Nano-vibration exciter: Hypoxia-inducible factor 1 signaling pathway-mediated extracellular vesicles as bioactive glass substitutes for bone regeneration.

Bioactive glasses (BG) play a vital role in angiogenesis and osteogenesis through releasing functional ions. However, the rapid ion release in the early stage will cause excessive accumulation of metal ions, which in turn leads to obvious cytotoxicity, long-term inflammation, and bone repair failure. Inspired by the vibration exciter, small extracellular vesicles (sEVs) obtained by treating mesenchymal stem cells with copper-doped bioactive glass (CuBG-sEVs), is prepared as a nano-vibration exciter. The nano-vibration exciter can convert the ion signals of CuBG into biochemical factor signals through hypoxia-inducible factor 1 (HIF-1) signaling pathway and its activated autophagy, so as to better exert the osteogenic activity of BG. The results showed that CuBG extracts could significantly improve the enrichment of key miRNAs and increase the yield of CuBG-sEVs by activating HIF-1 signaling pathway and its activated autophagy. Cell experiments showed that CuBG-sEVs are favor to cell recruitment, vascularization and osteogenesis as the enrichment of key miRNAs. The animal experiments results showed that CuBG-sEVs stimulated angiogenesis mediated by CD31 and promoted bone regeneration by activating signaling pathways related to osteogenesis. These findings underscored the significant potential of sEVs as alternative strategies to better roles of BG.

An injectable and degradable heterogeneous microgel assembly capable of forming a "micro-nest group" for cell condensation and cartilage regeneration.

Cell condensation, linking the migration and chondrogenic differentiation of MSCs, plays a crucial role in cartilage development. Current cartilage repair strategies are inadequately concerned with this process, leading to a suboptimal quality of regenerated cartilage. Inspired by the "nest flocks" structure of Social Weavers, a degradable heterogeneous microgel assembly (F/S-MA) is developed, which can release SDF-1, to form a "micro-nest group" structure and bond with HAV peptides to promote cell recruitment, condensation and chondrogenic differentiation. First, slow-degrading microgels (S-microgels) grafted with HAV peptides and fast-degrading microgels (F-microgels) loaded with SDF-1 are fabricated by an amidation reaction and Schiff base reaction, respectively. They employ sulfhydryl-modified gelatin as assembling agents to form F/S-MA through a thiol-ene reaction, exhibiting injectability, tissue adhesion, and microporosity. F-microgels undergo rapid degradation, leading to the release of SDF-1 and the formation of a "micro-nest group" in F/S-MA. Consequently, F/S-MA exhibits cell recruitment ability, meanwhile facilitating BMSC condensation through the synergistic effects of the "micro-nest group" and HAV peptides. In vitro experiments prove that F/S-MA enhances the expression of cell-condensation-related markers, ultimately upregulating the secretion of cartilage matrix. Animal experiments show that F/S-MA optimizes the quality of regenerated cartilage by improving cell recruitment and condensation. F/S-MA enhances cell condensation through structural and component design, which will provide new insights for cartilage regeneration.

Injectable and tissue adhesive EGCG-laden hyaluronic acid hydrogel depot for treating oxidative stress and inflammation.

Oxidative stress and inflammation are common pathological mechanisms for the progression of tissue degeneration. Epigallocatechin-3-gallate (EGCG) features antioxidant and anti-inflammatory properties, which is a promising drug for the treatment of tissue degeneration. Herein, we utilize the phenylborate ester reaction of EGCG and phenylboronic acid (PBA) to fabricate an injectable and tissue adhesive EGCG-laden hydrogel depot (EGCG HYPOT), which can achieve anti-inflammatory and antioxidative effects via smart delivery of EGCG. Specifically, the phenylborate ester bonds, formed by EGCG and PBA-modified methacrylated hyaluronic acid (HAMA-PBA), endow EGCG HYPOT injectability, shape adaptation and efficient load of EGCG. After photo-crosslinking, EGCG HYPOT exhibits good mechanical properties, tissue adhesion and sustained acid-responsive release of EGCG. EGCG HYPOT can scavenge oxygen and nitrogen free radicals. Meanwhile, EGCG HYPOT can scavenge intracellular reactive oxygen species (ROS) and suppress the expression of pro-inflammatory factors. EGCG HYPOT may provide a new idea for alleviation of inflammatory disturbance.

