Synergistic effects of biological stimuli and flexion induce microcavities promote hypertrophy and inhibit chondrogenesis during in vitro culture of human mesenchymal stem cell aggregates

IF 3.2 3区 生物学 Q2 BIOCHEMICAL RESEARCH METHODS
Bo Zhang, Jim Berilla, Sungwoo Cho, Rodrigo A. Somoza, Jean F. Welter, Peter E. Alexander, Harihara Baskaran
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引用次数: 0

Abstract

Interzone/cavitation are key steps in early stage joint formation that have not been successfully developed in vitro. Further, current models of endochondral ossification, an important step in early bone formation, lack key morphology morphological structures such as microcavities found during development in vivo. This is possibly due to the lack of appropriate strategies for incorporating chemical and mechanical stimuli that are thought to be involved in joint development. We designed a bioreactor system and investigated the synergic effect of chemical stimuli (chondrogenesis-inducing [CIM] and hypertrophy-inducing medium [HIM]) and mechanical stimuli (flexion) on the growth of human mesenchymal stem cells (hMSCs) based linear aggregates under different conditions over 4 weeks of perfusion culture. Computational studies were used to evaluate tissue stress qualitatively. After harvesting, both Safranin-O and hematoxylin & eosin (H&E) staining histology demonstrated microcavity structures and void structures in the region of higher stresses for tissue aggregates cultured only in HIM under flexion. In comparison to either HIM treatment or flexion only, increased glycosaminoglycan (GAG) content in the extracellular matrix (ECM) at this region indicates the morphological change resembles the early stage of joint cavitation; while decreased type II collagen (Col II), and increased type X collagen (Col X) and vascular endothelial growth factor (VEGF) with a clear boundary in the staining section indicates it resembles the early stage of ossification. Further, cell alignment analysis indicated that cells were mostly oriented toward the direction of flexion in high-stress region only in HIM under flexion, resembling cell morphology in both joint cavitation and hypertrophic cartilage in growth plate. Collectively, our results suggest that flexion and HIM inhibit chondrogenesis and promote hypertrophy and development of microcavities that resemble the early stage of joint cavitation and endochondral ossification. We believe the tissue model described in this work can be used to develop in vitro models of joint tissue for applications such as pathophysiology and drug discovery.

Abstract Image

生物刺激和屈曲诱导微腔的协同作用在体外培养人间充质干细胞聚集体的过程中促进肥大并抑制软骨生成。
区间/空腔是早期关节形成的关键步骤,但尚未在体外成功开发。此外,目前的软骨内骨化模型(早期骨形成的重要步骤)缺乏关键的形态结构,如体内发育过程中发现的微空腔。这可能是由于缺乏适当的策略来纳入化学和机械刺激,而这些刺激被认为参与了关节的发育。我们设计了一个生物反应器系统,并研究了化学刺激(软骨生成诱导培养基[CIM]和肥大诱导培养基[HIM])和机械刺激(屈曲)对基于人间充质干细胞(hMSCs)的线性聚集体在不同条件下生长的协同效应。计算研究用于定性评估组织应力。收获后,Safranin-O 和苏木精及伊红(H&E)染色组织学显示,仅在 HIM 中屈曲培养的组织聚集体在较高应力区域存在微腔结构和空隙结构。与 HIM 处理或仅屈曲相比,该区域细胞外基质(ECM)中的糖胺聚糖(GAG)含量增加,表明其形态变化类似于关节空洞化的早期阶段;而染色切片中边界清晰的 II 型胶原(Col II)减少,X 型胶原(Col X)和血管内皮生长因子(VEGF)增加,表明其类似于骨化的早期阶段。此外,细胞排列分析表明,只有在屈曲状态下的 HIM 中,细胞在高应力区大多朝向屈曲方向,这与关节空洞化和生长板肥厚软骨中的细胞形态相似。总之,我们的研究结果表明,屈曲和 HIM 可抑制软骨生成,促进肥大和微腔的发展,这与关节空洞化和软骨内骨化的早期阶段相似。我们相信,这项工作中描述的组织模型可用于开发关节组织的体外模型,以应用于病理生理学和药物发现等领域。
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
Biotechnology Journal
Biotechnology Journal Biochemistry, Genetics and Molecular Biology-Molecular Medicine
CiteScore
8.90
自引率
2.10%
发文量
123
审稿时长
1.5 months
期刊介绍: Biotechnology Journal (2019 Journal Citation Reports: 3.543) is fully comprehensive in its scope and publishes strictly peer-reviewed papers covering novel aspects and methods in all areas of biotechnology. Some issues are devoted to a special topic, providing the latest information on the most crucial areas of research and technological advances. In addition to these special issues, the journal welcomes unsolicited submissions for primary research articles, such as Research Articles, Rapid Communications and Biotech Methods. BTJ also welcomes proposals of Review Articles - please send in a brief outline of the article and the senior author''s CV to the editorial office. BTJ promotes a special emphasis on: Systems Biotechnology Synthetic Biology and Metabolic Engineering Nanobiotechnology and Biomaterials Tissue engineering, Regenerative Medicine and Stem cells Gene Editing, Gene therapy and Immunotherapy Omics technologies Industrial Biotechnology, Biopharmaceuticals and Biocatalysis Bioprocess engineering and Downstream processing Plant Biotechnology Biosafety, Biotech Ethics, Science Communication Methods and Advances.
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