Pre-culture of mesenchymal stem cells within RGD-modified hyaluronic acid hydrogel improves their resilience to ischaemic conditions

IF 9.4 1区医学 Q1 ENGINEERING, BIOMEDICAL

Acta Biomaterialia Pub Date : 2020-04-15 DOI:10.1016/j.actbio.2020.02.043

Laura B. Gallagher , Eimear B. Dolan , Janice O'Sullivan , Ruth Levey , Brenton L. Cavanagh , Lenka Kovarova , Martin Pravda , Vladimir Velebny , Tom Farrell , Fergal J. O'Brien , Garry P. Duffy

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引用次数: 15

Abstract

The incorporation of the RGD peptide (arginine-glycine-aspartate) into biomaterials has been proposed to promote cell adhesion to the matrix, which can influence and control cell behaviour and function. While many studies have utilised RGD modified biomaterials for cell delivery, few have examined its effect under the condition of reduced oxygen and nutrients, as found at ischaemic injury sites. Here, we systematically examine the effect of RGD on hMSCs in hyaluronic acid (HA) hydrogel under standard and ischaemic culture conditions, to elucidate under what conditions RGD has beneficial effects over unmodified HA and its effectiveness in improving cell viability. Results demonstrate that under standard culture conditions, RGD significantly increased hMSC spreading and the release of vascular endothelial factor-1 (VEGF) and monocyte chemoattractant factor-1 (MCP-1), compared to unmodified HA hydrogel. As adhesion is known to influence cell survival, we hypothesised that cells in RGD hydrogels would exhibit increased cell viability under ischaemic culture conditions. However, results demonstrate that cell viability and protein release was comparable in both RGD modified and unmodified HA hydrogels. Confocal imaging revealed cellular morphology indicative of weak cell adhesion. Subsequent investigations found that RGD was could exert positive effects on encapsulated cells under ischaemic conditions but only if hMSCs were pre-cultured under standard conditions to allow strong adhesion to RGD before exposure. Together, these results provide novel insight into the value of RGD introduction and suggest that the adhesion of hMSCs to RGD prior to delivery could improve survival and function at ischaemic injury sites.

Statement of significance

The development of a biomaterial scaffold capable of maintaining cell viability while promoting cell function is a major research goal in the field of cardiac tissue engineering. This study confirms the suitability of a modified HA hydrogel whereby stem cells in the modified hydrogel showed significantly greater cell spreading and protein secretion compared to cells in the unmodified HA hydrogel. A pre-culture period allowing strong adhesion of the cells to the modified hydrogel was shown to improve cell survival under conditions that mimic the myocardium post-MI. This finding may have a significant impact on the use and timelines of modifications to improve stem cell survival in harsh environments like the injured heart.

Abstract Image

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在rgd修饰的透明质酸水凝胶中预培养间充质干细胞可提高其对缺血条件的恢复能力

在生物材料中掺入RGD肽(精氨酸-甘氨酸-天冬氨酸)可以促进细胞与基质的粘附，从而影响和控制细胞的行为和功能。虽然许多研究利用RGD修饰的生物材料进行细胞递送，但很少有研究在缺血损伤部位发现的缺氧和营养减少的情况下检测其效果。在这里，我们系统地研究了RGD在标准和缺血培养条件下对透明质酸(HA)水凝胶中的hMSCs的影响，以阐明在什么条件下RGD比未修饰的HA有有益的作用，以及它在提高细胞活力方面的有效性。结果表明，在标准培养条件下，与未修饰的HA水凝胶相比，RGD显著增加了hMSC的扩散和血管内皮因子-1 (VEGF)和单核细胞化学引诱因子-1 (MCP-1)的释放。由于已知黏附会影响细胞存活，我们假设RGD水凝胶中的细胞在缺血培养条件下会表现出更高的细胞活力。然而，结果表明，RGD修饰和未修饰的HA水凝胶的细胞活力和蛋白质释放是相当的。共聚焦成像显示细胞形态显示弱细胞粘附。随后的研究发现，RGD可以在缺血条件下对被包被细胞产生积极作用，但前提是在标准条件下对hMSCs进行预培养，使其在暴露前与RGD有很强的粘附性。总之，这些结果为引入RGD的价值提供了新的见解，并表明分娩前hMSCs与RGD的粘附可以改善缺血损伤部位的存活和功能。开发一种既能维持细胞活力又能促进细胞功能的生物材料支架是心脏组织工程领域的主要研究目标。本研究证实了改性透明质酸水凝胶的适用性，即与未改性透明质酸水凝胶中的细胞相比，改性水凝胶中的干细胞表现出更大的细胞扩散和蛋白质分泌。在模拟心肌心肌梗死后的条件下，培养前允许细胞与改性水凝胶的强粘附被证明可以提高细胞存活率。这一发现可能对改善干细胞在恶劣环境(如受伤的心脏)中的存活率的使用和修改时间表产生重大影响。

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

Acta Biomaterialia 工程技术-材料科学：生物材料

CiteScore

16.80

自引率

3.10%

发文量

776

审稿时长

30 days

期刊介绍： Acta Biomaterialia is a monthly peer-reviewed scientific journal published by Elsevier. The journal was established in January 2005. The editor-in-chief is W.R. Wagner (University of Pittsburgh). The journal covers research in biomaterials science, including the interrelationship of biomaterial structure and function from macroscale to nanoscale. Topical coverage includes biomedical and biocompatible materials.