioactivity and so on, which is expected to assist PAs to play a synergistic effect. This article reviews the recent progress of polysaccharides in the field of cancer phototherapy, including the advantages of polysaccharides as nanocarrier materials to deliver PAs; the main mechanism for the preparation of PAs-loaded polysaccharides nanoformulation; construction of polysaccharides-based NDDS for delivery of PAs and its functional modification strategy, hoping to further improve the therapeutic effect of phototherapy against cancer.

pH/ROS dual-sensitive and chondroitin sulfate wrapped poly (ß-amino ester)-SA-PAPE copolymer nanoparticles for macrophage-targeted oral therapy for ulcerative colitis.

An oral nanoparticle (NPs) encapsulated in chitosan/alginate hydrogel (CA-Gel) with dual-sensitive in pH and reactive oxygen species (ROS) was developed to load curcumin (CUR) based on the intracellular-specific characteristics of macrophages. Chondroitin sulfate (CS) wrapped PBAE-SA-PAPE with intracellular pH/ROS dual-sensitive characteristics and CUR via a simple nanoprecipitation method to form NPs (CS-CUR-NPs), and mixed CA-Gel to acquire the final preparation (CS-CUR-NPs-Gel). CS-CUR-NPs displayed an ideal average particle size (179.19±5.61nm) and high encapsulating efficiency (94.74±1.15%). CS showed a good targeting ability on macrophages and the CA-Gel contribution in protecting NPs from being destroyed in the upper gastrointestinal tract. As expected, CS-CUR-NPs-Gel could significantly alleviate inflammation in DSS-induced UC mice via TLR4-MAPK/NF-κB pathway. This study is the first to attempt to design a novel pH/ROS dual-stimulated release strategy in helping intracellular CUR delivery and anticipated for efficient anti-UC therapy.

Entrapment of Macrophage-Target Nanoparticles by Yeast Microparticles for Rhein Delivery in Ulcerative Colitis Treatment.

In this study, we developed an advanced colitis-targeted nanoparticles (NPs)-into-yeast cell wall microparticles (YPs) drug delivery system for ulcerative colitis (UC) therapy. In brief, YPs entrap hyaluronic acid (HA), and polyethylenimine (PEI) modified rhein (RH)-loaded ovalbumin NPs (HA/PEI-RH NPs) to form HA/PEI-RH NYPs. YPs can make HA/PEI-RH NPs pass through gastric environment stably and be degraded by ß-glucanase to promote drug release from HA/PEI-RH NYPs in the colon. Cellular uptake evaluation confirmed that HA/PEI-RH NPs could specifically target and enhance the uptake rate via HA ligands. In biodistribution studies, HA/PEI-RH NYPs were able to efficiently accumulate in the inflammed colon in mice. In vivo experiments revealed that the HA/PEI-RH NYPs could significantly alleviate inflammation by inhibiting the TLR4/MyD88/NF-κB signaling pathway. Therefore, HA/PEI-RH NYPs have advantages of good gastric stability, ß-glucanase-sensitive release ability, macrophage-targeted ability, and anti-UC effects. These advantages indicate YPs-entrapped multifunctional NPs are a promising oral drug delivery system for UC therapy.