人类胚胎干细胞的无异种软骨分化自动化:提高效率,确保高质量批量生产

IF 3.4 3区 环境科学与生态学 Q3 CELL & TISSUE ENGINEERING
JunLong Chen , Oki Kataoka , Kazeto Tsuchiya , Yoshie Oishi , Ayumi Takao , Yen-Chih Huang , Hiroko Komura , Saeko Akiyama , Ren Itou , Masafumi Inui , Shin Enosawa , Hidenori Akutsu , Makoto Komura , Yasushi Fuchimoto , Akihiro Umezawa
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引用次数: 0

摘要

导言:修复受损软骨是一项重大挑战,尤其是在先天性软骨缺损(如小耳症或先天性气管狭窄)或外伤的情况下,因为软骨的再生潜力本身就是有限的。干细胞疗法和组织工程学为克服软骨愈合中的这些局限性提供了前景广阔的方法。然而,挑战在于含软骨器官的大小,这就需要大量细胞来填充受损区域。因此,可无限增殖的多能干细胞是非常理想的细胞来源。本研究旨在确定从人类胚胎干细胞(ESCs)中提取软骨的分化条件,并开发一种自动化细胞培养系统,以促进治疗应用的大规模生产。方法通过传统的手工培养或台式多管培养器和自动培养基交换集成细胞培养箱,使用无异种培养基形成胚状体(EBs),从人类ESCs(SEES2,临床试验兼容品系)中提取软骨细胞片。将细胞片植入免疫缺陷 NOG 小鼠的皮下组织以获得软骨组织。通过组织学染色和定量 PCR 分析检测了软骨组织的特性。分化的软骨在组织学上是一致的,具有软骨特有的弹性和强度。软骨组织经阿尔新蓝、黄芩苷 O 和甲苯胺蓝染色,定量 PCR 显示 ACAN、COL2A1 和 Vimentin 等分化标记物增加。自动化大大提高了人ESC衍生软骨细胞分化的效率。EB 中组成细胞的数量和 EB 的播种密度是影响软骨分化效率的关键因素。通过将软骨分化过程自动化,我们实现了软骨细胞的规模化生产。由此产生的软骨组织有望用于气管、关节、耳朵和鼻子等器官的临床修复。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Automated xeno-free chondrogenic differentiation from human embryonic stem cells: Enhancing efficiency and ensuring high-quality mass production

Introduction

Repairing damaged cartilage poses significant challenges, particularly in cases of congenital cartilage defects such as microtia or congenital tracheal stenosis, or as a consequence of traumatic injury, as the regenerative potential of cartilage is inherently limited. Stem cell therapy and tissue engineering offer promising approaches to overcome these limitations in cartilage healing. However, the challenge lies in the size of cartilage-containing organs, which necessitates a large quantity of cells to fill the damaged areas. Therefore, pluripotent stem cells that can proliferate indefinitely are highly desirable as a cell source. This study aims to delineate the differentiation conditions for cartilage derived from human embryonic stem cells (ESCs) and to develop an automated cell culture system to facilitate mass production for therapeutic applications.

Methods

Cartilage cell sheets were derived from human ESCs (SEES2, clinical trial-compatible line) by forming embryoid bodies (EBs) with either conventional manual culture or a benchtop multi-pipetter and an automated medium exchange integrated cell incubator, using xeno-free media. Cell sheets were implanted into the subcutaneous tissue of immunodeficient NOG mice to obtain cartilage tissue. The properties of cartilage tissues were examined by histological staining and quantitative PCR analysis.

Results

We have optimized an efficient xeno-free system for cartilage production with the conventional culture method and successfully transitioned to an automated system. Differentiated cartilage was histologically uniform with cartilage-specific elasticity and strength. The cartilage tissues were stained by Alcian blue, safranin O, and toluidine blue, and quantitative PCR showed an increase in differentiation markers such as ACAN, COL2A1, and Vimentin. Automation significantly enhanced the efficiency of human ESC-derived chondrocyte differentiation. The number of constituent cells within EBs and the seeding density of EBs were identified as key factors influencing chondrogenic differentiation efficiency. By automating the process of chondrogenic differentiation, we achieved scalable production of chondrocytes.

Conclusions

By integrating the differentiation protocol with an automated cell culture system, there is potential to produce cartilage of sufficient size for clinical applications in humans. The resulting cartilage tissue holds promise for clinical use in repairing organs such as the trachea, joints, ears, and nose.
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来源期刊
Regenerative Therapy
Regenerative Therapy Engineering-Biomedical Engineering
CiteScore
6.00
自引率
2.30%
发文量
106
审稿时长
49 days
期刊介绍: Regenerative Therapy is the official peer-reviewed online journal of the Japanese Society for Regenerative Medicine. Regenerative Therapy is a multidisciplinary journal that publishes original articles and reviews of basic research, clinical translation, industrial development, and regulatory issues focusing on stem cell biology, tissue engineering, and regenerative medicine.
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