类器官芯片技术的最新进展与挑战

Intan Rosalina Suhito, Tae-Hyung Kim
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引用次数: 2

摘要

传统的二维细胞培养很难模仿人类相关的模型,这被认为是生物学研究中的一个主要挑战。类器官是最近在三维(3D)体外组织工程中取得的突破,它能更好地反映体内器官(如脑、心、肾、肺和肝)的生理、形态和功能特性。因此,类器官被广泛应用于各种有影响力的生物医学应用,包括器官发育、疾病建模和临床药物测试。然而,类器官技术仍然存在一些局限性,包括低可重复性、血管化、营养吸收和分布有限(影响类器官成熟水平)、缺乏标准化和克隆内变异性。人们已经努力克服类器官培养的这些缺点。微流控技术成功地促进了类器官芯片系统的建立,有效地控制了类器官的结构和生理特征。本文综述了类器官芯片技术的最新进展。我们希望这项研究将激励研究人员探索微流体装置和自组装3D细胞培养之间的可能结合,以利用提高的类器官质量,这将对未来的组织再生和再生治疗产生有利的影响。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Recent advances and challenges in organoid-on-a-chip technology
Conventional 2-dimensional cell culture poorly mimics human-relevant models, which is considered a major challenge in biological research. Organoids are a recent breakthrough in 3-dimensional (3D) in vitro tissue engineering that better reflect the physiological, morphological, and functional properties of in vivo organs (e.g., brain, heart, kidney, lung, and liver). Consequently, organoids are extensively used in various impactful biomedical applications including organ development, disease modeling, and clinical drug testing. However, organoid technology still has several limitations, including low reproducibility, vascularization, limited nutrient uptake and distribution (affecting the level of organoid maturation), lack of standardization, and intra-clonal variability. Efforts have been made to overcome these shortcomings of organoid culture. Microfluidic technology has successfully facilitated the establishment of organoid-on-a-chip systems, which effectively improve the structural and physiological features of organoids in a controlled manner. This review discusses the recent advances and developments in organoid-on-a-chip technology. We hope that this study will motivate researchers to explore the possible engagement between microfluidic devices and self-assembled 3D cell cultures to leverage the enhanced quality of organoids, which will have favorable impacts on future tissue regeneration and regenerative therapies.
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