Kim Hyung-Jun, Park Sohyun, Jeong Seonghyeon, Kim Jihoon, Cho Young-Jae
Division of Pulmonary and Critical Care Medicine, Department of Internal Medicine, Seoul National University Bundang Hospital, Seongnam, Korea.
Department of Internal Medicine, Seoul National University College of Medicine, Seoul, Korea.
Int J Stem Cells. 2024 Feb 28;17(1):30-37. doi: 10.15283/ijsc23090. Epub 2023 Oct 11.
The lung is a complex organ comprising a branched airway that connects the large airway and millions of terminal gas-exchange units. Traditional pulmonary biomedical research by using cell line model system have limitations such as lack of cellular heterogeneity, animal models also have limitations including ethical concern, race-to-race variations, and physiological differences found . Organoids and on-a-chip models offer viable solutions for these issues. Organoids are three-dimensional, self-organized construct composed of numerous cells derived from stem cells cultured with growth factors required for the maintenance of stem cells. On-a-chip models are biomimetic microsystems which are able to customize to use microfluidic systems to simulate blood flow in blood channels or vacuum to simulate human breathing. This review summarizes the key components and previous biomedical studies conducted on lung organoids and lung-on-a-chip models, and introduces potential future applications. Considering the importance and benefits of these model systems, we believe that the system will offer better platform to biomedical researchers on pulmonary diseases, such as emerging viral infection, progressive fibrotic pulmonary diseases, or primary or metastatic lung cancer.
肺是一个复杂的器官,由连接大气道和数百万个终末气体交换单位的分支气道组成。传统的利用细胞系模型系统进行的肺部生物医学研究存在局限性,如缺乏细胞异质性,动物模型也存在局限性,包括伦理问题、种族差异以及生理差异。类器官和芯片上模型为这些问题提供了可行的解决方案。类器官是三维的、自组织的结构,由许多源自干细胞的细胞组成,这些干细胞在维持干细胞所需的生长因子作用下培养而成。芯片上模型是仿生微系统,能够定制使用微流体系统来模拟血液通道中的血流或真空来模拟人类呼吸。本综述总结了肺类器官和肺芯片上模型的关键组成部分以及先前进行的生物医学研究,并介绍了潜在的未来应用。考虑到这些模型系统的重要性和益处,我们相信该系统将为肺部疾病的生物医学研究人员提供更好的平台,如新兴病毒感染、进行性纤维化肺部疾病或原发性或转移性肺癌。
