Sabrina Lazar, Sirjan Mor, Jianing Chen, Dake Hao, Aijun Wang
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引用次数: 0
Abstract
Extracellular vesicle (EV)-based technologies represent a new advancement for disease treatment. EVs can be administered systemically, injected into the injury site directly, or applied locally in conjunction with bioengineered implantable scaffolds. Matrix-bound vesicles (MBVs), a special class of vesicles localized in association with the extracellular matrix (ECM), have been identified as critical bioactive factors and shown to mediate significant regenerative functions of ECM scaffolds. Loading EVs onto bioscaffolds to mimic the MBV-ECM complex has been shown superior to EV bolus injection in recent in vivo studies, such as in providing enhanced tissue regeneration, EV retention rates, and healing efficacy. Different types of natural biomaterials, synthetic polymers, and ceramics have been developed for EV loading, and these EV functionalized biomaterials have been applied in different areas for disease treatment. The EV functionalized scaffolds can be designed to be biodegradable, off-the-shelf biomaterials as a delivery vehicle for EVs. Overall, the bioengineered EV-loaded bioscaffolds represent a promising approach for cell-free treatment in clinical applications.
基于细胞外囊泡(EV)的技术是疾病治疗的新进展。细胞外囊泡可以全身给药、直接注射到受伤部位或与生物工程植入支架一起局部应用。基质结合囊泡(MBVs)是一类与细胞外基质(ECM)结合的特殊囊泡,已被确定为关键的生物活性因子,并被证明能介导 ECM 支架的重要再生功能。在最近的体内研究中,在生物支架上加载 EV 以模拟 MBV-ECM 复合物已被证明优于 EV 栓注,例如在增强组织再生、EV 保留率和愈合效果方面。目前已开发出不同类型的天然生物材料、合成高分子材料和陶瓷,用于EV负载,这些EV功能化生物材料已被应用于不同领域的疾病治疗。EV 功能化支架可设计成生物可降解的现成生物材料,作为 EV 的输送载体。总之,生物工程EV负载生物支架是临床应用中一种很有前景的无细胞治疗方法。
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