Wound healing is known as one of the most complicated biological processes for injured skin caused by surgical, trauma, burns, or diabetic diseases, which causes a nonfunctioning mass of fibrotic tissue. Recent reports have suggested that exosomes (EXOs) secreted by this type of stem cells may contribute to their paracrine effect. In this study, the EXOs were isolated from the supernatant of cultured adipose-derived stem cells (ADSCs) via ultracentrifugation and filtration. The EXO loaded in the alginate-based hydrogel was used as a bioactive scaffold to preserve the EXO in the wound site in the animal model. The physical and biochemical properties of EXO loaded Alg hydrogel were characterized and results proved that fabricated structure was biodegradable and biocompatible. This bioactive wound dressing technique has significantly improved wound closure, collagen synthesis, and vessel formation in the wound area. Results offer a new viewpoint and a cell-free therapeutic strategy, for wound healing through the application of the composite structure of EXO encapsulated in alginate hydrogel. K E Y W O R D S adipose-derived stem cells, alginate based hydrogel, exosomes, wound dressing, wound healing
Combat or burn injuries are associated with a series of risks, such as microbial infection, an elevated level of inflammatory response, and pathologic scar tissue formation, which significantly postpone wound healing and also lead to impaired repair. Skin engineering for wound healing requires a biomimetic dressing substrate with ideal hydrophilicity, holding antioxidant and antimicrobial properties. In addition, available bioactive specification is required to reduce scar formation, stimulate angiogenesis, and improve wound repair. In this study, we successfully fabricated chitosan (Ch)–based hydrogel enriched with isolated exosome (EXO) from easy‐accessible stem cells, which could promote fibroblast cell migration and proliferation in vitro. Full‐thickness excisional wound model was used to investigate the in vivo dermal substitution ability of the fabricated hydrogel composed Ch and EXO substrates. Our finding confirmed that the wounds covered with Ch scaffold containing isolated EXO have nearly 83.6% wound closure ability with a high degree of re‐epithelialization, whereas sterile gauze showed 51.5% of reduction in wound size. In summary, obtained results imply that Ch‐glycerol‐EXO hydrogel construct can be utilized at the full‐thickness skin wound substitution and skin tissue engineering.
Exosomes (EXOs) are naturally occurring nanosized lipid bilayers that can be efficiently used as a drug delivery system to carry small pharmaceutical, biological molecules and pass major biological barriers such as the blood-brain barrier. It was hypothesized that EXOs derived from human endometrial stem cells (hEnSCs-EXOs) can be utilized as a drug carrier to enhance tumor-targeting drugs, especially for those have low solubility and limited oral bioactivity. In this study, atorvastatin (Ato) loaded EXOs (AtoEXOs) was prepared and characterized for its physical and biological activities in tumor growth suppression of 3 D glioblastoma model. The AtoEXOs were obtained in different methods to maximize drug encapsulation efficacy. The characterization of AtoEXOs was performed for its size, stability, drug release, and in vitro anti-tumor efficacy evaluated comprising inhibition of proliferation, apoptosis induction of tumor cells. Expression of apoptotic genes by Real time PCR, Annexin V/PI, tunnel assay was studied after 72 h exposing U87 cells where encapsulated in matrigel in different concentrations of AtoEXOs (5, 10 μM). The results showed that the prepared AtoEXOs possessed diameter ranging from 30–150 nm, satisfying stability and sustainable Ato release rate. The AtoEXOs was up taken by U87 and generated significant apoptotic effects while this inhibited tumor growth of U87 cells. Altogether, produced AtoEXOs formulation due to its therapeutic efficacy has the potential to be an adaptable approach to treat glioblastoma brain tumors.
Acute renal failure (ARF) is a clinical challenge that is highly resistant to treatment, and its high rate of mortality is alarming. Ischemia–reperfusion injury (IRI) is the most common cause of ARF. Especially IRI is implicated in kidney transplantation and can determine graft survival. Although the exact pathophysiology of renal IRI is unknown, the role of inflammatory responses has been elucidated. Because mesenchymal stromal cells (MSCs) have strong immunomodulatory properties, they are under extensive investigation as a therapeutic modality for renal IRI. Extracellular vesicles (EVs) play an integral role in cell‐to‐cell communication. Because the regenerative potential of the MSCs can be recapitulated by their EVs, the therapeutic appeal of MSC‐derived EVs has dramatically increased in the past decade. Higher safety profile and ease of preservation without losing function are other advantages of EVs compared with their producing cells. In the current review, the preliminary results and potential of MSC‐derived EVs to alleviate kidney IRI are summarized. We might be heading toward a cell‐free approach to treat renal IRI.
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