Artificial Microvesicles: New Perspective on Healing Tendon Wounds.

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2024-01-01 Epub Date: 2022-09-01 DOI:10.1159/000526845
Elena Zakirova, Alexander Aimaletdinov, Milana Mansurova, Angelina Titova, Igor Kurilov, Catrin Sian Rutland, Albina Malanyeva, Albert Rizvanov
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Abstract

Tendons have a limited capacity to repair both naturally and following clinical interventions. Damaged tissue often presents with structural and functional differences, adversely affecting animal performance, mobility, health, and welfare. Advances in cell therapies have started to overcome some of these issues, however complications such as the formation of ectopic bone remain a complication of this technique. Regenerative medicine is therefore looking toward future therapies such as the introduction of microvesicles (MVs) derived from stem cells (SCs). The aim of the present study was to assess the characteristics of artificially derived MVs, from equine mesenchymal stem cells (MSCs), when delivered to rat tendon cells in vitro and damaged tendons in vivo. The initial stages of extracting MVs from equine MSCs and identifying and characterizing the cultured tendon stem/progenitor cells (TSCs) from rat Achilles tendons were undertaken successfully. The horse MSCs and the rat tendon cells were both capable of differentiating in 3 directions: adipogenic, osteogenic, and chondrogenic pathways. The artificially derived equine MVs successfully fused with the TSC membranes, and no cytotoxic or cytostimulating effects were observed. In addition, co-cultivation of TSCs with MVs led to stimulation of cell proliferation and migration, and cytokine VEGF and fractalkine expression levels were significantly increased. These experiments are the first to show that artificially derived MVs exhibited regeneration-stimulating effects in vitro, and that fusion of cytoplasmic membranes from diploid cell lines originating from different species was possible. The experiment in vivo demonstrated the influence of MVs on synthesis of collagen I and III types in damaged tendons of rats. Explorations in vivo showed accelerated regeneration of injured tendons after introduction of the MVs into damaged areas. The results from the studies performed indicated obvious positive modifying effects following the administration of MVs. This represents the initial successful step required prior to translating this regenerative medicine technique into clinical trials, such as for tendon repair in injured horses.

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人造微囊:肌腱伤口愈合的新视角。
肌腱的自然修复和临床干预能力有限。受损组织通常会出现结构和功能差异,对动物的表现、活动能力、健康和福利产生不利影响。细胞疗法的进步已开始克服其中一些问题,但异位骨的形成等并发症仍是这种技术的并发症之一。因此,再生医学正将目光投向未来的疗法,如引入源自干细胞(SCs)的微囊泡(MVs)。本研究旨在评估从马间质干细胞(MSCs)中人工提取的微囊在体外输送到大鼠肌腱细胞和体内受损肌腱时的特性。从马间充质干细胞中提取中胚层物质以及从大鼠跟腱中鉴定和表征培养的肌腱干/祖细胞(TSCs)的初始阶段已经成功完成。马间充质干细胞和大鼠肌腱细胞都能向三个方向分化:成脂、成骨和软骨途径。人工衍生的马间充质干细胞成功地与TSC膜融合,且未观察到细胞毒性或细胞刺激作用。此外,TSCs 与 MVs 共同培养可刺激细胞增殖和迁移,细胞因子 VEGF 和 Fractalkine 的表达水平也显著增加。这些实验首次表明,人工衍生的中空膜在体外具有刺激再生的作用,而且来自不同物种的二倍体细胞系的细胞质膜可以融合。体内研究表明,将中空蛋白导入受损部位后,受伤肌腱的再生速度加快。研究结果表明,使用中空蛋白后,会产生明显的积极调节作用。这表明,在将这种再生医学技术转化为临床试验(如用于受伤马匹的肌腱修复)之前,已经迈出了成功的第一步。
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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