Advancement of Organoid Technology in Regenerative Medicine.

IF 2.2 Q3 ENGINEERING, BIOMEDICAL
Babak Arjmand, Zahra Rabbani, Faezeh Soveyzi, Akram Tayanloo-Beik, Mostafa Rezaei-Tavirani, Mahmood Biglar, Hossein Adibi, Bagher Larijani
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引用次数: 4

Abstract

Purpose: Organoids are three-dimensional cultures of stem cells in an environment similar to the body's extracellular matrix. This is also a novel development in the realm of regenerative medicine. Stem cells can begin to develop into 3D structures by modifying signaling pathways. To form organoids, stem cells are transplanted into the extracellular matrix. Organoids have provided the required technologies to reproduce human tissues. As a result, it might be used in place of animal models in scientific study. The key goals of these investigations are research into viral and genetic illnesses, malignancies, and extracellular vesicles, pharmaceutical discovery, and organ transplantation. Organoids can help pave the road for precision medicine through genetic editing, pharmaceutical development, and cell therapy.

Methods: PubMed, Google Scholar, and Scopus were used to search for all relevant papers written in English (1907-2021). The study abstracts were scrutinized. Studies on the use of stem-cell-derived organoids in regenerative medicine, organoids as 3D culture models for EVs analysis, and organoids for precision medicine were included. Articles with other irrelevant aims, meetings, letters, commentaries, congress and conference abstracts, and articles with no available full texts were excluded.

Results: According to the included studies, organoids have various origins, types, and applications in regenerative and precision medicine, as well as an important role in studying extracellular vesicles.

Conclusion: Organoids are considered a bridge that connects preclinical studies to clinical ones. However, the lack of a standardized protocol and other barriers addressed in this review, hinder the vast use of this technology.

Lay summary: Organoids are 3D stem cell propagations in biological or synthetic scaffolds that mimic ECM to allow intercellular or matrix-cellular crosstalk. Because these structures are similar to organs in the body, they can be used as research models. Organoids are medicine's future hope for organ transplantation, tumor biobank formation, and the development of precision medicine. Organoid models can be used to study cell-to-cell interactions as well as effective factors like inflammation and aging. Bioengineering technologies are also used to define the size, shape, and composition of organoids before transforming them into precise structures. Finally, the importance of organoid applications in regenerative medicine has opened a new window for a better understanding of biological research, as discussed in this study.

Abstract Image

Abstract Image

类器官技术在再生医学中的进展。
目的:类器官是干细胞在类似于人体细胞外基质环境中的三维培养。这也是再生医学领域的一个新发展。通过改变信号通路,干细胞可以开始发育成3D结构。为了形成类器官,干细胞被移植到细胞外基质中。类器官提供了复制人体组织所需的技术。因此,它可以代替动物模型用于科学研究。这些研究的主要目标是研究病毒和遗传疾病、恶性肿瘤、细胞外囊泡、药物发现和器官移植。类器官可以通过基因编辑、药物开发和细胞治疗为精准医疗铺平道路。方法:使用PubMed、Google Scholar和Scopus检索1907-2021年所有相关英文论文。研究摘要被仔细审查了。包括干细胞衍生类器官在再生医学中的应用研究,类器官作为ev分析的3D培养模型,以及用于精准医学的类器官。具有其他不相关目的的文章、会议、信件、评论、大会和会议摘要以及没有全文的文章被排除在外。结果:根据纳入的研究,类器官具有多种来源、类型和在再生医学和精准医学中的应用,并在细胞外囊泡研究中发挥重要作用。结论:类器官被认为是连接临床前研究和临床研究的桥梁。然而,缺乏标准化的协议和其他障碍,阻碍了这项技术的广泛使用。概要:类器官是三维干细胞在生物或合成支架中的繁殖,模拟ECM,允许细胞间或基质-细胞串扰。由于这些结构与人体器官相似,因此可以用作研究模型。类器官是器官移植、肿瘤生物库形成、精准医学发展的未来希望。类器官模型可用于研究细胞间的相互作用以及炎症和衰老等有效因素。生物工程技术还用于确定类器官的大小、形状和组成,然后将其转化为精确的结构。最后,正如本研究所讨论的,类器官在再生医学中的重要性为更好地理解生物学研究打开了一扇新的窗口。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
4.90
自引率
11.50%
发文量
41
期刊介绍: Regenerative Engineering is an international journal covering convergence of the disciplines of tissue engineering, advanced materials science, stem cell research, the physical sciences, and areas of developmental biology. This convergence brings exciting opportunities to translate bench-top research into bedside methods, allowing the possibility of moving beyond maintaining or repairing tissues to regenerating them. The journal encourages both top-down engineering approaches and bottom-up strategies integrating materials science with stem cell research and developmental biology. Convergence papers on instructive biomaterials, stimuli-responsive biomaterials, micro- and nano-patterning for regenerative engineering, elastomeric biomaterials, hydrogels for tissue engineering, and rapid prototyping and bioprinting approaches are particularly welcome. The journal provides a premier, single-blind peer-reviewed forum for the publication of original papers, authoritative reviews, rapid communications, news and views, and opinion papers addressing the most important issues and efforts toward successfully regenerating complex human tissues and organs. All research articles feature a lay abstract highlighting the relevance and future impact for patients, government and other health officials, and members of the general public. Bridging the gap between the lab and the clinic, the journal also serves as a dedicated platform for showcasing translational research that brings basic scientific research and discoveries into clinical methods and therapies, contributing to the improvement of human health care. Topics covered in Regenerative Engineering and Translational Medicine include: Advanced materials science for regenerative and biomedical applicationsStem cells for tissue regenerationDrug delivery for tissue regenerationNanomaterials and nanobiotechnology for tissue regenerationStudies combining tissue engineering/regeneration with developmental biologyConvergence research in pre-clinical and clinical phases
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