Kexin Jiao, Chun Liu, Saraswat Basu, N. Raveendran, T. Nakano, S. Ivanovski, Pingping Han
{"title":"Bioprinting extracellular vesicles as a ‘cell-free' regenerative medicine approach","authors":"Kexin Jiao, Chun Liu, Saraswat Basu, N. Raveendran, T. Nakano, S. Ivanovski, Pingping Han","doi":"10.20517/evcna.2023.19","DOIUrl":null,"url":null,"abstract":"Regenerative medicine involves the restoration of tissue or organ function via the regeneration of these structures. As promising regenerative medicine approaches, either extracellular vesicles (EVs) or bioprinting are emerging stars to regenerate various tissues and organs (i.e., bone and cardiac tissues). Emerging as highly attractive cell-free, off-the-shelf nanotherapeutic agents for tissue regeneration, EVs are bilayered lipid membrane particles that are secreted by all living cells and play a critical role as cell-to-cell communicators through an exchange of EV cargos of protein, genetic materials, and other biological components. 3D bioprinting, combining 3D printing and biology, is a state-of-the-art additive manufacturing technology that uses computer-aided processes to enable simultaneous patterning of 3D cells and tissue constructs in bioinks. Although developing an effective system for targeted EVs delivery remains challenging, 3D bioprinting may offer a promising means to improve EVs delivery efficiency with controlled loading and release. The potential application of 3D bioprinted EVs to regenerate tissues has attracted attention over the past few years. As such, it is timely to explore the potential and associated challenges of utilizing 3D bioprinted EVs as a novel ‘cell-free’ alternative regenerative medicine approach. In this review, we describe the biogenesis and composition of EVs, and the challenge of isolating and characterizing small EVs - sEVs (< 200 nm). Common 3D bioprinting techniques are outlined and the issue of bioink printability is explored. After applying the following search strategy in PubMed: ‘bioprinted exosomes’ or ‘3D bioprinted extracellular vesicles’, eight studies utilizing bioprinted EVs were found that have been included in this scoping review. Current studies utilizing bioprinted sEVs for various in vitro and in vivo tissue regeneration applications, including angiogenesis, osteogenesis, immunomodulation, chondrogenesis and myogenesis, are discussed. Finally, we explore the current challenges and provide an outlook on possible refinements for bioprinted sEVs applications.","PeriodicalId":73008,"journal":{"name":"Extracellular vesicles and circulating nucleic acids","volume":"47 1","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2023-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"1","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Extracellular vesicles and circulating nucleic acids","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.20517/evcna.2023.19","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 1
Abstract
Regenerative medicine involves the restoration of tissue or organ function via the regeneration of these structures. As promising regenerative medicine approaches, either extracellular vesicles (EVs) or bioprinting are emerging stars to regenerate various tissues and organs (i.e., bone and cardiac tissues). Emerging as highly attractive cell-free, off-the-shelf nanotherapeutic agents for tissue regeneration, EVs are bilayered lipid membrane particles that are secreted by all living cells and play a critical role as cell-to-cell communicators through an exchange of EV cargos of protein, genetic materials, and other biological components. 3D bioprinting, combining 3D printing and biology, is a state-of-the-art additive manufacturing technology that uses computer-aided processes to enable simultaneous patterning of 3D cells and tissue constructs in bioinks. Although developing an effective system for targeted EVs delivery remains challenging, 3D bioprinting may offer a promising means to improve EVs delivery efficiency with controlled loading and release. The potential application of 3D bioprinted EVs to regenerate tissues has attracted attention over the past few years. As such, it is timely to explore the potential and associated challenges of utilizing 3D bioprinted EVs as a novel ‘cell-free’ alternative regenerative medicine approach. In this review, we describe the biogenesis and composition of EVs, and the challenge of isolating and characterizing small EVs - sEVs (< 200 nm). Common 3D bioprinting techniques are outlined and the issue of bioink printability is explored. After applying the following search strategy in PubMed: ‘bioprinted exosomes’ or ‘3D bioprinted extracellular vesicles’, eight studies utilizing bioprinted EVs were found that have been included in this scoping review. Current studies utilizing bioprinted sEVs for various in vitro and in vivo tissue regeneration applications, including angiogenesis, osteogenesis, immunomodulation, chondrogenesis and myogenesis, are discussed. Finally, we explore the current challenges and provide an outlook on possible refinements for bioprinted sEVs applications.
再生医学涉及通过这些结构的再生来恢复组织或器官的功能。作为有前途的再生医学方法,细胞外囊泡(EVs)或生物打印是再生各种组织和器官(即骨骼和心脏组织)的新兴明星。作为一种极具吸引力的无细胞、现成的用于组织再生的纳米治疗剂,EV是由所有活细胞分泌的双层脂质膜颗粒,通过交换EV货物的蛋白质、遗传物质和其他生物成分,作为细胞间的通讯媒介发挥着关键作用。3D生物打印结合了3D打印和生物学,是一种最先进的增材制造技术,它使用计算机辅助过程在生物墨水中实现3D细胞和组织结构的同时图案化。尽管开发一种有效的靶向电动汽车递送系统仍然具有挑战性,但3D生物打印可能提供一种有前途的方法,可以通过控制装载和释放来提高电动汽车的递送效率。在过去的几年里,生物3D打印电动汽车在组织再生方面的潜在应用引起了人们的关注。因此,现在是时候探索利用3D生物打印电动汽车作为一种新的“无细胞”替代再生医学方法的潜力和相关挑战。本文综述了电动汽车的生物起源和组成,以及小型电动汽车- sev (< 200 nm)的分离和表征所面临的挑战。概述了常见的3D生物打印技术,并探讨了生物墨水可打印性的问题。在PubMed中应用以下搜索策略:“生物打印外泌体”或“3D生物打印细胞外囊泡”后,发现有8项利用生物打印ev的研究已被纳入本范围综述。本文讨论了目前利用生物打印的sev进行各种体外和体内组织再生应用的研究,包括血管生成、成骨、免疫调节、软骨形成和肌肉生成。最后,我们探讨了当前面临的挑战,并对生物打印sev应用的可能改进进行了展望。