Phosphoserine enhanced Cu-doped bioactive glass dynamic dual-network hydrogel for craniofacial bone defect repair.

Flexible hydrogels containing various osteogenic inorganic constituents, which can accommodate complicated shape variations, are considered as ideal grafts for craniofacial bone defect reconstruction. However, in most hybrid hydrogels, poor interaction between the polymer network and particles has detrimental effects on hydrogel rheological and structural properties, clinical manipulation and repair efficacy. In this article, we designed and prepared a series of hyaluronic acid composite hydrogel containing Cu-doped bioactive glass (CuBG) and phosphoserine (PS), in which hyaluronic acid was modified by methacrylate groups and phenylboronic acid groups to form a double crosslinked network. PS acted as an interaction bridge of CuBG particles and HAMA-PBA network to improve the mechanical properties of the composite hydrogels. The CuBG/PS hydrogels exhibited suitable rheological properties (injectable, self-healing, shape-adaptable), bone tissue integrating ability and anti-bacterial property. Meanwhile, we found that CuBG and PS have synergistic effect on improving osteogenic efficiency both in vitro and in vivo, particularly when the ratio of CuBG to PS is lower than 3 (9CB/3PS). This work provided a versatile and scalable approach to enhanced the interaction within inorganic particles and polymer network in hydrogels without extra modification on components.

Injectable chondroitin sulfate-grafted self-antioxidant hydrogels ameliorate nucleus pulposus degeneration against overactive inflammation.

Overactive inflammatory cascade accompanied by oxidative stress in the nucleus pulposus exacerbates intervertebral disc degeneration (IVDD). Hydrogels have been demonstrated to be promising in treating IVDD, yet they remain less efficacious in the case of anti-inflammation associated with antioxidation. In this study, we designed an injectable self-antioxidant hydrogel (HA/CS) with enhanced inflammation inhibitory performance for delivering chondroitin sulfate (CS) with well-documented anti-inflammatory property to treat IVDD. The hydrogel was rapidly formed via dynamic boronate ester bonding between furan/phenylboronic acid and furan/dopamine-modified hyaluronic acid (HA), and mechanically enhanced by Diels-Alder reaction-induced secondary crosslinking, partial dopamine groups of which contribute to grafting phenylboronic acid-modified CS (CS-PBA). This hydrogel exhibits favorable injectability, mechanical property, and pH-responsive delivery behavior. The dopamine moiety endows the hydrogel with efficient antioxidative property. By sustained delivery of CS, the HA/CS hydrogel is well competent to inhibit inflammatory cytokine expression and maintain anabolic/catabolic balance in an inflammation-simulated environment. Most importantly, the HA/CS hydrogel significantly ameliorates degeneration in a puncture-induced IVDD rat model. The self-antioxidant HA/CS hydrogel designed in this work may serve as a novel and promising therapeutic platform for IVDD.

Sequence-Selective Terpolymerization from Monomer Mixtures Using a Simple Organocatalyst.

One-step synthesis of block copolymer from mixed monomers is of great interest and challenge. Using a simple non-nucleophilic organobase as the catalyst, we have achieved sequence-selective terpolymerization from a mixture of phthalic anhydride (PA), an epoxide, and rac-lactide (LA). Alcohol-initiated alternating copolymerization of PA and epoxide occurs first and exclusively because PA is substantially more active than LA for reacting with base-activated hydroxyl. When PA is fully consumed, LA polymerizes from the termini of the first block while excess epoxide stays intact because of the mild basicity of the catalyst. The two polymerizations thus occur tandemly, both in chemoselective manners, so that an aromatic-aliphatic block copolyester is generated in this one-step synthesis. The effectiveness and versatility of this approach is demonstrated by the use of ethylene oxide and several monosubstituted epoxides as well as mono-, di-, or tetrahydroxy initiators.