Development of scaffold-free tissue-engineered constructs derived from mesenchymal stem cells with serum-free media for cartilage repair and long-term preservation

IF 2 4区 生物学 Q3 BIOTECHNOLOGY & APPLIED MICROBIOLOGY Cytotechnology Pub Date : 2024-07-02 DOI:10.1007/s10616-024-00637-y
Satoshi Maeda, Masaya Matsumoto, Kotaro Segawa, Kaori Iwamoto, Norimasa Nakamura
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Abstract

Synovial mesenchymal stem cells (sMSCs) have great potential for cartilage repair, but their therapeutic design to avoid adverse effects associated with unknown factors remains a challenge. In addition, because long-term preservation is indispensable to maintain high quality levels until implantation, it is necessary to reduce their fluctuations. This study aimed to investigate the properties and feasibility of novel scaffold-free tissue-engineered constructs using serum-free media and to develop long-term preservation methods. sMSCs were cultured in serum-free media, seeded at high density in a monolayer, and finally developed as a sheet-like construct called “gMSC1”. The properties of frozen gMSC1 (Fro-gMSC1) were compared with those of refrigerated gMSC1 (Ref-gMSC1) and then examined by their profile. Chondrogenic differentiation potential was analyzed by quantitative real-time polymerase chain reaction and quantification of glycosaminoglycan content. Xenografts into the cartilage defect model in rats were evaluated by histological staining. gMSC1 showed nearly similar properties independent of the preservation conditions. The animal experiment demonstrated that the defect could be filled with cartilage-like tissue with good integration to the adjacent tissue, suggesting that gMSC1 was formed and replaced the cartilage. Furthermore, several chondrogenesis-related factors were significantly secreted inside and outside gMSC1. Morphological analysis of Fro-gMSC1 revealed comparable quality levels to those of fresh gMSC1. Thus, if cryopreserved, gMSC1, with no complicated materials or processes, could have sustained cartilage repair capacity. gMSC1 is a prominent candidate in novel clinical practice for cartilage repair, allowing for large quantities to be manufactured at one time and preserved for a long term by freezing.

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利用无血清培养基开发由间充质干细胞衍生的无支架组织工程构建物,用于软骨修复和长期保存
滑膜间充质干细胞(sMSCs)在软骨修复方面具有巨大潜力,但其治疗设计如何避免未知因素带来的不良影响仍是一项挑战。此外,由于长期保存对于在植入前保持高质量水平不可或缺,因此有必要减少其波动。本研究旨在利用无血清培养基研究新型无支架组织工程构建物的特性和可行性,并开发长期保存方法。在无血清培养基中培养 sMSCs,并将其高密度单层播种,最终形成片状构建物 "gMSC1"。将冷冻的 gMSC1(Fro-gMSC1)与冷藏的 gMSC1(Ref-gMSC1)的特性进行比较,然后对它们的特征进行研究。通过实时定量聚合酶链反应和糖胺聚糖含量定量分析了软骨分化潜能。gMSC1显示出几乎相似的特性,与保存条件无关。动物实验表明,缺损部位可以被软骨样组织填充,并与邻近组织很好地融合,这表明 gMSC1 已经形成并取代了软骨。此外,gMSC1 内外还显著分泌了多种软骨生成相关因子。Fro-gMSC1的形态学分析表明,其质量水平与新鲜gMSC1相当。因此,如果进行冷冻保存,gMSC1 不需要复杂的材料或过程,就能具有持续的软骨修复能力。gMSC1 可以一次性大量生产,并通过冷冻长期保存,是临床软骨修复新方法的一个重要候选材料。
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来源期刊
Cytotechnology
Cytotechnology 生物-生物工程与应用微生物
CiteScore
4.10
自引率
0.00%
发文量
49
审稿时长
6-12 weeks
期刊介绍: The scope of the Journal includes: 1. The derivation, genetic modification and characterization of cell lines, genetic and phenotypic regulation, control of cellular metabolism, cell physiology and biochemistry related to cell function, performance and expression of cell products. 2. Cell culture techniques, substrates, environmental requirements and optimization, cloning, hybridization and molecular biology, including genomic and proteomic tools. 3. Cell culture systems, processes, reactors, scale-up, and industrial production. Descriptions of the design or construction of equipment, media or quality control procedures, that are ancillary to cellular research. 4. The application of animal/human cells in research in the field of stem cell research including maintenance of stemness, differentiation, genetics, and senescence, cancer research, research in immunology, as well as applications in tissue engineering and gene therapy. 5. The use of cell cultures as a substrate for bioassays, biomedical applications and in particular as a replacement for animal models.
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