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用于马匹治疗应用的自体骨髓间充质基质细胞运输条件评估

Evaluation of transport conditions for autologous bone marrow-derived mesenchymal stromal cells for therapeutic application in horses.

作者信息

Espina Miguel, Jülke Henriette, Brehm Walter, Ribitsch Iris, Winter Karsten, Delling Uta

机构信息

Large Animal Clinic for Surgery, Faculty of Veterinary Medicine, University of Leipzig , Leipzig , Germany.

Translational Centre for Regenerative Medicine (TRM), University of Leipzig , Leipzig , Germany.

出版信息

PeerJ. 2016 Mar 22;4:e1773. doi: 10.7717/peerj.1773. eCollection 2016.

DOI:10.7717/peerj.1773
PMID:27019778
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4806605/
Abstract

Background. Mesenchymal stromal cells (MSCs) are increasingly used for clinical applications in equine patients. For MSC isolation and expansion, a laboratory step is mandatory, after which the cells are sent back to the attending veterinarian. Preserving the biological properties of MSCs during this transport is paramount. The goal of the study was to compare transport-related parameters (transport container, media, temperature, time, cell concentration) that potentially influence characteristics of culture expanded equine MSCs. Methods. The study was arranged in three parts comparing (I) five different transport containers (cryotube, two types of plastic syringes, glass syringe, CellSeal), (II) seven different transport media, four temperatures (4 °C vs. room temperature; -20 °C vs. -80 °C), four time frames (24 h vs. 48 h; 48 h vs. 72 h), and (III) three MSC concentrations (5 × 10(6), 10 × 10(6), 20 × 10(6) MSC/ml). Cell viability (Trypan Blue exclusion; percent and total number viable cell), proliferation and trilineage differentiation capacity were assessed for each test condition. Further, the recovered volume of the suspension was determined in part I. Each condition was evaluated using samples of six horses (n = 6) and differentiation protocols were performed in duplicates. Results. In part I of the study, no significant differences in any of the parameters were found when comparing transport containers at room temperature. The glass syringe was selected for all subsequent evaluations (highest recoverable volume of cell suspension and cell viability). In part II, media, temperatures, or time frames had also no significant influence on cell viability, likely due to the large number of comparisons and small sample size. Highest cell viability was observed using autologous bone marrow supernatant as transport medium, and "transport" at 4 °C for 24 h (70.6% vs. control group 75.3%); this was not significant. Contrary, viability was unacceptably low (<40%) for all freezing protocols at -20 °C or -80 °C, particularly with bone marrow supernatant or plasma and DMSO. In part III, various cell concentrations also had no significant influence on any of the evaluated parameters. Chondrogenic differentiation showed a trend towards being decreased for all transport conditions, compared to control cells. Discussion. In this study, transport conditions were not found to impact viability, proliferation or ability for trilineage differentiation of MSCs, most likely due to the small sample size and large number of comparisons. The unusual low viability after all freezing protocols is in contrast to previous equine studies. Potential causes are differences in the freezing, but also in thawing method. Also, the selected container (glass syringe) may have impacted viability. Future research may be warranted into the possibly negative effect of transport on chondrogenic differentiation.

摘要

背景。间充质基质细胞(MSCs)越来越多地用于马属动物患者的临床应用。对于MSCs的分离和扩增,实验室步骤是必不可少的,之后细胞会被送回主治兽医处。在此运输过程中保持MSCs的生物学特性至关重要。本研究的目的是比较可能影响培养扩增的马属动物MSCs特性的运输相关参数(运输容器、培养基、温度、时间、细胞浓度)。方法。本研究分为三个部分,比较(I)五种不同的运输容器(冷冻管、两种类型的塑料注射器、玻璃注射器、CellSeal),(II)七种不同的运输培养基、四种温度(4℃与室温;-20℃与-80℃)、四个时间框架(24小时与48小时;48小时与72小时),以及(III)三种MSCs浓度(5×10⁶、10×10⁶、20×10⁶个MSCs/ml)。对每种测试条件评估细胞活力(台盼蓝排斥法;活细胞百分比和总数)、增殖和三系分化能力。此外,在第一部分中测定了悬浮液的回收体积。每种条件使用六匹马的样本进行评估(n = 6),分化方案重复进行。结果。在研究的第一部分,在室温下比较运输容器时,未发现任何参数有显著差异。选择玻璃注射器用于所有后续评估(细胞悬浮液的可回收体积和细胞活力最高)。在第二部分中,培养基、温度或时间框架对细胞活力也没有显著影响,可能是由于比较次数多且样本量小。使用自体骨髓上清液作为运输培养基并在4℃下“运输”24小时时观察到最高细胞活力(70.6%对对照组75.3%);这没有统计学意义。相反,在-20℃或-80℃的所有冷冻方案中,活力低至不可接受(<40%),特别是使用骨髓上清液或血浆以及二甲基亚砜时。在第三部分中,各种细胞浓度对任何评估参数也没有显著影响。与对照细胞相比,所有运输条件下软骨分化均呈下降趋势。讨论。在本研究中,未发现运输条件会影响MSCs的活力、增殖或三系分化能力,很可能是由于样本量小和比较次数多。所有冷冻方案后异常低的活力与之前的马属动物研究结果相反。潜在原因可能是冷冻方法以及解冻方法的差异。此外,所选容器(玻璃注射器)可能影响了活力。未来可能需要研究运输对软骨分化的潜在负面影响。

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