Bone mesenchymal stem cell-derived exosomes involved co-delivery and synergism effect with icariin via mussel-inspired multifunctional hydrogel for cartilage protection.

Mesenchymal stem cells (MSC) are particularly effective in promoting cartilage regeneration due to their immunomodulatory, anti-inflammatory and regenerative repair functions of tissues and organs. Meanwhile, the intra-articular delivery and synergy with other therapeutic drugs have been the key issues driving their further application. We report a mussel-inspired multifunctional hydrogel system, which could achieve co-delivery and synergism effect of MSC-derived exosomes (Exos) with icariin (ICA). The ICA and Exos co-delivered articular cavity injection system are expected to retain in the joint cavity and promote cartilage regeneration, due to the thermosensitive, self-healing and adhesion properties of the mussel-inspired multifunctional hydrogel. The experimental results proved that Exos enhanced the cellular uptake of ICA by more than 2-fold evenly, and the synergism of Exos and ICA efficiently improve the cell proliferation and migration. After synergic treatment, the content of matrix metalloproteinase 13 in the supernatant and intracellular decreased by 47% and 59%, respectively. In vivo study, ICA-loaded Exos exhibited prolonged retention behavior by multifunctional hydrogel delivery, thus displayed an increased cartilage protection. In the model of osteoarthritis, co-delivery hydrogel system relieved the cartilage recession, ensuring appropriate cartilage thickness.

"Shell-Core" Bilayer Nanoparticle as Chemotherapeutic Drug Co-Delivery Platforms Render Synchronized Microenvironment Respond and Enhanced Antitumor Effects.

Background: Synergistic chemotherapy has been proved as an effective antitumor means in clinical practice. However, most co-administration treatment often lacks simultaneous control over the release of different chemotherapeutic agents. Materials and Methods: ß-cyclodextrin modified hyaluronic acid was the "shell", and the oxidized ferrocene-stearyl alcohol micelles served as the "core", where doxorubicin (DOX) and curcumin (CUR) were loaded in shell and core of the bilayer nanoparticles (BNs), respectively. The pH- and glutathione (GSH)-responsive synchronized release behavior was evaluated in different mediums, and the in vitro and in vivo synergistic antitumor effect and CD44-mediated tumor targeting efficiency were further investigated. Results: These BNs had a spherical structure with the particle size of 299 ± 15.17 nm, while the synchronized release behaviour of those two drugs was proved in the medium with the pH value of 5.5 and 20 mM GSH. The co-delivery of DOX and CUR reduced the IC50 value by 21% compared to DOX alone, with a further 54% reduction after these BNs delivery measurements. In tumor-bearing mouse models, these drug-loaded BNs showed significant tumor targeting, enhanced antitumor activity and reduced systemic toxicity. Conclusion: The designed bilayer nanoparticle could be considered as potential chemotherapeutic co-delivery platform for efficient synchronized microenvironment respond and drug release. Furthermore, the simultaneous and synergistic drug release guaranteed the enhanced antitumor effects during the co-administration treatment.