Enhanced Superficial Zone Chondrocyte Expansion and Redifferentiation by Culture on Chondrocyte-Derived Decellularized Matrices.

IF 2.7 4区医学 Q1 ORTHOPEDICS

CARTILAGE Pub Date : 2025-08-31 DOI:10.1177/19476035251369735

Thomas J Manzoni, Anh Ho, Lilly Smull, Valarie C West, Jeffery D V Waters, Karina Lemus, James Adams, Alvin W Su, Justin Parreno

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引用次数: 0

Abstract

BackgroundCell-based therapies to regenerate native-like cartilage are limited by the inability to re-express zone-specific molecules. While monolayer-expanded (passaged) chondrocytes are a clinically approved cell source, the resulting tissues have reduced Proteoglycan-4 (PRG4) expression. This may be due to poor attachment, slow proliferation, and dedifferentiation of superficial zone chondrocytes (SZC) on polystyrene. Optimizing expansion conditions is therefore critical. Chondrocyte-derived decellularized extracellular matrix (CD-ECM) has been shown to enhance proliferation and reduce dedifferentiation of full-thickness chondrocytes, but its effect on SZC remains unknown. We tested the hypothesis that culturing SZC on CD-ECM would improve attachment, proliferation, and reduced dedifferentiation, enabling formation of PRG4-expressing tissue.MethodsPrimary bovine SZC were seeded on polystyrene or CD-ECM. Attachment, expansion rate, and gene expression were evaluated during passaging. Cells from each condition were assessed for their capacity to form PRG4-expressing bioengineered tissue.ResultsPrimary bovine SZC had increased attachment and reached confluency faster on CD-ECM. SZC on CD-ECM were smaller, with fewer actin stress fibers, and exhibited reduced expression of dedifferentiation markers. Furthermore, SZC expanded on CD-ECM were stimulated to form tissues rich in Collagen II and Aggrecan with higher Proteoglycan-4 expression.ConclusionsThe use of CD-ECM for passaging SZC may aid in achieving an adequate number of SZC for bioengineering purposes.

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通过培养软骨细胞衍生的脱细胞基质增强浅表区软骨细胞的增殖和再分化。

基于细胞的软骨再生疗法受到无法重新表达区域特异性分子的限制。虽然单层扩张（传代）软骨细胞是临床批准的细胞来源，但由此产生的组织中蛋白多糖-4 （PRG4）表达减少。这可能是由于聚苯乙烯表面带软骨细胞（SZC）附着不良、增殖缓慢和去分化所致。因此，优化膨胀条件至关重要。软骨细胞来源的脱细胞外基质（CD-ECM）已被证明可以增强全层软骨细胞的增殖并减少其去分化，但其对SZC的影响尚不清楚。我们验证了在CD-ECM上培养SZC可以改善附着、增殖和减少去分化，从而形成表达prg4的组织的假设。方法用聚苯乙烯或CD-ECM分别播种原代牛SZC。在传代过程中评估附着、扩增率和基因表达。评估每种条件下的细胞形成表达prg4的生物工程组织的能力。结果原代牛SZC在CD-ECM上的附着增强，达到融合速度较快。CD-ECM上的SZC较小，肌动蛋白应激纤维较少，去分化标志物表达减少。此外，刺激CD-ECM上的SZC扩增形成富含II型胶原和聚集蛋白的组织，且蛋白聚糖-4表达较高。结论使用CD-ECM传代SZC有助于获得足够数量的SZC用于生物工程目的。

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

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.