Bioenergetic-active exosomes for cartilage regeneration and homeostasis maintenance

Exosome: an overview on enhanced biogenesis by small molecules

Exosomes are extracellular vesicles that received attention for their potential use in the treatment of various injuries. They communicate intercellularly by transferring genetic and bioactive molecules from parent cells. Although exosomes hold immense promise for treating neurodegenerative and oncological diseases, their actual clinical use is very limited because of their biogenesis and secretion. Recent studies have shown that small molecules can significantly enhance exosome biogenesis, thereby remarkably improving yield, functionality, and therapeutic effects. These molecules modulate critical pathways toward optimum exosome production in a mode that is either ESCRT dependent or ESCRT independent. Improved exosome biogenesis may provide new avenues for targeted cancer therapy, neuroprotection in neurodegenerative diseases, and regenerative medicine in wound healing. This review explores the role of small molecules in enhancing exosome biogenesis and secretion, highlights their underlying mechanisms, and discusses emerging clinical applications. By addressing current challenges and focusing on translational opportunities, this study provides a foundation for advancing cell-free therapies in regenerative medicine and beyond.

pH-Responsive Engineered Exosomes Enhance Endogenous Hyaluronan Production by Reprogramming Chondrocytes for Cartilage Repair

Trauma or inflammation-caused cartilage injury leads to joint dysfunction and pain. Exogenous hyaluronic acid (HA) injection is a well-established treatment, but it has a short duration in vivo and requires multiple injections. Here, a new strategy for in situ reprogramming chondrocytes to continuously produce endogenous high molecular weight HA is developed. This involves a pH-responsive engineered exosome decorated with vesicular stomatitis virus glycoprotein (VSV-G) and hyaluronan synthase type 2 (HAS2). Such engineered exosomes successfully deliver HAS2 to the chondrocyte membranes via VSV-G-mediated membrane fusion triggered by low pH, rather than being degraded in lysosomes. This results in the generation of HAS2-chondrocytes, which are characterized to produce high molecular weight HA in vitro and in vivo. With increased endogenous HA, the injected engineered exosomes enhance cartilage regeneration and inhibit osteoarthritis (OA) progression. Notably, one-shot administration of engineered exosomes drastically increases the intra-articular concentration of high molecular weight HA to 145% of the exogenous HA injection group. Importantly, such endogenous HA is sustained for 4 weeks, whereas the injected exogenous HA rapidly decreases within 2 weeks. The findings demonstrate that pH-responsive engineered exosomes capable of generating endogenous HA hold great potential to replace the treatment of multiple injections of exogenous HA for cartilage repair.

Intelligent Nanomaterials Design for Osteoarthritis Managements

Osteoarthritis (OA) is the most prevalent degenerative joint disorder, characterized by progressive joint degradation, pain, and diminished mobility, all of which collectively impair patients' quality of life and escalate healthcare expenditures. Current treatment options are often inadequate due to limited efficacy, adverse side effects, and temporary symptom relief, underscoring the urgent need for more effective therapeutic strategies. Recent advancements in nanomaterials and nanomedicines offer promising solutions by improving drug bioavailability, reducing side effects and providing targeted therapeutic benefits. This review critically examines the pathogenesis of OA, highlights the limitations of existing treatments, and explores the latest innovations in intelligent nanomaterials design for OA therapy, with an emphasis on their engineered properties, therapeutic mechanisms, and translational potential in clinical application. By compiling recent findings, this work aims to inspire further exploration and innovation in nanomedicine, ultimately advancing the development of more effective and personalized OA therapies.