Cartilage Organoids from Articular Chondroprogenitor Cells and Their Potential to Produce Neo-Hyaline Cartilage.

IF 2.7 4区医学 Q1 ORTHOPEDICS

CARTILAGE Pub Date : 2025-02-10 DOI:10.1177/19476035241313179

Daphne M A Menssen, Jeske C A Feenstra, Rob P A Janssen, Florencia Abinzano, Keita Ito

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引用次数: 0

Abstract

Introduction: The use of autologous human primary articular chondrocytes (hPACs) for repairing damaged cartilage is the golden standard; however, their 2-dimensional (2D) expansion induces dedifferentiation, making it challenging to create hyaline cartilage. Spinner flasks are efficient for generating cartilage organoids, allowing hPACs to proliferate without dedifferentiation; however, porcine notochordal cell-derived matrix (NCM) is needed for aggregation, limiting clinical application. Human articular chondroprogenitor cells (hACPCs) can be expanded many fold while maintaining chondrogenic potential. Therefore, the scalable production of hACPC cartilage organoids without NCM in spinner flasks was investigated in this study.

Methods: hPAC organoids with NCM and hACPC organoids using bone morphogenetic protein 9 (BMP-9) were produced in spinner flasks in 14 days. Thereafter, approximately 20 organoids were fused in low adhesive wells for 21 days. Organoids underwent mechanical testing, and both organoids and fused constructs were evaluated using biochemical, histological, and immunohistochemical analysis.

Results: The hACPCs self-assembled and synthesized abundant extracellular matrix once stimulated with BMP-9. The hPAC and hACPC organoids showed similar mechanical properties, but hACPC organoids and fused constructs showed a more uniform matrix and cell distribution.

Conclusion: The hACPC organoids fused into a neo-hyaline cartilage-like tissue, demonstrating their potential for improved, scalable cartilage tissue repair.

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简介：使用自体人类原代关节软骨细胞（hPACs）修复受损软骨是黄金标准；然而，它们的二维（2D）扩增会诱发再分化，这使得创建透明软骨具有挑战性。旋转瓶能有效生成软骨组织块，使hPACs增殖而不发生再分化；然而，猪脊索细胞衍生基质（NCM）需要聚集，限制了临床应用。人关节软骨生成细胞（hACPCs）可扩增数倍，同时保持软骨生成潜能。因此，本研究调查了在旋转瓶中不使用 NCM 的 hACPC 软骨器官组织的规模化生产情况。方法：在旋转瓶中使用骨形态发生蛋白 9（BMP-9）在 14 天内生产出含有 NCM 的 hPAC 器官组织和 hACPC 器官组织。之后，将大约 20 个器官组织融合在低粘性孔中 21 天。对器官组织进行机械测试，并通过生化、组织学和免疫组化分析对器官组织和融合构建体进行评估：结果：在BMP-9的刺激下，hACPCs能自我组装并合成丰富的细胞外基质。hPAC和hACPC器官组织显示出相似的机械性能，但hACPC器官组织和融合构建物显示出更均匀的基质和细胞分布：结论：hACPC有机体融合成新软骨样组织，显示了其在改善软骨组织修复方面的潜力。

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来源期刊

CARTILAGE ORTHOPEDICS-

CiteScore

6.90

自引率

7.10%

发文量

期刊介绍： CARTILAGE publishes articles related to the musculoskeletal system with particular attention to cartilage repair, development, function, degeneration, transplantation, and rehabilitation. The journal is a forum for the exchange of ideas for the many types of researchers and clinicians involved in cartilage biology and repair. A primary objective of CARTILAGE is to foster the cross-fertilization of the findings between clinical and basic sciences throughout the various disciplines involved in cartilage repair. The journal publishes full length original manuscripts on all types of cartilage including articular, nasal, auricular, tracheal/bronchial, and intervertebral disc fibrocartilage. Manuscripts on clinical and laboratory research are welcome. Review articles, editorials, and letters are also encouraged. The ICRS envisages CARTILAGE as a forum for the exchange of knowledge among clinicians, scientists, patients, and researchers. The International Cartilage Repair Society (ICRS) is dedicated to promotion, encouragement, and distribution of fundamental and applied research of cartilage in order to permit a better knowledge of function and dysfunction of articular cartilage and its repair.